Siemens BT300 HVAC Drive Operator's Manual DPD01809 2019-05-29 Smart Infrastructure
Copyright Notice Copyright Notice Notice Document information is subject to change without notice by Siemens Industry, Inc. Companies, names, and various data used in examples are fictitious unless otherwise noted. No part of this document may be reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose, without the express written permission of Siemens Industry, Inc. Warning This equipment generates, uses, and can radiate radio frequency energy.
Copyright Notice • • Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. Consult the dealer or an experienced radio/TV technician for help. To the Reader Your feedback is important to us. If you have comments about this manual, please submit them to: SBT_technical.editor.us.sbt@siemens.com Credits APOGEE is a registered trademark of Siemens Industry, Inc.
Copyright Notice 4 | 187 Siemens Industry, Inc.
Table of contents How to Use this Manual............................................................................................... 9 Chapter 1 - User Interfaces on Siemens BT300 ..................................................... 11 Drive Keypad ........................................................................................................................... 11 Keypad Buttons ...........................................................................................................
Basic Settings (M3.1.1) ............................................................................ 38 Motor Control Settings (M3.1.2) ............................................................. 39 Start/Stop setup (M3.2) ............................................................................................ 41 Start Function (P3.2.4) ............................................................................. 43 Stop Function (P3.2.5) ...............................................................
Active faults (M4.1) .................................................................................................. 117 Reset faults (P4.2) .................................................................................................... 117 Fault History (M4.4) ................................................................................................. 118 Total Counters (M4.6) .............................................................................................. 118 Trip Counters (M4.
How to Use this Manual How to Use this Manual About This Manual This manual is written for the owner and user of the BT300 HVAC Variable Speed Drive. It is designed to help you become familiar with the BT300 HVAC Variable Speed Drive and its applications. This section covers manual organization, document conventions and symbols used in the manual, how to access help, related publications, and any other information that will help you use this manual.
How to Use this Manual Safety Symbols The following table lists the safety symbols used in this manual to draw attention to important information. Table 1: Warning Symbols. Symbol Description DANGER or WARNING: Dangerous voltage is present. DANGER ou AVERTISSEMENT: Présence de tension dangereuse. WARNING or CAUTION AVERTISSEMENT ou ATTENTION NOTE REMARQUE The following table describes the safety notices used in this manual to draw attention to important information. Table 2: Warning Descriptions.
Chapter 1 - User Interfaces on Siemens BT300 Drive Keypad Chapter 1 - User Interfaces on Siemens BT300 This chapter presents the different user interfaces on Siemens BT300: • Keypad • Siemens NET • Fieldbus Drive Keypad The control keypad with graphical interface is the interface between the Siemens BT300 HVAC Drive and the user. With the control keypad it is possible to control the speed of a motor, to supervise the state of the equipment and to set the variable frequency driver's parameters.
Chapter 1 - User Interfaces on Siemens BT300 Drive Keypad • • or These buttons allow you to move the cursor left (or right) when editing a parameter value. This button allows you to move to the next step when using a wizard, select an item in the menu, or select a setting for a parameter when editing. • This button allows you to quickly access the Control Page and to easily change between the Hand (Keypad) or Auto mode of operation.
Chapter 1 - User Interfaces on Siemens BT300 Drive Keypad • • • Location: Indicates the Menu name, Sub-menu name, or parameter name that is currently selected. ID: Indicates the parameter ID (if applicable) for the parameter selected. Tree: Indicates the menu, sub-menu, or parameter tree structure number. NOTE: This field always shows standard English digits regardless of the language selected by Language Selections (P6.1).
Chapter 1 - User Interfaces on Siemens BT300 Drive Keypad 4. Confirm the change with the button or ignore the change by returning to the previous level with the button. 5. To exit a parameter, press the button. Resetting a Fault When a fault has occurred, there are four ways to reset the fault: NOTE: Remove the external control signal before resetting the fault to prevent unintentional restart of the drive. • • If fieldbus communication is in use, command the Reset Fault object.
Chapter 1 - User Interfaces on Siemens BT300 NET (Software Tool) Selecting Auto from Hand 1. From any screen in the menu structure, press the 2. Use the or button. buttons to highlight Auto and press the 3. When Activate displays, press the button. button to confirm. Accessing the Control Page The Control Page enables easy operation and monitoring of the most essential values.
Chapter 1 - User Interfaces on Siemens BT300 Fieldbus NOTE: See the software’s Help menu for more information on using Siemens NET. Fieldbus The BT300 HVAC Drive has both RS-485 communication and Ethernet protocols built into the core product; there are no special order requirements for obtaining the desired protocols. The RS-485 protocols are: APOGEE-P1, BACnet MS/TP, Johnson N2, and Modbus RTU. The Ethernet protocols are: BACnet IP and Modbus TCP.
Chapter 2 - Control Board Terminal Connections Fieldbus Chapter 2 - Control Board Terminal Connections The control board terminals are located on the control module. The control module is identical for all sizes of the BT300 HVAC Drive. It contains the keypad, terminals, and the control processor of the drive. Connect the control wiring to the BT300 control terminals per the site-specific drawings. Figure 3: Slot A Terminal Connections. Figure 4: Slot B Terminal Connections. Siemens Industry, Inc.
Chapter 2 - Control Board Terminal Connections Analog Input Terminal Connections Figure 5: I/O-Related DIP Switches. Analog Input Terminal Connections The BT300 HVAC Drive consists of two analog inputs built on Slot A. When using analog inputs, the DIP switches must be correctly set and the analog inputs correctly configured before enabling them. When using an analog input for speed reference, the signal is automatically scaled for Minimum Frequency (P3.3.1) to Maximum Frequency (P3.3.
Chapter 2 - Control Board Terminal Connections Digital Input Terminal Connections Signal Range (P3.5.2.9) is used for programming the signal range of the analog input. Possible settings are 0 to 10 Vdc/0 to 20 mA or 2 to 10 Vdc/4 to 20 mA. Figure 7: Analog Input 2 Terminal Connections. Digital Input Terminal Connections The BT300 HVAC Drive consists of six digital inputs built on Slot A.
Chapter 2 - Control Board Terminal Connections Digital Output Terminal Connections Digital Output Terminal Connections The BT300 HVAC Drive consists of three digital (relay) outputs built on Slot B. See Figure 5 for the location of the DIO DIP switch. When using the digital outputs, the DIP switch must be correctly set and digital outputs correctly configured. Figure 10: Digital Output Terminal Connections. 20 | 187 Siemens Industry, Inc.
Chapter 3 - Start-up Information Procedure and Checklist Chapter 3 - Start-up Information Procedure and Checklist To provide the most reliable drive available, and to avoid any extra costs related to loss or reduction of warranty coverage, a factory-certified specialist should complete the startup procedures covered in the Startup Procedure and Checklist (125-1006). Commissioning Flowchart Table 3: Commissioning Flowchart.
Chapter 3 - Start-up Information Wizards Wizards Wizards are available in the Quick Setup (M1) menu. The wizards assist you with various start-up and commissioning functions. There are five wizards available in the BT300 HVAC Drive that prompt for essential information needed for the following: • Start-up Wizard - Easy commissioning of the drive. • PID Mini-Wizard - Proper configuration of internal PID Loop Controller 1. • Multi-Pump Wizard - Proper configuration of the Multi-pump application.
