MON2000 Software for Gas Chromatographs User Manual Applies to Both: Daniel Danalyzer On-Line Gas Chromatographs Rosemount Analytical Process Gas Chromatographs Part Number 3-9000-522 Revision R JULY 2010
MON2000 Software for Gas Chromatographs Manual NOTICE DANIEL MEASUREMENT AND CONTROL, INC. AND ROSEMOUNT ANALYTICAL (COLLECTIVELY, “SELLER”) SHALL NOT BE LIABLE FOR TECHNICAL OR EDITORIAL ERRORS IN THIS MANUAL OR OMISSIONS FROM THIS MANUAL.
WARRANTY 1. LIMITED WARRANTY: Subject to the limitations contained in Section 2 herein and except as otherwise expressly provided herein, Daniel Measurement and Control, Inc. and Rosemount Analytical, (collectively“Seller”) warrants that the firmware will execute the programming instructions provided by Seller, and that the Goods manufactured or Services provided by Seller will be free from defects in materials or workmanship under normal use and care until the expiration of the applicable warranty period.
IMPORTANT INSTRUCTIONS • Read all instructions prior to installing, operating, and servicing this product. • Follow all warnings, cautions, and instructions marked on and supplied with this product. • Inspect the equipment packing case and if damage exists, notify your local carrier for liability. • Open the packing list and carefully remove equipment and spare or replacement parts from the case. Inspect all equipment for damage and missing parts.
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TABLE OF CONTENTS INTRODUCTION INSTALLATION AND SETUP 1.1 Description of Manual ....................................1-1 Section 1 – Introduction ................................1-1 Section 2 – Installation and Startup .................1-2 Section 3 – Getting Started ............................1-2 Section 4 – Control Functions.........................1-2 Section 5 – Application Functions ...................1-3 Section 6 – Chromatogram Viewer ..................1-3 Section 7 – Reports......................
ii TABLE OF CONTENTS MON2000 2.8.1 The Initial Logon ......................................... 2-18 2.8.2 Registering MON2000 ................................. 2-19 2.8.3 Update MON2000....................................... 2-21 2.9 Checklist for Setting Up MON2000 ............... 2-22 2.10 Communications ......................................... 2-22 2.10.1 Connect to the GC Unit ............................... 2-22 2.10.2 Disconnect from GC Unit ............................. 2-23 2.
TABLE OF CONTENTS MON2000 iii 2.17 Downloading an Application ......................... 2-72 2.18 Upgrading Flash .......................................... 2-75 2.19 Offline Edit of GC Application ....................... 2-76 2.19.1 File Selection .............................................. 2-77 2.19.2 Upload Application ...................................... 2-78 2.19.3 Upload BOS................................................ 2-81 GETTING STARTED CONTROL FUNCTIONS JULY 2010 3.
iv TABLE OF CONTENTS APPLICATION FUNCTIONS Application Functions MON2000 4.4 Calibration.................................................... 4-4 4.5 Baseline Run................................................. 4-5 4.6 Auto BTU Start Up and Valve Timing............... 4-7 4.6.1 Initiating an Auto BTU Start Up Run ................ 4-7 4.6.2 Starting a Valve Timing Run ......................... 4-12 4.7 GC Time .................................................... 4-13 4.7.1 View GC Time ....
TABLE OF CONTENTS MON2000 v 5.5.3 User Defined .............................................. 5-25 5.6 Limit Alarms ............................................... 5-27 Limit Alarms Description .............................. 5-30 5.7 Discrete Alarms .......................................... 5-31 5.7.1 Delayed Discrete Alarms .............................. 5-33 5.8 Streams ..................................................... 5-38 5.9 Analog Inputs .............................................
vi TABLE OF CONTENTS MON2000 5.18.5 Setting Optional Base Pressures .................... 5-86 5.18.6 Setting Optional Base Results ....................... 5-90 CHROMATOGRAM VIEWER Chromatogram Viewer 5.19 TCP/IP, Subnet, and Gateway Menu .............. 5-94 6.1 Chromatogram Viewer Function ...................... 6-1 6.2 Viewing a Live Chromatogram ........................ 6-2 6.2.1 From Online GC ............................................ 6-2 6.2.2 From GC Archive ..........................
TABLE OF CONTENTS MON2000 REPORTS vii 7.1 Report Display ..............................................7-1 7.1.1 View Report from Live Data............................7-1 7.1.2 View Report from File ....................................7-4 7.1.3 Print Report ..................................................7-6 7.1.4 Save Report to Disk.......................................7-6 7.1.5 Report Contents............................................7-8 Analysis Report.................................
viii TABLE OF CONTENTS LOGS MON2000 PLUS DATA COLLECTION/AUTOPOLLING MON2000 8.1 Maintenance Log........................................... 8-1 8.2 Parameter List .............................................. 8-3 8.3 Alarm Log .................................................... 8-6 8.4 Clear or Acknowledge Active Alarms ............... 8-9 8.5 Event Log .................................................... 8-9 9.1 Overview ..................................................... 9-1 9.
TABLE OF CONTENTS MON2000 MODBUS TEST ix 9.3 Data Collection ........................................... 9-35 9.3.1 Start Auto-Sequencing................................. 9-36 9.3.2 Transaction Log .......................................... 9-38 9.3.3 Auto-Sequencing Status............................... 9-38 9.3.4 Status Log ................................................. 9-39 10.1 Starting WinMB .......................................... 10-1 10.2 Establishing Communications............
x TABLE OF CONTENTS MON2000 C.2 Peak Detection .............................................C-2 C.3 Analysis Computations ..................................C-5 C.3.1 Conc. Analysis with Response Factor ..............C-5 Calibration....................................................C-5 Calc. in Mole Percent w/o Normalization ..........C-7 APPENDIX D, ANALOG OUTPUT CAL. FOR 2350A APPENDIX E, UPGRADE 2350A GC S/W AND 2350 EPROMS C.4 Post Analysis Computations ...........................C-9 C.4.
TABLE OF CONTENTS MON2000 xi E.9 Connect to GC for Upgraded App. ................. E-18 E.10 Guide to Standard Application Files ............... E-19 E.10.1 Importance of Standard Application Files........ E-19 E.10.2 Standard Applications v1.50 and Later .......... E-20 E.10.3 Standard Applications Prior to v1.50 ............. E-22 APPENDIX F, MODBUS REG. LIST FOR 2350A GC JULY 2010 F.1 Introduction – SIM_2251 & User_Modbus ........ F-1 F.1.1 Notes on User_Modbus ...............................
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INTRODUCTION MON2000 1-1 INTRODUCTION Welcome to the MON2000 User Manual (P/N 3-9000-522), a user guide that accompanies the MON2000 software produced by Daniel Measurement and Control, Inc., a Division of Emerson Process Management. Use this manual for installing the MON2000 and Modbus Test (WinMB) software programs, getting started, checking various gas chromatograph (GC) application settings, and configuring and monitoring your GC system. 1.
1-2 INTRODUCTION MON2000 Section 2 – Installation and Startup This section includes: • short description of the MON2000 software • minimum system requirements for installing MON2000 on a 32-bit Microsoft® Windows® platform • installation and Startup instructions • establishing communications and Logon procedures • instructions for customizing MON2000 and setting up security • instructions for downloading an application and using the Offline Edit function to change an application’s configuration Section 3
INTRODUCTION MON2000 1-3 Section 5 – Application Functions This section includes: • description of available GC Application functions and detailed step procedures Section 6 – Chromatogram Viewer This section includes: • description of available Chromatogram Viewer functions and detailed step procedures to view, save, and print chromatograms Section 7 – Reports This section includes: • descriptions of available reports and sample outputs • instructions on how to generate and print a given report Section 8
1-4 INTRODUCTION MON2000 Section 9 – Data Collection This section includes: • descriptions of Data Collection and AutoSequencing • instructions on how to configure, generate and run the Data Collection and AutoSequencing function using MON2000 PLUS Section 10 – Modbus Test This section includes: • short description of the WinMB software • minimum system requirements for installing WinMB on a 32-bit Microsoft® Windows® platform • installation and start up instructions • description of available Modbus Tes
MON2000 INTRODUCTION 1-5 Appendix A, PC Config Report This appendix provides a sample PC Config Report for reference only. Appendix B, Component Data Table This appendix provides two sample Component Data Tables for reference only. Appendix C, Data Computations This appendix discusses the various equations and computations involved with acquisition and analysis tasks. Appendix D, Analog Output Cal.
1-6 1.2 INTRODUCTION MON2000 DESCRIPTION OF ONLINE HELP Use the User Guide online help file to quickly access information regarding any MON2000 function. See Section 3.8 for more detailed information. 1.3 DESCRIPTION OF MON2000 MON2000 is a menu-driven, Windows-based software program designed to operate the gas chromatograph (GCs). MON2000 runs on an IBM-compatible personal computer (PC) and serves as an interface between you and the GC unit.
INTRODUCTION MON2000 • • • • • • 1-7 diagnostics event sequences halt operations stream assignments and sequences valve activations timing adjustments Reports that can be generated by MON2000 per the GC application: • • • • • • • • • • 24-Hour Averages Analysis Calibration Final Calibration Hourly Averages Monthly Averages PC Configuration Raw Data Variable Averages Weekly Averages Logs that are maintained by MON2000: • • • • Alarm Log Event Log Parameter List Maintenance Log ______________________
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INSTALLATION AND SETUP MON2000 2-1 INSTALLATION AND SETUP This section lists the system requirements to run MON2000 and provides installation procedures as well as initial logon instructions, communications setup, and software configuration. 2.1 SYSTEM REQUIREMENTS To achieve maximum performance when running the MON2000 software, ensure your PC system contains the following hardware.
2-2 INSTALLATION AND SETUP - Windows® 98 version 1 or later - Windows® 2000 version 1 or later - Windows® XP version 1 or later (see note for system requirements) Windows® NT Server version 4 (service pack 3 or later) - MON2000 Use the Settings>Control Panel>System/>General Page menu to check the system version number. For Windows® 95, the version number should be 4.00.950A/B or later. For Windows® 98 or Windows® 2000, the version number should be 1 or later.
INSTALLATION AND SETUP MON2000 2.2 2-3 INSTALLING MON2000 To install MON2000, do the following: If you are upgrading MON2000, you must install the new software with same directory as the current version. 1. Either place the MON2000 CD in your CD-ROM drive or insert Installation Disk 1 into your floppy drive. 2. Launch Windows® Explorer® by either: • Clicking the button (see the taskbar) to access the Programs menu option. • Double-clicking the Windows® Explorer® icon on your desktop. 3.
2-4 2.3 INSTALLATION AND SETUP MON2000 INSTALLING THE CRYPKEY LICENSE SERVICE FOR MON2000 PLUS The CrypKey License Service must be installed on all NT-based systems. If you try to run MON2000 PLUS before installing the CrypKey License Service, an error will result. To install the CrypKey License Service, do the following: 1. After installing MON2000 PLUS, the program folder should display automatically; if it doesn’t, open Windows® Explorer® and access the MON2000 PLUS program folder. 2.
INSTALLATION AND SETUP MON2000 2-5 1. Label 3 blank formatted 3.5-inch floppy disks “MON2000 Install Disk 1”, “MON2000 Install Disk 2”, and “MON2000 Install Disk 3”. 2. Place the MON2000 CD in your CD-ROM drive. 3. Launch Windows® Explorer®. 4. Ensure that the Show all files option in Windows® Explorer® is selected. (a) Use the View > Folder Options menu to access the Folder Options dialog. (b) Click the View tab. (c) In the Advanced Settings pane, find the gray folder icon labeled Hidden Files.
2-6 INSTALLATION AND SETUP MON2000 7. Open the Disk1 folder on your CD. 8. Copy all files from the Disk1 folder to the “MON2000 Install Disk 1” floppy. 9. Remove the “MON2000 Install Disk 1” from your floppy drive. 10. Repeat Steps 5 through 8 to copy the Disk2 and Disk3 folders to your “MON2000 Install Disk 2” and “MON2000 Install Disk 3” floppy disks. 11. Remove the MON2000 CD from your CD-ROM drive. 2.
MON2000 INSTALLATION AND SETUP 2-7 2. Start MON2000 on the target computer. The License Configuration screen displays. 3. Select Transfer in from another computer... from the License menu.
2-8 INSTALLATION AND SETUP MON2000 Transfer License In (Step 1 of 3) screen displays. 4. Click Browse to select a disk path to the removeable storage medium that holds the license file. Click OK to accept your selection.
MON2000 INSTALLATION AND SETUP 2-9 5. Click Next. The Transfer License In (Step 2 of 3) screen displays. 6. Remove the removeable storage medium from the targeted computer and insert it into the source computer. 7. Launch MON2000 PLUS on the source computer. When the startup screen displays, press Enter.
2-10 INSTALLATION AND SETUP MON2000 Configuration screen displays with the message “Unlimited license”. 8. Select Transfer out to another computer...
MON2000 INSTALLATION AND SETUP 2-11 License Configuration screen. The Transfer License Out (Step 1 of 2) screen displays. 9. Click Browse to select a disk path to the removeable storage medium that holds the license file. Click OK to accept your selection.
2-12 INSTALLATION AND SETUP MON2000 10. Click Next. The Transfer License Out (Step 2 of 2) screen displays.
MON2000 INSTALLATION AND SETUP 2-13 11. Click Finish. MON2000 PLUS on the source computer is no longer licensed. 12. Remove the removeable storage medium from the source computer and reinsert it into targeted computer.
2-14 INSTALLATION AND SETUP MON2000 13. On the targeted computer, click Next on the Transfer License In (Step 2 of 3) screen. The Transfer License In (Step 3 of 3) screen displays.
INSTALLATION AND SETUP MON2000 2-15 14. Click Finish. The License Configuration screen displays. MON2000 PLUS is now licensed for unlimited use on the targeted computer. 2.6 UNINSTALLING MON2000 To uninstall MON2000 using Windows® 95, Windows® 98, Windows® 2000 or Windows® NT, 1. Click the JULY 2010 button (see the taskbar).
2-16 INSTALLATION AND SETUP MON2000 2. Click Settings and then Control Panel. The Control Panel dialog appears. 3. Double-click the Add/Remove Programs icon. If using Windows XP, click the Start button, then Add/Remove Programs. 4. The Add/Remove Program Properties dialog appears. 5. Select MON2000 and click the button.
INSTALLATION AND SETUP MON2000 2-17 6. Windows® displays the following confirmation dialog. 7. Click the button to continue. Windows® deletes the program files only. Any files shared by other programs or created by the user are not deleted. Click the button to abort and return to the Add/Remove Program Properties dialog. 2.7 STARTING MON2000 To start MON2000 after a successful installation, Use the Windows® Start menu (Start > Programs >MON2000 menu) by clicking the button.
2-18 INSTALLATION AND SETUP MON2000 Files\MON2000\MON2000 is the default setting. 2.8 PERFORMING YOUR FIRST LOGON 2.8.1 The Initial Logon Each new GC unit is shipped with one super user named “Emerson”. After logon, ensure that this user name appears in the Users list as a super user (see Section 2.11.1). To log on for the first time, 1. Start the MON2000 software program by clicking the desktop icon or by using the Windows® Start menu (see Section 2.7). 2. Click in the User Name data field. 3.
INSTALLATION AND SETUP MON2000 2-19 4. When you have successfully logged on, the MON2000 main window appears. 2.8.2 Registering MON2000 After your have successfully performed your initial logon (see Section 2.8.1), MON2000 automatically prompts you to register your copy of MON2000 software. An active Internet connection is required for registration. Registering your MON2000 software allows you to receive information about free updates and related products.
2-20 INSTALLATION AND SETUP MON2000 1. Use the File>Register MON2000 menu. Follow the prompts in the Register MON2000 dialog to input your name, MON2000 serial number (located inside the CD jewel case), and other relevant information. 2. Click the button to continue. 3. Choose the desired registration method by clicking the corresponding radio button. You must have an active internet connection to register via the website. 4. Click the Registering MON2000 button.
INSTALLATION AND SETUP MON2000 2.8.3 2-21 Update MON2000 Provided there is an active internet connection to the computer on which MON2000 is installed, clicking the File>Update MON2000 submenu sends the user to the Emerson® Chromatograph Controllers website (www.emersonprocess.com/daniel/products/GC/ Controllers/Productdetail.htm). Updating the software requires a previously installed, registered copy of MON2000.
2-22 2.9 INSTALLATION AND SETUP MON2000 CHECKLIST FOR SETTING UP MON2000 To ensure optimum performance, • Configure your system security (see Section 2.11.1). Verify that you have assigned a password to the super user, and/or created a secure system Admin account. • Configure how MON2000 will save your analytic and diagnostic information (see Section 2.16.2). • Establish communications between MON2000 and the GC unit (see Section 2.10 and Section 5.17). 2.
MON2000 INSTALLATION AND SETUP 2-23 3. MON2000 appears the connection status dialog while dialing the selected unit. If another user is already connected to the GC, the unit will “lock out” the second user. When a PC connection is active, the GC Controller front panel will indicate a “System Lockout”. This status times out after 10 minutes. The messages “Reading dictionary”, “Reading GC Application data”’ and “Logon” appears in the status bar and an information screen appears.
2-24 INSTALLATION AND SETUP MON2000 A Terminating communications message appears in the status bar. If MON2000 does not detect an active connection to terminate, an “Invalid selection or not downloaded” message appears. 2.11 CUSTOMIZING MON2000 Use the following functions to customize users, the directory of GC applications, and PC communications parameters. 2.11.1 Configure Users Use this function to create new user accounts or edit the existing account data.
MON2000 INSTALLATION AND SETUP 2-25 users access to the MON2000 Users submenu, which allows Super users to add, edit, or change security levels. Click the dialog appears. button. Then the Users 3. Use the File>Change Administrator menu to change the Administrator password. The Change Administrator Password dialog box appears. Insert the old password, enter the new password and confirm the change. Then, click the your changes.
2-26 INSTALLATION AND SETUP MON2000 4. To configure a new user or edit existing user parameters, (a) Click the appropriate Name cell and type Super users can write changes the desired user name. to the GC unit, configure Note that the user name is not caseMON2000, and access the sensitive but punctuation (e.g., commas Users function. or spaces) is preserved. Regular and Read only users (b) Click the appropriate Type cell and use the provided combo box to select the desired security level.
MON2000 INSTALLATION AND SETUP 2-27 2.11.2 Set Up GC Directory Do not delete any currently used applications from the GC Directory. If an entry is inadvertently deleted, you may need to reinstall the application software for that GC. This function allows you to set up a directory listing of all GC units MON2000 can control for this application. From the GC Directory, you can configure the PC serial port communication parameters for a specific GC unit.
2-28 INSTALLATION AND SETUP MON2000 3. Press the F1 key to open the MON2000 Application help file for detailed information about these settings. 4. MON2000 is configured with two default directories: • Default 1: parameters are set for 9600 baud rate 5. Default 2: parameters are set for 19200 baud rate. 6.
MON2000 INSTALLATION AND SETUP 2-29 GC Controller system interface board) for the GC unit. To successfully connect to the GC unit, the COM IDs specified via the File>GC Directory and the Application>Serial Ports dialogs must match. See Section 5.17.1 for more information. 7. Click the Comments cell to enter any helpful information regarding a particular GC unit, such as location or purpose. 8.
2-30 INSTALLATION AND SETUP MON2000 pull-down menu for a “Direct Connect” option or a previously configured modem. 2.11.3 Dial-up Connection Use this command to run the Dial-up dialog to configure the GC Controller modem. The default properties from Windows® Control Panel are used so you must ensure that the modem connects at the GC Controller’s configured baud rate. It may be necessary to enter a modem initialization string.
MON2000 INSTALLATION AND SETUP 2-31 3. The Modem Properties dialog appears and the General Data Connection Modem Preferences are activated.
2-32 INSTALLATION AND SETUP MON2000 4. Click the Advanced tab to configure the Hardware settings. The Advanced Data default settings are: Table 2-2 Advanced Data Connection Preferences Data Bits 8 Parity None Stop Bits 1 5. Click the button to apply your changes, or click the button to discard the changes and return to the GC Directory dialog.
INSTALLATION AND SETUP MON2000 2-33 6. Next, from the GC Directory dialog, scroll over to configure the following parameters: The Baud Rate, Data Bits, and Stop Bits parameters were configured above.
2-34 INSTALLATION AND SETUP MON2000 The Extra Delay is enabled for Ethernet connections. The default value is “0” and the default 30 seconds timeout is used. If the value is changed to greater than “0”, the value is used as the timeout. The entered value is multiplied by 10 inside MON2000, therefore the maximum timeout is 100,000 ms or 100 seconds (ex: If timeout value needs to be 15 seconds, the user should enter 1,500).
MON2000 INSTALLATION AND SETUP 2-35 7. Click the button to accept the changes. While connecting, MON2000 dials the number, attempts to connect via the selected modem and displays progress messages. A message box appears when a connection has been made or if the attempt to connect fails. Once a connection has been established and while MON2000 remains connected via the modem, the Connect button is disabled and the Disconnect button is enabled.
2-36 INSTALLATION AND SETUP MON2000 2.11.4 Modem Initialization Strings/Setup This section provides “examples” of modem initialization strings and setups that have been tested and proven operable. This string of text characters, known as 'AT commands', has special meaning to the PC modem and is used by the modem for every telephone connection made to a selected GC unit.
MON2000 INSTALLATION AND SETUP 2-37 By default, MON2000 provides a modem initialization string that serves the purpose for most Hayes-compatible modems. Therefore, in most cases, you need not enter a different string. However, for some modems, you may want to consult the following pages which document initialization strings and modem setups that have been field-tested. The default initialization string that MON2000 provides is sent to the PC modem first.
2-38 INSTALLATION AND SETUP MON2000 Interpretation of the AT commands for that particular modem was as follows: • \N0 = normal mode; no error control; data is buffered (versus ‘direct mode,’ ‘reliable mode, ’or ‘auto reliable mode’) • \C0 = disable auto reliable buffer (versus ‘buffer data for 4 seconds or 200 characters’) • \Q0 = disable flow control (versus ‘enable XON/XOFF flow control,’ ‘enable unilateral CTS flow control,’ or ‘enable bilateral CTS/ RTS flow control’) U.S.
INSTALLATION AND SETUP MON2000 2-39 With these switch settings, initialization string &F was required. See Table 2-4 for further explanation of these switch settings and the parameters they control. Table 2-4 DIP Switch Settings for U.S. Robotics Sportster Modem Switch Function 1 UP (off) – Normal DTR; computer must provide DTR signal for modem to accept commands. At GC At PC DOWN (on) – Modem ignores DTR. 2 UP (off) – Verbal (word) results. DOWN (on) – Numeric results.
2-40 INSTALLATION AND SETUP MON2000 GVC/MaxTech 28.8 Kbps Modem The following setup for GVC 28.8 Kbps external Voice/Data/FAX modems was verified at Daniel Canada. At the GC Controller: To make these settings for the modem at the GC Controller, you will need to use a terminal program (such as ProComm o other commercial modem software) to input the “AT” commands to the modem before connecting it to the GC Controller. AT&F5 Factory default with v.42bis flow control disabled (must be first).
INSTALLATION AND SETUP MON2000 2-41 At the PC, use &F5%C1M0 which indicates a factory default with v.42bis flow control disabled / compression ON / speaker OFF. 2.12 2350 TO 2350A RETROFIT INSTRUCTIONS The 2350A GC Controller CPU assembly has been designed to include all digital I/O and COM3 and COM4 serial ports. This eliminates the requirement (and additional cost) for an I/O assembly or DSPI/O assembly. In addition, BOS is now resident in the DiskOnChip, instead of an EPROM set.
2-42 INSTALLATION AND SETUP MON2000 The PC/104 Bus is designed to allow any combination of option boards to be installed in any order, with the exception of the CSA approved Radicom modem board which must be the top board in the assembly. (see Figure 2-1). Figure 2-1 2350A Controller Card Cage Assembly If you are using the CSA approved Radicom modem; ensure that it is the top card in the card cage assembly.
INSTALLATION AND SETUP MON2000 2.13 2-43 CONVERSION PROCESS Use the following process to retrofit a 2350 GC Controller to a 2350A GC Controller. 1. At the GC Controller site, remove the Controller enclosure's front panel. SERIOUS PERSONAL INJURY OR DEATH POSSIBLE Before removing the unit cover from the GC Controller, make certain the power supply switch is OFF and the AC power cord is disconnected. Observe all safety precautions when you are working in a hazardous environment.
