OPERATION MANUAL X Series Process Indicator PR 5410 © 2008 by Fairbanks Scales, Inc.
Disclaimer Every effort has been made to provide complete and accurate information in this manual. However, although this manual may include a specifically identified warranty notice for the product, Fairbanks Scales makes no representations or warranties with respect to the contents of this manual, and reserves the right to make changes to this manual without notice when and as improvements are made.
Table of Contents Table of Contents 1 Warnings and Safety Precautions............................................................................. 10 1.1 INTENDED USE .........................................................................................................................10 1.2 INITIAL INSPECTION ..................................................................................................................10 1.3 BEFORE COMMISSIONING ......................................................
Table of Contents 3.5 CONNECTING LOAD CELLS, CONTINUED 3.5.3 3.5.4 3.5.5 3.5.6 4 Connecting up to 8 Load Cells (650 Ohms) Using 6-Wire Connecting Cable Connecting Load Cells with External Supply Connecting Load Cells via Intrinsically Safe Load Cell Interface PR 1626/60 Connecting Platforms (CAP...) 53 54 55 56 Commissioning ........................................................................................................... 57 4.1 DATA PROTECTION/POWER FAILURE ...................................
Table of Contents 4.7 CONFIGURING GENERAL PARAMETERS, CONTINUED 4.7.7 4.7.8 Fieldbus Parameters Network Parameters 91 92 4.8 LIMIT VALUES, DIGITAL INPUTS AND OUTPUTS ..........................................................................93 4.8.1 4.8.2 4.8.3 4.8.4 4.8.5 4.8.6 Conditions for Limit Values and Digital Inputs, States for Outputs Configuring Digital Inputs and Outputs Configuring Outputs Configuring Inputs Configuring Limit Values BCD Output 93 94 94 95 97 99 4.9 ANALOG OUTPUT .........
Table of Contents 6 PR 1612 Commands ................................................................................................. 127 6.1 6.2 7 Main commands for indicator function Error Messages for PR 1612 Commands 127 127 Fieldbus Interface ..................................................................................................... 128 7.1 FIELDBUS INTERFACE PROTOCOL ........................................................................................... 128 7.1.1 7.1.2 7.1.
Table of Contents 12.4 WEIGHING ELECTRONICS ........................................................................................................145 12.4.1 12.4.2 12.4.3 12.4.4 Load Cells Principle Accuracy and Stability Sensitivity 145 146 146 146 12.5 MECHANICAL DATA ................................................................................................................146 12.5.1 12.5.2 12.5.3 Construction Dimensions Weight 146 146 146 12.6 USE IN LEGAL-FOR-TRADE MODE ...................
Section 1: Warnings and Safety Precautions 1 Warnings and Safety Precautions This instrument has been built and tested in compliance with the safety regulations for measuring and control instrumentation for protective class I (protective earth connection) according to IEC 1010/ EN61010 or VDE 0411. The instrument was in perfect condition with regard to safety features when it left the factory.
Section 1: Warnings and Safety Precautions 1.3.3 Grounding and Shock Prevention PR 5410/00 The instrument must be connected to protective earth via a protective earth conductor (PE) in the power connector. The power cable contains a protective earth conductor which must not be interrupted inside or outside the unit (e.g., by using an extension cable that does not have a protective earth connection). The PE conductor is connected to the back panel of the housing inside the instrument. 1.3.
Section 2: Process Indicator 2 Process Indicator The instrument is equipped with a six-digit 7-segment display and additional status indication. Local operation is performed using 6 double-function keys. 2.
Section 2: Process Indicator 2.2 HOUSING The instrument has aluminium housing and a front panel compliant with IP 65. It is suitable for installation in a control cabinet. Keypad, display and display board form a unit with the front panel. A square cut-out is required for installation. The cable connectors are on the back panel of the housing. A 6-pin plug-in terminal block is provided for connection of the load cells. The built-in serial interface has a 9-contact D-Sub female connector.
Section 2: Process Indicator 2.3 DISPLAY AND CONTROLS 2.3.1 Display The display permits indication of 6-digit weight values (digit height 18 mm) with decimal point and polarity sign. Possible units of mass are t, kg, g or lb. Status indication Weight value Mass unit Front keys (Indicator / navigation) , 2.3.
Section 2: Process Indicator 2.3.3 Selection Using the Navigation Keys (VNC) Press the down arrow key to scroll down, or the up arrow key to scroll up in a menu. Press to select a menu item. To choose the desired setting for the selected menu, press or . Press the key to exit a menu and continue the operation on the next higher level. An arrow in front of a menu item indicates that there are menu sublevels. The menu item selected by pressing is shown inversely.
Section 2: Process Indicator 2.3.5 System Messages during Input (VNC) The following types of messages are displayed as confirmation prompts / warnings during input: Question mark A question mark indicates that a choice of options (e.g. [Save] for saving or [Undo] for cancelling) is available. “Stop“ An important indication that an action cannot be executed (e.g., if saving is not possible because the CAL switch is closed).
Section 2: Process Indicator 2.3.
Section 2: Process Indicator 2.3.7 Plug-in Cards On the main board, the PR 5410 Process Indicator can be fitted with up to 2 plug-in cards. Mounting different types of cards on Slots 1 and 2 is mandatory (exception: PR 5510/04)! If a card is fitted on Slot 4, only one more card may be mounted on Slots 1 or 2. Product PR 5510/02 2 serial RS-232 interfaces PR 5510/04 1 serial RS-232 interface and 1 serial RS-485/RS-422 interface.
Section 3: Installing the Instrument and Plug-In Cards 3 Installing the Instrument and Plug-in Cards Before starting work, please read Chapter 1 and follow all instructions. Further procedures: • Check the consignment: unpack the components specific to the application. • Safety check: inspect all components for damage. • Make sure the on-site installation is correct and complete including cables, e.g. power cable fuse protection, load cells, cable junction box, data cable, console/cabinet, etc.
Section 3: Installing the Instrument and Plug-In Cards 3.3.1 Network Port The network port is built in as standard equipment. The port contains powerful TCP/IP connection circuitry with transfer rates of 10 or 100 Mbit/sec. The LEDs on the connector indicate whether the port is functioning.
Section 3: Installing the Instrument and Plug-In Cards Connecting a Remote Display / Remote Terminal A PR 1627 remote display or a PR 1628 remote terminal can be connected to the built-in RS-232 interface [Builtin RS232] or to the PR 5510/04 card. Press -[Serial ports parameters]-[Remote display]-[Builtin RS232]-[Param] and select [Baudrate] 4800. The baud rate now corresponds to the default settings of PR 1627 or PR 1628. The following settings cannot be changed: [Bits] 7, [Parity] even and [Stopbits] 1.
Section 3: Installing the Instrument and Plug-In Cards 3.3.3 Optocoupler Inputs The main board has 3 digital inputs for process control, electrically isolated by optocouplers, each bipolar potential-free.