Chapter 3 - Start-up Information Wizards Step 7 Parameter/Question Fan or Pump (Application Type) Settings Pump Automatically sets the following: Accel Time 1 (P1.13) = 30 Decel Time 1 (P1.14) = 30 Start Function (P3.2.4) = Ramping Stop Function (P3.2.5) = Ramping Fan Automatically sets the following: Accel Time 1 (P1.13) = 120 Decel Time 1 (P1.14) = 120 Start Function (P3.2.4) = Flying Start Stop Function (P3.2.5) = Coast to Stop 8 Motor Nom Voltg (P3.1.1.
Chapter 3 - Start-up Information Wizards Step Parameter/Question Settings 21 Start Function (P3.2.4) Defines the start function of the drive. 0 = Ramping Start 1 = Flying Start 22 Stop Function (P3.2.5) Defines the stop function of the drive. 0 = Coast to Stop 1 = Ramping Stop 23 Motor Switch (P3.1.2.2) Prevents the drive from tripping when a motor switch is located between the drive and motor. 0 = No 1 = Yes 24 Bypass Wizard (P1.21) Enable parameter for the Bypass Wizard.
Chapter 3 - Start-up Information Wizards Step Parameter/Question Settings 9 Analog Input Signal Range 0 to 10V/0 to 20 mA 2 to 10V/4 to 20 mA 10 Keypad SP1 (P3.12.2.1) or Keypad SP2 (P3.12.2.2) Varies 11 Sleep Function? No Yes If the option Yes is selected for Sleep Function, you will be prompted for the sleep function settings: Step Parameter/Question Settings 12 Sleep Frequency Limit 1 (P3.13.2.7) Varies 13 Sleep Delay 1 (P3.12.2.8) Varies 14 Wake-up Level 1 (P3.12.2.
Chapter 3 - Start-up Information Wizards Fire Mode Wizard (P1.20) The Fire Mode feature of the drive is designed to place the drive in a mode that ignores all commands from the keypad, fieldbuses, and the personal computer tool. In addition, the drive will ignore all alarms and faults of the drive and continue providing frequency to the attached motor. This is designed for instances when the destruction of equipment is better than loss of life.
Chapter 3 - Start-up Information Wizards Step 1 Parameter/Question Select the Bypass (P3.17.4) mode Settings Electronic Conventional Disabled If Conventional is selected, the following changes occur automatically, the wizard completes, and the message: Bypass Wizard is now complete. Press OK to continue. displays. • Control Signal 2 A (P3.5.1.2) is set to DigIN Slot0.1 to disable the reverse command on Digital Input 2. • Run Interlock 2 (P3.5.1.13) is set to DigIN SlotA.
Chapter 3 - Start-up Information Wizards Step Parameter/Question Settings 10 Auto Bypass Delay (P3.18.4) Range: 0 to 30 s 11 Fault Selection (P3.18.3) Select faults to enable auto Bypass: Any Fault Undervoltage Overvoltage Overcurrent AI Low Unit Temperature Motor Overtemp External Fault Underload Fault * Feature of the Electronic Bypass Option. For more details , see BT300 Bypass Operator’s Manual (DPD01391) The Bypass Wizard is now complete.
Chapter 4 - Parameters and Menu Structure Wizards Chapter 4 - Parameters and Menu Structure All information and parameters are organized in a menu structure: Quick Setup (M1) P1.17 PID Mini-Wizard P1.18 Multi-Pump Wizard All basic parameters required to quickly setup P1.19 Startup Wizard the BT300 VFD for P1.20 Fire Mode Wizard operation and all available wizards. Diagnostics (M4) M4.1 Active Faults Diagnostics information such as active faults, fault history and counters. M4.2 Reset Faults M4.
Chapter 4 - Parameters and Menu Structure Quick Setup (M1) Quick Setup (M1) The Quick Setup parameter group is a collection of parameters that are the most commonly used during installation and commissioning. They are collected in the first parameter group so that they can be found quickly and easily. However, they can be also be reached and edited in the actual parameter groups. Changing a parameter value in the Quick Setup group also changes the value of this parameter in its actual group.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Structure Parameter Unit ID Description 104 Time allowed for motor to decelerate from Maximum Frequency (P1.9) to a standstill (0). Also see Menu Structure P3.4.3. Ctrl. Place Auto 172 Start/Stop commands are given differently depending upon the control place. This parameter defines whether the Start/Stop command is controlled by digital inputs as defined in Control Signal 1 A (P3.5.1.1) and Control Signal 2 A (P3.5.1.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Multimonitor (M2.1) On the Multi-Monitor page, you can collect nine values to monitor. The display fields can be changed by selecting the display field to be changed with the and arrow buttons, and then pressing the button. Scroll through the list of items until the desired value to be monitored is highlighted. Items with a checkmark are already actively displayed in the multimonitor display.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Structure Parameter Unit ID Description M2.2.17 DriveStatusWord 43 Bit coded status of the drive B1 = Ready B2 = Run B3 = Fault B6 = Run Enable B7 = Alarm Active B10 = DC Current (in stop) B11 = DC Brake Active B12 = Run Request B13 = Motor Regulator Active M2.2.18 Last ActiveFault 37 Fault code of last activated fault that has not been reset. See Fault Codes. M2.2.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Table 7: Monitoring of Timer Functions. Structure Parameter Unit ID Description M2.3.1 TC 1, TC 2, TC 3 1441 Status of the three time channels M2.3.2 Interval 1 1442 Status of timer interval M2.3.3 Interval 2 1443 Status of timer interval M2.3.4 Interval 3 1444 Status of timer interval M2.3.5 Interval 4 1445 Status of timer interval M2.3.6 Interval 5 1446 Status of timer interval M2.3.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Multi-pump monitoring (M2.6) The Multi-Pump monitoring values are the actual values related to the use of several drives/motors. See Multi- Pump (M3.14). The Multi-Pump monitoring values are presented in the following table: Table 10: Multi-Pump Monitoring. Structure Parameter Unit ID Description M2.6.1 Motors Running 30 The number of motors running at the moment when Multi-Pump functionality is used. M2.6.