2-44 INSTALLATION AND SETUP MON2000 4. Lower the TB down and out of the way, held in place by its ground straps at the bottom of the board. This exposes the Card Cage Assembly. 5. Loosen the four screws that secure the Card Cage Assembly to the chassis. Then remove the Card Cage Assembly away from its chassis mount so that it is easy to work on. 6. Locate the System Interface and Driver board. It is mounted to the top of the Card Cage Assembly. 7.
INSTALLATION AND SETUP MON2000 2-45 10. Remove the DSPI/O board assembly (drawing P/N CE-12976) and cables from the third slot of the card cage assembly. This board is not used on the 2350A GC Controller. 11. Remove any other optional boards, such as memory expansion boards and associated cables. These parts are not used on the 2350A GC Controller. 12. Leave the Analog Board assembly (drawing P/N BE-18044) with attached cable in the card cage. This board is used on the 2350A basic configuration. 13.
2-46 INSTALLATION AND SETUP MON2000 (a) Then carefully lower the front panel on its bottom hinges. The front panel is heavy, so make sure it does not drop and cause damage. The DIP switch is located on the lower left side of the front panel (see Figure G-2).
MON2000 INSTALLATION AND SETUP 2-47 17. For rack mount and panel mount Controllers, use a flat head screw driver to remove the access panel on the right side of the card cage assembly (see Figure 2-3). Figure 2-3 Right Side View Rack and Panel Mount Units 18. Inspect or change the DIP switch settings as necessary. (a) See Table 2-5 as a guide. (b) Make sure you record in the GC Controller's maintenance records any changes you make to the switch settings.
2-48 INSTALLATION AND SETUP MON2000 • Switch "6" is a spare for future use. Switches "7" and "8" are set as needed for the presence of an optional LOI (Local Operator Interface) connected via COM8 When the COM4A Board is installed. If the COM4A Board is not installed, the LOI is connected via COM4.
INSTALLATION AND SETUP MON2000 2.14 2-49 BASIC 2350A CONFIGURATION At this point, install, if any, all mounting hardware and optional PC/104 boards onto the 2350A CPU Board. 1. Install the 2350A CPU (P/N 3-2350-090) into slot 3 of the card cage assembly. 2. Install cables on the CPU Board in the following sequence: (a) Digital I/O cable (P/N 3-2350-081) from CPU J7 to the System Interface Board J2. (b) Digital I/O cable (P/N 3-2350-080) from CPU J4 to the System Interface Board J3.
2-50 INSTALLATION AND SETUP MON2000 The serial port setup in the MON2000 Software for COM4 must be selected as Front Panel (see Figure 2-4). If all four serial ports are required for communications on a system with keyboard and display, an optional COM4A Board must be installed and a COM7 and COM8 cable (P/N 3-2350-086) connected (see Figure 2-5). The serial port setup in the MON2000 Software for COM8 must be configured as Front Panel. See Figure G-4b.
MON2000 INSTALLATION AND SETUP 2-51 Figure 2-4 Serial Port 4 with COM4A Board Figure 2-5 Serial Port 8 with COM4A Board JULY 2010 BASIC 2350A CONFIGURATION
2-52 2.15 INSTALLATION AND SETUP MON2000 2350A OPTIONS The following board configurations are optional for the Model 500 GC with 2350A Controller. 2.15.1 The COM4A Board 1. To add four additional communications ports at the GC Controller site, remove the Controller enclosure's front panel. SERIOUS PERSONAL INJURY OR DEATH POSSIBLE Before removing the unit cover from the GC Controller, make certain the power supply switch is OFF and the AC power cord is disconnected.
MON2000 INSTALLATION AND SETUP 2-53 4. Lower the TB down and out of the way, held in place by its ground straps at the bottom of the board. This exposes the Card Cage Assembly. 5. Loosen the four screws that secure the Card Cage Assembly to the chassis. Then remove the Card Cage Assembly away from its chassis mount so that it is easy to work on. 6. Locate the System Interface and Driver board. It is mounted to the top of the Card Cage Assembly.
2-54 INSTALLATION AND SETUP MON2000 (i) Install the ten position connector from COM8 to J12 on the System Interface Board. (j) Connect the Analog cable to J6 on the System Interface Board. With COM4A Boards installed, Serial Port 8 is usually assigned via MON2000 Application>Serial Ports menu. Select Front Panel from the Usage pull-down menu (see Figure 2-6 and Figure 2-7).
MON2000 INSTALLATION AND SETUP 2-55 2.15.2 2350A Modem Installation To install the Internal Modem for the 2350A GC Controller, follow these steps: Refer to P/N 3-9000-537 2350A GC Hardware manual for COM settings and pinouts. 1. To add a modem, at the GC Controller site, remove the Controller enclosure's front panel. (a) For the explosion-proof Controller, the front panel is secured by 16 screws. Remove those screws first. (b) Then carefully lower the front panel on its bottom hinges.
2-56 INSTALLATION AND SETUP MON2000 5. Loosen the four screws that secure the Card Cage Assembly to the chassis. Then remove the Card Cage Assembly away from its chassis mount so that it is easy to work on. 6. Locate the System Interface and Driver board. It is mounted to the top of the Card Cage Assembly. (a) Disconnect the Analog cable from J6 on the System Interface Board, then disconnect all CPU cables from the System Interface Board.
INSTALLATION AND SETUP MON2000 2-57 (c) Plug one end of the modem extension cable (P/N 3-2350-075) into J1 of the modem assembly. The in-line jack on the remaining end of the modem extension cable attaches to the lower left inside wall of the card cage shield (after the CPU assembly is reinstalled and all cables reconnected to the System Interface board). No software setup is required for this board. 7.
2-58 INSTALLATION AND SETUP MON2000 2.15.3 2350A Ethernet Installation To add an ethernet assembly: 1. To add an ethernet card at the GC Controller site, remove the Controller enclosure's front panel. (a) For the explosion-proof Controller, the front panel is secured by 16 screws. Remove those screws first. (b) Then carefully lower the front panel on its bottom hinges. The front panel is heavy, so make sure it does not drop and cause damage.
MON2000 INSTALLATION AND SETUP 2-59 5. Locate the System Interface and Driver board. It is mounted to the top of the Card Cage Assembly. (a) Disconnect the Analog cable from J6 on the System Interface Board, then disconnect all CPU cables from the System Interface Board. (b) Remove the CPU assembly and install the COM4A Board, with associated mounting hardware to J19 and J20 PC/ 104 Bus connector on the CPU assembly.
2-60 INSTALLATION AND SETUP MON2000 No software setup is required for this board. Table 2-7 System Interface Board Cable Connections Connection Ribbon Cable J5 and J6 Analog I/O J8 Com3 J10 Com4 J4 Printer J11 Com2 J2 and J3 Digital I/O J12 Front Panel and Keyboard (if installed) Table 2-8 CPU Board Cable Connections Connection Ribbon Cable J1 Com1, Com2, and Printer J4 and J7 Digital I/O J6 Com3 and Com4 (a) If the 2350A BOS version is v1.
MON2000 INSTALLATION AND SETUP 2-61 Figure 2-9 Ethernet Jumper Configuration BOS v1.82 and Earlier Figure 2-10 Ethernet Jumper Configuration BOS v1.
2-62 INSTALLATION AND SETUP MON2000 2.15.4 Ethernet TCP/IP Settings If you plan to connect via an Ethernet connection, use the following instructions. To configure the Ethernet TCP/IP settings for the 2350A GC Controller: 1. Obtain the IP Address, Subnet Mask, and Gateway addresses (numbers) for the Target 2350A GC Controller from your supervisor or Information Technology Department.
INSTALLATION AND SETUP MON2000 2-63 6. In the Subnet Mask field, enter the subnet mask address (number) obtained from your Supervisor or the Information Technology Department. 7. In the Gateway Address field, enter the Gateway Address (number) obtained from your Supervisor or the Information Technology Department. 8. Click the changes. button to apply all 9. Disconnect from the controller, using the toolbar icon or by using the File>Disconnect menu.
2-64 INSTALLATION AND SETUP MON2000 2.15.5 MON2000 TCP/IP Settings To configure the Ethernet TCP/IP settings for the MON2000, 1. From the File menu, select GC Directory. 2. Ensure that an Ethernet location has been created or an existing location modified and that an Ethernet card installed in the PC has been selected in the field labeled Connection Type (Direct/Remote).
INSTALLATION AND SETUP MON2000 2-65 3. Enter the same 'IP Address' into the Server Name/IP Address field of the GC Directory that was previously entered in the GC Controller (see Section 2.11.2). 4. Set the number of retries to three. Click the changes.
2-66 2.16 INSTALLATION AND SETUP MON2000 CONNECT VIA GC EXTERNAL MODEM Ensure you have a pre-existing PC connection to the GC unit before installing the external modem. If the GC unit is already on location, do this via another remote operator connection, or, onsite, via use of a portable PC and serial cable. Ideally, configure the GC unit and install the external modem prior to placement at the remote location. Note: You cannot set the Serial Ports parameters from the GC unit front panel.) 2.16.
MON2000 INSTALLATION AND SETUP 2-67 4. Connect a custom-made serial line cable (for RS-232 serial transmission) from the serial port of the external modem to an available serial port on the GC Controller Terminal Board for field wiring. Special hardware modifications may be needed when operating an external GC modem from the GC serial ports 3 or 4 (COM3 or COM4), as follows: • DE-20782 (see drawing addendum of Model 500 Gas Chromatograph System Hardware Reference Manual, P/N 3-9000-537).
2-68 INSTALLATION AND SETUP MON2000 2.16.2 Select Program Settings This function allows you to configure where database, GC applications, and Modbus Test program files are stored. 1. Use the File > Program Settings menu to access this function. 2. The Program Settings dialog appears. 3. To use a Chromatogram file extension other than the default (e.g. .
INSTALLATION AND SETUP MON2000 2-69 4. Use the provided check boxes to turn the following settings on/off. Note that the default settings are ON. Table 2-9 Optional Program Settings Setting Function Editing replaces existing text in tables If enabled, replaces selected table cell entry with user input. If disabled, appends user input to end of the selected table cell entry. Prompt to confirm discard changes Display confirmation dialog before exiting a dialog that contains changed data.
2-70 INSTALLATION AND SETUP MON2000 2.16.3 Generate PC Config Report This function allows you to generate or print out a report of the currently active GC application control settings. See Appendix A for a sample print-out of a PC Config Report. Output data for the PC Config Report depends on the GC Controller and its application. To view a PC Config Report already saved to disk, see Section 7.1.2. 1. Use the File > PC Config Report menu to access this function. The PC Config Report dialog appears. 2.
MON2000 If you want to use the standard Windows® Print dialog to select a printer, deselect the Use default printer option. INSTALLATION AND SETUP 2-71 3. Use the Output radio buttons to either save the report to disk, print the report with or without form feeds, or display the report via the report viewer (see Section 7.1). The File option will open the Save As dialog, with CONFIG.TXT as the default file name.
2-72 2.17 INSTALLATION AND SETUP MON2000 DOWNLOADING AN APPLICATION This function allows the MON2000 operator to download applications to GC Controllers. GC applications with the .APP extension can only be down loaded to 2350A GC Controllers and Model 700 units. The Download feature is NOT available if the keylock switch is closed. At the end of the download process, MON2000 displays the Set GC Time dialog, which allows you to accept or change the GC Controller's date and time.
MON2000 INSTALLATION AND SETUP 2-73 2. Click the desired .app file. The file name appears in the File name data field. GC application files contain all control settings and application program functions (see Section 5) specific to a particular GC Controller. For 2350A GC Controllers and the Model 700 controller, application files (.app files) are normally stored in the \GC\APP directory. 3. Click the button to download the selected application file to the connected GC unit.
2-74 INSTALLATION AND SETUP MON2000 Table 2-10 Main Menu Function Keys Enabled by Download Key Function Description F1 Help Access context-sensitive online help. F2 Start Auto Sequence Initialize the Auto-Sequencing function. This function is also available via the Control > Auto Sequence menu. F3 Halt Stop a function at the end of the current cycle. This function is also available via the Control > Halt menu. F5 Edit TEVs Display the Timed Event Tables.
INSTALLATION AND SETUP MON2000 2.18 2-75 UPGRADING FLASH Use this function to download a BOS file to a connected GC Controller. Only download a BOS file when upgrading the GC firmware or after the GC unit has been out of service. You must first connect to the GC to use the Upgrade Flash function. 1. Use the File > Upgrade Flash menu to access the Select BOS File To Download dialog. 2. Click the desired BOS file. The file name appears in the File name data field. 3.
2-76 2.19 INSTALLATION AND SETUP MON2000 OFFLINE EDIT OF GC APPLICATION Use this function to edit a GC application file that is saved on disk or has been downloaded (and is currently on, or being used by, the GC unit). When selecting Offline Edit, you can choose either: • File Selection – Allows you to edit a GC application file stored on disk. • Upload Application – Allows you to upload the current GC application data from the GC Controller and save to file for future editing.
INSTALLATION AND SETUP MON2000 2-77 2.19.1 File Selection This function allows you to edit a GC application file stored on disk. 1. Use the File > Offline Edit > File Selection menu to access this function. The Open GC Application File dialog appears. Using the directory tree, select the desired application file. The GC application files (.APP) are normally stored in the \GC\App directory. JULY 2010 2. Click the button. 3.
2-78 INSTALLATION AND SETUP MON2000 Note that the application file name is displayed in the GC status dialog and the File Edit mode (i.e., Offline Edit) is displayed in main screen titlebar. When you have finished editing this file, you can download it to the GC Controller (see Section 2.17) or save for future use. 2.19.2 Upload Application This function allows you to upload the application from an online GC Controller to a disk file and edit that file.
MON2000 INSTALLATION AND SETUP 2-79 3. The Save Uploaded GC Application File menu appears. Use this dialog to choose the directory and file name or create a special file name for this particular application upload. Click the button. 4. MON2000 displays the message “Uploading C:\GC\APP\2350A.app” in the progress status bar. MON2000 continues with the upload process and displays the message, “Uploading Segment 1 (through segment 15)” in the status bar and a progress bar appears.
2-80 INSTALLATION AND SETUP MON2000 MON2000 prompts you to save the parameters file. 5. The Save Parameter File dialog appears. Use this dialog to choose the directory location and file name or create your own parameter file name. Click the button to continue. 6. MON2000 saves the parameter data to the selected directory. When the upload is complete, your connection to the GC unit is automatically terminated. 7. You are now viewing the uploaded application file off-line.
INSTALLATION AND SETUP MON2000 2-81 2.19.3 Upload BOS When connected to the GC, this function allows you to upload the current BOS (i.e., firmware) file from the GC Controller to save for future download (see Section 2.18). 1. Use the File > Offline Edit > Upload BOS menu to access this function. 2. The Save Uploaded GC BOS File dialog appears. By default, GC BOS files are stored in C:\GC\APP folder.
2-82 INSTALLATION AND SETUP 3. Use this dialog to choose the directory location and file name or create a file name for this particular upload. Click the button to continue. The message: “Uploading C:\GC\APP\2350A.bos” appears in the status bar and a progress bar appears. 4. MON2000 begins to upload the BOS to the selected file. When the upload is complete, normal MON2000 operations resume. Upload BOS MON2000 MON2000 will not perform a BOS upload during an analysis run.
GETTING STARTED MON2000 3-1 GETTING STARTED 3 This section shows you how to get started with the MON2000 software, covering such functions as logging on, navigation, and configuring your PC printer for MON2000. 3.1 LOGGING ON To log on, 1. Start the MON2000 software program by clicking the desktop icon or using the Windows® Start menu (see Section 2.7). 2. Click the User Name data field and type your assigned user name (up to 12 characters).
3-2 GETTING STARTED MON2000 3. If required, click the User PIN data field and type your assigned PIN. If you enter an incorrect user name or user PIN, a error message appears: Click the to the Logon dialog. button to exit and return 4. When you have successfully logged on, the MON2000 main window appears.
GETTING STARTED MON2000 3.2 3-3 LOGGING OFF To log off, Ensure that you exit the MON2000 program and shut down Windows before powering off the PC. 1. Disconnect from the GC unit (see Section 2.10.2). 2. Exit the MON2000 program by • using the File > Exit menu • pressing the ESC key • clicking the 3.3 button MON2000 USER INTERFACE Use the following sections to familiarize yourself with the MON2000 user interface.
3-4 3.3.1 GETTING STARTED MON2000 Main Window The MON2000 main window typically looks like this: titlebar, with connection data GC Status bar view area toolbar menu bar MON2000 Status bar Use the available menus, icons (see toolbar area and Section 3.3.4), and function keys (see Section 3.4) to access the desired functions.
GETTING STARTED MON2000 3.3.2 3-5 GC Status Bar The status bar appears across the bottom of the application window. To display or hide the status bar, click the Status Bar command using the View menu (ALT + V, G). Access this menu command from the View menu (ALT+ V, S) to display and hide the GC Status Bar, which displays the following: • • • • • • • • • • GC - name of the GC currently online Alarm status (Unacknowledged) Detector number Mode (e.g.
3-6 GETTING STARTED MON2000 The right areas of the status bar indicate which of the following keys are activated: Indicator Description CAP the Caps Lock key is ON. NUM the Num Lock key is ON SCRL the Scroll Lock key is ON Your connection status is also displayed in the titlebar. If “Online Edit” appears, then MON2000 is connected to the GC and is recognizing the existing application. If “Connected” appears, then MON2000 is connected to the GC but does not recognize the existing application.
GETTING STARTED MON2000 3-7 The GC Status bar consists of: Item Description GC GC unit to which MON2000 is currently connected A status flag indicates an active alarm, an unacknowledged alarm, or the File Edit mode (offline editing). Det # detector monitoring the alarm status of the currently connected GC A GC unit can have up to 2 detectors.
3-8 3.3.3 GETTING STARTED MON2000 View Menu Use the View menu to toggle (i.e., switch ON or OFF) which main window component you wish to view. See Section 3.3.1 for an identification and definition of each component. 3.3.4 ToolTips To view a ToolTip, move the mouse cursor to the Toolbar icon you want identified. MON2000 displays the ToolTip for five seconds. 3.3.
GETTING STARTED MON2000 3.3.6 3-9 Shortcut to Save or Print Data From any active dialog, right-click the displayed data to access this menu. Microsoft Internet Explorer 5.0 (or later) is required to view a spreadsheet file saved in HTML format. Choose the Save Sheet option to save data to disk or the Print Sheet option to queue data to your PC printer. MON2000 prints the report to your configured printer (see Section 3.7). 3.
3-10 GETTING STARTED MON2000 Table 3-1 Frequently Used Keystrokes (Continued) Keystroke Action SPACE Toggle settings (via radio buttons or check boxes). TAB Move to next control element (e.g., button) in window; use File > Program Settings (see Section 2.16.2) to use TAB key to move to next data field. Table 3-2 Application-Specific Function Keys Function Key Action F2 Start Auto Sequence These keystrokes are available from the main menu only.
GETTING STARTED MON2000 3.5 3-11 PROCEDURES GUIDE Use the following table to look up the related manual section and menu (and keystroke) for a given procedure. Table 3-3 Menu and Manual Section per MON2000 Procedure Task or Data Item Section(s) Menu [Keystroke] 24-Hour Average, component(s) measured 5.5.2 Application > Calculations > Averages alarms, related components 5.2 5.6 5.7 5.
3-12 GETTING STARTED MON2000 Table 3-3 Menu and Manual Section per MON2000 Procedure (Continued) Task or Data Item Section(s) Menu [Keystroke] communications baud rate, at PC 2.11.3 File > (COM ID) component code and name 5.2 Application > Component Data [F6] component full scale (for output) 5.1 5.10 Application > System (CGM Analog Output Config and Baseline Offset) Application > Analog Outputs component(s) programmed for input 5.9 5.
GETTING STARTED MON2000 3-13 Table 3-3 Menu and Manual Section per MON2000 Procedure (Continued) Task or Data Item Section(s) Menu [Keystroke] existing alarm(s) 8.3 Log > Alarm Log full-scale value (for input) 5.9 Application > Analog Inputs GPM liquid equivalent (on/off) 5.5.1 Application > Calculations > Control height or area measurement method 5.2 Application > Component Data [F6] High Alarm 5.6 Application > Limit Alarms (Analyzer) I.D. 2.11.2 5.
3-14 GETTING STARTED MON2000 Table 3-3 Menu and Manual Section per MON2000 Procedure (Continued) Task or Data Item Section(s) Menu [Keystroke] Rolling Average, component for 5.5.2 Application > Calculations > Averages Rolling Average, number of analyses 5.5.2 Application > Calculations > Averages Rolling Average, stream number(s) 5.5.2 Application > Calculations > Averages Spectrum Gain 5.3 Application > Timed Events [F5] stream number(s) (for output) 5.6 5.7 5.10 5.
GETTING STARTED MON2000 3.6 3-15 KEYLOCK SWITCH CONTROL If your GC unit has the keylock control enabled, you will not be able to write changes or new data to the GC Controller. The following error dialog will display. To see which Modbus registers are affected by the keylock control, view the Communications section of the PC Config Report via the Report Viewer (see Appendix A for instructions and an example).
3-16 GETTING STARTED MON2000 The stream sequences can be changed in the System dialog box. (GC applications version 1.7 and above.) • Automatic calibration in the Analog Outputs dialog box • Report display • GC report request (GC applications version 1.7 and above) • MON2000 printer control (GC applications version 1.7 and above) • View archive data • Trend data • Maintenance Log editing (GC applications version 1.
GETTING STARTED MON2000 3-17 2. The Printer Setup dialog appears. 3. Use the provided data fields, radio buttons, check and combo boxes to select the desired settings. Your configuration will be cleared (i.e., the settings will return to the default values) when you exit MON2000. Click the button to configure more advanced settings. Refer to the printer operator manual for more information. 4. Click the printer. button to queue the Click the button to abort and return to the main window.
3-18 3.8 GETTING STARTED MON2000 USING ONLINE HELP Currently, the online help feature contains all user information and instructions for each MON2000 function as well as the MON2000 system. To access the MON2000 Application Help file, • Press the F1 key at any time to view help topics that discuss the currently active dialog or function. • Use the Help > Help Topics menu to view the help contents dialog. Use the scroll bars and arrows to display more of a topic.
GETTING STARTED MON2000 3.9 3-19 OPERATING MODES FOR MODEL 700 The Model 700 GC supports four different operating modes. Each mode allows the GC to analyze data from a given number of detectors, streams, and methods. See Table 3-4 for more information. Table 3-4 Operating Modes for Model 700 Mode ID Number Detectors Supported Streams Supported Methods Supported 0 1 1 1 1 2 1 1 2 2 2 2 3 2 1 2 3.
3-20 GETTING STARTED MON2000 2. MON2000 appears the About MON2000 dialog. The Call/Query Ratio estimates the quality of your serial communications. If this ratio is less than or equal to 0.5, then the connection is problematic. The maximum value of 1 indicates a good connection. The TAPI version represents the Telephony API software MON2000 accesses for dial-up (i.e., remote) communications. 3. Click the button to exit and return to the main window.
CONTROL FUNCTIONS MON2000 4-1 CONTROL FUNCTIONS 4 The options in the Control pull-down menu allow you to initiate various operating modes of the gas chromatograph (GC) unit. 4.1 AUTO SEQUENCE Use this function to start continuous GC analysis runs that follow a predefined stream sequence. At the initial startup, the current stream (in the stream sequence) is the first stream analyzed. See Section 5.8 for detailed instructions on configuring the predefined sequence. 1.
4-2 CONTROL FUNCTIONS MON2000 Use the status bar to monitor the progress of this function. To change the operating parameters, such as the Timed Event Tables (TEVs) and Component Data Tables (CDTs), See Section 4 for information about Application functions. 4.2 SINGLE STREAM Use this function to start continuous GC analysis run(s) on a single stream. 1. Use the Control > Single Stream menu to access this function. 2. The Start Single Stream Analysis dialog appears. 3.
CONTROL FUNCTIONS MON2000 4-3 6. Click the button to accept your selections and continue. Click the button to abort and return to the main window. 7. The Single Stream GC Analysis begins (if you selected the Purge Stream option, MON2000 performs this 60-second task first). Use the Report Display option in the Reports menu to view the results of the Single Stream function. Use the status bar to monitor the progress of this function. 4.