Section 3: Installing the Instrument and Plug-In Cards 3.3.4 Optocoupler Outputs The main board has 3 digital outputs for process control, electrically isolated by optocouplers, each bipolar potential-free. Number of outputs: Output: 3 ( CH1, CH2, CH3 ) Max. switching voltage: 31 VDC, Protected against incorrect polarity Max.
Section 3: Installing the Instrument and Plug-In Cards 3.4 ACCESSORIES 3.4.1 Installing Plug-in Cards The main board has two slots with identical pin allocation (34 contact pins in two rows of 17) and another slot (34 contact pins in two rows of 17) for plug-in cards. The slot designations are “Slot 1 ... 2" and "Slot 4" (left). Up to 2 cards can be mounted. Accordingly, the back panel is provided with two cut-outs for the retainer plates of the cards.
Section 3: Installing the Instrument and Plug-In Cards 3.4.2 Cable Connection in the D-Sub Connector Mating Plug The connections on the back panel are plug-in type. Keep the conductors as short as possible and connect them to the terminals. The connector housings are conductive (metallized), i.e., part of the shield, and must be fastened to the back panel by screws. Mounting a cable: • • • • • • • • • • • Open the connector housing (catches) Release and open the cable clamp Remove approx.
Section 3: Installing the Instrument and Plug-In Cards 3.4.3 PR 5510/02 Serial I/O The plug-in card contains two RS-232 channels (A and B), which can be used simultaneously and independently. Max. 2 PR 5510/02 cards can be plugged in (Slot 1 ... 2). The relevant interface parameters are adjustable in required.
Section 3: Installing the Instrument and Plug-In Cards 3.4.4 PR 5510/04 Serial I/O The plug-in card has two channels (1x RS-232 and 1x RS-422/485), which can be used simultaneously and to a great extent independently. The RS-422/485 interface is electrically isolated. Up to 2 PR 5510/04 cards (Slot 1 and 2) can be plugged in. The relevant interface parameters can be configured under for RS-422/485 additionally.
Section 3: Installing the Instrument and Plug-In Cards PR 5510/04 RS-422/485 When mounting, the RS-485/422 interface must be configured by DIL switch S101 on the card. Using RS-485 is compulsory with a multi-point connection (tristate status). The RS-485 interface can be used also for point-to-point connection. Like 2-wire or 4-wire connections, this is dependent on the other communicating units. A 2-wire connection is half-duplex and cannot send and receive simultaneously.
Section 3: Installing the Instrument and Plug-In Cards Connecting a PR 1627 Remote Display over RS-485 Four-wire transmission, point to point, full duplex (simultaneous sending and receiving possible) with PR 1627/00 remote display. Configuration: -[Serial ports parameter]-[Remote display]-[Slot1/2-RS-485] RS-422 Point-to-Point Connection (Four-Wire) Four-wire transmission: full duplex (simultaneous sending and receiving possible) RS-422 can be used only for point-to-point connection.
Section 3: Installing the Instrument and Plug-In Cards Connecting Several PR 1627 Remote Displays over RS-485 Connection of several PR 1627 remote displays over RS-485, four-wire, full-duplex (simultaneous sending and receiving possible): 10/08 30 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards 3.4.5 PR 5510/07 Analog Input/Output Card The plug-in card with 15-contact D-Sub socket for the analog channels is configured as 1 analog output (active) and 4 analog inputs. The analog inputs are not supported by the standard instrument.
Section 3: Installing the Instrument and Plug-In Cards Channel Current 0...+ 20mA DC Voltage 0...+ 10V DC Voltage 0...+ 5V DC S201 CH1 CH2 CH3 CH4 ---- ON ON ON ON ---- OFF OFF OFF OFF ---- OFF OFF OFF OFF ---- S202 Analog input Signal selection CH1 CH2 CH3 CH4 ---- OFF OFF OFF OFF ---- ON ON ON ON ---- OFF OFF OFF OFF ---- 250 ohms 100 kohms > 10 Mohms Input resistance Pin allocation of rear socket (for installation, see Chapter 3.4.
Section 3: Installing the Instrument and Plug-In Cards 3.4.6 PR 5510/08 BCD Output (Open Emitter) The plug-in card is used for BCD-coded output of a 5-decade weight value. Cyclical output of the weight value with 4-bit (plus or minus sign, stability, error). The value is intrinsically consistent and can be output continuously or the digital input DATA_IN control can be used to freeze (hold) the value.
Section 3: Installing the Instrument and Plug-In Cards External supply voltage required: pin 1 - Uext, reference potential pin 26 – GND 10/08 34 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Outputs The PR 5510/08 outputs (pins 2 - 24) use common supply voltage at the collector as reference potential and open emitter outputs. A non-activated output has high impedance, and an active output has a voltage by approximately 1.7 V lower than the supply voltage. The load to be connected is applied between the output (pins 2 … 24, 25*) and GND (pin 26). Input When using as DATA_IN, the input (pin 25) can control the 23 outputs.
Section 3: Installing the Instrument and Plug-In Cards 3.4.7 PR 5510/09 BCD Output (Open Collector) The plug-in card is used for BCD-coded output of a 5-decade weight value. Cyclical output of the weight value is with 4-bit corresponding status (polarity sign, stability, error). The value is intrinsically consistent and can be output continuously or the digital input DATA_IN control can be used to freeze (hold) the value.
Section 3: Installing the Instrument and Plug-In Cards External supply voltage is required : pin 1 - Uext, reference potential pin 26 – GND 10/08 37 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Outputs PR 5510/09 outputs (pins 2 ... 24) use common GND as a reference potential and open collectors. A non-activated output has high impedance, and an active output has a voltage by approximately 0.9 V higher than GND. The load to be connected is applied between the collector [pins 2 … 24,(25*)] and Uext [PIN 1]. Input When using as DATA_IN, the input (pin 25) can control the 23 outputs.
Section 3: Installing the Instrument and Plug-In Cards PR 5510/09 connector, pin allocation: BCD output for weight value Output circuitry 10/08 39 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Output Modes In all modes, data is output with each internal PLC cycle. Mode 1 : Continuous data output (follow), no DATA_IN: Continuous output of consistent data without request, e.g. for remote display. - The driver modules are always enabled. PIN25 is output. Mode 2: Data output on external request DATA_IN (hold): Output of consistent data in "held" condition on request, otherwise continuous.
Section 3: Installing the Instrument and Plug-In Cards 3.4.8 PR 5510/12 6 Optocoupler Inputs / 12 Optocoupler Outputs The card converts external binary process signals to internal signal levels and vice versa. 12 digital outputs for process control, electrically isolated with passive optocoupler outputs, each bipolar potential-free. 6 digital inputs for process control, electrically isolated via optocouplers, each bipolar potential-free. The input signal is logical "0" with open input.