Chapter 4 - Parameters and Menu Structure Monitor Menu (M2) Structure Parameter Unit ID Description M2.8.17 FB Data Out 5 870 Raw value of process data out 32-bit signed format. M2.8.18 FB Data Out 6 871 Raw value of process data out 32-bit signed format. M2.8.19 FB Data Out 7 872 Raw value of process data out 32-bit signed format. M2.8.20 FB Data Out 8 873 Raw value of process data out 32-bit signed format. 36 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Temperature inputs monitoring (M2.9) The Temperature Inputs monitoring values are the actual values of the temperature inputs connected using slot C, D, or E. If no sensor is available, the monitoring values do not exist. The Temperature Inputs monitoring values are presented in the following table: Table 12: Temperature Inputs Monitoring. Structure Parameter Unit ID Description M2.9.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Basic Settings (M3.1.1) Table 14: Basic Motor Settings. Structure P3.1.1.1 Parameter Motor Nom Voltg Unit V Min Varies Max Varies Default Varies ID 110 Description Defines nominal motor voltage from motor nameplate data. Also see Menu Structure P1.1. P3.1.1.2 Motor Nom Freq Hz 8 320 60 111 Defines nominal motor frequency from motor nameplate data. Also see Menu Structure P1.2. P3.1.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Motor Control Settings (M3.1.2) Table 15: Motor Control Settings. Structure Parameter Unit Min Max Default ID Description 1.5 Varies Varies 601 Motor noise can be minimized using a high switching frequency. Increasing the switching frequency reduces the capacity of the drive. It is recommended to use a lower frequency when the motor cable is long in order to minimize capacitive currents in the cable.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description Disabled Enabled Enabled 608 Enable parameter for the over voltage controller. When enabled, the drive acceleration and speed can be modified by the controller to prevent the drive from tripping. 50 150 100 659 Parameter for adjusting stator voltage in permanent magnet motors.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Start/Stop setup (M3.2) The start/stop commands are given from different locations depending on the selected control place. Auto Control Place I/O A: Start, stop, and reverse commands are controlled by two digital inputs chosen with Control Signal 1 A (P3.5.1.1) and Control Signal 2 A (P3.5.1.2). The functionality/logic for these inputs is selected with I/O A Start/Stop Logic (P3.2.6). The I/O B Control Force (P3.5.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Min Max Default P3.2.5 Structure Stop Function Parameter Coasting Ramping Coasting 506 Defines the stop function of the drive. 0 = Coast to Stop 1 = Ramping Stop P3.2.6 I/O A Logic Forw-Back Start-Rev (edge) ForwBack 300 See I/O Table. P3.2.7 I/O B Logic Forw-Back Start-Rev (edge) ForwBack 363 Same as I/O A Logic (P3.2.6). I/O B Ctrl Force (P3.5.1.5) is used to determine when this logic is followed. P3.2.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Start Function (P3.2.4) Table 18: Start Function. Selection Name Description 0 Ramping After the Start command, the speed of the motor is accelerated according to the set acceleration parameters to frequency setpoint. 1 Flying Start After the Start command, the drive quickly adjusts the output frequency until the actual motor speed has been found. Then the motor ramps to the frequency setpoint. Stop Function (P3.2.
Chapter 4 - Parameters and Menu Structure Parameters (M3) NOTE: The Start/Stop contact must be opened before the motor can be started. The used stop mode is Coasting in all examples. 44 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Logic Selection Name CS1: Forward CS2: Backward 0 Note The functions take place when the contacts are closed. Figure 12: I/O A Start/Stop logic = 0. Table 21: Legend to I/O A Start/Stop logic = 0. 1 Control signal (CS) 1 activates causing the output frequency to rise. The motor runs forward. 8 Run enable signal is set to FALSE, which drops the frequency to 0. The run enable signal is configured with RunEnable (P3.5.1.11).
Chapter 4 - Parameters and Menu Structure Parameters (M3) Logic 1 Selection Name Note CS1: Forward (edge) CS2: Inverted stop Figure 13: I/O A Start/Stop logic = 1. Table 22: Legend to IO A Start/Stop logic = 1. 1 Control signal (CS) 1 activates causing the output frequency to rise. The motor runs forward. 6 CS1 activates and the motor accelerates (FWD) towards the set frequency because the Run enable signal has been set to TRUE. 2 CS2 inactivates causing the frequency to drop to 0.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Logic 2 Selection Name Note CS1: Forward (edge) Used to exclude the possibility of an unintentional start. The Start/Stop contact must be CS2: Backward (edge) opened before the motor can be restarted. Figure 14: I/O A Start/Stop logic = 2. Table 23: Legend to I/O A Start/Stop logic = 2. Siemens Industry, Inc. Smart Infrastructure 1 Control signal (CS) 1 activates causing the output frequency to rise. The motor runs forward.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Logic Selection Name 3 Note CS1: Start CS2: Reverse Figure 15: I/O A Start/Stop logic = 3. Table 24: Legend to I/O A Start/Stop logic = 3. 1 Control signal (CS) 1 activates causing the output frequency to rise. The motor runs forward. 7 Run enable signal is set to FALSE, which drops the frequency to 0. The run enable signal is configured with Run Enable (P3.5.1.11). 2 CS2 activates which causes the direction to start changing (FWD to REV).
Chapter 4 - Parameters and Menu Structure Parameters (M3) Logic Selection Name 4 CS1: Start (edge) CS2: Reverse Note Used to exclude the possibility of an unintentional start. The Start/Stop contact must be opened before the motor can be restarted. Figure 16: I/O A Start/Stop logic = 4. Table 25: Legend to I/O A Start/Stop logic = 4. 1 Control signal (CS) 1 activates causing the output frequency to rise. The motor runs forward because CS2 is inactive.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Control reference settings (M3.3) The frequency reference source is programmable for all control places except the computer, which always takes the reference from the PC tool. Auto Control Place I/O A: The source of frequency reference can be selected with I/O Control Reference A Selection (P3.3.3). The I/O B Reference Force (P3.5.1.6) will determine when the I/O Control Reference B is in use.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description PresetFreq0 Motor Pot Ref Keypad Ref 121 Defines the location of Keyboard Control Reference: 1 = Preset Freq 0 2 = Keypad Reference 3 = Fieldbus 4 = AI1 5 = AI2 6 = AI1+AI2 7 = PID 1 Reference 8 = Motor Potentiometer 0 Parameter P3.3.2 0 184 Defines the frequency reference when in HAND (keypad) mode of operation.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.3.12 Preset Freq 1 Hz Parameter P1.8 or P3.3.1 Parameter P1.9 or P3.3.2 10 105 Defines the frequency to be used when the following occurs: 1. PresetFreqMode (P3.3.10) is set to Binary Coded and Preset Freq Sel0 (P3.5.1.15) is activated. Preset Freq Sel1 (P3.5.1.16) is deactivated. Preset Freq Sel2 (P3.5.1.17) is deactivated. 2. PresetFreqMode (P3.3.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.3.15 Preset Freq 4 Hz Parameter P1.8 or P3.3.1 Parameter P1.9 or P3.3.2 25 127 Defines the frequency to be used when the following occurs: 1. PresetFreqMode (P3.3.10) is set to Binary Coded & Preset Freq Sel0 (P3.5.1.15) is deactivated. Preset Freq Sel1 (P3.5.1.16) is deactivated. Preset Freq Sel2 (P3.5.1.17) is activated. P3.3.16 Preset Freq 5 Hz Parameter P1.8 or P3.3.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Understanding Preset Frequencies Preset frequency mode (P3.3.10) You can use the preset frequency parameters to define certain frequency references in advance. These references are then applied by activating/deactivating the digital inputs connected to parameters Preset frequency selection 0 (P3.5.1.15), Preset frequency selection 1 (P3.5.1.16) and Preset frequency selection 2 (P3.5.1.17).
Chapter 4 - Parameters and Menu Structure Parameters (M3) Binary Coded Operation The values of the preset frequencies are automatically limited between the Minimum Frequency (P3.3.1) and Maximum Frequency (P3.3.2). The following table displays the operation to select the preset frequencies: Table 28: Preset Frequencies 1 Through 7. Required Action For use with 1/O Control Reference (P3.3.3), Preset Freg0 is selected. Activated Frequency Preset Frequency 0 (P3.3.11) B2 (P3.5.1.17) B1 (P3.5.1.16) B0 (P3.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Table 30: Ramp and Brakes Settings. Structure Parameter Unit Min Max Default ID Description P3.4.1 Ramp 1 Shape s 0 10 0 500 S-curve time ramp 1. P3.4.2 Accel Time 1 s 0.1 3000 20 103 Defines the time required to increase output freq from 0 to Max Frequency (P3.3.1). P3.4.3 Decel Time 1 s 0.1 3000 20 104 Defines the time required to decrease output freq from Max Frequency (P3.3.1) to 0 frequency. P3.4.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 17: Acceleration/Deceleration (S-shaped). Flux braking (P3.4.12) Instead of DC braking, flux braking is a useful way to raise the braking capacity in cases where additional brake resistors are not needed. When braking is needed, the frequency is reduced and the flux in the motor is increased, which in turn increases the motor's capability to brake. Unlike DC braking, the motor speed remains controlled during braking.