4-4 4.4 CONTROL FUNCTIONS MON2000 CALIBRATION Use this function to calibrate the GC unit. Calibration runs are determined by the CDT and Streams settings. See Section 5.2 and Section 5.8 for detailed instructions on how to edit these settings. 1. Use the Control > Calibration menu to access this function. If the GC unit is in Auto Sequence mode, calibration will not start until 2 or more analysis runs have been completed.
CONTROL FUNCTIONS MON2000 4-5 Purging allows sample gas to flow through the sample loop for 60 seconds prior to beginning the first analysis. 4. Select the desired calibration type. (a) Click the Manual radio button to perform a manual calibration. The CDT for the selected stream(s) will not be updated with raw data that are outside the acceptable deviations (as listed on the CDT). For more information, See Section 5.2. For either choice, only VAR (variable) components on the CDT are updated.
4-6 CONTROL FUNCTIONS MON2000 1. Use the Control > Baseline Run menu to access this function. If the GC unit is in Auto Sequence mode, MON2000 prompts that the continuous analysis must be stopped. Halt the analysis (See Section 4.3) and wait for an Idle status. Then continue initiating the baseline run. 2. The Start Baseline Run dialog appears. MON2000 displays the stream to be used for the baseline run. To select which stream is used for the baseline calibration, See Section 5.8. 3.
CONTROL FUNCTIONS MON2000 4.6 4-7 AUTO BTU START UP AND VALVE TIMING The Auto BTU Start Up process, which takes about an hour to complete, automatically performs the following sequence of tasks: 1. Sets the timing for each valve. 2. Matches all the component peaks. 3. Adjusts the timed events based on peak integration times. 4. Runs a calibration. 5. Checks the range and order of response factors. 6. Adjusts the retention time deviations to avoid peak overlapping.
4-8 CONTROL FUNCTIONS MON2000 2. Select Valve Timing from the Control menu. The Valve Timing window displays. MON2000 displays in the Stream field the calibration stream(s) to be used for the Auto BTU Start Up run. 3. Select the Auto BTU Start Up checkbox. 4. To use the default Component Data and Timed Event tables, select the Default CDT/ TEV checkbox.
MON2000 CONTROL FUNCTIONS 4-9 It is strongly recommended that you use the Default CDT/TEV. When the Default CDT/TEV checkbox is selected, the Valve # and CDT Component fields are read-only. 5. To use the GC’s existing CDT/TEV tables, select the Configured CDT/TEV checkbox. You can enter a valve number in the Valve # field and select the component number from the drop-down list of the CDT Component field in the table below the checkboxes.
4-10 CONTROL FUNCTIONS MON2000 6. To allow sample gas to flow through the sample loop for 60 seconds prior to beginning the first analysis, click the Purge stream for 60 seconds check box. It is strongly recommended that you check the Purge stream for 60 seconds check box. 7. Click OK to begin the Auto BTU Start Up process. When the process starts, the GC Status window indicates that the GC is in Vlv Timing mode.
MON2000 CONTROL FUNCTIONS 4-11 The following six potential system alarms can be triggered during the Auto BTU Start Up process: • Valve Timing 1 Failure: Triggered if the timing for valve 1 cannot be determined after a ten second change of VALVE OFF time. • Valve Timing 2 Failure: Triggered if the timing for valve 2 cannot be determined after a ten second change of VALVE OFF time.
4-12 4.6.2 CONTROL FUNCTIONS MON2000 Starting a Valve Timing Run If the GC is in Auto Sequence mode, halt the analysis (See Section 4.3) and then return to the Valve Timing window. 1. Select Valve Timing from the Control menu. The Start Valve Timing Run dialog appears. 2. If the Auto BTU Start Up checkbox is selected, uncheck it. The valve timing feature is now enabled. 3. MON2000 displays in the Stream field the calibration stream(s) to be used for the valve timing run. 4.
CONTROL FUNCTIONS MON2000 4-13 5. You can enter a valve number in the Valve # field and select the component number from the drop-down list of the CDT Component field in the table below the checkboxes. The list of components are from the CDT of the corresponding calibration stream. 6. Click the button to accept your selections and to continue. Click the button to abort and return to the main window. 7. The Valve Timing run begins.
4-14 CONTROL FUNCTIONS MON2000 2. The following MON2000 dialog appears. 3. Click the button to exit this dialog and return to the main window. 4.7.2 Set GC Time To set the system date and time used by the GC, 1. Use the Control > GC Time > Set menu to select the Set option. 2. The Set GC Time dialog appears MON2000 indicates whether the GC Controller is on daylight saving or standard time, which depends on the configured system parameters. 3.
CONTROL FUNCTIONS MON2000 4-15 provided scroll arrows to increase or decrease the highlighted value. 5. Click the button or press the enter key to write the selected date/time to the GC Controller. Click the button to abort and return to the main window. 4.8 STOP NOW Use this function to immediately stop all analysis runs. 1. Use the Control > Stop Now menu to access this function. 2. MON2000 prompts you to confirm your selection. Click the button to proceed.
4-16 CONTROL FUNCTIONS MON2000 3. Any GC function in progress is stopped. The Mode field in the status bar displays ‘Idle’.
APPLICATION FUNCTIONS MON2000 5-1 APPLICATION FUNCTIONS 5 The options in the Application pull-down menu allow you to manipulate or edit the control settings that exist for particular gas chromatograph (GC) application functions. You can edit an application while online with the GC Controller or when using the Offline Edit function (see Section 2.19 for information on Offline Edit; see Section 2.17 to download an application first). 5.
5-2 APPLICATION FUNCTIONS MON2000 2. The System dialog appears. Click and edit any value presented in the white cells. Note that the Daylight Savings Time option, when set to “Override,” will make the GC Controller ignore the time change from Standard to Daylight Savings (i.e., Standard Time will remain). 3. Click the button to accept your changes and return to the main window. Click the button to abort and return to the main window.
APPLICATION FUNCTIONS MON2000 5-3 Table 5-1 Description of Items in System Dialog Item Function Stream Sequence Defines the order of stream analysis for Detector 1. Stream Sequence 2 Defines the order of stream analysis for Detector 2; only available with selected hardware. Edit Note that this item is not available in all GC applications. Aux. Stream Sequence Defines the auxiliary order of stream analysis for Detector 1.
5-4 APPLICATION FUNCTIONS MON2000 Table 5-1 Description of Items in System Dialog (Continued) Item Function Number of Valves Identifies number of chromatographic valves (application-specific). Daylight Savings Time Allows the GC Controller to adjust automatically for DST. “Normal” enables automatic DST adjustment (United States). “Override” disables automatic DST adjustment. CGM Analog Output Displays chromatogram trace signals for strip chart generation from Detectors 1 and/or 2, trace 1 only.
APPLICATION FUNCTIONS MON2000 5-5 Table 5-1 Description of Items in System Dialog (Continued) Item Function Max Archive Averages maximum number of averages (1-254) Max Archive Avg.
5-6 5.2 APPLICATION FUNCTIONS MON2000 COMPONENT DATA Use this function to view and/or edit the Component Data Tables (CDTs) for a given GC application. 1. Use the Application > Component Data menu or press the F6 key to access this function. 2. The Component Data Tables menu appears, listing the CDTs available per associated stream(s). Choose the desired CDT. The number of available CDTs depends on the GC unit configuration. The standard GC application contains 4 CDTs.
MON2000 APPLICATION FUNCTIONS 5-7 4. View or edit data. Double-click a given table cell or use one of the edit function buttons to make your changes. To add a new component, move the cursor to the last table cell (last row, last column) and press ENTER. Some table cells will change into pull-down menus when selected. Choose your data from the pull-down menu provided. Note that a red component name indicates a standard component.
5-8 APPLICATION FUNCTIONS MON2000 Table 5-2 Description of Standard Parameters in a CDT Item Function Number (#) component number Edit An index number that acts as an identification label when used in other menus/dialogs (e.g., Limit Alarms, Analog Outputs). Up to 20 components can be defined per data table. Component names assigned to the various components displayed Components can be selected from the standard list, by pressing the F2 key (see Section 5.2.1), or entered by the user.
APPLICATION FUNCTIONS MON2000 5-9 Table 5-2 Description of Standard Parameters in a CDT (Continued) Item Function Edit Fixed/Variable whether a component response factor is fixed or variable A fixed response factor will not be updated during calibration. Calibration Concentration component concentration in calibration gas To enter a PPM, type “Xp”; e.g., “4.0p” will appear as “4.0 ppm”. Values above 90 PPM are converted to percentages.
5-10 APPLICATION FUNCTIONS MON2000 See Table 5-2 an asterisk (*) in the column heading indicates a column that contains standard component values. If any of these values is modified, the corresponding component becomes non-standard (i.e., user-defined). It is not recommended that you edit a standard component value. 5.2.1 Select Standard Component(s) To select standard component(s) to be used by the displayed CDT, 1. Select the Component cell where you want the new component. 2.
APPLICATION FUNCTIONS MON2000 5.2.2 5-11 Select Standard Values To read the values for the standard components, click the button or press the F3 key to access the Standard Components dialog. Click the CDT. 5.2.3 Typically, this function should only be performed when the MON2000 software is upgraded. User-defined components are not affected by this update.
5-12 5.2.4 APPLICATION FUNCTIONS MON2000 View Raw Data To view the raw data for the displayed CDT, 1. Select the desired row from the currently displayed CDT. 2. Click the button or press the F4 key to access the Raw Data dialog. 3. The Stream Selection dialog appears. Double-click the desired stream or click the button to exit. Only the streams associated with this CDT will display in the list menu. 4.
APPLICATION FUNCTIONS MON2000 5-13 RT is automatically targeted by MON2000). Then, press the DOWN ARROW key to advance to the next 'Raw Data' value. (d) Repeat Step (c) until all Retention Times have been copied to the CDT. 6. Click the Data screen. button to clear the Raw Following is an example of a Raw Data Table. Table 5-3 Raw Data Table Some methods are a combination of the above types, e.g. 103 is LAST OF FUSED GROUP (3) and INHIBIT ON (100).
5-14 5.2.5 APPLICATION FUNCTIONS MON2000 Sort Retention Time To sort the components listed in the displayed CDT by their retention times, 1. Click the button or press the F6 key to access this function. MON2000 sorts components by the corresponding detector number first, then by the Retention Time. 2. MON2000 automatically sorts the components. Sorting the CDT components by retention time may affect one or more of the following: • • • • • 5.
APPLICATION FUNCTIONS MON2000 5-15 Valve Events • Type - use the pull-down menu to select between valve number (Valve #), discrete output channel number (DO #), and stream switch (Strm Sw); additional selections SSO1, SSO2, Bleed1, Bleed2, Block1 and Block2 are available for the Model 700 GC applications • Valve/DO # (for valves and discrete outputs only) - input the valve number or discrete output channel number.
5-16 APPLICATION FUNCTIONS MON2000 Spectrum Gain Events • Detector # - use the pull-down menu to select between detectors #1 and #2 See Section 6.6 for editing • Gain - input the gain value for that detector. TEVs from CGM Viewer. LIMITS: 0 to 24 • Time - input the time that the event is to occur. LIMITS: 0.0 to 6000.0 seconds To access the Timed events feature, 1. Use the Application > Timed Events menu or press the F5 key to access this function. 2.
MON2000 APPLICATION FUNCTIONS 5-17 3. Click the button to accept your selection. The Timed Events Table dialog appears. Click the button to abort and MON2000 returns you to the main window. 4. View or edit data. To add a new timed event, move the cursor to the last table cell (last row, last column) and press the ENTER key. Use the check boxes to toggle the listed sample valves ON or OFF. Double-click a given table cell or use one of the edit function buttons to make your changes.
5-18 APPLICATION FUNCTIONS MON2000 5. To sort data based on time, click the button for the corresponding table. 6. Click the button to accept your changes and return to the main window. If you configure duplicate TEVs (i.e., 2 or more TEVs contain the same parameter settings), an error dialog will display but your data will be saved. Click the button to abort and return to the main window.
APPLICATION FUNCTIONS MON2000 5.4 5-19 USER DEFINED The user-defined functions allow you to edit a user-defined operator entry for an applicationspecific variable. These variables may be used in reports, calculations, and/or for controlling the GC operations; however, user-defined variables are not used by all applications. 5.4.1 Numeric Use this function to edit values for defined initialized variables.
5-20 5.4.2 APPLICATION FUNCTIONS MON2000 Selection Use this function to edit values for defined selection variables. The User Defined Selections dialog defines the names and values for all application-specific selection variables. 1. Use the Application > User Defined > Selection menu to access this function. 2. The User-Defined Selections dialog appears. Double-click the desired Option cell and use the provided pull-down menu to select the new setting. 3.
APPLICATION FUNCTIONS MON2000 5-21 2. The User-Defined Text Strings dialog appears. Double-click the desired String cell and type the new text. 3. Click the button to accept your changes and return to the main window. String length (i.e., how many characters you can enter) is limited to the number cited in the Size cell. Click the button to abort and return to the main window. 5.
5-22 APPLICATION FUNCTIONS MON2000 2. The Control Calculations dialog appears. Click the check boxes to toggle a calculation ON or OFF for a given stream. Scroll towards the end of the list to set metric calculations. You can use the arrow keys to move from one Stream cell to another, and press the space bar to toggle the calculation. Before enabling a metric calculation, ensure that you also enable the Metric Base Conditions setting in the Systems dialog (see Section 5.1). 3.
APPLICATION FUNCTIONS MON2000 5.5.2 5-23 Averages Use this function to designate, by streams and components, averages of standard calculations MON2000 should perform. 1. Use the Application > Calculations > Averages menu to access this function. 2. The Averages Calculations dialog appears. Double-click the desired cell and either type the new data or use the provided pull-down menu to select the new setting.
5-24 APPLICATION FUNCTIONS MON2000 To set a custom time interval per calculation, set the Type to Variable and enter the desired interval length in the Hours cell. A setting of “0” means an average calculation will be performed for each analysis run of that stream. Any GC analysis variable with defined alarm limits cannot be averaged or archived while in an active alarm state (see Section 5.6 for more information on Limit Alarms).
APPLICATION FUNCTIONS MON2000 5-25 To save this archive to disk, right-click the archive table and select the Save Sheet option from the pop-up menu. An error message displays when the last available stream or component is reached. 5. To copy the stream settings from a highlighted row and apply them to the next row, click the button or press the F7 key. This feature also increments the Stream value to the next available stream (e.g., incrementing from Stream 2 to Stream 8), per the GC application. 6.
5-26 APPLICATION FUNCTIONS MON2000 2. The User-Defined Calculations dialog appears. 3. Click the calculation name you wish to edit, or click in the next available blank Label cell. The Label field accepts 15 characters. 4. Click the button to edit or create the calculation function. The Edit User-Defined Calculation dialog appears.
APPLICATION FUNCTIONS MON2000 5-27 (a) To change the calculation function, click the appropriate cell and use the pulldown menu to choose the desired operator. The calculation completes each step from top to bottom. To change or add a variable name, use the Variables pull-down menu. To select a stream or component, click the appropriate cell and use the pulldown menu to choose the desired stream/ component. Enter any constant values in the Value 1 and Value 2 cells.
5-28 APPLICATION FUNCTIONS MON2000 1. Use the Application > Limit Alarms menu to access this function. 2. The Limit Alarms dialog appears. 3. To change the assigned variable, stream or component, click the appropriate cell and use the provided pull-down menu. Note that you must first select a variable before entering the related data. 4. To assign the discrete hardware output that will be set when the alarm is active, click in the appropriate cell and use the provided pull-down menu.
APPLICATION FUNCTIONS MON2000 5-29 output of “0 - Not used” indicates that no output is set. A discrete output can be used to monitor one or more inputs. If you are using discrete outputs to reflect the status of discrete inputs, ensure that the output assignments set here coordinate with those set in the Discrete Alarms dialog (see Section 5.7). To set discrete outputs, see Section 5.12. 5. To change the alarm type, click the appropriate cell and use the provided pulldown menu.
5-30 APPLICATION FUNCTIONS MON2000 8. To copy the component settings from a highlighted row and apply them to the next row, click the button or press the F6 key. This feature increments the Component value to the next available component (e.g., incrementing from “Ammonia” to “Benzene”), per the GC application. 9. Click the button to accept your changes and return to the main window. Click the button to abort and return to the main window.
APPLICATION FUNCTIONS MON2000 5-31 • Type - High uses only the high and the highhigh limits, Low uses only the low and the low-low limits, and All uses both low and both high limits 5.7 Type Purpose Low-Low If the variable value falls below this limit, the low-low limit alarm is activated. This alarm is for extreme situations Low If the variable value falls below this limit, the low limit alarm is activated. High If the variable value rises above this limit, the high limit alarm is activated.
5-32 APPLICATION FUNCTIONS MON2000 2. The Discrete Alarms dialog appears. 3. Use the provided Discrete Input pull-down menu to select the identification number of the discrete hardware input to be used for alarm purposes. Input values can range from “1” to “N”, per the discrete hardware output identification number and the GC application. A discrete input of “0 - Not used” indicates that no input has been assigned. To configure discrete inputs, see Section 5.11.
APPLICATION FUNCTIONS MON2000 5-33 the discrete hardware output to be used for alarm purposes. A discrete output can be used to monitor one or more inputs. If you are using discrete outputs to reflect the status of GC analysis data alarms, ensure that the output assignments set here coordinate with those set in the Limit Alarms dialog (see Section 5.6). Output values can range from “1” to “N”, per the discrete hardware output identification number and the GC application.
5-34 APPLICATION FUNCTIONS MON2000 For example, if discrete input #1 is closed for 60 seconds, discrete alarm #1 will be activated, which will in turn activate discrete output #3. MON2000 will display an active alarm in the bottom row of the GC column of the GC Status Bar. MON2000 will also copy the alarm description in the Alarm Text column to the appropriate Alarm screens.
MON2000 APPLICATION FUNCTIONS 5-35 To set up a discrete alarm, do the following: 1. Select Applications > User Defined > Selection.... The User-Defined Selections window displays. 2. Locate the Delyd_alm variable under the Name column and set its Option to ON and click OK. Note that setting the Option to OFF disables the delayed discrete alarm feature. 3. Select Applications > Discrete Alarms.... The Discrete Alarms window displays.
5-36 APPLICATION FUNCTIONS MON2000 4. For the appropriate alarm, select the discrete output that should be activated if the associated discrete input is closed. By default, discrete outputs #1, #2, and #3 can be selected. To make discrete output #4 available for selection, do the following: (a) Select Applications > User Defined > Selection.... The User-Defined Selections window displays. (b) Set EnableComAlarm to Disable. (c) Select Applications > Discrete Outputs....
MON2000 APPLICATION FUNCTIONS 5-37 7. Select Applications > User Defined > Numeric.... The User-Defined Numerics window displays. 8. The following variables apply to the delayed discrete alarm: • delay_alm_da: Defines which discrete alarm will be activated. • delay_alm_di: Defines which discrete input will be used to initiate the delayed discrete alarm.
5-38 5.
MON2000 APPLICATION FUNCTIONS 5-39 To use the Streams function, 1. Use the Application > Streams menu to access this function. 2. The Streams dialog appears. 3. To edit the settings displayed, click the appropriate cell, use the provided pull-down menus, or to choose the check boxes to enable or disable the automatic calibration and baseline calibration. See the following tables for details.
5-40 APPLICATION FUNCTIONS MON2000 The standard settings include: Table 5-4 Description of Standard Stream Settings Std Setting Description number label assigned by MON2000 This number correlates with the stream switch. A maximum of 12 streams can be controlled by MON2000 and a standard GC application.
APPLICATION FUNCTIONS MON2000 5-41 For calibration (CAL) streams, you can edit the following control parameters: Table 5-5 Description of Calibration Stream Settings Cal Setting Description Tot number of runs made for each calibration Range: 1 to 10 Avg number of last calibration runs to average E.g., if 5 calibration runs are performed and Avg is set to “3”, then the last 3 runs are used to average the calibration results.
5-42 APPLICATION FUNCTIONS MON2000 Table 5-5 Description of Calibration Stream Settings (Continued) Cal Setting Description Auto Cal Auto Base enable/disable the automatic calibration and baseline run (first check box sets the automatic calibration; second check box sets the baseline run) For the automatic calibration to work, at least one stream switch (valve event Strm Sw) must be included in the corresponding TEV (see Section 5.3).
APPLICATION FUNCTIONS MON2000 5-43 . Table 5-6 Description of GC Calculation Parameters Par Setting Description PSIA BAR base temperature in PSIA or bar units To change the displayed system units, see Section 5.1 for details. deg F deg C base temperature in degrees Fahrenheit or Celsius Opt Pres 1 Opt Pres 2 Opt Pres 3 If compressibility is activated for a particular stream (Calculation Control function, (see Section 5.5.
5-44 5.9 APPLICATION FUNCTIONS MON2000 ANALOG INPUTS This function allows you to: • assign identifying labels • assign scale ranges • calibrate analog inputs for zero and full scale values Electrical current signals ranging from 4 to 20mA ( ± 10 %) are accepted as analog inputs. To use the Analog Inputs function, 1. Use the Application > Analog Inputs menu to access this function. 2. The Analog Inputs dialog appears.
APPLICATION FUNCTIONS MON2000 5-45 See the following table for details or refer to Step 3 for a more automated process. Table 5-7 Description of Analog Input Settings Setting Description Channel channel number assigned Number of available analog inputs is dependent upon the GC Controller model.
5-46 APPLICATION FUNCTIONS MON2000 Table 5-7 Description of Analog Input Settings (Continued) Setting Description Full Scale Calib Adjustment mA calibrated analog inputs for known full scale electrical current levels Table 5-8 Gain Operating Ranges for Models 500, 700 and 1000 GCs GC GRI PAZ (12-bit AD) Value (12-bit AD) PAZ (16-bit AD) Value (16-bit AD) 1 0.0 to 0.0 600 to 800 0 to 4095 4800 to 6400 -32767 to 32767 2 0.8 to 1.
APPLICATION FUNCTIONS MON2000 5-47 4. The Zero Scale Adjustment dialog appears. Click the button to continue. MON2000 accepts a Zero Scale calibration value that is higher than the Full Scale value. A higher Zero Scale value can be useful in the applications that require an inverse display, or record, of analog signal levels. 2350A GC Controllers and Model 700 units support up to 4 Analog channels. 5. The Full Scale Adjustment dialog appears. Adjust the Analog Input to its Full Scale value.
5-48 APPLICATION FUNCTIONS MON2000 7. To perform a GRI (Gain Ratio Index) calculation, click the press the F4 key. button or A GRI calculation confirms the GC Controller preamp operation. It can be performed after a preamp calibration has been completed, or as a trouble shooting procedure. Ensure that you halt any ongoing analysis runs (see Section 4.3) before performing a GRI calculation. 8. Click the button to accept your changes and return to the main window.
MON2000 APPLICATION FUNCTIONS 5-49 2. The Analog Outputs dialog appears. To edit the settings displayed, double-click the appropriate cell or click and use the provided pull-down menus. When assigning analog outputs, first check the CGM Analog Output Config field in the System dialog (see Section 5.1). An analog output assignment that uses the same analog output number as the CGM setting will produce erratic CGM trace output, possibly with incorrect scaling.
5-50 APPLICATION FUNCTIONS MON2000 See the following table for details. Table 5-9 Description of Analog Output Settings Setting Description number assigned to Analog Output Number of available analog outputs is dependent upon the GC Controller model. If the GC unit includes a Daniel Analog Expansion Module (AEM), P/N 1-0500001, reserve analog output number 1 (first row) for the variable Bargraph.
APPLICATION FUNCTIONS MON2000 5-51 Table 5-9 Description of Analog Output Settings (Continued) When defining a new analog output, perform a calibration first to obtain accurate Zero and Full Adjustment values (see Section 5.10.4 or Section 5.10.5). JULY 2010 Setting Description Fixed Value analog output value used during fixed operation Zero Adjustment value used to correct Zero Scale Full Adjustment value used to correct Full Scale 3.
5-52 APPLICATION FUNCTIONS MON2000 5.10.2 Changing a Variable To change a variable assignment, click the appropriate Variable cell. Use the provided pull-down menu and click the desired variable to select it. 5.10.3 Changing the Bargraph Use this function to designate which AEM output analog signals can be used to drive the bargaph device inputs. Each of the 16 available AEM output signals can be assigned to represent various GC analysis data variables.
APPLICATION FUNCTIONS MON2000 5-53 3. To change a variable assignment, click the appropriate Variable cell. Use the provided pull-down menu and click the desired variable to select it. 4. Click the button to accept your changes and return to the Analog Outputs dialog. Click the button to abort and return to the Analog Outputs dialog. 5.10.4 Performing a Manual Calibration To manually calibrate an analog output, 1. Select the desired analog output by clicking anywhere in the corresponding row. 2.