Section 3: Installing the Instrument and Plug-In Cards Passive; external supply voltage required (I/O channels potential-free, no common reference) 10/08 42 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Output circuitry Input circuitry 10/08 43 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Circuit diagram: PR 5510/12 – PR 1623/10 – PR 1623/20 10/08 44 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards Circuit diagram: PR 5510/12 – PR 1623/10 – PR 1623/30 10/08 45 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards 3.4.9 PR 1721/31 Profibus Interface Profibus interface PR 1721/31 is a plug-in card for mounting in Slot 4; see Chapter 3.4.1. Communication protocols and syntax comply with the Profibus-DP standard to IEC 61158, with transfer rates up to 12 Mbit/s. Internal 34-pin connector on flat cable for Slot connection: 4 External 9-contact D-Sub socket in retainer connection: plate Transfer rate: Dimensions (LxWxH): Weight: 87 x 55 x 15 mm 125 g 9.
Section 3: Installing the Instrument and Plug-In Cards 3.4.10 PR 1721/32 Interbus Interface The Interbus interface PR 1721/32 is a plug-in card for installation in Slot 4; see Chapter 3.4.1. The interface is based on the Interbus chip technology and enables transfer rates of 500 kbit/s and 2 Mbit/s.
Section 3: Installing the Instrument and Plug-In Cards 3.4.11 PR 1721/34 DeviceNet Interface DeviceNet interface PR 1721/34 is a plug-in card for installation in Slot 4; see Chapter 3.4.1. It is a complete DeviceNet adaptor (slave) with CAN controller and transfer rates of up to 500 kbit/s.
Section 3: Installing the Instrument and Plug-In Cards 3.4.12 PR 1721/37 EtherNet/IP Schnittstelle The EtherNet/IP interface is a plug-in card for installation in Slot 4, see chapter 3.4.1. The card is fitted with a standard RJ-45 socket for Ethernet connection and contains a powerful TCP/IP and EtherNet/IP connecting circuitry with transfer rates of 10 and 100Mbits/s.
Section 3: Installing the Instrument and Plug-In Cards Flashing 2Hz green Flashing red 10/08 Modul not initialized RAM, ROM or ASIC test error 50 51207 Revision 1
Section 3: Installing the Instrument and Plug-In Cards 3.4.13 PR 5510/14 ModBus TCP Interface The Ethernet interface PR 5510/14 is a plug-in card for installation in Slot 4, Chapter 3.4.1. The card is fitted with a standard RJ-45 socket for Ethernet connection. It contains powerful TCP/IP and ModBus TCP connecting circuitry with transfer rates of 10 and 100Mbits/s.
Section 3: Installing the Instrument and Plug-In Cards 3.5 CONNECTING LOAD CELLS Load cells or analog platforms (e.g., from the CAPP series) can be connected. The supply voltage is protected from short circuit and overload. The card is fitted with a solder link (factory setting: closed; see Chapter 3.5.5), which should be opened only when the supply voltage and thus also the sense voltage are reduced to below approx. +/- 4 VDC. Terminal block +M -M +V +S -S -V Housing 3.5.1 Connection + meas. - meas.
Section 3: Installing the Instrument and Plug-In Cards 3.5.3 Connecting up to 8 Load Cells (650 Ohms) Using 6-Wire Connecting Cable Via cable junction box PR6130/.. using PR 6135 or PR6136 connecting cable: The cable colors shown here are valid for PR 62 . . series load cells and for the PR 6135 connecting cable. When using different load cells, the cable colors may have different assignments.
Section 3: Installing the Instrument and Plug-In Cards 3.5.4 Connecting Load Cells with External Supply When the load of the load cells is < 75 ohms (e.g. more than 4 load cells with 350 ohms), external load cell supply is required. In this case, the internal supply is replaced by a potential-free external supply. The neutral wire of the external supply voltage (0 ext. supply) must be connected to the instrument housing to ensure that the voltage is symmetrical to 0. The internal supply is not connected.
Section 3: Installing the Instrument and Plug-In Cards 3.5.5 Connecting Load Cells via Intrinsically Safe Load Cell Interface PR 1626/60 The cable colors shown here are valid for the PR 62.. series load cells and for PR 6135 and PR 6136 connecting cables. When using other load cells, the assignments of cable colors may differ. For this reason, the relevant manual or data sheet should be consulted for assignments of cable colors before connecting.
Section 3: Installing the Instrument and Plug-In Cards 3.5.6 Connecting Platforms (CAP...) One Combics analog platform (CAP... series) can be connected to the instrument. The following example shows a platform with 6-wire connection and another one with 4-wire connection. Platforms with 4-wire connection require links between +V and +S and between –V and –S. The cable colors shown above are valid for a CAPP4 500 x 400 and a CAPP1 320 x 420, as an example.
Section 4: Commissioning 4 Commissioning Front panel key assignment and operating concept are described in Chapter 2.3. 4.1 DATA PROTECTION/POWER FAILURE The calibration data and parameters as well as all configuration and interface data are stored in non-volatile (EAROM) memory. Unauthorized data changing can be prevented by an access code; the front panel keys can be disabled. Additional write protection is provided for calibration data and parameters (CAL switch, see Chapter 4.1.1).
Section 4: Commissioning 4.2 SWITCHING ON THE INSTRUMENT The instrument can be put into operation and calibrated using a PC with the VNC program (on the enclosed CD), an Internet browser or the ConfigureIt program. On initial start-up, the date and time must be set.
Section 4: Commissioning 4.2.4 Setting the Network Address Using Front-Panel Keys Press Setup at the instrument DS,PTS,Tw BIOS w BIO,S..
Section 4: Commissioning 4.2.7 Loading New Software Press Setup at the instrument DS,PTS,Tw BIOS w BIO,S..w FLASH w E THERw SERIALw DHC,P..
Section 4: Commissioning 4.3 CONFIGURATION AND CALIBRATION USING FRONT KEYS 4.3.1 Meaning of Front Keys The instrument can be set directly via front keys: Press Setup SETUP w CD 000w Setup-Menu, press Calibration menu, 'Cd' is flashing With the next parameter group (Cp) is selected, with switch to the parameter number ('000' is flashing), the parameter table is described in chapter 4.3.3 . If a selection has to be performed, / have to be used.
Section 4: Commissioning 4.3.3 Parameter Table - SEtuP - Cd Calibration data - 000 CALIb nEW new calibration, VIEW view data, Mod modify calibration - 001 MAX.FSd Decimal point position, Max (Scale range) and weight unit - 002 StEP Scale interval - 003 dEAdLo Deadload setting by weight (LoAd) or mV/V (MVoLt) - 004 SPAn Calibration weighing range by weight (LoAd) or mV/V (MVoLt) - 005 0-rnG Show used zeroset range - 006 uVolt.
Section 4: Commissioning - 056 WGt. 20 Weight at 20 mA - oP Operating parameter - 060 Addr Instrument address - 061 PIn Access Code - 062 ALIbI Alibi storage, nonE, GroSS, nEt , Gr.nE.tA., Gr.nE. oder Gr.tA - 063 SEqnr Next free sequence number - 064 tArKEY Tare-Key, Function, Disable - 065 ZErKEY Zeroset-Key, Function, Disable - 066 nbtKEY N.B.