Chapter 4 - Parameters and Menu Structure Parameters (M3) 58 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) The digital inputs settings are presented in the following table: Table 31: Digital Inputs Settings. Structure P3.5.1.1 Parameter Ctrl Signal 1 A (Start Forward) Default DigIN SlotA.1 ID 403 Description Defines the location for selection of Control Signal 1 A as defined by I/O A Logic (P3.2.6) [Start Forward] Possible settings are as follows: TimeChannel.# DigIN Slot0.# DigIN SlotA.# DigIN SlotC.# DigIN SlotD.# DigIN SlotE.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Default ID Description P3.5.1.12 Run Interlock 1 DigIN Slot0.2 1041 Defines the input monitored for proof of the interlock application when Mot. Interlock Start (P3.2.11) is enabled. The drive cannot be started if any of the interlocks are open. This function can be used for a damper interlock, preventing the drive from starting with the damper closed. P3.5.1.13 Run Interlock 2 DigIN Slot0.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Default ID Description P3.5.1.28 Interlock 3 DigIN Slot0.1 428 Defines the location for the interlock feedback for motor 3 when using the multi-pump feature. P3.5.1.29 Interlock 4 DigIN Slot0.1 429 Defines the location for the interlock feedback for motor 4 when using the multi-pump feature. P3.5.1.30 Interlock 5 DigIN Slot0.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Parameter Default P3.5.1.50 Structure Remote Safety 7* DigIN Slot0.2 1823 ID Defines the location of the remote safety. Description P3.5.1.51 Remote Safety 8* DigIN Slot0.2 1824 Defines the location of the remote safety. P3.5.1.52 Essential Services* DigIN Slot0.1 1827 Defines the location of the essential service activation signal. NOTE: Requires EssentServEnable (P3.18.5) to be enabled to take effect. P3.5.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.5.2.5 AI1 Custom Max P3.5.2.6 AI1 Signal Inv P3.5.2.7 AI2 Signal Sel P3.5.2.8 AI2 Filter Time P3.5.2.9 AI2 Signal Range P3.5.2.10 AI2 Cutom Min P3.5.2.11 AI2 Custom Max P3.5.2.12 AI2 Signal Inv P3.5.2.13 AI3 Signal Sel P3.5.2.14 AI3 Filter Time P3.5.2.15 AI3 Signal Range P3.5.2.16 AI3 Cutom Min Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.5.2.17 AI3 Custom Max P3.5.2.18 AI3 Signal Inv P3.5.2.19 AI4 Signal Sel P3.5.2.20 AI4 Filter Time P3.5.2.21 AI4 Signal Range P3.5.2.22 AI4 Cutom Min P3.5.2.23 AI4 Custom Max P3.5.2.24 AI4 Signal Inv P3.5.2.25 AI5 Signal Sel P3.5.2.26 AI5 Filter Time P3.5.2.27 AI5 Signal Range 64 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.5.2.28 AI5 Cutom Min % -160 160 0 191 Defines the custom minimum to be used for bypassing the AI5 Signal Range (P3.5.2.27). P3.5.2.29 AI5 Custom Max & -160 160 100 192 Defines the custom maximum to be used for bypassing the AI5 Signal Range (P3.5.2.27). P3.5.2.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Digital outputs, slot B (Basic) Table 33: Digital Outputs, Slot B. Structure Parameter P3.5.3.2.1 RO1 Function P3.5.3.2.2 RO1 ON Delay P3.5.3.2.3 RO1 OFF Delay P3.5.3.2.4 RO2 Function P3.5.3.2.5 RO2 ON Delay P3.5.3.2.6 RO2 OFF Delay P3.5.3.2.7 RO3 Function Unit Min Max Default ID Description None Remote Start Run 11001 See Basic RO Functions Table.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Selection Selection name Description 13 Limit supervision 2 Activates if the signal value falls below or exceeds the set supervision limit (P3.8.3 or P3.8.7) depending on the selected function. 14 Start command active Start command is active. 15 Reserved 16 Fire mode ON 17 RTC timer 1 control Time channel 1 is used. 18 RTC timer 2 control Time channel 2 is used. 19 RTC timer 3 control Time channel 3 is used.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Selection Selection name Description 45 Interlock Proofing Selects relay output for the Interlock Proofing signal. 46 Interlock Proofed Selects relay output for the Interlock Proofed signal. 47 Stop Forced Selects relay output for the Local Stop Forced from keypad signal. 48 Remote Start Selects relay output for the Remote Start signal Slot C (M3.5.3.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Table 37: Digital Outputs, Slot E. Structure Parameter Unit Min Max Default ID P3.5.3.5.1 RO1 Function None Remote Start None 14001 P3.5.3.5.2 RO2 Function None Remote Start None 14002 P3.5.3.5.3 RO3 Function None Remote Start None 14003 P3.5.3.5.4 RO4 Function None Remote Start None 14004 P3.5.3.5.5 RO5 Function None Remote Start None 14005 P3.5.3.5.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Settings Description 7 Motor Power Track the Motor Power based on 0 to PnMotor. 8 Motor Voltage Track the Motor Voltage based on 0 to VnMotor. 9 DC Link Voltage Track the DC Link Voltage based on 0 - 1000 Vdc. 10 PID 1 Output Track the PID1 Output based on 0 - 100% 11 PID 2 Output Track the PID2 Output based on 0 - 100%. 12 Process Data In 1 Track the Process Data In 1 where 5000 = 50.00%.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Table 41: Analog Outputs, Slot D. Structure Parameter Unit Min Max Default ID Structure 0% Test ProcessDataIn8 0% Test 13050 See AO Functions Table. 0 300 1 13051 Filter time of analog output signal 0 = No filtering AO1 Min Signal 0 Vdc/0 mA 2 Vdc/4 mA 0 Vdc/0 mA 13052 Settings: 0 = 0 Vdc/ mA 1 = 2 Vdc/4 mA P3.5.4.4.4 AO1 MinScale Varies Varies Varies 13053 Min Scale in process unit. P3.5.4.4.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Fieldbus Data Mapping (M3.6) Fieldbus data In/Out mappings provide further information over the fieldbus that is not available in the current object mappings. Data sent to the fieldbus can be chosen with a parameter ID number, and the data is scaled to an unsigned 16-bit format according to the format on the keypad. For example, 25.5 on the keypad becomes 255 over the fieldbus data mapping.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.6.6 FB DataOut 6 Sel 0 35000 Voltage (6) 857 Defines the data to be sent to the fieldbus as FB DataOut 6. See FBDataOut 1 Sel (P3.6.1) for further details. BACnet = AV_25 P1 = Subpoint 55 P3.6.7 FB DataOut 7 Sel 0 35000 DC Link (7) 858 Defines the data to be sent to the fieldbus as FB DataOut 7. See FBDataOut 1 Sel (P3.6.1) for further details.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max 35000 Default P3.6.8 FB DataOut 8 Sel 0 Last Fault (37) P3.6.9 FB Run Enable Disabled Enabled Enabled ID Description 859 Defines the data to be sent to the fieldbus as FB DataOut 8. See FBDataOut 1 Sel (P3.6.1) for further details. BACnet = AV_27 P1 = Subpoint 57 1829 Defines the run enable when in fieldbus control. NOTE: When fieldbus is not in use, see Run Enable (P3.5.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Prohibited Frequencies (M3.7) In some systems it may be necessary to avoid certain frequencies due to mechanical resonance problems. By setting up prohibited frequencies, these ranges are skipped. The prohibited frequencies settings are presented in the following table: Table 44: Prohibited Frequencies Settings. Structure Parameter Unit Min Max Default ID Description P3.7.