5-54 APPLICATION FUNCTIONS MON2000 10. Click the button to accept your changes and exit from the Analog Outputs dialog. 11. Return to the Analog Outputs dialog. Wait until the Current Value of the analog output is equal to the Full Scale value (see Step 2). 12. Record the value, in engineering units, read by the receiving device (e.g., a voltmeter). 13. Set Zero Adjustment to the value recorded in Step 8. 14. Set Full Adjustment to the value recorded in Step 12. 15. Set the Fixed/Var parameter to “Var”.
MON2000 APPLICATION FUNCTIONS 5-55 4. The Full Scale Adjustment dialog appears. Input the appropriate value and click the button. 5. If the values entered are within tolerance, data in the zero and full adjustment columns is updated. Otherwise, MON2000 displays an error message.
5-56 5.11 APPLICATION FUNCTIONS MON2000 DISCRETE INPUTS Use this function to assign labels to the GC discrete inputs and control their operational modes. The number of discrete inputs available depends on the GC application. 1. Use the Application > Discrete Inputs menu to access this function. 2. The Discrete Inputs dialog appears. To edit the settings displayed, double-click the appropriate cell or click and use the provided pull-down menus. See the following table for details.
APPLICATION FUNCTIONS MON2000 5-57 3. Click the button to accept your changes and return to the main window. Click the button to abort and return to the main window. 5.12 DISCRETE OUTPUTS Use this function to assign labels to the GC discrete outputs and control their operational modes. The number of discrete outputs available depends on the GC application. 1. Use the Application > Discrete Outputs menu to access this function. 2. The Discrete Outputs dialog appears.
5-58 APPLICATION FUNCTIONS MON2000 See the following table for details.
APPLICATION FUNCTIONS MON2000 5-59 2. The Valves dialog appears, per GC type. Valves dialog for Model 700 GC Valves dialog for 2350A GCs To edit the settings displayed, double-click the appropriate cell or click and use the provided pull-down menus.
5-60 APPLICATION FUNCTIONS MON2000 See the following table for details. Table 5-12 Description of Valve Settings Setting Description Channel channel number assigned Label name used to identify the valve (12 characters maximum) By default, the 2350A GC stream valves are shown first and are labeled S1 - S12 followed by the analytical valves (AV1 - AV5). Model 700 GCs analytical valves are shown first and are labeled AV1 - AV5 followed by the stream valves (S1 - S8).
APPLICATION FUNCTIONS MON2000 5.14 5-61 TEMPERATURE CONTROL Use the Temperature Control function for monitoring the Temperature of the Oven (Detector/s and Columns) and the Stream Switching block to determine when the Model 700 is thermally stable. The bottom row labeled Temperature (C) displays the current temperatures. The settings and values are shown in the following figure and table. The settings and values are preset at the factory and are based on the specific customer application.
5-62 APPLICATION FUNCTIONS MON2000 3. Use the pull down menu to select the appropriate mode setting (e.g. AUTOMATIC, MANUAL, or OUT OF SERVICE). Ensure that the temperature is constant for the Oven (i.e. Multivalve System block and column module kit) and the SSS. Column Function Factory Default Setting Column 1 Detector/s or Block Temperature 80o C (176.0o F) Column 2 Column Temperature 80o C (176.0o F) Column 3 Sample Stream Block Temperature 40o C (104.
MON2000 APPLICATION FUNCTIONS 5-63 1. Use the Application > FID Configuration menu to access this function. The FID Configuration window appears. Information concerning the current status of the FID Preamplifier Assembly displays in the upper left corner. 2. To modify FID parameters, do the following: (a) Halt the analysis.
5-64 APPLICATION FUNCTIONS MON2000 (b) Click Modify. The blue background of the parameter fields will turn white, indicating that they are now modifiable. The parameters that you can configure are: • FID ignition - Select Manual if you wish to control the ignition of the FID (default); select Auto to let the GC control the ignition of the FID. • Number of ignition attempts - Indicates the number of times the GC will try to light the flame.
MON2000 APPLICATION FUNCTIONS 5-65 3. If Flame status is OFF, due to a power failure or maintenance, for example, you can restart the flame by doing the following: (a) Click H2 Open. The H2 valve status parameter displayed in the FID PreAmp Status table changes to OPEN. (b) Click Light flame. The Flame status parameter displayed in the FID PreAmp Status table will change to ON when the FID internal temperature exceeds the value set in the Flame On sense temperature field.
5-66 APPLICATION FUNCTIONS MON2000 (b) Click Modify to make the appropriate selection from the Digital filtering dropdown list. (c) Click Save to accept the change, or Cancel to reject the change. (d) Click Close to leave the FID Advanced Configuration window. 5. To reset the FID counts parameter, click Autozero FID. 5.
MON2000 APPLICATION FUNCTIONS 5-67 1. Use the Application > LOI Status Variables menu to access this function. The LOI Status Variables window appears. 2. If Include Mole Percents for current stream is checked, which is the default, the maximum number of variable you can select is five; if Include Mole Percents for current stream is not checked, you can choose up to 25 variables. 3. To select a new variable, click on the appropriate drop-down list under the Variable column. 4.
5-68 APPLICATION FUNCTIONS MON2000 the F8 key. This feature also increments the Component value to the next available component (e.g., incrementing from “Ammonia” to “Benzene”), per the GC application. 6. Enter a value in the Precision column that indicates the number of decimal places to display for this particular variable. For component concentrations, the range of possible Precision values is between 2 and 6. For all other variables, the range of possible values is between 0 and 6. 5.
APPLICATION FUNCTIONS MON2000 5-69 To edit the settings displayed, double-click the appropriate cell or click and use the provided pull-down menus. For proper communications, these parameters, which are continuously downloaded to the GC, must be identical to the parameters set in the MON2000 GC Directory. See the following table and individual sections for details. Table 5-13 Description of Serial Port Settings Setting Description Port Serial port number for GC Controller.
5-70 APPLICATION FUNCTIONS MON2000 Table 5-13 Description of Serial Port Settings (Continued) Setting Description Baud Rate Baud rate setting. Range: 1200, 2400, 4800, 9600, 19200, 38400. For high performing PCs, set the baud rate to 19200. If you experience a communications failure at this rate, set the baud rate to 9600. Baud rate settings less than 9600 may result in real-time delivery that is unacceptably slow. Data Bits Number of data bits. Range: 7, 8. Default: 8.
APPLICATION FUNCTIONS MON2000 5-71 Table 5-13 Description of Serial Port Settings (Continued) Setting Description Com ID Modbus slave address. To use the address defined by the GC Controller DIP switches, set to 0. Read/Write Read/write setting Range: R (Read only), W (Write only), RW (Read and write). This parameter only functions with slave ports. Mode Only applies to 2350A CPU board (P/N 2-3-2350-190) or Model 700 CPU board (P/N 2-3-0700-036).
5-72 APPLICATION FUNCTIONS MON2000 These ports can be configured with the Usage settings to accommodate any one of the following end-connection devices: The optional internal modem installed on a Model 700 or Model 500 uses COM9 only, except when a keyboard and display are installed. The optional internal modem would then use COM8 only. For proper communications, these parameters, which are continuously downloaded to the GC, must be identical to the parameters set in the MON2000 GC Directory.
MON2000 APPLICATION FUNCTIONS 5-73 CPU board. See the appropriate GC hardware manual for instructions and drawings. Communications between the GC and a DCS or multi-drop serial data highway can be established with Modbus protocol. For this, the Usage setting should be either User_Modbus or SIM_2251. In any Modbus host-slave configuration, there must be one Host to which any one of the GCs can respond as a Slave. Thus, the controller could be connected to a maximum of 4 different serial data networks.
5-74 APPLICATION FUNCTIONS MON2000 The Mode column applies only to the following CPU boards: • 2350A CPU board (P/N 2-3-2350-190) • Model 700 CPU board (P/N 2-3-0700-036) 5.18 GC SERIAL PORT AND CABLE CONFIGURATIONS This section provides more detailed information about the serial port connections of the 2350A GC Controller. It identifies serial port pin assignments and diagrams for designing RS-232 serial cables necessary for your application.
MON2000 APPLICATION FUNCTIONS 5-75 Phoenix plug (bare-wire) connections are available to all four serial ports. Pin-outs are identical for all four serial port Phoenix plugs and jacks. Each Phoenix plug / jack (male) combination allows bare-wire connection and uses 9 pins as illustrated: Figure 5-1 Phoenix Connector Pinout for J5, J6, J10, J11 DB-9 plug connections available for serial ports 1 and 2 only.
5-76 APPLICATION FUNCTIONS MON2000 Both of the GC Controller DB-9 jacks are female and have identical pin assignments. A DB-9 male pin numbering scheme is also illustrated, but for reference purposes only. Figure 5-2 DB-9 Connector and Pinout, P2 and P3 5.18.1 GC DB-9 Serial to External Modem DB-25 To make an RS-232 serial connection between one of the DB-9 serial ports of the GC, and an external modem with DB-25 serial port, you will need to manufacture a cable.
MON2000 APPLICATION FUNCTIONS 5-77 “null-modem” type cable, as shown below, to make the connection between the GC and an external modem. Figure 5-3 GC DB-9 Port to External Modem DB-25 Port 5.18.2 GC Phoenix Plug to External Modem DB-25 To make an RS-232 serial connection between one of the Phoenix Plug serial ports of the GC, and an external modem with DB-25 serial port, you will need to manufacture the cable and its DB-25, male plug cable end as illustrated in Figure 5-4.
5-78 APPLICATION FUNCTIONS MON2000 Figure 5-4 Phoenix Plug Port to External Modem DB-25 Port 5.18.3 Com ID The GC Controller Com ID is usually preset at the factory and defined by the DIP switch settings on the controller system interface board. Five switches are reserved for defining the Com ID; therefore, Com ID values range from 1 to 31. Normally it is not necessary to change the Com ID value to anything other than 0.
APPLICATION FUNCTIONS MON2000 5-79 Table 5-15 Description of Com ID Settings Connection Usage Read/Write Protocol PC or modem (direct serial connection) PC User_Modbus SIM_2251 R RW ASCII RTU DCS User_Modbus SIM_2251 R RW ASCII RTU Printer (direct serial connection) Report W ASCII 1. User_Modbus and SIM_2251 are slave port protocols (the GC Controller can operate only as a slave). 2.
5-80 APPLICATION FUNCTIONS MON2000 5.18.4 Registers To accommodate installations that use Modbus registers and the User_Modbus protocol, MON2000 enables you to assign GC analysis variables to registers. This function is not required for normal GC operation. Only use this function if you are designing a special installation to directly access the GC Controller Modbus registers. See Appendix F for more information regarding GC Modbus registers.
MON2000 APPLICATION FUNCTIONS 5-81 3. From the Serial Ports dialog, click the button or press the F3 key. 4. The Registers dialog appears. 5. View or edit data. Double-click a given table cell or use one of the edit function buttons, described below, to make your changes. For each default 0 FloatPt scale assigned, reserve 2 Modbus registers for a given variable. Scale assignments other than 0 FloatPT require only one register per variable.
5-82 APPLICATION FUNCTIONS MON2000 7. To change the stream assignment, click the appropriate cell. Use the provided pulldown menu and click the desired stream to select it. To copy the stream settings from a highlighted row and apply them to the next row, click the button or press the F7 key. This feature also increments the Stream value to the next available stream (e.g., incrementing from Stream 2 to Stream 8), per the GC application. An error message displays when the last available stream is reached.
MON2000 APPLICATION FUNCTIONS 5-83 (b) Click the button or press the F5 key. A menu list of all available scales and ranges appears. (c) Double-click the desired new scale and corresponding range. Note that any of the available 33 scales can be redefined via the Edit Scales function (see Step 10). 10. To redefine a scale or create a custom scale, (a) Click the button or press the F2 key. (b) The Edit Scales dialog appears. All 33 scaling options will display.
5-84 APPLICATION FUNCTIONS MON2000 (c) Input the new Zero Scale or Full Scale values as appropriate. To convert floating point data to a whole integer, each scale definition follows this algorithm: RF – RZ integer = ⎛ -------------------⎞ D fp = 3977 ⎝ SF – SZ ⎠ where RF = range, Full Scale =4095 Rz = range, Zero Scale =0 SF = scale, Full =100 Sz = scale, Zero =0 Dfp = data, floating pt =97.13 (% from Methane) (d) Click the button to accept your changes and return to the Registers dialog.
MON2000 APPLICATION FUNCTIONS 5-85 11. To check for conflicting Modbus register assignments, (a) Click the button or press the F6 key. (b) MON2000 displays the first encountered error. For this example, you would change the register number for Row 2. You would then verify all subsequent register numbers as well. (c) Click the button to accept your changes and return to the Serial Ports dialog. MON2000 automatically checks for conflicting Modbus register assignments.
5-86 APPLICATION FUNCTIONS MON2000 5.18.5 Setting Optional Base Pressures As discussed in Section 5.18.4, you can assign GC analysis variables to various Modbus registers. Follow the procedure below to add the “Optional Base Pressure” variable to the Registers List. Up to three (3) optional base pressures can be used for GC analysis calculations. These optional base pressure values are entered via the Streams function (see Section 5.8). • “Results - Opt.
APPLICATION FUNCTIONS MON2000 5-87 (c) Scroll to the Opt Press columns and note these values along with the corresponding optional pressure and stream number(s). (d) If you wish to enter different pressure values, do so now and then click the button to accept your changes. Otherwise, click the return to the main window. button to 2. Use the Application > Serial Ports menu to access the Register function.
5-88 APPLICATION FUNCTIONS MON2000 3. From the Serial Ports dialog, click the button or press the F3 key. The Registers dialog appears. 4. From the Registers dialog, use the Variable pull-down menu to select the Optional Base Pressures option. 5. Use the corresponding component pulldown menu to select the desired optional base pressure option.
APPLICATION FUNCTIONS MON2000 5-89 6. To assign a scale, ensure that the correct row is selected and click the button or press the F5 key. Double-click the desired scale option to apply. For instructions on creating or editing a scale, see Section 5.18.4. 7. The “Optional Base Pressure” variable should be listed with the settings specified. 8. Click the changes.
5-90 APPLICATION FUNCTIONS MON2000 5.18.6 Setting Optional Base Results As discussed in Section 5.18.4, you can assign GC analysis variables to various Modbus registers. Follow the procedure below to add the “Results - Opt. Base Press” variable to the Registers List. A group of 12 GC analysis calculations can be used to reflect the use of different base pressures. See Section C.3 for more information. To assign the “Results - Opt. Base Press” variable, 1.
APPLICATION FUNCTIONS MON2000 5-91 (d) If you wish to enter different pressure values, do so now and then click the button to accept your changes. Otherwise, click the return to the main window. button to 2. Use the Application > Serial Ports menu to access this function. 3. From the Serial Ports dialog, click the button or press the F3 key. The Registers dialog appears.
5-92 APPLICATION FUNCTIONS MON2000 4. From the Registers dialog, use the Variable pull-down menu to select the Results - Opt. Base Press option. 5. Use the corresponding component pulldown menu to select the desired optional base pressure option. Metric GC analysis variables are available only if the Metric Base Conditions option has been enabled (see Section 5.1). See Table 5-16 to determine which number you should enter. 6.
APPLICATION FUNCTIONS MON2000 5-93 . Table 5-16 GC Analysis Variable Number per Optional Pressure GC Analysis Variable Optional Pressure U.S. Metric 1 2 3 Gross Heating Value or Btu (Dry) Heating Value, Superior, MJ/m3 (Dry) 1 13 25 Gross Heating Value or Btu (Sat.) Heating Value, Superior, MJ/m3 (Sat.) 2 14 26 Gross Heating Value or Btu (Act.) Heating Value, Superior, MJ/m3 (Act.) 3 15 27 Net Btu (Dry) Heating Value, Inferior, MJ/m3 (Dry) 4 16 28 Net Btu (Sat.
5-94 APPLICATION FUNCTIONS MON2000 Table 5-16 GC Analysis Variable Number per Optional Pressure (Continued) GC Analysis Variable U.S. Optional Pressure Metric 1 2 3 Use the above index numbers to assign “Results - Opt. Base Press” to User_Modbus registers. 5.19 TCP/IP, SUBNET, AND GATEWAY MENU Use this function to configure the TCP/IP, Subnet, and Gateway communication parameters for the 2350A GC Controller. 1. Use the Application > TCP/IP menu to access this function. 2.
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5-96 APPLICATION FUNCTIONS TCP/IP, Subnet, and Gateway Menu MON2000 JULY 2010
CHROMATOGRAM VIEWER MON2000 6-1 CHROMATOGRAM VIEWER 6 Use the Chromatogram Viewer to display and print live, archived, or saved chromatograms (from a .cgm file on disk). The 2350A GC Controller saves the most recent chromatograms for each stream running in the Stream Sequence, as well as the chromatogram from the most recent calibration run for each CDT. See the following sections for further instructions. 6.1 CHROMATOGRAM VIEWER FUNCTION To access the Chromatogram Viewer, 1. Connect to the GC. 2.
6-2 CHROMATOGRAM VIEWER MON2000 4. Click the button to exit this dialog. Any display changes or open data will be lost. See Section 6.4 to save a chromatogram to disk. 6.2 VIEWING A LIVE CHROMATOGRAM 6.2.1 From Online GC To view a live chromatogram trace from the online GC, 1. Check the View current CGM option. If a chromatogram contains data for more than one detector, a Select Detector menu dialog displays. Double-click either “Detector 1”, “Detector 2”, or “Both”. 2.
CHROMATOGRAM VIEWER MON2000 6-3 coded; use the Chromatogram pull-down menu to select a specific chromatogram. 6.2.2 From GC Archive To view the most recent chromatogram trace from the online GC archive, 1. Click the button. The Available Chromatograms dialog appears. 2. Double-click the desired entry. If a chromatogram contains data for more than one detector, a Select Detector menu dialog displays. Double-click either “Detector 1”, “Detector 2”, or “Both”. 3. MON2000 plots the archived chromatogram.
6-4 CHROMATOGRAM VIEWER MON2000 zoom in on a particular point, click and drag your mouse over that area; repeat as necessary. Use the Restore State or Zoom Out options from the right-click menu (see Section 6.9) to return to the original display. You can display up to 8 chromatograms at one time. Each chromatogram is colorcoded; use the Chromatogram pull-down menu to select a specific chromatogram. 6.2.3 From File on Disk To view a chromatogram trace from a file previously saved to disk, 1.
MON2000 CHROMATOGRAM VIEWER 6-5 3. The Chromatogram window displays. If a chromatogram contains data for more than one detector, a Select Detector menu dialog displays. Double-click either “Detector 1”, “Detector 2”, or “Both”.
6-6 CHROMATOGRAM VIEWER MON2000 4. MON2000 displays the chromatogram file. The corresponding data is dynamically displayed in the provided legends. Use the Graph and Chromatogram functions to manipulate the display. To zoom in on a particular point, click and drag your mouse over that area; repeat as necessary. Use the Save State, Restore State, or Zoom In or Out options from the right-click menu (see Section 6.9) to return to the original display for both Live and Archived CGM views.
CHROMATOGRAM VIEWER MON2000 6-7 You can display up to 8 chromatograms at one time. Each chromatogram is colorcoded; use the Chromatogram pull-down menu to select a specific chromatogram 5. Click the button to save the selected comparison file to disk. The Save Chromatogram Comparison File dialog appears. 6. Enter the file name to be saved and click the button to save the file to disk. Or, Click the dialog.
6-8 6.3 CHROMATOGRAM VIEWER MON2000 REMOVING A CHROMATOGRAM FROM VIEW To remove a chromatogram trace from the Viewer display (and close the cgm file, if reading from disk), 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the button. MON2000 removes the chromatogram from view and, if applicable, closes the .cgm file. 6.4 SAVING A CHROMATOGRAM TO DISK To save a currently displayed chromatogram to disk, 1.
CHROMATOGRAM VIEWER MON2000 6-9 MON2000 displays the Save Chromatogram File window. Use the provided directory tree to select the desired file location and name, then click the button. 3. MON2000 saves the specified chromatogram along with its corresponding graph settings. 6.5 GRAPH FUNCTIONS Use the Graph buttons to access any of the following graph-related functions. 6.5.
6-10 CHROMATOGRAM VIEWER 2. Click the dialog appears. MON2000 button. The Edit Graph 3. Use the provided attributes and options to change the chromatogram display and printer speed as desired. 4. Click the button to accept your changes and return to the Chromatogram Viewer dialog. Click the button to abort and return to the Chromatogram Viewer dialog. 5. The chromatogram display changes as specified. Additional display options are available by right-clicking the display area. See Section 6.
CHROMATOGRAM VIEWER MON2000 6.5.3 6-11 Printing the Chromatogram To print a currently displayed area of the chromatogram, 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the 6.6 button. CHROMATOGRAM FUNCTIONS Use the Chromatogram buttons to access any of the following chromatogram-related functions. To save the displayed chromatogram to disk, see Section 6.4. To remove a chromatogram from view, see Section 6.3.
6-12 6.6.1 CHROMATOGRAM VIEWER MON2000 Editing the Chromatogram Use the Edit Chromatogram function to change the x/y offset values and other display parameters such as color. 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the button. The Edit Chromatogram dialog appears. 3. Use the X Offset and Y Offset values to change the chromatogram display as desired. 4. Use the Color pull-down menu to assign a different color to this chromatogram. 5.
CHROMATOGRAM VIEWER MON2000 6.6.2 In the edit mode, initial focus is applied to the currently selected event in the table, or to the event with the closest time. If more than one CGM is displayed, only the selected CGM timed events will be available to edit. JULY 2010 6-13 Editing TEVs from CGM Viewer To edit the Timed Events Table (TEV) from the Chromatogram Viewer window, 1.
6-14 CHROMATOGRAM VIEWER MON2000 MON2000 displays the Timed Events Table dialog.
CHROMATOGRAM VIEWER MON2000 6-15 2. Click the button to save your changes, or press the F8 key. Save changes and discard changes options are available from the rightclick menu. 3. Press the ESC key to discard changes. 6.6.3 Editing Retention Times from CGM Viewer To edit component retention from the Chromatogram Viewer window, 1. Double-click the left mouse button to edit the retention times from the CGM viewer You must access the Component Data Table to add, insert, and delete retention times.
6-16 CHROMATOGRAM VIEWER MON2000 Or, Press the F9 key. MON2000 displays the message, “Reading GC Data” in the status bar, then actives the TEV Table. 2. Click the button to save your changes, or press the F8 key. Press the ESC key to discard changes. 6.6.5 Viewing the Chromatogram Results Save changes and discard changes options are available from the rightclick menu. To read a table of calculation results for a selected chromatogram, 1.
MON2000 CHROMATOGRAM VIEWER 6-17 Click the button to display the report using ALL calculations. Click the button to return to the Chromatogram Viewer dialog.
6-18 6.6.6 CHROMATOGRAM VIEWER MON2000 Entering a Description To enter a description for the selected chromatogram, 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the button. The Edit Description dialog appears. 3. Type the desired statement(s). 4. Press the ENTER key to accept this description. Use the button or press the ESC key to exit this dialog without accepting your entry. 5. Click the button to save this description with the chromatogram file.
CHROMATOGRAM VIEWER MON2000 6.6.7 6-19 Forcing a Calibration Use the Forced Cal function to calibrate the GC, using the raw data and stream number for the selected GC Archive chromatogram. The results are stored in the CDT under the corresponding stream number. The selected GC Archive chromatogram must be from a good calibration gas run. To perform a forced calibration, 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the 6.6.8 button.
6-20 CHROMATOGRAM VIEWER MON2000 3. MON2000 toggles the display of the TEVs and Components spreadsheets and the CGM view. Cur/All View 1 6.7 Cur/All View 2 VIEWING BASELINE DATA Use the Baseline function to display the retention times and baselines for the selected chromatogram. 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the button. This removes the integration lines from a displayed Archive CGM. 3.
CHROMATOGRAM VIEWER MON2000 6.8 6-21 VIEWING RAW DATA Use the Raw Data function to display the Raw Data Table for the selected chromatogram. 1. Use the Chromatogram pull-down menu to select a specific chromatogram. 2. Click the button. The Raw Data dialog displays and shows the raw data for all CGMs in the graph area. 3. Click the button to return to the Chromatogram Viewer dialog. 6.9 DISPLAY OPTIONS Right-click the graph area to access these options, or use the corresponding keystroke(s).