Section 4: Commissioning 4.3.4 New Calibration using Front Keys Example: Max (Maximum load) 600 kg, scale interval 200 g, setting deadload with empty scale. At start of a new calibration the instrument has got the following default values: Max 3000 kg, scale interval 1 kg. START 1. Warm-up the instrument (minimum 0,5 hours), open CAL switch 2. Press , SEtuP is shown NEW CALIBRATION (Cd 000) 3. Press , Cd 000 (Cd is flashing) 4. Press , CALIb is shown (with CAL switch closed CAL.
Section 4: Commissioning 4.3.5 Subsequent Change of Deadload using Front Keys If due to mechanical modifications the deadload (weight of empty scale / hopper) has changed, the procedure is as follows: START 1. Warm-up the instrument (minimum 0,5 hours), open CAL switch 2. Press , SEtuP is shown 3. Press , Cd 000 (Cd is flashing), switch to parameter number with change with to Cd 003 , (000 is flashing), MODIFY DEADLOAD (Cd 003) , dEAdLo is shown 4. Press 5.
Section 4: Commissioning 4.3.7 View Calibration Data for Deadload and Maximum Load Normally all settings of the instrument should be documented or printed out during commissioning. If an instrument has to be replaced by another one due to breakdown and no new calibration can / should be done, the values for deadload and maximum load in mV/V are absolutely required. Therefore the following has to be done: 1. Press , SEtuP is shown 2.
Section 4: Commissioning 4.4 OPERATION USING A PC 4.4.1 Operation Using the VNC Program VNC stands for 'virtual network computing' and is a program for remote operation of computers. The program distinguishes between the VNC server and VNC client (viewer). The server program is part of the instrument software. The client program (viewer) must be installed and executed on the PC to be used for operating the instrument.
Section 4: Commissioning 4.4.2 Operation Using Internet Browser With the Internet browser, the [IP address] must be entered. Example: The menu appears on the monitor. The line in brackets below the header corresponds to the device name specified in [Hostname]. [Remote Configuration (VNC)], [Remote Configuration (VNC) Pop up Window] For instrument operation using the VNC program without additional installation of VNC, see Chapter 4.4.
Section 4: Commissioning 4.4.3 INFO Function When you press , the program releases and status messages are displayed. The other functions; see Chapters 0 and 0. key also has Info Show version Show status Show HW-slots Show alibi memory When you select [Show version], the installed program releases and the board number are displayed: Info/Version Firmware Rel. 01.00.00 2006-12-02 10:50 Rel. 01.00.00 2006-12-02 10:50 Rel. 01.00.
Section 4: Commissioning 4.4.4 Setup Function (VNC) Press to configure the main operating parameters. The configuration depends on the application licenses registered and the plug-in cards installed. Calibration is in a simple dialogue. Compliance with the relevant (verification) standards must be checked by the person commissioning the instrument or the verification officer. To protect the calibration data from overwriting, close the corresponding CAL switch on the back panel of the instrument.
Section 4: Commissioning 4.4.6 Calibration Menu - Calibration Calibration of weighing electronics - New Reset Span and deadload - Max - Scale interval - Deadload at - Max at by load - Calibrated at - Sensitivity (µV/d) - Test Exit calibration - Modify Contin, Cancel 0.00001 ...<3000>... 999999 , t, lb, g <1>, 2, 5, 10, 20, 50 <0.000000 mV/V> or [by load] <1.000000mV/V> or [by load] 0.00001 ...
Section 4: Commissioning 4.5 CALIBRATION Calibration using weights, mV/V or load cell data can be done using the VNC program. During calibration, the instrument must be set to gross weight display (reset tare, if necessary). For a ’legal-for-trade’ application, set the mode under -[Calibration]-[Param] to [W&M] before starting calibration; see Chapter 0. Select [New] to go to the maximum capacity [Max] (see Chapter 4.5.3); select the scale interval and determine the dead load.
Section 4: Commissioning 4.5.2 Selecting the Calibration Mode You can choose between [New] and [Modify] with the softkeys: New Modify Param New Calibration Open the menu via -[Calibration]. When you press [New], the data is set to default first and calibration is started. SPAN and deadload will be reset You are prompted to confirm: Press [Continue] for the default settings, or [Cancel] to cancel the selection.
Section 4: Commissioning 4.5.3 Determining the Maximum Capacity (Max) The maximum capacity (Max) determines the maximum weight without dead load of the weight to be measured and the displayed number of digits behind the decimal point. Normally, Max is less than the load cell capacity (nominal capacity * number of load cells). Permissible values are: [Max] from 0.00010 to 999999, with in kg, t, g or lb Max must be an integer multiple of the scale interval.
Section 4: Commissioning 4.5.4 Determining the Scale Interval Max Scale interval WP A/Calibration 3000 d 3000 d 3000 kg 1kg The scale interval 1, 2, 5 10, 20 or 50 can be set by pressing . The weight unit is taken from [Max] and cannot be changed here. The number of digits behind the decimal point must be determined already when entering [Max] as well.
Section 4: Commissioning Possible error messages: The dead load entered in mV/V plus maximum capacity in mV/V is higher than 3 mV/V ( = 36 mV). Set deadload failed above physmax The scale is not stable. Remedial action: Check the mechanical function of the scale; adapt the filter setting; reduce the resolution; if necessary, adapt the stability conditions. Set deadload failed no standstill Set deadload failed deadload < -0.
Section 4: Commissioning Set SPAN failed Load below deadload The weight on the scale is less than the dead load after input of the weight value. The next step is calculation of the test value with [Test] (see Chapter 0), and calibration is completed with (see Chapter 4.5.12). Determining span without weight WP A/Calibration 3000 d 3000 d 3.00 kg 3000.00 kg Max Scale interval Deadload at Max at Not calibrated Sensitivity by load 833.33 by mV/V by data 3000 kg 1 kg 0.001000 0.000000 4.000000 Linear.
Section 4: Commissioning The calibration dialog provides an overview of all settings: Max Scale interval Deadload at Max at Calibrated at Sensitivity WP A/Calibration 1000 d 1000 kg 1000 d 1 kg 500.00 kg 0.500000 1000.00 kg 1.000000 1000.00 kg 1.000000 2500.00 12.000000 After selecting [mV/V], the values for the Max and for the dead load (if necessary) can be entered. The next step is calculation of the test value with [Test] (see Chapter 0), and calibration is completed by pressing (see Chapter 4.5.
Section 4: Commissioning [Nominal load] Nominal load Emax of a load cell (not the overall nominal weight of the scale). [Gravity] Acceleration of gravity at the place of installation; default is the value for Hamburg, Germany, 9.81379 m/s². [Hysteresis error] When switching from [Not specified] to [Specified], values for [Correction A/B] must be filled in. The data is given on the load cell certificate.