Chapter 4 - Parameters and Menu Structure Parameters (M3) 1. Set Prohibited Frequency Range 1 Low Limit (P3.7.1) to a value of 44.5. 2. Set Prohibited Frequency Range 1 High Limit (P3.7.2) to a value of 45.5. NOTE: The drive will still ramp through these speeds, but will not control within this range. The speed at which the drive ramps through this range can be changed by the Ramp Time Factor (P3.7.7) to make it faster. For example. If Acceleration Time 1 (P3.4.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure P3.8.5 Parameter Superv2 Item Unit Min Output Frequency Max Analog Input 2 Default Output Frequency ID 1435 Description Defines the drive data to supervise for Superv2 Mode (P3.8.6) in accordance with the Superv2 Limit (P3.8.7) with deadband defined with Superv2 Hyst (P3.8.8) Refer to Superv1 Item (P3.8.1) for settings. NOTE: A relay output can be triggered in accordance with this supervised item.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Protections (M3.9) Protections define the way the drive is to respond to conditions that can occur in the drive. Table 46: Protections Settings. Structure Parameter Unit Min Max Default ID Description P3.9.1 AI Low Fault No Action Fault, Coast No Action 700 Defines the response to a low analog input signal. Response settings are as follows: 0 = No Action 1 = Alarm 2 = Alarm and run to PresetAlarmFreq (P3.3.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description 0 150 100 708 Motor thermal loadability states how much the motor can be thermally loaded. 0 3 0 709 Defines the response to a motor stall. Response settings are as follows: 0 = No Action 1 = Alarm 2 = Fault (stop according to stop mode) 3 = Fault (stop by coasting) A 0 2*IH IH 710 For a stall stage to occur, the current must have exceeded this limit.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.9.22 PID1 Supervision No Action Fault, Coast Fault 749 Defines the response to a PID1 fault. Response settings are as follows: 0 = No Action 1 = Alarm 2 = Fault (stop according to stop mode) 3 = Fault (stop by coasting) P3.9.23 PID2 Supervision No Action Fault, Coast Fault 757 Defines the response to a PID2 fault.
Chapter 4 - Parameters and Menu Structure Parameters (M3) motor is reduced as well as its capacity. If the motor is equipped with an external fan, the load reduction at low speeds is small. The motor thermal protection is based on a calculated model and uses the output current of the drive to determine the load on the motor. The motor thermal protection can be adjusted with parameters. The thermal current IT specifies the load current above which the motor is overloaded.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Motor thermal load (P3.9.10) Setting the value to 130% means that the nominal temperature will be reached with 130% of the motor’s nominal current. Figure 19: Motor Temperature Calculation. Stall Protection (P3.9.11 through P3.9.14) The motor stall protection protects the motor from short-time overload situations such as one caused by a stalled shaft.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 20: Stall characteristics settings. Stall time limit (P3.9.13) This time can be set between 1.0 and 120.0s. This is the maximum time allowed for a stall stage. The stall time is counted by an internal up/down counter. If the stall time counter value goes above this limit, the protection will cause a trip (see Parameters of Stall Protection ‘[P3.9.11]). Figure 21: Stall time count. Under-load protection (P3.9.15 through P3.9.
Chapter 4 - Parameters and Menu Structure Parameters (M3) The torque values for setting the under-load curve are set in percentage which refers to the nominal torque of the motor. The motor’s name plate data, parameter motor nominal current and drives nominal current IL are used to find the scaling ratio for the internal torque value. If other than a nominal motor is used with the drive, the accuracy of the torque calculation decreases. Under-load protection: Field weakening area load (P3.9.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 23: Underload time counter function. Automatic Reset (M3.10) The Automatic Reset settings define how the automatic reset feature operates as well as what faults are allowed to be reset automatically. The automatic reset settings are presented in the following table: Structure Parameter Unit Min Max Default ID Description P3.10.1 Automatic Reset Disabled Enabled Disabled 731 Determines if the Automatic Reset feature can be used.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description P3.10.10 UnitOverTemp Flt No Yes Yes 724 Determines if the automatic reset feature can reset when a unit over temperature fault condition occurs. P3.10.11 MotorOverTempFlt No Yes Yes 725 Determines if the automatic reset feature can reset when a motor over temperature fault condition occurs. P3.10.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 24: Automatic reset function. Timer Functions (M3.11) The timer functions (time channels) in the BT300 drive allow you to program functions to be controlled by the internal RTC (Real Time Clock). Almost every function that can be controlled by a digital input can also be controlled by a time channel.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Interval 1 (M3.11.1) Table 47: Interval 1. Min Max P3.11.1.1 Structure ON Time Parameter hh:mm:ss 0:00:00 23:59:59 1464 ON Time Defines the time ON is issued to the time the channel defined in AssignToChannel (P3.11.1.5) on the day of week defined in From Day (P3.11.1.3) to and including day defined in To Day (P3.11.1.4). P3.11.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Interval 2 (M3.11.2) Table 48: Interval 2. Structure Parameter Unit Min Max Default ID Description P3.11.2.1 ON Time hh:mm:ss 0:00:00 23:59:59 0:00:00 1469 See description for P3.11.1.1 P3.11.2.2 OFF Time hh:mm:ss 0:00:00 23:59:59 0:00:00 1470 See description for P3.11.1.2 P3.11.2.3 From Day Sunday Saturday Sunday 1471 See description for P3.11.1.3 P3.11.2.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Interval 5 (M3.11.5) Table 51: Interval 5. Structure Parameter Unit Min Max Default ID Description P3.11.5.1 ON Time hh:mm:ss 0:00:00 23:59:59 0:00:00 1484 See description for P3.11.1.1 P3.11.5.2 OFF Time hh:mm:ss 0:00:00 23:59:59 0:00:00 1485 See description for P3.11.1.2 P3.11.5.3 From Day Sunday Saturday Sunday 1486 See description for P3.11.1.3 P3.11.5.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Timer 3 (M3.11.8) Table 54: Timer 3. Structure Parameter P3.11.8.1 Duration P3.11.8.2 AssignToChannel Unit s Min Max Default ID Description 0 72000 0 1491 See description for P3.11.6.1 Not Used Time Channel 3 Not Used 1494 See description for P3.11.6.2 Example Problem: We have a variable frequency drive for air conditioning in a warehouse. It needs to run between 7:00 A.M. until 5:00 P.M. on weekdays, and 9:00 A.M.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Solution: Set up two intervals: one for weekdays, and one for weekends. A timer is also needed for activation outside the normal office hours. The example configuration is completed as follows: 1. Interval 1 (used for the weekdays) – – – – – Set ON Time (P3.11.1.1) to a value of 07:00:00. Set OFF Time (P3.11.1.2) to a value of 17:00:00. Set From Day (P3.11.1.3) to a value of Monday. Set To Day (P3.11.1.4) to a value of Friday.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description % F % 1036 See Table Process Unit Selection. Varies Varies Varies 0 1033 Defines the minimum of the range for the process unit. Varies Varies Varies 100 1034 Defines the maximum of the range for the process unit. ProcessUnitDeci. 0 4 2 1035 Defines the number of positions after the decimal place that will display. P3.12.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter Unit Min Max Default ID Description Not Used Test Sequence Keypad SP1 332 See Table Setpoint Source. AIs and ProcessDataIn's are handled as percent and scaled according to Setpoint Min and Setpoint Max. NOTE: ProcessDataIn uses two decimals. % -200 200 0 1069 Minimum value of Setpoint at Analog Signal Minimum. SP 1 Maximum % -200 200 100 1070 Maximum value of Setpoint at Analog Signal Maximum. P3.12.2.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Settings Description 5 AI3 Use analog input 3. 