6-22 CHROMATOGRAM VIEWER MON2000 Table 6-1 Display Options for Chromatogram Viewer Keystroke Right-Click Option Description CTRL C Copy to clipboard allows you to copy this graph to another application such as MSWord or Excel F8 Cursor to nearest point snap cursor to nearest point in both the X and Y directions CTRL V Paste from clipboard allows you to plot a range of points from another application such as MSWord or Excel CTRL P Print Graph Area print currently displayed chromatograph area
REPORTS MON2000 7-1 REPORTS 7 The options listed in the Reports menu enable you to display, print, or store various preconfigured GC reports. You must be currently online with the desired GC unit to generate a report from the controller. See the following sections for more information on specific reports and related functions. 7.1 REPORT DISPLAY This function allows you to immediately display, print, or store preconfigured reports on GC analysis data.
7-2 REPORTS MON2000 3. Select the report type, stream, and update setting from the lists provided. Table 7-1 Description of Report Display Settings Setting Description Reports list of pre-defined reports; Shows report type (Analysis, Raw Data, Calibration, etc...
MON2000 REPORTS 7-3 5. MON2000 generates the report, per your specifications, and displays the results in the File Viewer dialog. MON2000 creates a temporary HTML file to display the generated report. If you want to save this report to disk, see Section 7.1.4. The display refreshes per the update setting configured in the Report Display dialog (see Section 7.4).
7-4 REPORTS MON2000 See the following sections for instructions printing the displayed file or opening other report files from disk. 6. Click the button or press the ESC key to exit this function and return to the Report Display dialog. 7.1.2 View Report from File MicroSoft Internet Explorer 5.0 (or later) is required to view a report file in HTML format. To open a report file for viewing, 1. Use the Reports > Report Display menu to access this function. 2. The Report Display dialog appears.
REPORTS MON2000 7-5 3. Click the button or press the F3 key to access the File Viewer dialog. 4. Click the dialog appears. button. The Open 5. Use the provided directory tree to select the By default, the Open dialog displays the c:\GC\Save directory. desired report file. Click the button. 6. MON2000 opens the file and displays it in the File Viewer dialog. Use the scroll bars to see other areas of the report. Use the button to increase or decrease the font size displayed.
7-6 REPORTS MON2000 Use the and buttons to browse through multiple report files. 7. Click the button or press the ESC key to return to the Report Display dialog. 7.1.3 Print Report To print a report, The refresh function displays a newly generated report and deletes the currently displayed report (see Section 7.1.1 for details). You should print or save the current report immediately after it is displayed. 1. Display a live report or open a report file from disk. See Section 7.1.1 or Section 7.1.
REPORTS MON2000 7-7 2. Click the button. The Save HTML Document dialog appears. MicroSoft Internet Explorer 5.0 (or later) is required to view a report file in HTML format. 3. Select the directory in which you want to save this report and type the desired name. You can save the report in any of these formats: • • • • • .txt, ASCII Tab-delimited .cvs, Comma-deliminted .xls, Excel .htm, HTML .xml, EXtensible Markup Language Note that the default location is c:\GC\Save. 4. Click the JULY 2010 button.
7-8 7.1.5 REPORTS MON2000 Report Contents This section includes examples of the following reports: Analysis, Raw Data, Calibration, 24-Hour Average, Weekly Average, Hourly Average, and Variable Average. After each sample report, a table describes the contents and identifies which functions affect the data.
REPORTS MON2000 7-9 Analysis Report JULY 2010 Report Contents
7-10 REPORTS MON2000 Table 7-3 Contents Guide for Analysis Report Content Related Function(s) Menu Section Component Name Component Data Table (CDT) Application > Component Data [F6] 5.2 GC Analysis Data variables (std) Calculations, Control Application > Calculations > Control 5.5.1 GC Analysis Data variables (user) Calculations, User Defined Application > Calculations > User Defined 5.5.3 Alarms Limit Alarms Application > Limit Alarms 5.
REPORTS MON2000 7-11 Raw Data Report Table 7-4 Contents Guide for Raw Data Report Content Related Function(s) Menu Section Retention Time Peak Area Peak Height Det(ector) Integration Start/End Peak Width 1/2 Height standard GC application n/a n/a Mthd (method) standard GC application, peak derivation method (non-edit) Chromatogram Viewer 6.2.
7-12 REPORTS MON2000 Calibration Report Table 7-5 Contents Guide for Calibration Report Content Related Function(s) Menu Section Component Name Cal. Conc. CDT Application > Component Data [F6] 5.2 Raw Data New RF RF % Dev. New RT RT % Dev. CDT (additional columns) Application > Component Data [F6] 5.2 Alarms Limit Alarms Application > Limit Alarms 5.6 Streams used for analysis display “0”s in the calibration raw data columns (see Section 5.
REPORTS MON2000 7-13 Final Calibration Report Table 7-6 Contents Guide for Final Calibration Report Content Related Function(s) Menu Section Component Name Cal. Conc. CDT Application > Component Data [F6] 5.2 Old RF New RF RF % Dev. Old RT New RT RT % Dev. standard GC application Application > Component Data [F6] 5.2 Application > Limit Alarms 5.
7-14 REPORTS MON2000 Average Reports There are five types of Average Reports: • • • • • Hourly Average Report 24-Hour Average Report Weekly Average Report Monthly Average Report Variable Average Report Sample 24-Hour Average Report Report Contents JULY 2010
REPORTS MON2000 7-15 Table 7-7 Contents Guide for Average Reports Content Related Function(s) Menu Section Item Number Analysis data/calculation Stream Component Calculations, Averages Application > Calculations > Averages 5.5.2 Old RF New RF RF % Dev. Old RT New RT RT % Dev. standard GC application n/a n/a results of ongoing or completed averages 7.2 GC REPORT REQUEST This function allows you to send a report to a printer connected to the GC Controller. 1.
7-16 REPORTS MON2000 3. Select the report you wish to print. The GC Config Report is a snapshot of the PC Config Report. Contents include: • • • • • • • current alarms streams control calculations CDTs TEVs GC serial port settings analog outputs See Appendix A for a sample PC Config Report. For reports other than the GC Config, a Streams list displays. Double-click the appropriate stream and the controller sends the report to the printer. Click the button.
REPORTS MON2000 7-17 2. The GC Printer Control dialog displays. 3. Use the provided data fields, check and combo boxes to select the desired settings. See Table 7-8 for detailed descriptions. You can, for example, set a report to print after each analysis and every 12 hours. 4. Click the button to accept your selections and return to the main window. Click the button to abort and return to the main window.
7-18 REPORTS MON2000 Table 7-8 Description of Settings for GC Printer Control (Continued) Setting Description Hours hour interval at report should print Use this setting for intervals less than 24 hours. For example, use this setting if you wish to print a report every 8 hours. Ensure that the Time value is “00:00” to disable the 24-hour setting or “12:00 AM” to disable the 12-hour setting. This setting only applies to streams enabled (i.e., checked ON) for report printing.
REPORTS MON2000 7-19 1. Use the Reports > MON2000 Printer Control menu to access this function. 2. The Printer Control dialog displays. Use the provided data fields, check and combo boxes to select the desired settings. See Table 7-9 for detailed descriptions. You can, for example, set a report to print after each analysis and every 12 hours. 3. Click the button to accept your selections and return to the main window. Each report generation interrupts all current functions.
7-20 REPORTS MON2000 Table 7-9 Description of Settings for MON2000 Printer Control (Continued) Setting Description Hours hour interval at report should print Use this setting for intervals less than 24 hours. For example, use this setting if you wish to print a report every 8 hours. Ensure that the Time value is “00:00” to disable the 24-hour setting or “12:00 AM” to disable the 12-hour setting.
REPORTS MON2000 7-21 The standard GC application can store up to ninety-nine days of analysis runs and calibration records. 7.5.1 View Data Model 500/Model 700 To view, print, copy or save archived data, 1. Use the Reports > Archive Data > View Data menu to access this function. 2. MON2000 displays the Date Range Selection pop-up dialog. Select All Dates radio button or choose Selected Dates. Select the Start date and End Date (date range) for the report to be archived.
7-22 REPORTS 3. Click the selection. MON2000 button to apply your Or, Click the button to return to the View Data window. MON2000 displays the message “Reading GC Data” in the status bar. 4. The Select Archive Record dialog appears. Double-click the desired archived report or record. (If no records are found, an information dialog displays.) Select a range (multiple) of records to archive by leftclicking the mouse at the beginning record and dragging the pointer to the last record to be archived.
MON2000 REPORTS 7-23 5. The Calculation Results from Ext. Modbus window appears. Use the button or press the ESC key to exit this function and return to the main window. As applicable, use the scroll bars to see other areas of the record.
7-24 REPORTS MON2000 6. To print, copy to the clipboard, or save the report to disk, right-click the Archive Data sheet and select the desired option from the popup menu. Or, use the , or buttons for these functions. Use the Save File dialog to choose the directory location and file name. You can save the report in any of these formats: • • • • • .txt, ASCII Tab-delimited .cvs, Comma-deliminted .xls, Excel .htm, HTML .xml, EXtensible Markup Language 7. Click the main window. 7.5.
REPORTS MON2000 7-25 1. Click Export Data and the Export Archive window displays. 2. The exported data file is saved in the default (GC>Directory). Use the pull-down menu to save the data file to a different directory. 3. Click an existing file (to write over an existing file) or enter a 'new' file name in the 'Data Field'. 4. Save the file as either: • .csv (spreadsheet application format) • .
7-26 REPORTS MON2000 If the GC you are using is a Model 2350A, the Data Selection Range' dialog appears. Choose the date range as: • • • • All dates (radio button) or, Selected Dates (radio button) Start date End date Default Settings Also note that the Date Range dialog only displays when files are archived for more than one day. Date Range Selection 5. Click the button to apply your selection. Click the button to abort and return to the Trend Data window. 6.
REPORTS MON2000 7-27 The operator may select several records individually by holding down the 'Ctrl' key and clicking the mouse pointer on random selected reports. Reports that are several hours apart may be viewed in this manner. Or, as the example .BMP above shows, the operator may click a report and drag the mouse pointer down, highlighting several reports in sequential order. 7.5.3 Reset To delete archived data and reset the GC Controller memory, 1.
7-28 7.6 REPORTS MON2000 TREND DATA This function allows you to view, print, or save graphical representations, or trend lines, of accumulated analysis data for the 2350A and the Model 700 GC Controllers. 7.6.1 Trend Data Model 700/2350A GCs 1. Use the Reports > Trend Data menu, then click the function. button to access this 2. The Trend Data dialog appears. Use the enabled Graph and Trend pushbuttons to access the Trend Data features. See the following sections for detailed information. 3.
REPORTS MON2000 7.6.2 7-29 View Live Trend Online Model 700/2350A To view a live trend from the online Model 700/ 2350A GC, You cannot view a live trend if the corresponding analysis record does not exist in the GC memory. An error message will display: 1. Click the button. 2. The Select menu for variable displays. Double-click the desired variable. If the selected variable applies to a single component (e.g.
7-30 REPORTS MON2000 3. The Select menu for streams appears. Double-click the left mouse button on the desired stream to make your selection. 4. MON2000 displays the Date Range Selection pop-up dialog. Select All Dates radio button or choose Selected Dates. From the pull-down menu, select the date range for the Trend report. Click the selection. to apply your Or, Click the trend window. button to return to the 5.
MON2000 REPORTS 7-31 The Trend Data window appears.
7-32 REPORTS MON2000 The corresponding data is dynamically displayed in the provided legend. Use the Graph and Trend Options functions to manipulate the display. To zoom in on a particular point, click and drag your mouse over that area; repeat as necessary. Use the Restore State or Zoom Out options from the right-click menu (see Section 7.6.10) to return to the original display. 7.6.
MON2000 REPORTS 7-33 3. MON2000 displays the trend file. The corresponding data is dynamically displayed in the provided legend. Use the Graph and Trend Options functions to manipulate the display. To zoom in on a particular point, click and drag your mouse over that area; repeat as necessary. Use the Restore State or Zoom Out options from the right-click menu (see Section 7.6.10) to return to the original display.
7-34 7.6.4 REPORTS MON2000 Edit Graph Display 1. Click the dialog appears. button. The Edit Graph 2. Use the provided attributes and options to change the trend display as desired. 3. Click the button to accept your changes and return to the Trend Data dialog. Click the button to abort and return to the Trend Data dialog. 4. The trend display changes as specified. Additional display options are available by right-clicking the display area. See Section 7.6.10 for more information. 7.6.
REPORTS MON2000 7.6.6 7-35 Describe Trend 1. Click the button. The Edit Description dialog appears. 2. Type the desired statement(s). 3. Press the ENTER key to save this description. Use the button or press the ESC key to exit this dialog without saving your entry. 7.6.7 Print Trend To print the displayed trend graph, click the button. MON2000 prints the report to your configured printer (see Section 3.7).
7-36 7.6.8 REPORTS MON2000 Save Trend To save a currently displayed trend to disk, 1. Click the button. The table is saved as a binary file with a .trd extension. 2. Use the provided directory tree to select the desired file location and name, then click the button. 3. MON2000 saves the trend along with its graph settings. 7.6.
REPORTS MON2000 7-37 2. The Archive dialog appears. 3. Click the button to return to the Trend Data dialog. 7.6.10 Display Options Right-click the graph area to access these options, or use the corresponding keystroke(s). Options are listed in alphabetical order.
7-38 REPORTS MON2000 Table 7-10 Display Options for Trend Data Keystroke Right-Click Option Description CTRL C Copy to clipboard allows you to copy this graph to another application such as MS Word or Excel F8 Cursor to nearest point snap cursor to nearest point in both the X and Y directions CTRL V Paste from clipboard allows you to plot a range of points from another application such as Meshwork or Excel CTRL P Print Plot Area print currently displayed chromatograph area CTRL S Print Se
LOGS MON2000 8-1 LOGS 8Y The options in the Logs pull-down menu allows you to keep a maintenance record, keep a parameter record, and view the Alarm and Event Logs. 8.1 MAINTENANCE LOG Use this function to track maintenance activities performed on a given GC unit. To read and edit the Maintenance Log, 1. Use the Logs > Maintenance Log menu to access this function. MON2000 retrieves the data from the GC unit. 2. The Maintenance Log dialog appears.
8-2 LOGS MON2000 3. To add the log entry text, (a) Click the “Add Message F4” button or click the last ‘Log Message’ cell and press the RETURN key. The Maintenance Log message dialog displays. (b) Add text in the appropriate Log Message cell, then click the button to apply the changes. Click the button to discard your changes and return to the Main window. 4. To change the log entry text, (a) Click the appropriate Log Message cell. A Log Message can contain up to 1000 characters.
LOGS MON2000 8-3 (d) To accept your edits, press the RETURN key. To cancel your edits, click the button or press the ESC key. 5. To delete a log entry, click the desired log entry and press the DELETE key. 6. Click the button to write this data to the GC unit. Click the button to abort and return to the main window. 8.2 PARAMETER LIST Use this function to keep a record of the hardware components and associated parameters for a given GC unit. To read and edit the Parameter List, 1.
8-4 LOGS MON2000 2. The Parameter List dialog appears.
LOGS MON2000 8-5 Table 8-1 Items in Parameter List (Continued) Type Parameter Analysis Settings Flows in cc/min Sample Loop 1 Sample Loop 2 Detector Valve Part Numbers Sample System Sample Valve 1 Flow Rate (cc/min) Sample 1 Pressure (PSIG) Sample Valve 2 Flow Rate (cc/min) Sample 2 Pressure (PSIG) SCS Oven Temperature (°C) Solenoid Purge Flow (cc/min/stream) Column OD (in.) ID (in.) Length Support Mesh Phase Connected Function 3. To save this data to disk, click the button or press the F3 key.
8-6 LOGS MON2000 This feature only saves the files in .par format. Use the Save Parameter File dialog to choose the directory location and file name. 4. To open an existing parameter file from disk, click the press the F4 key. button or Use the Open Parameter File dialog to choose the desired file. 5. Click the button to write your changes to the GC unit. Click the button to abort and return to the main window. 8.3 ALARM LOG Use this function to read and/or clear the various entries in the Alarm Log.
LOGS MON2000 8-7 To view the Alarm Log, 1. Use the Logs > Alarm Log menu to access this function. MON2000 retrieves the last 50 alarms from the GC unit. 2. The Alarm Log dialog appears.
8-8 LOGS MON2000 Table 8-2 Alarm Log Attributes (Continued) Attribute Description Alarm Message 1 describes the alarm condition If an alarm message is changed (see Section 5.6 and Section 5.7) all affected alarm entries, including those previously recorded, will include that change. Alarm Message 2 displays the alarm limit and current condition values, as applicable 3. By default, MON2000 displays all recorded alarms.
LOGS MON2000 8-9 5. To acknowledge all unacknowledged alarms, (a) Ensure you have selected the correct display option (see Step 3). (b) Click the the F3 key. button or press In the Active Alarm view, click the button or press the F4 key. If an alarm is cleared before the condition has been resolved, MON2000 redisplays the alarm entry as an active alarm. 6. Click the button to exit and return to the main window. 8.
8-10 LOGS MON2000 2. The Event Log dialog appears, displaying each system or operator event and the corresponding data. Table 8-3 Event Log Attributes Attribute Description User Id user name Date date event occurred Time time event occurred Event Message indicates event type (i.e., describes event) Old Value if applicable, the value before the event New Value if applicable, the value after the event 3. Click the button to exit and return to the main window.
MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9-1 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9 The Data Collection feature is only available with the MON2000 PLUS program. 9.1 OVERVIEW The MON2000 PLUS program provides configurable automatic collection and storage of analysis and calibration data from the gas chromatograph controller.
9-2 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 All Model 500 and 1000 GC’s with 2350A and older 2350/2360 GC Controllers and Model 700 GC Controllers are supported in the acquisition of the following types of data: • Alarms - Selection of Alarm Log, Active Alarms, or Unacknowledged Alarms.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-3 • Condition Start - Start of conditional polls. The poll commands following the Condition Start are run only when the condition is met. The condition is defined through the status change of a Modbus register (SIM_2251 or User_Modbus). • Condition End - End of conditional polls. The poll commands following the Condition End are run normally.
9-4 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Select a desired command from the list of available commands and input the necessary data to complete the command (see Table 9-1 for a list of commands). The completed command is added to the Polling Control file. Continue with the next desired command. This process is continued until all commands are selected and configured for the file. Edit the polling control file by adding, deleting, and inserting commands.
MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9-5 Table 9-1 List of Commands Command Description Await This command instructs the Auto-Sequencing module to await a specific time of day prior to continuing processing the commands in this file. The user enters the desired time of day in hours and minutes.
9-6 9.2.1 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Create a New Polling Control File To create and configure a new polling control file, 1. Use the Data Collection > Configuration>New File menu to access this function. 2. MON2000 PLUS displays the Configuration for Data Collection window. 3. From the Polling Output File(s) table select Report and/or Data type by clicking the appropriate check box. Enter the Default Filename field for the chosen selections. 4.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-7 8. The Save Polling Control File dialog appears. Enter a filename and click the Save button to save the *.apc file. 9.2.2 Open an Existing Polling Control File To edit or modify the configuration of an existing file, 1. From the MON2000 PLUS main window, use the Data Collection>Configuration> Open File menu. 2. Click the button and the Open Polling Control File window displays. 3.
9-8 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 4. The Configuration for Data Collection window displays. 5. Use the buttons to modify the Data Collection configuration or Polling Control file. 6. When you have finished modifying the file, click the button to apply the changes. 7. The Save Polling Control File dialog appears.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-9 8. A Save Polling Control message prompts you to replace the exiting file or rename the Polling Control file (*.apc) file. Click the button to replace the existing file. Or, 9. Click the changes. 9.2.3 button to discard your Await Command This command instructs the auto-sequencing module to wait for a specific time of day prior to processing the commands in the file. The user enters the desired time of day in hours and minutes.
9-10 9.2.4 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Connect/Logon Command The Connect/Logon command instructs the Auto-Sequencing module to establish communications with the indicated GC controller, using the communication method and parameters as indicated in the GC directory entry and logon to the GC Controller. After selection of the Connect command the user selects the desired GC controller from a list of the GC directory entries.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9.2.5 9-11 Connect/No Logon Command The Poll Command Connect/No Logon allows the Auto-Sequencing function to execute without logging on to a GC Controller. To configure the Connect/No Logon Command, 1. Select Connect/No Logon from the General Configuration Command pull-down list. 2. From the GC Entry list that is configured in the File>GC Directory menu, select the desired GC Controller. 3.
9-12 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 To configure the Delay (Seconds) Command, 1. From the General Configuration List of Commands pull-down list, select Delay (Seconds). 2. Enter the time delay, in one second increments, in the Delay field. 3. Enter a description for the Delay (Seconds) command in the Command Description field. 9.2.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9.2.8 9-13 Disconnect Command Use the Disconnect Command to terminate communications with a currently connected GC Controller. To configure the Disconnect command, 1. From the General Configuration: List of Commands, use the Commands pull-down list and select Disconnect. 2. Enter a description for the Disconnect Command in the Command Description field. No additional input parameters are required for this command.
9-14 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9.2.10 Poll Command: Alarms To configure the Alarms Command, from the Configuration for Data Collection window, 1. Select POLL from the General Configuration Commands pull-down list. Each Poll Command includes the criteria to define acquisition and storage of a single type of data. 2. Press the RIGHT ARROW key on your keyboard or LEFT-CLICK the mouse in the Type field and select Alarms from the pulldown list. 3.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-15 6. Use the Time Selection pull-down list and choose one of the following: • Start/End Time • Most Recent • Since Last Collected Use the Up and Down arrows and enter the starting date, starting time, ending date and ending time in the appropriate data fields. 7. If Active Alarms or Unacknowledged Alarms is selected, no additional information is necessary and all of the entries of the selected type are returned. 8.
9-16 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 10. Click the button to save the changes and return to the Configuration for Data Collection window. Or, Click the changes. button to discard your 9.2.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-17 4. Click the button and the Poll Command: Averages dialog box displays. 5. From the Averages Configuration dialog, for a single record, select Average - Single Record. If the Average - Single Record is selected, only the average values are included in the output file.
9-18 MON2000 PLUS DATA COLLECTION/AUTO-POLLING If Complete Output Complete Output is selected, click the check boxes to select Average, Min, Max, or Samples values. MON2000 All averages referenced by a single Poll command must be for the same averaging interval (e.g. hourly, daily, weekly, monthly, variable). Use the Result Grouping pull-down list and select By Period or By Average.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-19 6. From the Output File table, enter/edit the filename and file format (*.txt or *.csv) for the Averages Output file. 7. Click the button to apply the configuration changes. 8. MON2000 PLUS displays the Save Changes dialog. 9. Click the button to write the changes and return to the Configuration for Data Collection window. Or, Click the changes. button to discard your 9.2.
9-20 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 4. Press the RIGHT ARROW key on your keyboard, or LEFT-CLICK the mouse in the Command Description field. Enter a description for the CGM Archive command. 5. Click the button and the Poll Command: CGM Archive dialog box appears. 6. Enter the Stream number for data collection. 7. Use the Analysis/Calibration pull-down list and select the CGM Archive for the Last Analysis or Last Calibration. 8. Click the button to apply the configuration changes.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-21 9.2.13 Poll Command: CGM on Alarm Use the CGM on Alarm command to poll the CGM when an alarm condition is set or cleared. Setup continuous polls so that MON2000 PLUS can determine and retrieve the CGM with the alarm condition. The data is saved to an output file in CGM format and is stored in the "\GC\SAVE\ERRORS" folder. The file name is based on the Date/Time and ends with an 'a'. To configure the CGM on Alarm Command, 1.
9-22 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 2. Select Condition Start from the pull-down list in the Type column. 3. Enter a description in the Command Description column. 4. Select a default output file format by clicking either the Report or Data checkbox on the Polling Output File(s) table. 5. Enter a default output file name. 6. Click the Poll Command Details button located at the bottom of the Configuration for Data Collection window. The Poll Command: Condition Start window appears. 7.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-23 10. To apply the configuration changes, click OK. To discard your changes and return to the Configuration for Data Collection window, click Cancel. 9.2.15 Poll Command: Condition End Use the Condition End command to stop conditional polling. To configure the Condition End command, 1. From the General Configuration (List of Commands) table, select Poll from the Command column. 2. Select Condition End from the pull-down list in the Type column. 3.