Section 4: Commissioning 4.5.10 Linearization After selecting -[Calibration]-[New]/[Modify] and after completing calibration, select the linearization menu with softkey [Linear.]: by load by mV/V by data Linear. Test When you press [Linear.] the menu shown below appears: Max at WP A/Calibration/Linearisation 3000.00 kg 1.000000 Add by mV/V by load To add a new linearization point, press [Add], fill in the weight value, apply the weight and press [by load].
Section 4: Commissioning 4.5.12 Finishing / Saving the Calibration Finish the calibration with . You are prompted to confirm whether calibration should be closed without determining the test value. Calibration not complete Exit calibration? If not all data was determined when calibrating with [New] (e.g. dead load not set/entered), this message is shown: Press [Yes] to confirm and then press displayed: again; another prompt is Exit calibration ? Press [Save] to save changes in calibration data.
Section 4: Commissioning [Test mode] With [Absolute], the test value is determined when the test is called. With [Relative], the deviation from the initially stored test value is displayed; see Chapter 0. [W & M] Setting for 'legal-for-trade' mode; select [None], [OIML], [NTEP] (for USA) or [NSC] (for Australia); see Chapter 0. [Standstill time] Parameters [Standstill range] and [Standstill time] are required for determining the mechanical stability of the scale. Input in seconds; permissible range: 0.
Section 4: Commissioning [Overload] Weighing range above the maximum capacity (Max), without error message. Available range: 0 to 999900 d. In 'legal-for-trade' mode max. 9 d=e has to be entered. WP A/Calibration Min Range mode 50 d Single range [Min] Minimum weight at which a print command can still be executed. Range is 0 to 999900 d. In 'legal-for-trade' mode min. 20 d has to be entered.
Section 4: Commissioning Multi-interval scale With [Range mode] = [Multi-interval], the scale has up to three ranges with different resolution. Each range has the corresponding interval. Unlike [Multiple range], switching the interval is also triggered by weight reduction; i.e., when the weight drops below the range limits. During calibration, the multiple range/multi-interval function is always switched off.
Section 4: Commissioning 4.6 ERROR MESSAGES 4.6.1 Measuring Circuit Error Messages The weighing electronics can generate error messages, which are output on the weight display. Display EPPOP1 EPPOP2 EPPOP3 VNC text Arith err Overload No EOC EPPOP6 No sense voltage Negative Input EPPOP7 Cause Internal arithmetic overflow (faulty calibration values) Input voltage is higher than Max + (x d) Input signal is higher than the permissible range of 36 mV.
Section 4: Commissioning 4.7 CONFIGURING GENERAL PARAMETERS The configuration of parameters which are not related to the weighing electronics is divided into several sections (see Chapter 4.4.5 ). 4.7.1 Select Date and Time -[Date & Time] to set date and time. Setup/Clock Date Time 4.7.2 2005-08-17 16:21:52 Date and time can be overwritten Serial Ports To configure the serial interfaces, press and select [Serial ports parameter].
Section 4: Commissioning [Remote display] Select the serial interface to which the remote display is connected and then select [Param] to define the [Baudrate] and the remote display type [Mode] connected. Setup/Serial ports/Builtin RS232 Assigned to Remote display Protocol Remote display Baudrate 9600 bd Select [Baudrate] with Bits 7 set the baud rate with Parity even Stopbits 1 Mode single transmitter and The available baud rates are 300, 600, 1200, 2400, 4800 or 9600.
Section 4: Commissioning 4.7.3 SMA Protocol Select an RS-485 interface under -[Serial ports parameter]. Setup/Serial ports Printer Remote display JBUS/MOD-Bus SMA - none Slot1 RS232 Slot2 RS485 Slot1 RS485 Param Only the baud rate is adjustable; the other parameters are fixed. Setup/Serial ports/Slot1 RS485 Assigned to SMA Protocol SMA Baudrate to select [Baudrate] and 9600 bd Press Bits 8 set the baud rate with Parity none Stopbits 1 The SMA protocol is described in Chapter 4.8. 4.7.
Section 4: Commissioning 4.7.5 Operating Parameters Define the basic operating parameters under -[Operating parameter]. Setup/Operating parameter Address A PIN ****** Use alibimemory none Sequencenumber 0 SetTareKey tare & reset tare SetZeroKey only when not tared ShowGrossTarekey enabled PrintKey enabled Testkey enabled [Address] Device address; e.g. for print-out. [PIN] The access code can be used to protect the [Setup] from unauthorized operation. Enter a number with up to 6 digits.
Section 4: Commissioning 4.7.6 Printing Parameters Setup Serial ports parameter Date & Time Operating parameter Printing parameter Print mode 1. Item 2. Item 3. Item 4. Item 5. Item 6. Item Press and to select [Printing parameter] Setup/Printing parameter Print selected items Select [Print selected items] Sequencenumber or [via NiceLabel] Grossweight CR/LF -none-none-none- When selecting item [via Nice Label] under [Print mode], printing with Nice Label Express (NLE) is configured.
Section 4: Commissioning 4.7.7 Fieldbus Parameters Setup Serial ports parameter Date & Time Operating parameter Printing parameter Fieldbus parameter and Select [Fieldbus parameter] with This menu item can only be selected if a Fieldbus card is installed in Slot 4.
Section 4: Commissioning 4.7.8 Network Parameters You can configure settings for the network connections (built-in LAN adapter) under parameter]. -[Network Setup/Network parameter HW address 00:90:6C:FB:E9:85 Hostname PR5410-UDOWEIGH Use DHCP IP Address 172.24.21.82 Subnetmask 255.255.240.0 Standardgateway 0.0.0.
Section 4: Commissioning 4.8 LIMIT VALUES, DIGITAL INPUTS AND OUTPUTS 4.8.1 Conditions for Limit Values and Digital Inputs, States for Outputs The limit values and digital inputs can be combined with conditions that must be met before an action is executed. With outputs, these conditions can be output as states directly.
Section 4: Commissioning 4.8.2 Press Configuring Digital Inputs and Outputs and select [Digital I/O parameter] to open the configuration menu for outputs and inputs: Output 1 Output 2 Output 3 Input 1 on Input 1 off Input 2 on Input 2 off Input 3 on Input 3 off BCD out 4.8.
Section 4: Commissioning 4.8.4 Configuring Inputs An action both for signal change from 0 to 1 (on) and from 1 to 0 (off) can be determined for each of the three inputs. The action may be dependent on another condition which must be met.
Section 4: Commissioning 2. Determining a condition The selected action of each digital input can be combined with a condition that must be met for signal change from 0 to 1 (on) or for signal change from 1 to 0 (off). Select the condition from the list; see Chapter 4.8.1. No condition is defined when selecting [no condition]; the action is executed directly.