6 AI4 Use analog input 4. 7 AI5 Use analog input 5. 8 AI6 Use analog input 6. 9 ProcessDataIn1 Use ProcessDataIn1. 10 ProcessDataIn2 Use ProcessDataIn2. 11 ProcessDataIn3 Use ProcessDataIn3. 12 ProcessDataIn4 Use ProcessDataIn4. 13 ProcessDataIn5 Use ProcessDataIn5. 14 ProcessDataIn6 Use ProcessDataIn6. 15 ProcessDataIn7 Use ProcessDataIn7.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.12.3.5 FB 1 Maximum P3.12.3.6 FB 2 Source P3.12.3.7 FB 2 Minimum P3.12.3.8 FB 2 Maximum Unit % Min Max Default ID Description 337 Maximum value at Analog Signal Maximum. ProcessData Not Used In8 335 See FB 1 Source (P3.12.3.3). -200 200 0 338 Minimum value at Analog Signal Minimum. -200 200 100 339 Maximum value at Analog Signal Maximum. -200 200 Not Used % % 100 Table 60: Feedback Sources.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Feedforward (M3.12.4) Table 61: Feedforward. Structure Parameter P3.12.4.1 Function P3.12.4.2 Gain P3.12.4.3 FF 1 Source P3.12.4.4 FF 1 Minimum P3.12.4.5 FF 1 Maximum P3.12.4.6 FF 2 Source P3.12.4.7 FF 2 Minimum P3.12.4.8 FF 2 Maximum Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Process Supervision (M3.12.5) Table 62: Process Supervision. Structure Parameter Unit Min Max Default ID Description Disabled Enabled Disabled 735 Settings: 0 = Disabled 1 = Enabled Varies Varies Varies Varies 736 Upper actual/process value supervision. Lower Limit Varies Varies Varies Varies 758 Lower actual/process value supervision.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Pressure Loss Compensation (M3.12.6) Table 63: Pressure Loss Compensation. Structure Parameter Unit Min Max Default ID Description Disabled Enabled Disabled 1189 Enables the drive to raise or lower the setpoint depending on output frequency. SP 1 Max Comp. (P3.12.6.2) is the compensation at maximum frequency. This can be used with incorrectly placed sensors.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Dead band (P3.12.1.9) Reference Actual value Dead band delay (P3.12.1.10) Output locked 11105.emf Figure 25: Dead band. Sleep frequency limit 1 (P3.12.2.7), Sleep delay 1 (P3.12.2.8), and Wake-up level 1 (P3.12.2.9) This function puts the drive into sleep mode if the frequency stays below the sleep limit for a longer period than that set with the Sleep Delay (P3.12.2.8).
Chapter 4 - Parameters and Menu Structure Parameters (M3) Actual value Wake-up level (P3.12.2.9) Frequency Sleep delay (P3.12.2.8) Sleep limit (P3.12.2.7) Regulating mode Sleep Regulating mode 11106.emf Figure 26: Sleep limit, Sleep delay, Wake-up level. Feedforward function (P3.12.4.1) Feedforward usually needs accurate process models, but in some cases, a gain + offset type of feedforward is enough.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 27: Feedforward Control. Enable process supervision (P3.12.5.1) Actual value Upper limit P3.12.5.2) Reference Lower limit (P3.12.5.3) Delay (P3.12.5.4) Regulating mode Alarm or fault 11108.emf Figure 28: Process Supervision. Upper and lower limits around the reference are set. When the actual value goes above or below, a counter starts counting up towards the Delay (P3.12.5.4).
Chapter 4 - Parameters and Menu Structure Parameters (M3) Pressure Loss Compensation Figure 29: Position of Pressure Sensor. If pressurizing a long pipe with many outlets, the best place for the sensor is probably halfway down the pipe (Position 2). However, sensors may, for example, be placed directly after the pump. This will give the right pressure directly after the pump, but farther down in the pipe the pressure will drop depending on the flow. Enable Setpoint 1 (P3.12.6.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 30: Enable Setpoint 1 for Pressure Loss Compensation. PID Controller 2 (M3.13) The PID Controller 2 settings configure the second PID controller, which controls an external device. The PID Controller 2 consists of the following settings: ● Basic Settings ● Setpoints ● Feedback ● Process Supervision 104 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Basic Settings (M3.13.1) Table 64: PID Controller 2 Basic Settings. Structure Parameter Unit Min Max Default ID Description Disabled Enabled Disabled 1630 Enable parameter for the second PID controller. % 0 100 0 1100 The output value of the PID control in % of its maximum output value while it is stopped using Digital Input. Gain % 0 1000 100 1631 Defines the proportional gain of the PID loop. P3.13.1.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.13.2.4 SP 1 Source P3.13.2.5 SP 1 Minimum P3.13.2.6 SP 1 Maximum P3.13.2.7 SP 2 Source P3.13.2.8 SP 2 Minimum P3.13.2.9 SP 2 Maximum Unit Min Max Default ID Description Not Used Test Sequence Keypad SP1 1643 See Table Setpoint Sources. AIs and ProcessDataIn settings are handled as percent and scaled according to Setpoint Min and Setpoint Max. NOTE: Settings 9 through 16 use two decimal places.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Process Supervision (M3.13.4) Table 67: PID Controller 2 Process Supervision. Structure Parameter Unit Min Max Default ID Description Disabled Enabled Disabled 1659 Settings: 0 = Disabled 1 = Enabled Varies Varies Varies Varies 1660 Upper actual/process value supervision. Lower Limit Varies Varies Varies Varies 1661 Lower actual/process value supervision.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.14.6 Autoch:FreqLim P3.14.7 AutochMotorLimit P3.14.8 Bandwidth P3.14.9 Bandwidth Delay Unit Min Max Default ID Description 0 50 25 1031 Defines the level which the auto change is capable to take place. 0 4 1 1030 Defines the level which the auto change is capable to take place. % 0 100 10 1097 Percentage of the setpoint.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Criteria for disconnecting/removing motors: ● Feedback value outside bandwidth area. ● Regulating motor running at a “close-to-min” frequency (+2 Hz). ● Conditions above are fulfilled for a time longer than the bandwidth delay ● There are more motors running than the regulating one. Interlock function (P3.14.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 32: Multi-pump: FC Disabled. Selection 1, Enabled: If the regulating motor needs to be included in the auto-change or interlock logic make the connection according to the following figure. Each motor is controlled by a relay, but the contact logic ensures that the first connected motor is always connected to the drive and near the mains. 110 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Figure 33: Multi-pump: FC Enabled. Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Auto-change (P3.14.4) Table 70: Auto-Change Selections. Selection Selection Name Description 0 Disabled The priority/starting order of the motors is always 1-2-3-4-5 in normal operation. It may have changed during its run if interlocks have been removed and added again, but the priority/order is always restored after a stop. 1 Enabled The priority is changed at certain intervals to get an equal wear on all motors.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Table 71: Fire Mode Settings. Structure Parameter P3.16.1 FireMode Passwd P3.16.2 FireMode Activ.Open Unit Min 0 Max 9999 Default ID Description 0 1599 Defines use of the Fire Mode. Fire Mode is enabled when set to a value of 1001. A test mode can be entered by setting to a value of 1234 previous to the next activation as defined by FireMode Activ.Open (P3.16.2) or FireMode Activ.Close (P3.16.3). DigIN Slot0.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Structure Parameter P3.16.5 FireMode FreqSource P3.16.6 FireMode Reverse Unit Min Max FireMode Freq Motor Pot Ref Default ID Description FireMode Freq 1617 Selection of the frequency reference source to be followed when fire mode has be activated as defined by FireMode Activ.Open (P3.16.2) or FireMode Activ.Close (P3.16.3). Possible settings: 0 = Fire Mode Frequency (as defined by FireMode Freq (P3.16.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Application Settings (M3.17) The Applications Settings contain specific application information and are presented in the following table: Table 72: Application Settings.Information. Structure Parameter Unit Min Max Default ID Description Location for entering a password to the unit that will grant access to development parameters. P3.17.1 Password 0 65000 0 P3.17.