9-24 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9.2.16 Poll Command: Event Log 1. From the General Configuration: List of Commands, use the Commands pull-down list and select the POLL command. 2. Press the RIGHT ARROW key on your keyboard, or LEFT-CLICK the mouse Type field and select Event LOG from the pulldown list. 3. Press the RIGHT ARROW key on your keyboard, or LEFT-CLICK the mouse in the Command Description field. Enter a description for the Event Log command. 4.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING Event Log Selection 9-25 Additional Selections Ending Date Ending Time Most Recent n Days Enter number of n Days Since Last Collected No further information is needed Entire Log No further information is needed 6.
9-26 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Click the button to discard your changes and return to the Configuration for Data Collection window. 9.2.17 Poll Command: Maintenance Log To configure the Maintenance Log command, 1. From the General Configuration: List of Commands, use the Commands pull-down list and select the POLL command. 2. Press the RIGHT ARROW key on your keyboard, or LEFT-CLICK the mouse Type field and select Maintenance Log from the pull-down list. 3.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-27 4. Click the button and the Poll Command: Maintenance Log dialog box displays. 5. From the Maintenance Log Configuration Selection table, choose one of the following: Maintenance Log Selection Additional Selections Start/End Time • • • • Most Recent n Days • Enter number of n Days Since Last Collected • No further information is needed Entire Log • No further information is needed Start Date Start Time End Date End Time 6.
9-28 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 8. Click the button to discard your changes and return to the Configuration for Data Collection window. 9.2.18 Poll Command: Registers Blocks of Modbus Register data can be specified for collection. To configure the Registers Command, 1. From the General Configuration: List of Commands, use the Commands pull-down list and select the POLL command. 2.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 4. Click the 9-29 button and the Poll Command: Registers dialog appears.
9-30 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 (a) If SIM_2251 is selected and the Starting Register is in the range 701 - 999, then Record Selection includes the following: Record Selection Additional Selections Starting Record + n Starting Record number Number of Records (n) Total Number of Records Most Recent n Records Number of Records (n) Total Number of Records Location of Last Written Record Since Last Collection Total Number of Records Location of Last Written Record Date/Time Form
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-31 (c) For the standard registers, the values returned are stored in a single record in the output file, following the Date and Time when the registers are polled, the Starting Register, and Number of Registers.
9-32 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9.2.19 Poll Command: Reports The archived analysis reports (as viewable under MON2000 when connected to a controller, from the Reports>Archived Data>View Data menu) can be retrieved and stored. To configure the Reports Command, 1. From the Configuration for Data Collection window, click the ADD button to select another command. 2. Next, select the Poll command. 3.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-33 5. Click the button and the Poll Command: Reports dialog box appears. 6.
9-34 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 9. From the Output File table, enter/edit the filename and file format (*.txt or *.csv) for the Reports Output file. 10. Click the button to apply the configuration changes. Or, 11. Click the button to discard your changes and return to the Configuration for Data Collection window. 9.2.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-35 9.2.21 Run Command The run command (future release) instructs the Auto-Sequencing module to start execution of a user program. The user specifies whether the Auto-Sequencing module waits for completion of the user program before processing the poll control file commands, or continues immediately thus executing in parallel with the user program. This feature allows you to further process the collected data.
9-36 9.3.1 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Start Auto-Sequencing To initiate Auto-Sequencing, use the Data Collection>Start Auto menu, 1. Click START AUTO and the Start AutoSequencing dialog appears. 2. Click the button and the Open Polling Control File dialog appears. 3. Select the desired polling control file, and then click the button. 4. From the Output Files selection, click the desired radio button: • Append to the existing file • Overwrite the existing file 5.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-37 6. Click the button to confirm the start of automatic operation. MON2000 PLUS begins the Auto-Sequencing process and displays the Auto-Sequencing Status window. 7. The Auto-Sequencing module begins with the first command in the selected polling control file and performs the requested operation. Processing continues sequentially through the file performing the operations requested by each command.
9-38 9.3.2 MON2000 PLUS DATA COLLECTION/AUTO-POLLING MON2000 Transaction Log To enable the Transaction Logging functions, select the check box on the Start AutoSequencing dialog. If this option is chosen, one or more entries are made to the AutoPollCommsLog.txt file each time a command is executed. Transaction Log entries include a time stamp and a description of the command being executed.
MON2000 MON2000 PLUS DATA COLLECTION/AUTO-POLLING 9-39 As each command is processed the following general information is displayed (depending on the command being processed, the details of the exact data included will vary: • Polling Control file in use • Start time of operation • Command being processed • Description of command being processed • Status of completion of the command (level detail appropriate to the individual command) • Next Command to be processed • Status Log Auto-Sequencing must be sto
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MODBUS TEST MON2000 10-1 MODBUS TEST 10 The Modbus Test Program (WinMB) enables you to test the operation of the serial port communications, and determine Modbus register and log contents. Use this program as an aid to software debugging or for special installations. Via WinMB, you can troubleshoot with any device including the GC Controller, an ultrasonic meter, or a flow computer.
10-2 MODBUS TEST MON2000 If MON2000 displays an error, verify the installation directory via the Program Settings function (see Section 2.16.2). The Modbus Test Program main window appears. 10.2 ESTABLISHING COMMUNICATIONS Use the following instructions to configure the desired communications settings. If you are accessing WinMB via MON2000, WinMB defaults to the same communications and serial port settings as those set for MON2000. To set up a WinMB-specific configuration, see Section 10.2.3.
MODBUS TEST MON2000 10-3 10.2.1 Comparison of Modbus Protocols MON2000 software and the WinMB program accommodate two different Modbus protocols: SIM_2251 and User_Modbus. For each protocol, separate Modbus registers are reserved. Thus some settings for MON2000 and WinMB depend on which Modbus protocol is used. The protocol you need depends, ultimately, on the hardware used for data acquisition from the GC Controller Modbus register contents.
10-4 MODBUS TEST MON2000 10.2.2 Set GC Com Parameters via MON2000 Set the communication parameters for the GC Controller serial port to which your PC, or other device, is connected. To determine or reset the communications parameters at the GC Controller, 1. Use the Application > Serial Ports menu to access the Serial Ports function. The Serial Ports dialog appears. 2. Verify the MON2000 serial port Usage setting. (a) Determine the GC Controller serial port to which you are directly connected.
MODBUS TEST MON2000 10-5 Typical settings are: Table 10-2 Typical GC Communications Parameters RTS On/Off settings are required only when line settling is needed before data transmission begins. Parameter RTU Setting ASCII Setting Data Bits 8 7 Stop Bits 1 1 Parity None Even Handshake None None RTS On 0 0 RTS Off 0 0 Ptrcl RTU ASCII Note that the RTU protocol permits a more efficient data transmission for it uses significantly less bits than ASCII. 5. Check the Com ID setting.
10-6 MODBUS TEST MON2000 1. Click the button to access the Port Setup function. The Port Setup dialog appears. 2. Define the WinMB serial port setup options.
MODBUS TEST MON2000 10.3 To access previous settings, use the spin arrows to view and select. 10-7 GETTING MODBUS DATA Use the following steps to read or write register contents to the GC Controller (or any other device). See the following subsections for additional details. Before retrieving data, print a PC Config Report (see Section 2.16.3) and check the Communication data for variable names assigned to the Modbus registers. 1.
10-8 MODBUS TEST MON2000 2. Use the Function pull-down menu to select the desired read or write option. Table 10-4 Available Modbus Function Codes Function Code Description Broadcast 1 (Read Coil) read one or more coil values 3 (Read Reg) read one or more register values 5 (Set Single Coil) set (write) one coil value 5 (Set Single Reg) set (write) one register value 15 (Set Multiple Coils) set (write) multiple coil values 16 (Set Multiple Regs) set (write) multiple register values 3.
MODBUS TEST MON2000 Boolean registers are not user-defined (for either SIM_2251 or User_Modbus) and primarily contain alarm flags useful for debugging. To view the contents of Boolean registers, select the “1 (Read Coil)” function code. Numeric registers for User_Modbus can be userdefined (see Section 5.18.4). To view the contents of Numeric registers, select the “3 (Read Regs)” function code.
10-10 MODBUS TEST MON2000 4. Click the button to retrieve the selected registers (i.e., the specified data addresses) from the GC Controller (or other device). Click the button to cease transmission and return to the Modbus Function Selection options. Note that the transmitted/received packet displays in the Packet Input-Output window. 10.3.
MODBUS TEST MON2000 10-11 Table 10-6 Using Record Numbers with Templates Data Type Setting Other Setting(s) Result register template • Enter Data Addr value. • Enter Record No. value. • Enter Quantity value. Read Quantity fields (i.e., the number of fields specified by the Quantity setting) from the specified Record No. of the register (Data Addr). log template • Enter Record No. value. Read all fields associated with the Record No. • Enter Data Addr value. • Enter “0” for the Record No. value.
10-12 MODBUS TEST MON2000 5. To open an existing template file, click the button. The Select Template Configuration File dialog appears. Use the directory tree to locate the desired file (e.g., temp1.cfg), highlight it, and then click the button. 6. To edit the displayed file, • Use the provided combo boxes to select a different data type. The Offset and Size values change to accommodate the data type. • Click the button to change all template data types to the type last selected. 7.
MODBUS TEST MON2000 10-13 Use the directory tree to specify the desired location. Either select an existing file or type the new file name (e.g., temp2.cfg) in the File name data field. Then click the button. 8. Click the button to apply your selections and return to the main window. Click the button to return to the main window without applying your selections. 10.
10-14 MODBUS TEST MON2000 10.4.1 Set Log Parameters The Log Data function allows you to log the polled data to a specified file. To set the log parameters for WinMB, The Log Data function is not required for transmission of Modbus data. 1. Click the button to access the To disable this function, Log Data function. The Log Data List dialog deselect the Enable Logging check box. appears. 2. Click the Enable Logging check box to turn this function ON and to access the Log Data Parameters.
MON2000 MODBUS TEST 10-15 3. Use the Logging Mode pull-down menu to select either a Sampling or Continuous mode. Continuous mode records the polled data continuously until the connection is terminated or the Log Data function is disabled (see Step 2). Sampling mode records the polled data per the user-defined Time Interval (e.g., every 2 minutes). 4. Select the desired logging type. Append adds this log to the file specified, preserving previously logged data.
10-16 MODBUS TEST MON2000 6. The Save As dialog appears. Use the directory tree to specify the desired location and choose a format type. Either select an existing file or type the new file You can save log data name in the File name data field. in any of these formats: 7. Click the button to create this • .txt, ASCII tablog file, apply your selections, and return to deliminated the main window. • .xls, Excel Click the button to abort and return to the main window. • .htm, HTML 10.4.
MODBUS TEST MON2000 You can save log data in any of these formats: • .txt, ASCII tabdeliminated • .xls, Excel • .htm, HTML 10-17 2. Use the directory tree to specify the desired location and either select an existing file or type the new file name in the File name data field. 3. Click the button to save this data and return to the main window. Click the button to return to the main window without saving this data. 10.4.
10-18 10.5 MODBUS TEST MON2000 TROUBLESHOOTING COMMUNICATION ERRORS The WinMB Communication Error Log is maintained in a circular buffer that holds up to 512 entries. WinMB tracks the errors for a given session but does not store them. When you exit WinMB, all errors are cleared. To view any communication errors that occurred during the data transfer, from the File>Modbus Test menu, 1. Click the button to access the Communication Error Log function. The Error dialog appears.
MODBUS TEST MON2000 10.6 10-19 USING MODBUS TEST ONLINE HELP Use the WinMB online help file to quickly access reference terminology, function descriptions, and other related information. See the following sections for more information. 10.6.1 How to Access To access online help, use the File>Modbus Test menu to display the Modbus Help test dialog, then, • Press F1 on your PC keyboard Or, • Click the toolbar. button located on the The Modbus Test Program Help Index displays.
10-20 MODBUS TEST MON2000 10.6.2 How to Navigate To navigate within this help file, • Click the button to display an index, a topic-tree contents menu, and a search function. • Click the button to display an index where you can select a specific term. • Click the topic viewed. button to return to the last • Click the topic. button to print the current Use the scroll bars and arrows to display more of a topic. You can also resize and/or move the topic window for better viewing convenience.
PC CONFIG REPORT MON2000 A-1 APPENDIX A, PC CONFIG REPORT AA This appendix explains how to print a PC Config Report and provides an example for reference. A.1 Output data for the PC Config Report depends on the GC Controller and its application. HOW TO PRINT Use the following instructions to print the current application settings for the online GC. To view a PC Config Report already saved to disk, see Section 7.1.2. 1. Use the File > PC Config Report menu to access this function.
A-2 PC CONFIG REPORT MON2000 3. Use the Output radio buttons to either save the report to disk, print the report with or without form feeds, or display on screen. If you want to use the standard Windows® Print dialog to select a printer, uncheck the Use default printer option. 4. Click the button or press the F4 key to generate your customized PC Config Report and print or save this file. By default, if a print option is selected, MON2000 will print the report to your configured printer (see Section 3.
System Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 Description Value -------------------------------------------------------------------------------Stream Sequence 1 Aux. Stream Sequence Analyzer Name 2350_001 Unit Type 2350 System Description 2350 Standard 1 - 64 avgs Chromatogram Buffers Size 21000 Max Peaks Number of Valves Daylight Saving Time CGM Analog Output Config Baseline Offset CFG Baseline Number Metric Base Conditions 64 5 Normal 0 12 1 Off Max. Archive Averages 64 Max.
Component Data Table Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 Component Data Table #1 No. Component U/S DetID RetTime Resp Factor F/V CalConc AnalMthd -------------------------------------------------------------------------------1 C6+ 47/35/17 STD 1 30.2 2013490 VAR 0.0289 % AREA 2 PROPANE STD 1 50.2 1316330 VAR 1.0 % AREA 3 i-BUTANE STD 1 65.7 1520820 VAR 0.3 % AREA 4 n-BUTANE STD 1 73.6 1545350 VAR 0.3 % AREA 5 NEOPENTANE STD 1 86.3 1651260 VAR 0.
No. Component Lb/Gal GPMFactor Reid Vapor RelDenGas RelDenLqd -------------------------------------------------------------------------------1 C6+ 47/35/17 5.6681 0.4462 3.0194 3.3132 0.68 2 PROPANE 4.227 0.2756 188.64 1.5226 0.507 3 i-BUTANE 4.693 0.3271 72.591 2.0068 0.5629 4 n-BUTANE 4.869 0.3153 51.709 2.0068 0.584 5 NEOPENTANE 4.975 0.383 35.9 2.4911 0.5967 6 i-PENTANE 5.206 0.3661 20.445 2.4912 0.6244 7 n-PENTANE 5.261 0.3622 15.574 2.4912 0.
Timed Event Table Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 Timed Event Table #1 Analysis Time 225 Cycle Time 240 Sample Valve Y N N N N -------------------------------------------------------------------------------Valve # 2 ON Inhibit Valve # 0.0 @ 0.0 @ 2.0 8 1 @ 3.0 6 @ 4.0 @ 5.0 @ 7.0 @ 8.0 ON 3 Detector 1 ON Slope Sens Valve # @ 1 1 ON Strm Switch Peak Width 4 1 Valve # 1 OFF @ 10.0 Valve # 2 OFF @ 23.0 Inhibit OFF 1 @ 26.
User-Defined Numeric Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Name Type Value -------------------------------------------------------------------------------No entries found. ******************************************************************************** User-Defined Selection Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No.
Options for Maint_mode --------------------------No. Name ---------------------1 OFF 2 ON Options for Run_Aux_Seq --------------------------No. Name ---------------------1 OFF 2 ON ******************************************************************************** User-Defined Text Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No.
Calculation Control Report from 2350_001 2350_001.
HeatVal Inf Sat MJ/m3 N N N N N N N N HeatVal Inf Act MJ/m3 N N N N N N N N HeatVal Sup Dry MJ/kg N N N N N N N N HeatVal Inf Dry MJ/kg N N N N N N N N HeatVal Sup Dry Kc/m3 N N N N N N N N HeatVal Sup Sat Kc/m3 N N N N N N N N HeatVal Sup Act Kc/m3 N N N N N N N N HeatVal Inf Dry Kc/m3 N N N N N N N N HeatVal Inf Sat Kc/m3 N N N N N N N N HeatVal Inf Act Kc/m3 N N N N N N N N HeatVal Sup Dry Kc/kg N N N N N N N
Calculation User-Defined Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Variable S C -------------------------------------------------------------------------------1 label 1 Avg. Molecular Weight 1 1 + Gallons/1000 SCF 1 1 * Gas Density lbm/1000 ft3 1 1 / Heating Value Gross BTU Dry 1 1 - Mole Percent 1 1 Gallons/1000 SCF 1 2 + Gallons/1000 SCF 1 3 + User Calc Result 1 1 + Value 1 1 2 label 2 1: 16.
Streams Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 Cal Data No. Name Use Det CD TE Tot Avg Start Base Condition Int Auto PSIA °F -------------------------------------------------------------------------------1 Stream 1 ANL Det1 1 1 5 3 07:00 24 Y Y 14.73 60 2 Stream 2 ANL Det1 1 1 5 3 07:00 24 Y Y 14.73 60 3 Stream 3 ANL Det1 1 1 5 3 07:00 24 Y Y 14.73 60 4 Stream 4 ANL Det1 1 1 5 3 07:00 24 Y Y 14.
Analog Output Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Variable S C -------------------------------------------------------------------------------1 No. Mole Percent Zero Scale 1 Full Scale F/V 1 Fixed Value -------------------------------------------------------------------------------1 0 100 VAR 0 Bargraph No.
Scaling Values No. Zero Scale Full Scale -------------------------------------------------------------------------------1 0 100 2 0 100 3 0 100 4 0 100 5 0 100 6 0 100 7 0 100 8 0 100 9 0 100 10 0 100 11 0 0 12 0 0 13 0 0 14 0 0 15 0 0 16 0 0 ******************************************************************************** Discrete Input Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No.
Discrete Output Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Label Switch On-Time Off-Time -------------------------------------------------------------------------------1 DO 1 AUTO 00:00 00:00 2 DO 2 AUTO 00:00 00:00 3 DO 3 AUTO 00:00 00:00 4 Common_Alarm AUTO 00:00 00:00 5 Calib-Maint AUTO 00:00 00:00 ******************************************************************************** Valve Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No.
Global Data Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Variable name Indices S Type No. of Chars.
25 sim_dbtu 1 1 Float 26 sim_dummy 4 1 Float 27 sim_gpmwt 16 4 Float 28 sim_hour 1 1 Integer 29 sim_min 1 1 Integer 30 sim_molpct 16 4 Float 31 sim_month 1 1 Integer 32 sim_newdata 1 1 Integer 33 sim_rden_gas 1 1 Float 34 sim_rf 16 4 Float 35 sim_sbtu 1 1 Float 36 sim_smask 1 1 Integer 37 sim_stream 1 1 Integer 38 sim_totgpm 1 1 Float 39 sim_unnormal 1 1 Float 40 sim_wobbe 1 1 Float 41 sim_year 1 1 Integer *****************
Component Data Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. Structure Name No. of Streams No. of Components per Stream -------------------------------------------------------------------------------No entries found. ******************************************************************************** Data Files Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No. File Name No.
Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 No.
STRING 0 TIME VAR stream_data cycl_strt_tm STREAM_NO 1 STRING 0 0 VARIABLE anlyzr_name 1 1 STRING 0 0 VARIABLE seqtxt DET NO 1 0 VARIABLE rpt_header1 1 1 0 VARIABLE rpt_header2 1 1 0 TABLE 2 TVAR cdt stdusr CDT_TBL_NO 1* 0 TVAR cdt compnam CDT_TBL_NO 1* 0 TVAR analysis molpct STREAM_NO 1* 25 TVAR analysis wtpct STREAM_NO 1* 26 TVAR analysis liqvolpct STREAM_NO 1* 27 TVAR analysis gpm STREAM_NO 1* 28 TVAR analysis btu_gross STREAM_NO 1* 29
VARIABLE stream_data totl_ikg_dry STREAM_NO 1 0 STRING 0 STRING 32 VARIABLE strms base_pres STREAM_NO 1 0 STRING 250 STRING 251 VARIABLE strms base_temp STREAM_NO 1 0 STRING 32 STRING 250 STRING 251 STRING 32 VARIABLE stream_data z_factor STREAM_NO 1 STRING VARIABLE strms 0 0 base_pres STREAM_NO 1 0 VARIABLE op_pressures STREAM_NO 1 0 VARIABLE op_pressures STREAM_NO 2 0 VARIABLE op_pressures STREAM_NO 3 0 STRING 0 STRING 81 STRING 82 STRING 83 STR
VARIABLE op_pres_calc STREAM_NO 26 0 STRING 44 STRING 40 STRING 40 VARIABLE stream_data btuact_gross STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 3 0 VARIABLE op_pres_calc STREAM_NO 15 0 VARIABLE op_pres_calc STREAM_NO 27 0 STRING 52 STRING 30 STRING 30 VARIABLE stream_data btu_dry_net STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 4 0 VARIABLE op_pres_calc STREAM_NO 16 0 VARIABLE op_pres_calc STREAM_NO 28 0 STRING 45 STRING 41 STRING 41 VARIABLE strea
VARIABLE op_pres_calc STREAM_NO 20 0 VARIABLE op_pres_calc STREAM_NO 32 0 STRING VARIABLE stream_data 48 totl_gpmc3 STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 9 0 VARIABLE op_pres_calc STREAM_NO 21 0 VARIABLE op_pres_calc STREAM_NO 33 0 STRING VARIABLE stream_data 49 totl_gpmc4 STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 10 0 VARIABLE op_pres_calc STREAM_NO 22 0 VARIABLE op_pres_calc STREAM_NO 34 0 STRING VARIABLE stream_data 50 totl_gpmc5 STREAM_NO 1 0 VA
STRING 157 STRING 61 VARIABLE stream_data sup_m3_act STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 3 0 VARIABLE op_pres_calc STREAM_NO 15 0 VARIABLE op_pres_calc STREAM_NO 28 0 STRING 158 STRING 62 VARIABLE stream_data inf_m3_dry STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 4 0 VARIABLE op_pres_calc STREAM_NO 16 0 VARIABLE op_pres_calc STREAM_NO 28 0 STRING 159 STRING 63 VARIABLE stream_data inf_m3_sat STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 5 0
VARIABLE op_pres_calc STREAM_NO 9 0 VARIABLE op_pres_calc STREAM_NO 21 0 VARIABLE op_pres_calc STREAM_NO 33 0 STRING 185 STRING 68 VARIABLE stream_data ssat_kcal_m3 STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 7 0 VARIABLE op_pres_calc STREAM_NO 19 0 VARIABLE op_pres_calc STREAM_NO 31 0 STRING 186 STRING 69 VARIABLE stream_data sact_kcal_m3 STREAM_NO 1 0 VARIABLE op_pres_calc STREAM_NO 8 0 VARIABLE op_pres_calc STREAM_NO 20 0 VARIABLE op_pres_calc STREAM_N
STRING 190 STRING 73 VARIABLE stream_data sdry_kcal_kg STREAM_NO 1 0 STRING 191 STRING 74 VARIABLE stream_data idry_kcal_kg STREAM_NO 1 0 STRING 192 STRING 31 VARIABLE stream_data real_rd_gas STREAM_NO 1 STRING VARIABLE stream_data 34 real_rd_lqd STREAM_NO 1 STRING VARIABLE stream_data 0 0 58 rden_lqd_15 STREAM_NO 1 0 STRING 58 STRING 33 VARIABLE stream_data totl_unrml STREAM_NO 1 STRING VARIABLE stream_data 0 77 avg_molwgt STREAM_NO 1 0 STRING 35 STRING
STRING 76 STRING 38 VARIABLE stream_data reid_vapor STREAM_NO 1 STRING 0 38 TABLE 200 TVAR anlin TVAR aincur label 1* 1 0 1* 1 0 STRING 160 TABLE 160 TVAR calcs TVAR calcval label 1* 1 0 1* 1 0 * indicates index is incremented.