Section 4: Commissioning 4.8.5 Configuring Limit Values Each limit value consists of a switch-on and a switch-off point for definition of a hysteresis. The three pairs of values must be entered according to the same principle. The limit values always refer to the gross weight. Values between -0.01 x Max and 1.01 x Max of the relevant scale are permissible.
Section 4: Commissioning The output signal (Limit 1 out) of limit 1 switches OFF above a weight of 900 kg. The output signal (Limit 2 out) of limit 2 switches OFF below a weight of 290 kg. Both limit values have a hysteresis of 10 kg. In the event of a power failure, the two outputs go to OFF, thus indicating underfill and overfill at the same time.
Section 4: Commissioning 1. Determining an action Determine the action for the rising edge of the reference signal under [Limit 1 on] from the following list (here: Marker 1 is set when 900 kg are exceeded). Accordingly, an action for [Limit 1 off] can be determined.
Section 4: Commissioning 4.9 ANALOG OUTPUT Max. 1 PR5510/07 card can be mounted in Slot 1/2. Determine the analog output under -[Analog output parameter]. Setup Serial ports parameter Date & Time Operating parameter Printing parameter Fieldbus parameter Network paramter Calibration Limit parameter Digital I/O parameter Analog output parameter Press and to select [Analog output parameter] Setup/Analog output parameter Analog mode no output Analog range 0 ...
Section 4: Commissioning [Weight at 20 mA] Weight value for 20 mA output Press to return to the previous menu [Configuration]. 4.9.1 Adapting the Analog Output The output current can be adapted in small ranges. This is required, if small deviations from the nominal value occur in a connected PLC.
Section 4: Commissioning 4.10 ALIBI MEMORY The instrument is equipped with an alibi memory for approx. 80000 items. If the number is exceeded, the eldest items are overwritten. No license is required for using the alibi memory. At each print command a dataset with a sequence number is filed. The dataset can comprise of up to 3 items (Gross, Net and Tare).
Section 4: Commissioning 4.
Section 4: Commissioning The folder where the programs and configurations are placed is shown. With [Browse] a different folder can be searched and defined. To create an icon on the PC desktop for easy starting of the program the box has to be activated. Continue the installation with [Install]. The progress of installation is displayed, the installation may last some minutes depending on the performance of the PC.
Section 4: Commissioning 4.11.2 Program Start If the program has already been installed previously (see chapter 4.11.1 ), it can be started with the icon on the desktop: Define a New Project Select [File]-[New]-[ConfigureIt Project]. Enter the project name, this is the name of the folder and press [Next >]. The device type [ X3 (PR5410) ] has to be selected and a configuration name (file) has to be defined, continue with [Finish].
Section 4: Commissioning Define a New Configuration A new configuration is defined with [File]-[New][Configuration]. Select the instrument Type [ X3 (PR5410) ] and continue with [Next >]. Enter or select the folder, where the configuration has to be placed and enter the name for the configuration. Continue with [Finish]. In the Navigator the new configuration [Batch.cfg] is shown in the folder [Mixhouse].
Section 4: Commissioning 4.11.3 Establish Communication to the Instrument In the Navigator area the folder 'Mixhouse' with the configuration 'Charge.cfg' is present. After double click on the [Charge.cfg] and click on [Login] with [ConfigureIt] [Communication Parameter] the interface to the instrument can be set. With [Search Device] all instruments of the selected identical type can be found in the network. If the address of the instrument is known, it can be directly entered in [IPAddress].
Section 4: Commissioning 4.11.4 Transfer Dataset from Instrument to PC With [ConfigureIt]-[Load from Device] the complete dataset (including the calibration data and parameters) is transferred from the instrument to the PC. 4.11.5 Store Current Dataset on PC With [File]-[Save as] the complete dataset (including the calibration data and parameters) can be stored in a file. The folder can be selected and a new name for the file can be given. The file [Charge old.cfg] is added at [Mixhouse].
Section 4: Commissioning Modification of Dataset The configuration is selected in the Navigator, then select e.g. [Printer]. Modifications are started by selecting [Edit parameter]. After selection of the port, where the printer of the instrument is connected, the transmission parameters can be altered. Continue with [OK]. The new parameters are shown. With [File]-[Save As] the modified dataset can be stored in a file.
Section 4: Commissioning 4.11.6 Store Current Dataset or Selected Parameters in the Instrument With [ConfigureIT]-[Save to device] parts or the total configuration can be transferred to the instrument. Select with [>] the parameters to be transferred or with [>>] for all parameters. The transfer is started with [OK]. 4.11.7 Reset the Instrument to Factory Default With [ConfigureIt]-[Reset to default] the default data (data in the instrument when leaving the factory) are taken.
Section 4: Commissioning Sending the print file to a printer or selecting the data format of the dataset for storing. 4.11.9 Operation of the Instrument via Browser (VNC) Start the browser with [ConfigureIt]-[Activate Browser]. The program can be operated in the same manner as if it had been started directly, see chapter 4.3. 4.11.
Section 4: Commissioning 4.12 MODBUS / J-BUS PROTOCOL 4.12.1 Communication The MODBUS/J-BUS protocol implemented in the instrument permits fast, simple and reliable communication between a PC or a PLC and up to 127 instruments. PR 5410 fully supports ModbusRTU including functions 1, 2, 3, 4, 5, 6, 8 (sub-function 0), 15 and 16. J-bus is a French 'clone' of the Modbus. There is a small difference: J-bus addresses count from 0 (instead of 1) to hex FFFF (instead of dec. 9999).
Section 4: Commissioning 4.12.2 Function 1 or 2: Reading n Bits Command Range Device address 1 byte 1...127 Function number 1 byte 1, 2 Address of 1st bit 2 bytes 0,8,16... Number CRC 16 of bits 2 bytes 2 bytes 8,16,24. .. The bit address must always be the 1st bit of a byte. The number of bits to be read may not be smaller than 8 and must be a multiple of 8. Reply Device address 1 byte Function number 1 byte Number of Value of Value of read bytes 1st byte 2nd byte 1 byte 1 byte 1 byte 8th ...
Section 4: Commissioning 4.12.4 Function 5: Writing a Bit Command Range Reply Device address 1 byte 0...127 Function number 1 byte 5 Address of the bit 2 bytes 0...127 Value of the bit 1 byte 0 or 255 Always 0 CRC 16 1 byte 0 2 bytes Device address 1 byte Function number 1 byte Address of the bit 2 bytes Value of the bit 1 byte Always 0 CRC 16 1 byte 2 bytes If the address of the bit is out of the permissible range (0...127), an error message is sent as a reply.
Section 4: Commissioning 4.12.6 Function 8: Diagnosis Command Range Device address 1 byte 1...127 Function number 1 byte 8 Subfunction 2 bytes 0 Any value CRC 16 2 bytes 2 bytes This function is intended for testing the communication. Only sub-function 0 is supported. The received command is sent as a reply. Command Device address 1 byte Function number 1 byte Value of the command 2 bytes Subfunction 2 bytes CRC 16 2 bytes 4.12.