Chapter 4 - Parameters and Menu Structure Parameters (M3) Table 73: Bypass Settings. Structure Parameter P3.18.1 Bypass Delay P3.18.2 AutoBypass P3.18.3 AutoByp Faults P3.18.4 AutoBypass Delay P3.18.5 P3.18.6 Unit s Min Max Default ID Description 1 30 1 1818 Defines the time from when bypass is activated until the M1 (bypass) contactor is pulled in and the motor begins to spin. Disabled Enabled Disabled 1813 Enables parameter to the Auto Bypass feature.
Chapter 4 - Parameters and Menu Structure Diagnostics (M4) Diagnostics (M4) Table 74: Diagnostics. Menu and Parameter Group Description Active Faults (M4.1) Display of currently active faults 1 and 2. Reset Faults (P4.2) Parameter to acknowledge/reset a fault. Fault History (M4.4) Display of up to 40 previous faults. Total Counters (M4.6) Display of the overall counters (not resettable). Trip Counters (M4.7) Display of the counters (resettable). Software Info (M4.
Chapter 4 - Parameters and Menu Structure Diagnostics (M4) Fault History (M4.4) Fault history can contain a maximum number of 40 faults. Once the count of 40 has been reached, the FIFO method is used to store the newest faults. On each fault in memory, you will also find additional information about the drive when the fault occurred. See Chapter 5, Fault Tracing for more information. Total Counters (M4.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 76: Trip Counters. Structure Parameter Unit Min Max Default ID Description M4.7.1 Energy Counter Varies 2296 The amount of energy taken from the supply. NOTE: This is resettable. Highest energy unit that the display shows is MW (megawatts). If the counter scrolls past 999.9 MW, no unit will display. See Energy Counter (M4.6.1) for non-resettable version. M4.7.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) * If an option board has been installed in the slot, the name of this menu will change to the card name (such as, OPTB5). Basic I/O (M5.1) Displays the status of the Basic Slot A and Slot B I/O. See I/O Configuration (M3.5) for configuration information of the Basic I/O. Table 79: Basic Slot A and Slot B I/O. Structure Parameter Unit Min Max Default ID Description M5.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Slot D (M5.3) Displays the status of the available I/O for the option card installed in Slot D. The available parameters change depending upon the option card installed. See the I/O Option Board Type “B” User’s Manual (DPD01158) for a list of available option cards and their I/O types. Table 81: I/O Slot D. Structure Parameter Min. Max. Default Description M5.2.1 I/O Monitor (depends upon the option card installed in slot D.) M5.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Power unit settings (M5.6) Fan (M5.6.1) The cooling fan operates in Optimized or Always-On mode. In the Optimized mode, fan speed is controlled according to the drive’s internal logic that receives data from temperature measurements; the fan stops five minutes after the drive is in a ready state. In Always-On mode, the fan runs at full speed, without stopping. Table 84: Cooling Fan Settings. Structure Parameter Unit P5.6.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 86: Keypad Configuration Settings. Structure Parameter Unit min Min Max Default ID Description 0 60 0 804 Time until display returns to page defined in the Default Page (P5.7.2) 0 = Not used None Multimonitor Multimonitor 2318 Defines the default page to appear after Timeout Time (P5.7.1) has passed. 0 = None 1 = Enter Menu Index (see Menu Index (P5.7.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Figure 34: Connecting the RS-485 Cable. If the Siemens BT300 HVAC Drive is the last device on the bus, the bus termination may be required. See the figure below for enabling to bus termination: Figure 35: Bus Termination. Common Settings (M5.8.1) Common settings are presented in the following table: 124 | 187 Siemens Industry, Inc.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 87: Common Settings. Structure P5.8.1.1 Parameter Protocol Min. Max. No Protocol Default Modbus RTU No Protocol ID 2208 Description Defines the RS-485 base fieldbus protocol to be used: 0 = No Protocol 1 = N2 2 = BACnet MS/TP 3 = P14 = Modbus RTU NOTE: A new menu will be accessible at M5.8.3 depending upon the protocol selected. Configuration for protocol communications will be within that menu.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Monitoring (M5.8.3.2) The following monitoring values are available for the N2 fieldbus protocol: Table 89: N2 Fieldbus Protocol Monitoring. Menu Parameter ID Min Max Description M5.8.3.2.1 Fieldbus Protocol Status 2399 Initializing Faulted Displays the current protocol status as follows: 0 = Initializing 1 = Stopped 2 = Operational 3 = Faulted M5.8.3.2.2 Communication Status 2400 0.0 99.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 90: N2 Analog Inputs.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) NPT NPA Description 0= 1= BI 4 Faulted Not Faulted Faulted BI 5 Alarm Not Alarm Alarm BI 6 Ref. Frequency reached False True BI 7 Motor running zero speed False True BI 8 Flux ready Not Ready Ready Analog Outputs (AO) All analog outputs (AO) points have the following features: ● Support Change of State (COS) reporting based on override status. ● Always considered reliable.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 93: N2 Binary Outputs.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) 1. Complete all settings required for Monitoring as listed above. 2. Set Ctrl. Place Auto (P3.2.1) to a value of FieldbusCTRL. For commanding Start/Stop through the N2 protocol and Speed Reference through an Analog Input, complete the following changes: 1. Complete all settings required for Monitoring as listed above. 2. Set Ctrl. Place Auto (P3.2.1) to a value of FieldbusCTRL. 3. Set FieldbusCtrl Ref (P3.3.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Monitoring (M5.8.3.2) The following monitoring values are available for the BACnet MS/TP fieldbus protocol: Table 96: BACnet MS/TP Monitoring. Menu Parameter ID Min Max Description M5.8.3.2.1 Fieldbus Protocol Status 2393 Initializing Faulted Displays the current protocol status as follows: 0 = Initializing 1 = Stopped 2 = Operational 3 = Faulted M5.8.3.2.2 Communication Status 2394 0.0 99.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 97: BACnet Analog Inputs. Instance ID Object Name Description Units PV Access Menu AI_0 ANALOG IN 1 This is the value of Analog Input 1 PCT R M2.2.13 AI_1 ANALOG IN 2 This is the value of Analog Input 2 PCT R M2.