VARIABLE anlyzr_name 1 1 STRING 0 0 VARIABLE seqtxt DET NO 1 0 VARIABLE rpt_header1 1 1 0 VARIABLE rpt_header2 1 1 0 TABLE 50 TVAR raw_data peak_num STREAM_NO 1* 21 TVAR raw_data rt STREAM_NO 1* 21 TVAR raw_data area STREAM_NO 1* 21 TVAR raw_data height STREAM_NO 1* 21 TVAR raw_data detector STREAM_NO 1* 21 TVAR raw_data2 method STREAM_NO 1* 21 TVAR raw_data3 startint STREAM_NO 1* 21 TVAR raw_data3 endint STREAM_NO 1* 21 TVAR raw_data3 hal
STRING 0 VARIABLE stream_data stream_num STREAM_NO 1 0 VARIABLE strms name STREAM_NO 1 0 STRING 0 VARIABLE stream_data run_mode STREAM_NO 1 STRING 0 0 TIME VAR stream_data cycl_strt_tm STREAM_NO 1 STRING 0 0 VARIABLE anlyzr_name 1 1 STRING 0 0 VARIABLE seqtxt DET NO 1 0 VARIABLE rpt_header1 1 1 0 VARIABLE rpt_header2 1 1 0 TABLE 2 TVAR cdt compnam CDT_TBL_NO 1* 0 TVAR cdt cal_conc CDT_TBL_NO 1* 0 TVAR cal_avgs raw STREAM_NO 1* 0 TVAR cal_avgs
* indicates index is incremented.
TVAR cal_results rfdev STREAM_NO 1* 0 TVAR cal_results oldrt STREAM_NO 1* 0 TVAR cal_results newrt STREAM_NO 1* 0 TVAR cal_results updated STREAM_NO 1* 0 TVAR cal_results rtdev STREAM_NO 1* 0 ALARMS 0 * indicates index is incremented.
VARIABLE avg_archive2 1* 1 STRING 0 0 VARIABLE avg_archive1 avg 1* 2 0 VARIABLE avg_archive1 minimum 1* 2 0 VARIABLE avg_archive1 maximum 1* 2 0 1* 2 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 3 0 VARIABLE avg_archive1 minimum 1* 3 0 VARIABLE avg_archive1 maximum 1* 3 0 1* 3 0 VARIABLE avg_archive2 * indicates index is incremented.
STRING 0 STRING 0 VARIABLE avg_archive1 avg 1* 1 0 VARIABLE avg_archive1 minimum 1* 1 0 VARIABLE avg_archive1 maximum 1* 1 0 1* 1 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 2 0 VARIABLE avg_archive1 minimum 1* 2 0 VARIABLE avg_archive1 maximum 1* 2 0 1* 2 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 3 0 VARIABLE avg_archive1 minimum 1* 3 0 VARIABLE avg_archive1 maximum 1* 3 0 1* 3 0 VARIABLE avg_archive2 * indi
VARIABLE avg_data c 1* 1 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 VARIABLE avg_archive1 avg 1* 1 0 VARIABLE avg_archive1 minimum 1* 1 0 VARIABLE avg_archive1 maximum 1* 1 0 1* 1 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 2 0 VARIABLE avg_archive1 minimum 1* 2 0 VARIABLE avg_archive1 maximum 1* 2 0 1* 2 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 3 0 VARIABLE avg_archive1 minimum 1*
VARIABLE avg_data number 1* 1 0 VARIABLE avg_data label 1* 1 0 STRING VARIABLE avg_data 0 s 1* 1 STRING VARIABLE avg_data 0 129 c 1* 1 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 VARIABLE avg_archive1 avg 1* 1 0 VARIABLE avg_archive1 minimum 1* 1 0 VARIABLE avg_archive1 maximum 1* 1 0 1* 1 0 VARIABLE avg_archive2 STRING 0 VARIABLE avg_archive1 avg 1* 2 0 VARIABLE avg_archive1 minimum 1* 2 0 VARIABLE avg_archive1 maximum 1
Type Variable SubField Name Indices CP Flag ------------------------------------------------------------------------STRING 0 STRING 0 VARIABLE anlyzr_name 1 1 0 VARIABLE rpt_header1 1 1 0 VARIABLE rpt_header2 1 1 0 VARIABLE avg_data number 1* 1 0 VARIABLE avg_data label 1* 1 0 STRING VARIABLE avg_data 0 s 1* 1 STRING VARIABLE avg_data 0 129 c 1* 1 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 STRING 0 VARIABLE avg_archive1 avg 1* 1 0 VARIA
Communication Report from 2350_001 2350_001.BIN 6/2/2000 15:02:49 Slave Name Slave ID Slave Type ----------------------------------------------------------------------------------USER_MODBUS 0 PLC Emulation - Low-Hi SIM_2251 3 Daniel 2500 Emulation USER_MODBUS ------------Modbus Variable Field Reg.
18 sysalarm_set 19 1 Valve Timing Failure No 19 sysalarm_set 20 1 Excess Response Factor Deviation No 20 sysalarm_set 21 1 M200 Invalid Non-Volatile Data No 21 sysalarm_set 22 1 M200 Invalid A Module Data No 22 sysalarm_set 23 1 M200 Invalid B Module Data No 23 sysalarm_set 24 1 M200 Bad Options No 24 sysalarm_set 25 1 M200 Stack Overflow No 25 sysalarm_set 26 1 M200 Hardware Shutdown No 26 sysalarm_set 27 1 M200 Synchronization Failure No 27 sysalarm_s
51 sysalarm_set 52 1 Analog Output 4 LOW No 52 sysalarm_set 53 1 Analog Output 5 LOW No 53 sysalarm_set 54 1 Analog Output 6 LOW No 54 sysalarm_set 55 1 Analog Output 7 LOW No 55 sysalarm_set 56 1 Analog Output 8 LOW No 56 sysalarm_set 57 1 Analog Output 9 LOW No 57 sysalarm_set 58 1 Analog Output 10 LOW No 58 sysalarm_set 59 1 Analog Output 11 LOW No 59 sysalarm_set 60 1 Analog Output 12 LOW No 60 sysalarm_set 61 1 Analog Output 13 LOW No 61 sysa
84 sysalarm_set 85 1 NA No 85 lmtalarm_set 1 1 No 86 lmtalarm_set 2 1 No 87 lmtalarm_set 3 1 No 88 lmtalarm_set 4 1 No 89 lmtalarm_set 5 1 No 90 lmtalarm_set 6 1 No 91 lmtalarm_set 7 1 No 92 lmtalarm_set 8 1 No 93 lmtalarm_set 9 1 No 94 lmtalarm_set 10 1 No 95 lmtalarm_set 11 1 No 96 lmtalarm_set 12 1 No 97 lmtalarm_set 13 1 No 98 lmtalarm_set 14 1 No 99 lmtalarm_set 15 1 No 100 lmtalarm_set 16 1 No 101 lmtalarm_set 17
Numeric(Registers) 0 stream_data avg_molwgt 1 1 Char 4 Stream 1 No 2 analysis molpct 1 1 Char 4 C6+ 47/35/17 0 - 1 No 3 analysis molpct 1 2 Integer PROPANE 0 - 1 No 4 analysis molpct 1 3 Integer i-BUTANE 0 - 1 No 5 analysis molpct 1 4 Integer n-BUTANE 0 - 1 No 6 analysis molpct 1 5 Float NEOPENTANE No 8 analysis molpct 1 6 Float i-PENTANE No 10 analysis molpct 1 7 Float n-PENTANE No 12 analysis molpct 1 8 Float NITROGEN No 14 analys
Boolean(Coils) 16-Bit Integer 3001 sim_compno 1 1 No 3002 sim_compno 2 1 No 3003 sim_compno 3 1 No 3004 sim_compno 4 1 No 3005 sim_compno 5 1 No 3006 sim_compno 6 1 No 3007 sim_compno 7 1 No 3008 sim_compno 8 1 No 3009 sim_compno 9 1 No 3010 sim_compno 10 1 No 3011 sim_compno 11 1 No 3012 sim_compno 12 1 No 3013 sim_compno 13 1 No 3014 sim_compno 14 1 No 3015 sim_compno 15 1 No 3016 sim_compno 16 1 No 3017 sim_compno 1 1 No
3028 sim_compno 12 1 No 3029 sim_compno 13 1 No 3030 sim_compno 14 1 No 3031 sim_compno 15 1 No 3032 sim_compno 16 1 No 3033 sim_anlytime 1 1 No 3034 sim_stream 1 1 No 3035 sim_smask 1 1 No 3036 sim_month 1 1 No 3037 sim_day 1 1 No 3038 sim_year 1 1 No 3039 sim_hour 1 1 No 3040 sim_min 1 1 No 3041 sim_cycmonth 1 1 No 3042 sim_cycday 1 1 No 3043 sim_cycyear 1 1 No 3044 sim_cychour 1 1 No 3045 sim_cycmin 1 1 No 3046 sim
32-Bit Integer 5001 sim_cyctime 1 1 No 5002 sim_calcycle 1 1 No Floating-Point 7001 sim_molpct 1 1 No 7002 sim_molpct 2 1 No 7003 sim_molpct 3 1 No 7004 sim_molpct 4 1 No 7005 sim_molpct 5 1 No 7006 sim_molpct 6 1 No 7007 sim_molpct 7 1 No 7008 sim_molpct 8 1 No 7009 sim_molpct 9 1 No 7010 sim_molpct 10 1 No 7011 sim_molpct 11 1 No 7012 sim_molpct 12 1 No 7013 sim_molpct 13 1 No 7014 sim_molpct 14 1 No 7015 sim_molpct 15 1 N
7030 sim_gpmwt 14 1 No 7031 sim_gpmwt 15 1 No 7032 sim_gpmwt 16 1 No 7033 sim_dbtu 1 1 No 7034 sim_sbtu 1 1 No 7035 sim_rden_gas 1 1 No 7036 sim_compress 1 1 No 7037 sim_wobbe 1 1 No 7038 sim_unnormal 1 1 No 7039 sim_totgpm 1 1 No 7040 calcval 1 1 label 1 No 7041 calcval 2 1 label 2 No 7042 calcval 3 1 No 7043 calcval 4 1 No 7044 calcval 5 1 No 7045 sim_dummy 1 1 No 7046 sim_dummy 1 1 No 7047 sim_dummy 1 1 No 7048 s
7063 avgs avg 9 1 Not Used No 7064 avgs avg 10 1 Not Used No 7065 avgs avg 11 1 Not Used No 7066 avgs avg 12 1 Not Used No 7067 avgs avg 13 1 Not Used No 7068 avgs avg 14 1 Not Used No 7069 avgs avg 15 1 Not Used No 7070 avg_archive1 avg 1 1 Not Used No 7071 avg_archive1 avg 2 1 Not Used No 7072 avg_archive1 avg 3 1 Not Used No 7073 avg_archive1 avg 4 1 Not Used No 7074 avg_archive1 avg 5 1 Not Used No 7075 avg_archive1 avg 6
7096 sim_rf 2 1 No 7097 sim_rf 3 1 No 7098 sim_rf 4 1 No 7099 sim_rf 5 1 No 7100 sim_rf 6 1 No 7101 sim_rf 7 1 No 7102 sim_rf 8 1 No 7103 sim_rf 9 1 No 7104 sim_rf 10 1 No 7105 sim_rf 11 1 No 7106 sim_rf 12 1 No 7107 sim_rf 13 1 No 7108 sim_rf 14 1 No 7109 sim_rf 15 1 No 7110 sim_rf 16 1 No 7111 sim_rf 1 1 No 7112 sim_rf 2 1 No 7113 sim_rf 3 1 No 7114 sim_rf 4 1 No 7115 sim_rf 5 1 No 7116 sim_rf 6 1 No 7
7129 avgs avg 3 1 Not Used No 7130 avgs avg 4 1 Not Used No 7131 avgs avg 5 1 Not Used No 7132 avgs avg 6 1 Not Used No 7133 avgs avg 7 1 Not Used No 7134 avgs avg 8 1 Not Used No 7135 avgs avg 9 1 Not Used No 7136 avgs avg 10 1 Not Used No 7137 avgs avg 11 1 Not Used No 7138 avgs avg 12 1 Not Used No 7139 avgs avg 13 1 Not Used No 7140 avgs avg 14 1 Not Used No 7141 avgs avg 15 1 Not Used No 7142 avgs avg 16 1 N
7162 avgs avg 36 1 Not Used No 7163 avgs maximum 1 1 Not Used No 7164 avgs maximum 2 1 Not Used No 7165 avgs maximum 3 1 Not Used No 7166 avgs maximum 4 1 Not Used No 7167 avgs maximum 5 1 Not Used No 7168 avgs maximum 6 1 Not Used No 7169 avgs maximum 7 1 Not Used No 7170 avgs maximum 8 1 Not Used No 7171 avgs maximum 9 1 Not Used No 7172 avgs maximum 10 1 Not Used No 7173 avgs maximum 11 1 Not Used No 7174 avgs maximum
7195 avgs maximum 33 1 Not Used No 7196 avgs maximum 34 1 Not Used No 7197 avgs maximum 35 1 Not Used No 7198 avgs maximum 36 1 Not Used No 7199 avgs minimum 1 1 Not Used No 7200 avgs minimum 2 1 Not Used No 7201 avgs minimum 3 1 Not Used No 7202 avgs minimum 4 1 Not Used No 7203 avgs minimum 5 1 Not Used No 7204 avgs minimum 6 1 Not Used No 7205 avgs minimum 7 1 Not Used No 7206 avgs minimum 8 1 Not Used No 7207 avgs mini
7228 avgs minimum 30 1 Not Used No 7229 avgs minimum 31 1 Not Used No 7230 avgs minimum 32 1 Not Used No 7231 avgs minimum 33 1 Not Used No 7232 avgs minimum 34 1 Not Used No 7233 avgs minimum 35 1 Not Used No 7234 avgs minimum 36 1 Not Used No 7235 avg_archive1 avg 1 1 Not Used No 7236 avg_archive1 avg 2 1 Not Used No 7237 avg_archive1 avg 3 1 Not Used No 7238 avg_archive1 avg 4 1 Not Used No 7239 avg_archive1 avg 5 1 Not Used No
7261 avg_archive1 avg 27 1 Not Used No 7262 avg_archive1 avg 28 1 Not Used No 7263 avg_archive1 avg 29 1 Not Used No 7264 avg_archive1 avg 30 1 Not Used No 7265 avg_archive1 avg 31 1 Not Used No 7266 avg_archive1 avg 32 1 Not Used No 7267 avg_archive1 avg 33 1 Not Used No 7268 avg_archive1 avg 34 1 Not Used No 7269 avg_archive1 avg 35 1 Not Used No 7270 avg_archive1 avg 36 1 Not Used No 7271 avg_archive1 maximum 1 1 Not Used No 7272 avg_arch
7294 avg_archive1 maximum 24 1 Not Used No 7295 avg_archive1 maximum 25 1 Not Used No 7296 avg_archive1 maximum 26 1 Not Used No 7297 avg_archive1 maximum 27 1 Not Used No 7298 avg_archive1 maximum 28 1 Not Used No 7299 avg_archive1 maximum 29 1 Not Used No 7300 avg_archive1 maximum 30 1 Not Used No 7301 avg_archive1 maximum 31 1 Not Used No 7302 avg_archive1 maximum 32 1 Not Used No 7303 avg_archive1 maximum 33 1 Not Used No 7304 avg_archive1 max
7327 avg_archive1 minimum 21 1 Not Used No 7328 avg_archive1 minimum 22 1 Not Used No 7329 avg_archive1 minimum 23 1 Not Used No 7330 avg_archive1 minimum 24 1 Not Used No 7331 avg_archive1 minimum 25 1 Not Used No 7332 avg_archive1 minimum 26 1 Not Used No 7333 avg_archive1 minimum 27 1 Not Used No 7334 avg_archive1 minimum 28 1 Not Used No 7335 avg_archive1 minimum 29 1 Not Used No 7336 avg_archive1 minimum 30 1 Not Used No 7337 avg_archive1 min
7360 avg_archive1 avg 18 2 Not Used No 7361 avg_archive1 avg 19 2 Not Used No 7362 avg_archive1 avg 20 2 Not Used No 7363 avg_archive1 avg 21 2 Not Used No 7364 avg_archive1 avg 22 2 Not Used No 7365 avg_archive1 avg 23 2 Not Used No 7366 avg_archive1 avg 24 2 Not Used No 7367 avg_archive1 avg 25 2 Not Used No 7368 avg_archive1 avg 26 2 Not Used No 7369 avg_archive1 avg 27 2 Not Used No 7370 avg_archive1 avg 28 2 Not Used No 7371 avg_archive
7393 avg_archive1 maximum 15 2 Not Used No 7394 avg_archive1 maximum 16 2 Not Used No 7395 avg_archive1 maximum 17 2 Not Used No 7396 avg_archive1 maximum 18 2 Not Used No 7397 avg_archive1 maximum 19 2 Not Used No 7398 avg_archive1 maximum 20 2 Not Used No 7399 avg_archive1 maximum 21 2 Not Used No 7400 avg_archive1 maximum 22 2 Not Used No 7401 avg_archive1 maximum 23 2 Not Used No 7402 avg_archive1 maximum 24 2 Not Used No 7403 avg_archive1 max
7426 avg_archive1 minimum 12 2 Not Used No 7427 avg_archive1 minimum 13 2 Not Used No 7428 avg_archive1 minimum 14 2 Not Used No 7429 avg_archive1 minimum 15 2 Not Used No 7430 avg_archive1 minimum 16 2 Not Used No 7431 avg_archive1 minimum 17 2 Not Used No 7432 avg_archive1 minimum 18 2 Not Used No 7433 avg_archive1 minimum 19 2 Not Used No 7434 avg_archive1 minimum 20 2 Not Used No 7435 avg_archive1 minimum 21 2 Not Used No 7436 avg_archive1 min
7459 avg_archive1 avg 9 3 Not Used No 7460 avg_archive1 avg 10 3 Not Used No 7461 avg_archive1 avg 11 3 Not Used No 7462 avg_archive1 avg 12 3 Not Used No 7463 avg_archive1 avg 13 3 Not Used No 7464 avg_archive1 avg 14 3 Not Used No 7465 avg_archive1 avg 15 3 Not Used No 7466 avg_archive1 avg 16 3 Not Used No 7467 avg_archive1 avg 17 3 Not Used No 7468 avg_archive1 avg 18 3 Not Used No 7469 avg_archive1 avg 19 3 Not Used No 7470 avg_archive1
7492 avg_archive1 maximum 6 3 Not Used No 7493 avg_archive1 maximum 7 3 Not Used No 7494 avg_archive1 maximum 8 3 Not Used No 7495 avg_archive1 maximum 9 3 Not Used No 7496 avg_archive1 maximum 10 3 Not Used No 7497 avg_archive1 maximum 11 3 Not Used No 7498 avg_archive1 maximum 12 3 Not Used No 7499 avg_archive1 maximum 13 3 Not Used No 7500 avg_archive1 maximum 14 3 Not Used No 7501 avg_archive1 maximum 15 3 Not Used No 7502 avg_archive1 maximum
7525 avg_archive1 minimum 3 3 Not Used No 7526 avg_archive1 minimum 4 3 Not Used No 7527 avg_archive1 minimum 5 3 Not Used No 7528 avg_archive1 minimum 6 3 Not Used No 7529 avg_archive1 minimum 7 3 Not Used No 7530 avg_archive1 minimum 8 3 Not Used No 7531 avg_archive1 minimum 9 3 Not Used No 7532 avg_archive1 minimum 10 3 Not Used No 7533 avg_archive1 minimum 11 3 Not Used No 7534 avg_archive1 minimum 12 3 Not Used No 7535 avg_archive1 minimum 1
PC CONFIG REPORT MON2000 7558 avg_archive1 minimum No 36 3 A-61 Not Used *************************************************************************** ******* *************************************************************************** ***** TCP/IP Report from Model 2350A 4/28/2005 2:00:51 PM ------------------------------------------------------------------------------Usage PC Comm ID 0 Host Name DANIELGC Use DHCP/Specify an IP address Specify an IP Address IP Address 172.16.23.128 Subnet Mask 255.255.
A-62 PC CONFIG REPORT MON2000 This page is intentionally left blank.
APPENDIX B: COMPONENT DATA TABLE A This appendix provides a sample standard component data table as well as a table of the ISO-related components. • Table B-1, Example Standard Component Data Table • Table B-2, ISO Component Data Table All values depend on a base pressure of 14.73 PSIA and a base temperature of 60 oF (15.56 oC). BTU components that are listed in Table B-1 reference GPA Standard 2145-09. The ISO component data table references ISO Standard 6976: 1995(E).
B-2 Component Data Table Table B-1 Example Standard Component Data Table Mol Wt Reid Vapor Acetylene 26.04 0 0.899 0.615 0 0 1476.9 1426.5 Ethane 22 Air 28.9625 0 1 0.87586 7.3022 0.104759 0 0 Airmix1 26 Argon 39.95 0 1.3792 0 0 0 0 0 Argon 46 Ammonia 17.03 212 0.588 0.6173 5.15 0.0874 435.4 359.8 None * Benzene 78.11 3.224 2.6969 0.8844 7.373 0.2798 3750.5 3599.2 n-Hexane * 0.32117 3264.64 3012.45 n-Butane 33 Butanes 58.1222 62.
Component Name C6+ 57/28/14 Mol Wt Reid Vapor 94.1904 3.37386 Rel Dens Rel Dens Gas Liquid Lb/Gal 3.25214 GPM Factor 0.677036 5.64458 0.439881 Daniel Gross Dry Net Dry AGA 8 Sim 2251 BTU BTU Component I.D. No. 5194.53 4812.82 C6mix4 11 28.01 0 0.9671 0.801 6.68 0 321.2 321.2 CO 15 Carbon Dioxide 44.0095 0 1.5195 0.81716 6.8129 0.170618 0 0 CO2 17 Cis-2-Butene 56.11 45.54 1.9372 0.6271 5.228 0.2835 3079.3 2877.6 n-Butane 31 COS 60.
Reid Vapor GPM Factor H2S 34.0809 395 1.1767 0.79886 6.6602 0.135156 638.57 588.15 H2S 40 HCL 36.46 925 1.2588 0.8558 7.135 0.1349 0 0 None * Helium 4.0026 0 0.1382 0.12486 1.041 0.101559 0 0 Helium 13 Hydrogen 2.02 0 0.0696 0.07 0 0 325 274.4 Hydrogen 12 i-Butane 58.1222 72.644 2.0068 0.56283 4.6925 0.327158 3259.42 3006.94 i-Butane 03 i-Butene 56.11 63.4 1.9372 0.6004 5.006 0.296 3068.2 2866.5 n-Butane 27 i-Pentane 72.1488 20.474 2.
Rel Dens Rel Dens Gas Liquid Lb/Gal GPM Factor Daniel Gross Dry Net Dry AGA 8 Sim 2251 BTU BTU Component I.D. No. Mol Wt Reid Vapor n-Hexane 86.1754 4.961 2.9754 0.66406 5.5364 0.411121 4766.9 4414.19 n-Hexane 39 n-Nonane 128.2551 0.1809 4.4283 0.72224 6.0215 0.562592 7012.49 6508.02 n-Nonane 38 n-Octane 114.2285 0.5349 3.944 0.70655 5.8907 0.512168 6263.46 5809.41 n-Octane 20 n-Pentane 72.1488 15.576 2.4911 0.63071 5.2584 0.362396 4017.97 3715.
Rel Dens Rel Dens Gas Liquid Lb/Gal GPM Factor Daniel Gross Dry Net Dry AGA 8 Sim 2251 BTU BTU Component I.D. No. Component Name Mol Wt Reid Vapor Styrene 104.15 0.24 3.5959 0.911 7.595 0.3622 5042.7 4841 n-Octane * Toluene 92.14 1.032 3.1812 0.8718 7.268 0.3348 4485.4 4283.5 n-Heptane * Trans-2-Butene 56.11 49.8 1.9372 0.61 5.086 0.2914 3075.1 2873.4 n-Butane 30 Triptane 100.21 3.374 3.4596 0.6946 5.791 0.4571 5496.2 5093 n-Heptane * Water 18.0153 0.
Molar Mass Sum Factor (0°C) Sum Factor (15°C) Sum Factor (20°C) CV Sup kJ/Mol (0°C) CV Sup kJ/Mol (15°C) CV Sup kJ/Mol (20°C) CV Sup kJ/Mol (25°C) CV Inf kJ/Mol (0°C) CV Inf kJ/Mol (15°C) CV Inf kJ/ Mol (20°C) CV Inf kJ/ Mol (25°C) Acetylene 26.038 0.0949 0.0837 0.0837 1301.86 1301.37 1301.21 1301.05 1256.79 1256.94 1256.98 1257.03 Air 28.9625 0 0 0 0 0 0 0 0 0 0 0 Argon 39.948 0.0316 0.0283 0.0265 0 0 0 0 0 0 0 0 Ammonia 17.0306 0.1225 0.1095 0.