Section 4: Commissioning 4.12.8 Function 16: Writing n Successive Words Command Range Device address Function number 1 byte 0...127 1 byte 16 Address of 1st word 2 bytes 0...63 Number of words Number of bytes 2 bytes 1...64 1 byte 2...
Section 4: Commissioning 4.12.
Section 5: SMA Protocol 5 SMA Protocol 5.1 General The protocol of the 'Scale Manufacturers Association' (SMA) provides a simple access to the scale. It can be used for reading data, or for executing functions. The RS-485 interface is used as an interface. Fixed interface settings are 8 bits, no parity and 1 stop bit. The commands to the instrument are printable ASCII characters starting with = 0A hex and ending with = 0D hex. The instrument sends a reply on each received command after approx.
Section 5: SMA Protocol 5.3 SMA Command Set The SMA command set is intended for requesting weight values and status information as well as for control of the scale. The commands start with and end with . Format: c 5.3.1 Requesting a Weight Requesting a Weight Command: W Reply: The scale immediately returns the weight and status: gross weight if not tared, net weight if tared. For details, see Chapter 5.4.1 .
Section 5: SMA Protocol Requesting the High-Resolution Weight with Stability Command: Q Reply: The scale returns the weight and status only, when the stability condition is met: Gross weight if not tared, net weight if tared. The stability condition must be met for this function. The maximum waiting time for stability is set under [Tare timeout]; see Chapter 4.5.13.
Section 5: SMA Protocol Request for Taring with Fixtare Value Command: T Reply: The scale makes a taring attempt using the fixtare value and signals the tared status in the and characters. For details, see Chapter 5.4.1 . Request for Zero Setting of the Scale Command: Z Reply: The scale makes a zero setting attempt and signals the zero status in the character.
Section 5: SMA Protocol 5.3.4 Scale Data Scale Data – First Line Command: A Reply: The scale sends the first line of its scale data. : For details, see Chapter 5.4.1 . Scale Data – Other Lines Command: B Reply: The scale sends further lines of its scale data. : For details, see Chapter 5.4.1 . 5.3.5 Scale Information Scale Information - First Line Command: I Reply: The scale sends the first line of its scale information.
Section 5: SMA Protocol 5.4 SMA Reply Messages In this section, the replies are described in detail. The data format of each reply has a fixed length. The communication error is the only exception from this pre-definable format. Thus the controlling computer can check each reply according to fixed rules, because each data field is in a fixed position. 5.4.1 Standard Reply With most commands, the reply format is as described below: Exceptions are the commands: 'D', 'A'/'B' and 'I'/'N'.
Section 5: SMA Protocol Z <1> <_> <_> <_ _ _ _ _0.000> R <_> <1> <_> <_> <_ _ _ _ 7.025> <_> <1> <_> <_ _ _ _ 7.650> ... repeat... <_> <1> <_> <_> <_ _ _ _ 7.650> The scale repeats the weight, until another command is received. 5.4.2 Reply with Unknown Command ? 5.4.3 ! A command from the controlling computer that is not implemented, or invalid, is replied with an ASCII ‘?’.
Section 5: SMA Protocol 5.4.5 Reply with ‘A’ and ‘B’ Command Reply format with ‘A' and 'B' commands (variable length): : The reply format and meaning are: Start of reply from 'A'/'B' command The field name is three characters long, left-adjusted and filled up with spaces on the right, if necessary.
Section 5: SMA Protocol 5.4.6 Scale Reply with ‘I’ and ‘N’ Commands Reply format with ‘I' and 'N' commands (variable length): : Reply format and meaning: Start of reply from 'I'/'N' command ‘:’ The field name is three characters long, left-adjusted and filled up with spaces, if necessary.
Section 6: PR1612 Commands 6 PR 1612 Commands This function enables the use of the following commands of the PR 1612 command set. No license is required for using. 6.1 MAIN COMMANDS FOR INDICATOR FUNCTION Command WGA WNA WTA WDA Reaction QGAwwwwwwemz QNAwwwwwwemz QTAwwwwwwemz QDAwwwwwwemz WZA WSA WFA ZSC V Q Q Q QZSC QV5410-1.00 Description Read gross weight Read net weight Read tare weight Read difference weight wwwwwwe = Weight with sign and exponent (e.g. '002340' = 002.
Section 7: Fieldbus Interface 7 Fieldbus Interface 7.1 FIELDBUS INTERFACE PROTOCOL The interface works with an 8-byte write window and an 8-byte read window. The fieldbus exchanges its data cyclically with each slave. This means: In each cycle, 8 bytes are written and 8 bytes are read, also if the data content is unchanged. The fieldbus protocol ensures the data transport between the fieldbus master and the 2 x 8-byte data windows.
Section 7: Fieldbus Interface 7.1.1 Write Window (Input Area) Data transmission from the master to the slave (PR 5410) is in this window. Byte 0 Write data: MSB The first four bytes are used only for writing a data Byte 1 " value. Byte 2 " The register number is in byte 5. Bytes 6 and 7 contain bits in direct access independent of the write data. The command is executed after a 0-1 transition of the corresponding bit. 7.1.
Section 7: Fieldbus Interface 7.2 Description of the I/O Area (Read / Write Window) 7.2.1 Input Area Data transmission from the master to the PR 5410 (slave) is via the input area. Weight or data requests are transmitted to the slave by the master. The master has write access; the slave has read access. Byte 0 Write_Value (MSB) 1 ::: 2 ::: 3 Write_Value (LSB) 4 Read_Value_Select 5 Write_Value_Select 6 free free free 7 Name Description e.g. limit value " " " e.g. gross weight Write: Limit 1 On outp.
Section 7: Fieldbus Interface 7.2.2 Output Area Data transmission from the PR 5410 to the master is via the output area. The weight or data information requested by the master is transmitted to the master by PR 5410. The PR 5410 has write access, the master has read access. Byte 0 1 2 3 4 5 6 7 Name Read_Value (MSB) ::: ::: Read_Value (LSB) Read_Value _Selected Write Power Out 3 Active Fail Cmd Cmd Inp.
Section 7: Fieldbus Interface 7.2.3 Reading and Writing Register via Fieldbus Reading Data: Read_Value, Read_Value_Select, Read_Value_Selected When the master has to read from the instrument, the register number is transmitted in Read_Value_Select in the input area. The result is specified with Read_Value_Selected in the output area. Action of the master Writing register no.
Section 7: Fieldbus Interface Control Byte Some instrument functions can be executed by setting bits in the input area directly. Action of the master Setting bits in the control byte Response of PR 5410 The operation is handled Resetting bits in the control byte Waiting for the Result of the Action When an action taking a longer time was started, the end of execution can be waited for after starting (see Chapter 0 and Chapter 0).
Section 7: Fieldbus Interface 7.2.4 Example: Reading the Gross Weight The master writes value 8 in Read_Value_Select (byte 4) of the input area. Input area Byte 0 1 2 3 4 5 6 7 Value Description Gross 8 The master waits, until value 8 was reflected in Read_Value_Selected (byte 4) of the output area.
Section 7: Fieldbus Interface 7.3 Fieldbus Register 7.3.1 Register 0: IO Status Bits for Reading (Dynamic status), only reading is permitted Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Byte 0 Byte 1 Byte 2 Byte 3 7.3.
Section 7: Fieldbus Interface 7.3.3 Register 2: State of State-Controlled Action Bits Only reading is permitted; the signal state is shown. Bit 7 Byte 0 Byte 1 Byte 2 Bit 6 Bit 5 87: 86: 85: GetFixTare SetFixTare ResetPWF Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 84: ResetTest 83: SetTest 82: ResetTare 81: SetTare 89: ResetError 80: SetZero 88: Print Byte 3 7.3.4 Register 3: State of Edge-Controlled Action Bits Only reading is permitted; it is always 0. 7.3.
Section 7: Fieldbus Interface 7.3.6 Register 5: Device Type and Software Release Only reading is permitted. Bit 7 Bit 6 Bit 5 Byte 0 Byte 1 Byte 2 Byte 3 Bit 4 Bit 3 TYPE MSB TYPE LSB MAINVERSION SUBVERSION Bit 2 Bit 1 Bit 0 Bit 4 Bit 3 Bit 2 Board number MSB "" "" Board number LSB Bit 1 Bit 0 E.g. 5410 Rel 1.23 = 54100123hex 7.3.7 Register 6: Board Number Only reading is permitted. Bit 7 Bit 6 Bit 5 Byte 0 Byte 1 Byte 2 Byte 3 E.g. 148388723 = 08D83B73hex 7.3.
Section 7: Fieldbus Interface 7.3.12 Register 30, 31: Fixed Values (Read/Write) Register 30 Register 31 Fixed value for analog output; value (num) 0... 20000 corresponds to 20mA Fixed value for fixtare; see also SetFixTare, GetFixTare ( see Chapter 7.3.3) 7.3.13 Register 80 ... 89: State-Controlled Action Bits (Write) For setting bits, see Chapter 0. Only setting and resetting of single bits is possible. When changing a bit from 0 to 1, the corresponding action starts.
Section 9: Configuration Print-Out 8 Global SPM Variables For communication via OPC, the following variables are available BOOL BOOL BOOL BOOL BOOL BOOL R R R R R R Digital output 1 Digital output 2 Digital output 3 Digital input 1 Digital input 2 Digital input 3 X8 X9 X10 X0 X1 X2 BOOL BOOL BOOL R R R Output limit 1 Output limit 2 Output limit 3 X16 X17 X18 BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL BOOL R R R R R R R R R R R R R R R
Section 8: Global SPM Variables Global SPM Variables, Continued BYTE BYTE BYTE BYTE BYTE BYTE USINT R R R R R R R Indicator status ADC status Command status Exponent (digits behind the decimal point) Weight unit 2:g, 3:kg, 4:t, 5:lb Scale interval (multi-interval / multiple range: d1 or e1) Last error B4 B5 B6 B16 B17 B18 B19 DINT DINT DINT DINT DINT R R R R R Current gross weight Current net weight Current tare weight Current gross / net weight selected with X72 Max weight (full scale deflection) D
Section 9: Configuration Print-Out 9 Configuration print-out The print-out can be started by using front keys Configuration of PR5410 ======================================= Printed :2007-05-17 17:24:47 Firmware : Rel. 01.20.00.1024 2007-05-15 08:15 Appl-DEFAULT : Rel. 01.20 2007-05-08 15:52 Bios : Rel. 01.20.00.
Section 10: Repairs and Maintenance 10 Repairs and Maintenance Repairs are subject to inspection and must be carried out at. In case of defect or malfunction, please contact your local dealer or service center for repair. When returning the instrument for repair, please include a precise and complete description of the problem. Maintenance work may be carried out only by a trained technician with expert knowledge of the hazards involved and the required precautions. 10.
Section 11: Disposal 11 Disposal If you no longer need the packaging after successful installation of the equipment, you should discard it by the local facilities for waste disposal. The packaging is made of environmentally friendly materials and is a valuable source of secondary raw material. Place discharged batteries in local collection boxes (not in the household waste). For scrapping of the instrument, please contact your local authorities. Prior to scrapping, any batteries should be removed.
Section 12: Specifications 12 Specifications 12.1 INSTRUCTIONS FOR USE OF 'FREE SOFTWARE' The firmware in the PR 5410 / X3 instrument contains free software that is licensed under: GNU General Public License (GPL) Version 2, June 1991, and GNU Lesser General Public License (LGPL) Version 2.1, February 1999. This software, developed by third parties, is protected by copyright and is supplied free of charge.
Section 12: Specifications 12.3 EFFECT OF AMBIENT CONDITIONS 12.3.1 Environmental Conditions Temperature range Ambient temperature for operation -10... +40 °C -10... +50 °C Ambient temperature 'not legal for trade' Power-on temperature 0... +40 °C Storage/transport -20... +70 °C Humidity < 95 %, no condensation, (acc. to IEC 68-2) Protection type IP 65: front panel, otherwise IP30 (housing) 12.3.
Section 12: Specifications 12.4.2 Principle Principle Conversion / measuretime Digital filter DC voltage, delta-sigma converter, ratiometric to the load cell supply voltage 5, 10, 20, 40, 80, 160, 320, 640, 960, 1200, 1600 ms Selectable, 4th order (low-pass), Characteristic: Bessel, aperiodic, Butterworth, Tschebyscheff Configurable cut-off frequency 12.4.3 Accuracy and Stability Accuracy class Min. measuring signal (OIML) Min.
Section 12: Specifications 12.6.1 Documentation for Verification on the Enclosed CD The enclosed CD has a directory containing the following PDF documents (in preparation): - EC Declaration of Conformity to Council Directive 90/384/EEC - Plates and markings (sealing and labels) - Test certificate for the instrument - EC type approval 12.6.2 Additional Instructions Information on the meaning of the CAL switch to be sealed can be found in Chapter 4.1.1 .
Section 13: Index 13 Index A I Accessories ...................................................14 Adapting the analog output ...........................97 Analog input / output .............................. 15, 28 Analog output ......................................... 15, 96 I/O slots ........................................................ 21 IEC 1010......................................................... 7 Increased resolution ..................................... 68 Info key .......................
Section 13: Index PR 1721/32 Interbus interface ......................44 PR 1721/34 DeviceNet interface ..................45 PR 1721/37 ...................................................46 PR 5510/02 ...................................................23 PR 5510/04 ...................................................24 PR 5510/07 ...................................................28 PR 5510/08 ...................................................30 PR 5510/09 ..................................................
X Series Manufactured by Fairbanks Scale, Inc. 821 Locust Street Kansas City, MO 64106 www.fairbanks.