Molar Mass Sum Factor (0°C) Sum Factor (15°C) Sum Factor (20°C) CV Sup kJ/Mol (0°C) CV Sup kJ/Mol (15°C) CV Sup kJ/Mol (20°C) CV Sup kJ/Mol (25°C) CV Inf kJ/Mol (0°C) CV Inf kJ/Mol (15°C) CV Inf kJ/ Mol (20°C) CV Inf kJ/ Mol (25°C) C6+ 57/28/14 94.1904 0.3781 0.3367 0.3243 4580.15 4574.76 4572.96 4571.2 4238.87 4238.34 4238.12 4237.94 Carbon Monoxide 28.01 0.0265 0.0224 0.02 282.8 282.91 282.95 282.98 282.8 282.91 282.95 282.98 Carbon Dioxide 44.0095 0.0819 0.
Molar Mass Sum Factor (0°C) Sum Factor (15°C) Sum Factor (20°C) CV Sup kJ/Mol (0°C) CV Sup kJ/Mol (15°C) CV Sup kJ/Mol (20°C) CV Sup kJ/Mol (25°C) CV Inf kJ/Mol (0°C) CV Inf kJ/Mol (15°C) CV Inf kJ/ Mol (20°C) CV Inf kJ/ Mol (25°C) 3-Ethylpentane 100.21 0 0 0 0 0 0 0 0 0 0 0 H2S 34.0809 0.1 0.1 0.1 562.94 562.38 562.19 562.01 517.87 517.95 517.97 517.99 HCL 36.46 925 1.2588 0.8558 7.135 0.1349 0 0 0 0 0 0 Helium 4.0026 0.0006 0.
Molar Mass Sum Factor (0°C) Sum Factor (15°C) Sum Factor (20°C) CV Sup kJ/Mol (0°C) CV Sup kJ/Mol (15°C) CV Sup kJ/Mol (20°C) CV Sup kJ/Mol (25°C) CV Inf kJ/Mol (0°C) CV Inf kJ/Mol (15°C) CV Inf kJ/ Mol (20°C) CV Inf kJ/ Mol (25°C) n-Decane 142.2817 0.7523 0.645 0.614 6842.69 6834.9 6832.31 6829.77 6346.88 6346.14 6345.85 6345.59 n-Heptane 100.2019 0.4123 0.3661 0.3521 4862.87 4857.18 4855.29 4853.43 4502.28 4501.72 4501.49 4501.3 n-Hexane 86.1754 0.3286 0.295 0.
Component Name Molar Mass Sum Factor (0°C) Sum Factor (15°C) Sum Factor (20°C) CV Sup kJ/Mol (0°C) CV Sup kJ/Mol (15°C) CV Sup kJ/Mol (20°C) CV Sup kJ/Mol (25°C) CV Inf kJ/Mol (0°C) CV Inf kJ/Mol (15°C) CV Inf kJ/ Mol (20°C) CV Inf kJ/ Mol (25°C) Propyne 40.065 0 0 0 0 0 0 0 0 0 0 0 p-Xylene 106.167 0 0 0 0 0 0 0 0 0 0 0 Sulfur Dioxide 64.065 0.1549 0.1449 0.1414 0 0 0 0 0 0 0 0 Styrene 104.15 0 0 0 0 0 0 0 0 0 0 0 Toluene 92.141 0.3886 0.
B-12 Component Data Table MON 2000 Software for Gas Chromatographs JULY 2010
DATA COMPUTATIONS MON2000 C-1 APPENDIX C, DATA COMPUTATIONS CA C.1 DATA ACQUISITION The 2350A GC Controller performs a 12-bit analog to digital (A/D) conversion every 25 milliseconds on channel 0 during an analysis period. This is the period when the left side of the display is counting the elapsed time of the analysis. The fixed number on the right side of the display is the total cycle time. Exactly 40 equi-spaced data samples are taken every second for analysis by the controller.
C-2 DATA COMPUTATIONS MON2000 where PW is given in seconds. All the various details in the analysis process are independent of the value of N. Allowable values of N are one to 63 which corresponds to values of PW from 2 to 63 seconds. The variable N is known as the integration factor. This term is used because N determines how many points are averaged or integrated to form a single value. The integration of data upon input before storing serves two purposes.
MON2000 DATA COMPUTATIONS C-3 Having initiated a peak search by turning Inhibit off, the 2350A Controller performs a point by point examination of the signal slope. This is achieved by using a digital slope detection filter which is a combination low pass filter and differentiator. The output of this detector is constantly compared to a system constant entered by the operator called Slope Sensitivity. A default value of eight is assumed if no entry is made.
C-4 DATA COMPUTATIONS MON2000 The zero reference line will, in general, be nonhorizontal and thus compensates for any linear drift in the system from the time the peak sequence starts until it ends. In a single peak situation, peak area is the area of the component peak between the curve and the zero reference line. The peak height is the distance from the zero reference line to the maximum point on the component curve.
DATA COMPUTATIONS MON2000 C.3 C-5 ANALYSIS COMPUTATIONS There are two basic analysis algorithms included in the controller: • Area Analysis – calculates area under component peak • Peak Height Analysis – measures height of component peak C.3.1 CONC. ANALYSIS WITH RESPONSE FACTOR Calibration The concentration calculations discussed as follows require a unique response factor for each component in an analysis.
C-6 DATA COMPUTATIONS MON2000 Calculated response factors are stored by the controller for use in the concentration calculations, and are printed out in the configuration and calibration reports.
DATA COMPUTATIONS MON2000 C-7 Calc.
C-8 DATA COMPUTATIONS MON2000 Component concentrations may be input through analog inputs 1 to 4 or may be fixed. If a fixed value is used, the calibration for that component is the mole percent that will be used for all analyses:.
DATA COMPUTATIONS MON2000 C.4 C-9 POST ANALYSIS COMPUTATIONS C.4.1 Liquid Equivalent Computations The equivalent liquid volume, in gallons per 1000 standard cubic feet (GPM) is given by: Equation C-6 Equivalent Liquid Volume (GPM) BASEPRS BASETEMP + 459.67 GPM n = CONCN n × LCF n × -------------------------- × ------------------------------------------------------14.73 60 + 459.
C-10 DATA COMPUTATIONS P total number of components to be used in calculation of total BTU/CF “100” removed the “100” factored into the calculation of the concentration earlier in the analysis MON2000 (b) Ideal Relative Density Equation C-8 Ideal Relative Density of Total Gas Sample P ∑ CONCn ( RDn ) =1 TOTALRD = n--------------------------------------------100 where RDn relative Density of component “n” TOTAL RD relative Density of total gas sample CONCNn, P, 100 are defined in “1.
DATA COMPUTATIONS MON2000 C-11 where DI ideal gas relative density () Zb(air) compressibility factor of air, or 0.99959 Zb(gas) compressibility factor of gas mixture (d) Compressibility Factor Dry BTU Compressibility uses calculations from AGA Report No. 8 (1992) errata (1993) “Compressibility Factors of Natural Gas and other related Hydro-Carbon Gases”.
C-12 DATA COMPUTATIONS MON2000 where DRYBTU value from Equation C-7 CORRSATBTU corrected saturated BTU content per cubic foot of total gas sample at base conditions of BASE PRS and 60 °F Z compressibility of total gas as calculated in Equation C-10 BASEPRS base (contract) pressure specified; defaults to 14.
DATA COMPUTATIONS MON2000 C-13 where WVC Water volume content (provided by a “live analog input” Equation C-14 Wobbe Index Calculation CORR ( GROSS )BTU WI = -----------------------------------------------------RD where W.I.
C-14 DATA COMPUTATIONS MON2000 Equation C-16 Average Molecular Weight k ∑ ( CONCi ) ( MWi ) AVGMW = i=1 where AVGMW average molecular weight sum of weights of all components in sample k ∑ i=1 Equation C-17 Liquid Volume Percent ( WTpercent n ) ÷ ( D n ) - × 100 LVpercent = ------------------------------------------------------------k ∑ ( WTpercenti ) ÷ ( Di ) i=1 where LV percent liquid volume WT percent weight percent D density k ∑ All components in the sample must be measured in orde
DATA COMPUTATIONS MON2000 C-15 Equation C-18 Reid Vapor Pressure k ∑ ( CONCi ) ( VPi ) =1 RVP = i---------------------------------------------100 where RVP reid vapor pressure CONCi normalized concentration of component “i” in mole percent VPi vapor pressure at 100 F of component “i” (GPA2145 = 94) Equation C-19 Liquid Relative Density All components in the sample must be measured to calculate LRDT.
C-16 DATA COMPUTATIONS MON2000 Equation C-20 Liquid Density k ∑ ( LVi ) ( LDi ) All components on sample must be measured to calculate Liquid Density. =1 LD T = i------------------------------------100 where LDT liquid density of total sample in pounds per gallon LDi liquid density of component “i”. (GPA 2145-94) LVi liquid volume percent Equation C-21 Gas Density GD = ( RD ) ( 76.4976 ) where GD gas density in lb/1000 ft3 RD relative density (relative to air) 76.
DATA COMPUTATIONS MON2000 C-17 C.4.3 Multi-Level Calibration The properties of each gas component can be viewed using the Component Data menu. Included with the component properties in the Component Data Table are four coefficients labeled Multi-Level Calib 'a', 'b', 'c', and 'd' for each component. If these parameters are all zero, then linear calibration is used. See Section C.3.1 for the response factor calculations.
C-18 DATA COMPUTATIONS MON2000 The mole% value in the sample gas is then calculated as Equation C-23 Mole% Value 3 Mole % = 2 aP + bP + cP + d ----------------------------------------------responsefactor where P peak size measured in Sample Gas C.4.
DATA COMPUTATIONS MON2000 C-19 where JULY 2010 P peak size RRF Relative Response Factor Indirect Calibration
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ANALOG OUTPUT CAL. FOR 2350A MON2000 D-1 APPENDIX D, ANALOG OUTPUT CAL. FOR 2350A DA ALOG OUTPUT CAL. FOR 2350A The initial analog output adjustment will be set at the factory before shipment at standard values (4-20 mA or 1-5 V). It may be necessary to check and/or adjust these values, depending on output cabling or impedance. The adjustment may require two persons if the units are some distance apart. It will require a good digital meter to check the zero and full scale values at the receiving end.
D-2 ANALOG OUTPUT CAL. FOR 2350A MON2000 3. Select the channel to be calibrated. Output channels 1 and 2 can be scaled from either 4-20 mA or 1-5 V. Channels 3 to 10 are scaled from 4-20 mA. Although output channels for direct voltage measurement exist for analog output channels 1 and 2, it is recommended that they not be used for calibration purposes. Instead, use the current-out terminals and the 250-ohm resistor as described.
MON2000 ANALOG OUTPUT CAL. FOR 2350A D-3 4. To change a variable assignment, click the appropriate Variable cell. Use the provided pull-down menu and click the desired variable to select it. 5. For voltage values, set Zero Scale to “1.0” and Full Scale to “5.0”. If the channel is calibrated in milliamperes, set Zero Scale to “4” and Full Scale to “20”. 6. Set the Fixed/Var parameter to “Fixed”. 7. Set the Fixed Value to “0.0”. 8. Set Zero Scale Adjustment and the Full Scale Adjustment to “0.0”. 9.
D-4 ANALOG OUTPUT CAL. FOR 2350A MON2000 13. Click the button to accept your changes and exit from the Analog Outputs dialog. 14. Look at the voltmeter again and record the full scale reading. 15. Return to the Analog Outputs dialog and reselect the channel being calibrated. 16. Change the Zero Scale Adjustment to the Zero Scale voltage reading and the Full Scale Adjustment to the Full Scale voltage reading. Your voltmeter reading should be very close to 5.0 Volts.
ANALOG OUTPUT CAL. FOR 2350A MON2000 D.2 D-5 CALIBRATING BY PERCENTAGES This second example, shown below, demonstrates that it is also possible to calibrate your outputs as a percentage. For instance, you may wish to read directly values that may be scaled from 0 to 1200. Your voltage span is scaled from 1 to 5 volts so the range is approximately 4 Volts. Thus, 1200 divided by 4 equals 300 units per volt.
D-6 ANALOG OUTPUT CAL. FOR 2350A MON2000 To calibrate by percentages, 1. Use the Application > Analog Outputs menu to access this function. 2. The Analog Outputs dialog appears. 3. Select the channel to be calibrated. Output channels 1 and 2 can be scaled from either 4-20 mA or 1-5 V. Channels 3 to 10 are scaled from 4-20 mA. Although output channels for direct voltage measurement exist for analog output channels 1 and 2, it is recommended that they not be used for calibration purposes.
MON2000 ANALOG OUTPUT CAL. FOR 2350A D-7 4. To change a variable assignment, click the appropriate Variable cell. Use the provided pull-down menu and click the desired variable to select it. 5. Set Zero Scale to “0” and Full Scale to “1200”. 6. Set the Fixed/Var parameter to “Fixed”. 7. Set Fixed Value to “0.0”. 8. Set Zero Scale Adjustment and Full Scale Adjustment to “0.0”. 9. Click the button to accept your changes and exit from the Analog Outputs dialog. Your Voltmeter reading should be close to 1.
D-8 ANALOG OUTPUT CAL. FOR 2350A MON2000 13. Click the button to accept your changes and exit from the Analog Outputs dialog. 14. Look at the voltmeter again and record the full scale reading. 15. Return to the Analog Outputs dialog and reselect the channel being calibrated. 16. Change the Zero Scale Adjustment to the zero scale voltage reading and the Full Scale Adjustment to the full scale voltage reading. Your voltmeter reading should be very close to 5.0 Volts.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E-1 APPENDIX E, UPGRADE 2350A GC S/W AND 2350 EPROMS EA To upgrade the Model 500 2350A (GC) software and the 2350 EPROMs, perform all steps in the order they appear in this appendix. Before beginning the upgrade procedure, ensure that you have identified which standard (i.e., factory-released) application file was used to form the current user application for this GC. See Section E.10 for more information on standard applications. E.
E-2 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 3. The Save Uploaded GC Application File dialog appears. Use this dialog to assign a new file name to the GC Application file that is the target for uploading. For clarity, you could name this file “OLD.bin” to distinguish it from the upgraded application file. Press the ENTER key or click the button to continue. The existing file name of the GC application file for the connected GC displays in the File name field. 4.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E.3 E-3 UPGRADE USER-DEFINED APPLICATIONS Follow the installation instructions provided in Section 2.2 to upgrade the MON2000 software and/or a standard application file. Do not delete any existing MON2000 program or GC application files from the PC hard drive. The upgrade process uses information from these files and automatically overwrites any outdated program file.
E-4 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 1. Launch the Update BIN software by either: • clicking the button and using the Programs >MON2000 > Update BIN menu • double-clicking the Update BIN icon on your PC desktop 2. The Update BIN software program launches inside a DOS window. 3. Press the TAB key to access the Communication menu. 4. Use the ARROW keys to select the File Selection option, and then press ENTER. 5. The File Selection screen displays.
MON2000 UPGRADE 2350A GC S/W AND 2350 EPROMS E-5 Use the TAB and ARROW keys to select the desired application file from disk. This file is the file you will be upgrading. 6. Press the TAB key to access the Upgrade Config menu. 7. Use the ARROW keys to select the Merge option, and then press ENTER. 8. The File Selection screen displays. Use the TAB and ARROW keys to select the desired application file from disk. This file is the new application file you wish to merge into the existing file (see Step 5).
E-6 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 10. Use the ARROW+ENTER keys to select the desired application settings to upgrade. Press the SHIFT + ENTER keys to select multiple settings. Press the F2 key to select all the available settings. Press the F3 key to clear your selected settings. 11. Press the F4 key to begin the upgrade. 12. When the upgrade is done, press the ESC key or use the Communication > Exit menu to close the Update BIN program.
MON2000 UPGRADE 2350A GC S/W AND 2350 EPROMS E-7 2. The Update BIN software program launches inside a DOS window. 3. Use the ARROW keys to select the Connect option, and then press ENTER. 4. The Connect screen displays, listing the available GC units. Use the ARROW keys to select the appropriate GC, and then press ENTER. 5. Update BIN attempts to connect to the GC Controller. If the attempt fails, see Section E.4.2 for information on configuring the communications parameters for Update BIN.
E-8 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 6. The File Selection screen displays. Use the TAB and ARROW keys to select the desired application file from disk. This file is the new application file you wish to merge into the existing file (see Step 5). 7. The Merge screen displays. 8. Use the ARROW+ENTER keys to select the desired application settings to upgrade. Press the SHIFT + ENTER keys to select multiple settings. Press the F2 key to select all the available settings.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E-9 10. When the upgrade is done, use the Communications > Disconnect menu to cease communications with the GC unit. 11. Press the ESC key or use the Communication > Exit menu to close the Update BIN program. Ensure that you inspect the upgraded application file for any errors. E.4.2 Configure GC Connection To configure the GC communications parameters for the Update BIN software, 1.
E-10 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 4. The Parameters screen displays. 5. Use the ARROW keys and space bar to select the desired parameter and toggle between its options. 6. Press the ENTER key to accept your changes or press the ESC key to cancel. E.5 DISCONNECT POWER AND DISASSEMBLE PERSONELL AND EQUIPMENT Failure to follow the instructions below, may cause injury to personnel or damage equipment.
MON2000 UPGRADE 2350A GC S/W AND 2350 EPROMS E-11 1. Disconnect AC power from the GC Controller. When you have access to the GC Controller Terminal Board (TB) for field wiring (accessed from the rear on rack-mount versions and behind the front cover of explosion-proof models) disconnect the AC power cord from J21 before continuing working on the unit. 2.
E-12 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 (d) Unplug the TB power supply cord from its connection at the Card Cage Assembly power supply. (e) Loosen the four thumbscrews that secure the Card Cage Assembly to the chassis. Then remove the Card Cage Assembly away from its chassis mount so that it is easy to work on. (f) Unplug all cables connected to the boards in slots 2 through 6 of the Card Cage Assembly in order to access the SBC53 CPU Board. 3.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E-13 4. To reset the CPU registers, remove the jumper from J14 pins 1 and 2, and place it to short J14 pins 2 and 3. 5. After briefly shorting J14 pins 2 and 3, remove the jumper again. Place it back in its original position, shorting J14 pins 1 and 2. E.7 REASSEMBLY PROCEDURES 1. Place and securely plug the SBC53 CPU Board into slot number 2 of the Card Cage Assembly. 2. Reconnect all ribbon cables that were unplugged (see Section E.5).
E-14 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 3. Return and secure the Card Cage Assembly its original position in the chassis mounting. Tighten the four screws. 4. Return and secure the field wiring TB in its original position. Tighten the six screws. 5. Reconnect the AC power cord to J21 on the TB, and restore AC power to the 2350A GC Controller. E.
MON2000 UPGRADE 2350A GC S/W AND 2350 EPROMS E-15 (c) Change Drive C:\ to NONE by pressing PAGE DOWN. Verify that Drive A:\ is the only selected drive. Press ESCAPE, F10 (to save changes), Y (to verify that you want the changes to be made), then ENTER. 5. The CPU assembly will reboot and displays the Systems Configuration window. The speaker on the CPU will chirp and the monitor will prompt: “ENTER NEW DATE (mm-dd-yy)". Press ENTER. "ENTER NEW TIME:". Press ENTER. The A:\> prompt is displayed.
E-16 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 9. The Protected Mode Program screen displays. Verify that a "cold start - initial" message is displayed in the middle of the screen and LED D2 is blinking on the CPU assembly. 10. Press ESC to exit the program and power down. 11. Carefully remove the cable from J1 and J10 to prevent cracking the connector housing. Install the program label on the end of DiskOnChip opposite the serial number. E.8.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E-17 4. After the C:\> prompt is displayed, type ERASE *.*, then press ENTER. When prompted “ARE YOU SURE?” Type Y, then press ENTER. 5. At the C:\> prompt, type DIR, then press ENTER. Verify that only the Command.com file remains on the ‘C:’ drive, that the file size is 54,645 bytes, and that there are 16,105,472 bytes free. 6. Type A:, then ENTER to change back to the A:\ drive. Type INSTALL, then follow Steps 6 through 11 (see Section E.8.1). E.8.
E-18 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 3. Return and secure the Card Cage Assembly back into the chassis mounting. Tighten the four screws. 4. Return and secure the field wiring TB to the original position. Tighten the six screws. 5. Reconnect the AC power cord to J21 on the TB, and restore AC power to the GC Controller. E.9 CONNECT TO GC FOR UPGRADED APP. 1. Use MON2000 software to connect with the GC unit. Use the File > Connect menu to access this function. See Section 2.10.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E.10 E-19 GUIDE TO STANDARD APPLICATION FILES This section of the appendix lists the various standard application, or BIN files that have been released by for the GC Controller. E.10.
E-20 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E.10.2 Standard Applications v1.50 and Later If you are using a GC Application that is version 1.50 or later, you can quickly determine the original standard application name by viewing the variables listed in the System dialog. Use the Application > System menu to access this dialog.
UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E-21 Table E-2 System Variables for Standard Application Files Analyzer Name (BIN file) Unit Type CFG Base Name System Description Max.
E-22 UPGRADE 2350A GC S/W AND 2350 EPROMS MON2000 E.10.3 Standard Applications Prior to v1.50 For versions of GC Applications prior to version 1.50, the CFG Base Name variable did not exist. Therefore, a combination of other variables must be inspected to determine the standard application that was used to formulate the current user application. To determine the standard application used to create a user application prior to version 1.
MODBUS REG. LIST FOR 2350A GC F-1 MON2000________________________________________________________________________________ APPENDIX F, MODBUS REG. LIST FOR 2350A GC FA F.1 INTRODUCTION – SIM_2251 & USER_MODBUS GC Controller Modbus registers that may be of interest to the developer are of two varieties, SIM_2251 and User_Modbus. Differences are summarized in the following table. Table F-1 Comparison of SIM_2251 and User_Modbus SIM_2251 User_Modbus Serial slave port. Serial slave port.
F-2 MODBUS REG. LIST FOR 2350A GC ________________________________________________________________________________MON2000 All other User_Modbus registers can be defined by the user. To define User_Modbus register contents (through assignment of variables), see Section 5.18.4. To obtain a complete list of register assignments, both SIM_2251 and User_Modbus, use Model 700 to produce a PC-Config Report. To print a PC-Config Report, see Section 2.16.3; for an example report, see Appendix A, Section F.
MODBUS REG. LIST FOR 2350A GC F-3 MON2000________________________________________________________________________________ F.
F-4 MODBUS REG.
MODBUS REG.
F-6 MODBUS REG. LIST FOR 2350A GC ________________________________________________________________________________MON2000 F.2.1 SIM_2251 MODBUS REGISTER LIST The information in the following tables is derived from engineering specification number ES-17128-005, “Model 2251 Enhanced Specification Chromatograph Controller Modbus Communication Indices” and has been updated for the 2350A GC Controllers.
MODBUS REG.
F-8 MODBUS REG.
MODBUS REG.
F-10 MODBUS REG.
MODBUS REG.
F-12 MODBUS REG.
MODBUS REG.
F-14 MODBUS REG.
MODBUS REG.
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WARRANTY CLAIM PROCEDURES To make a warranty claim, you, the Purchaser, must: 1. Provide Daniel Measurement and Control, Inc. or Rosemount Analytical, Inc. with proof of the Date of Purchase and proof of the Date of Shipment of the product in question. 2. Return the product to Daniel Measurement Services (DMS) within 12 months of the date of original shipment of the product, or within 18 months of the date of original shipment of the product to destinations outside of the United States.
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CUSTOMER REPAIR REPORT FOR SERVICE, COMPLETE THIS FORM, AND RETURN IT ALONG WITH THE AFFECTED EQUIPMENT TO CUSTOMER SERVICE AT THE ADDRESS INDICATED BELOW. COMPANY NAME: ___________________________________________________________________________ TECHNICAL CONTACT:_____________________________________ PHONE: _________________________ REPAIR P. O.
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Daniel Measurement and Control, Inc., Daniel Measurement Services, Inc., and Rosemount Analytical Inc., Divisions of Emerson Process Management, reserves the right to make changes to any of its products or services at any time without prior notification in order to improve that product or service and to supply the best product or service possible. www.emersonprocess.