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Binary Outputs (BO) The binary outputs support the following BACnet properties: ● Active Text ● Event State ● Inactive Text ● Object Identifier ● Object Name ● Object Type ● Out of Service ● Present Value ● Priority Array ● Relinquish Default ● Status Flags Table 100: BACnet Binary Outputs.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 101: BACnet Analog Values. Instance ID Object Name Description Units PV Access Menu AV_0 SPEED REF Speed Reference, % of nominal speed. PCT C AV_1 FREQ STPT Frequency Setpoint Hz R AV_2 OUTPUT PCT Output Frequency in % PCT R AV_3 OUTPUT FREQ Output Frequency Hz R M2.2.1 AV_4 MOTOR SPEED Motor Speed rpm R M2.2.3 AV_5 MOTOR CRRNT Motor Current A R M2.2.4 AV_6 MOTOR VLTG Motor Voltage V R M2.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Instance ID Object Name Description Units PV Access Menu AV_37 FBCTRLWORDHI Fixed control word last 16 bits C M2.8.1 AV_38 FBSTATWORDLO Fixed status word first 16 bits R M2.8.11 AV_39 FBSTATWORDHI Fixed status word last 16 bits R M2.8.11 AV_40 MIN FREQ Minimum Frequency Hz W P3.3.1 AV_41 MAX FREQ Maximum Frequency Hz W P3.3.2 AV_42 ACCEL TIME Acceleration Time (1) s W P3.4.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Binary Values (BV) The binary outputs support the following BACnet properties: ● Active Text ● Event State ● Inactive Text ● Object Identifier ● Object Name ● Object Type ● Out of Service ● Present Value ● Priority Array* ● Relinquish Default* ● Status Flags Table 102: BACnet Binary Values. Instance ID Object Name Description Active/Inactive Text PV Access Menu BV_0 READY STATE Status of the Ready State. READY/NOTRDY R V2.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Instance ID Object Name Description Active/Inactive Text PV Access Menu BV_18 FBDATAOUT1B5 Fieldbus Process Data Out 1 Bit 5 ON/OFF R BV_19 FBDATAOUT1B6 Fieldbus Process Data Out 1 Bit 6 ON/OFF R BV_20 FBDATAOUT1B7 Fieldbus Process Data Out 1 Bit 7 ON/OFF R BV_21 FBCNTRLBIT10 Fieldbus Control Word Bit 10 ON/OFF C BV_22 FBCNTRLBIT11 Fieldbus Control Word Bit 11 ON/OFF C BV_23 FBCNTRLBIT12 Fieldbus Control Word B
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) 3. Select: Main Menu > I/O and Hardware (M5) > RS-485 (M5.8) > BACnet MSTP (M5.8.3) > Parameters (M5.8.3.1) > Baud Rate (P5.8.3.1.1) > Edit. 4. Enter the desired baud rate and press the button. 5. Select: Main Menu > I/O and Hardware (M5) > RS-485 (M5.8) > BACnet MSTP (M5.8.3) > Parameters (M5.8.3.1) > MAC Address (P5.8.3.1.2) > Edit. 6. Enter the desired network device address and press the button. 7.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Logically, the P1 FLN is a master-slave protocol, with the supervisory controller being the master. Device points are partitioned into common HVAC control types, such as analog input, analog output, digital input, and digital output. P1 FLN messaging supports the reading, writing and overriding of these points. The P1 FLN fieldbus protocol supports the following point types: ● Logical Digital Input (LDI) – a two-state input for reading status.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) P1 FLN Point Map The following is the P1 FLN point map for Application 2770 as used in the Siemens APOGEE Network: Table 105: P1 FLN Point Map. Point Number Point Type Factory Default Subpoint Name Engr. Units Slope Intercept On Text Off Text Drive Menu 1 LAO CTRL ADDRESS 99 1 0 2 LAO APPLICATION 2770 1 0 3 LDI AT SETPOINT OFF 4 LAI CURRENT 0 A 0.1 0 M2.2.4 5 LAI DC BUS VOLT 0 V 0.1 0 M2.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Point Number Point Type Factory Default Subpoint Name Engr. Units Slope Intercept On Text Off Text Drive Menu 36 LDI DIGITAL IN 4 OFF ON OFF P5.1.4 37 LDI DIGITAL IN 5 OFF ON OFF P5.1.5 38 LDI DIGITAL IN 6 OFF ON OFF P5.1.6 39 LDO RELAY OUT 1 OFF ON OFF P5.1.13 40 LDO RELAY OUT 2 OFF ON OFF P5.1.14 41 LDO RELAY OUT 3 OFF ON OFF P5.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Point Number Point Type Factory Default Subpoint Name Engr. Units Slope Intercept On Text Off Text Drive Menu 73 LAO ANYVALUE 0 1 0 74 LAI ID VERSION 0 1 0 M4.8.6 75 LAI AP VERSION 0 1 0 M4.8.7 76 LAO ACCEL TIME 0 SEC 0.1 0.1 P3.4.2 77 LAO DECEL TIME 0 SEC 0.1 0.1 P3.4.3 78 LDI AUTORESET OFF 79 LAI CURRENT LMT 0 80 LDI ENERGY OPT OFF ON OFF P3.1.2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) To command the Start/Stop and Speed Reference through P1 FLN, complete the following steps: 1. Complete all settings required for Monitoring as listed above. 2. Set Control Place Auto (P1.15 or P3.2.1) to a value of FieldbusCTRL. To command Start/Stop through the P1 protocol, and Speed Reference through an Analog Input, complete the following steps: 1. Complete all settings required for Monitoring as listed above. 2. Set Ctrl. Place Auto (P3.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Structure Parameter P5.8.3.1.5 Comm. Timeout P5.8.3.1.6 Operate Mode Unit s Min Max Default ID Description 0 65535 10 2321 Defines the time the device has to receive a token before indication of an error.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Structure Parameter Unit Min Max Default ID Description M5.8.3.2.8 Slave Dev. Failure 2388 Displays if the server (slave) has detected a parity error in the memory when reading a record. M5.8.3.2.9 Last Fault Response 2389 Displays the last fault response as fault code as follows: 0 = None (No fault detected since last power-up) 1 = Connection Timeout (time defined in Comm. Timeout (M5.8.3.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 107: Parity Type. Parity Type Stopbits Even 1 Odd 1 None 2 Communication Time-out (P5.8.3.1.5) The Modbus board initiates a communication error for a time defined with this parameter. 0 means that no fault is generated. Modbus RTU Monitoring Values Fieldbus Protocol Status (P5.8.3.2.1) Field Protocol Status indicates the status of the protocol. Table 108: FB Protocol Statuses. INITIALIZING Protocol is starting up.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Slave device failure (P5.8.3.2.8) An unrecoverable error occurred while the server (or slave) was attempting to perform the requested action. Last fault response (P5.8.3.2.9) Displays the last fault response as Fault code. Control word (P5.8.3.2.10) Displays the Control Word received from the bus. Word status (P5.8.3.2.11) Displays the current Status Word that is sent to the bus.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Function Code Modbus Function Name Access Type TCP/RTU Address Range (hex) 6 (0X06) Write Single Register TCP&RTU 16bit 40000 - 4FFFF 15 (0X0F) Write Multiple Coils TCP only Discrete 00000 - 0FFFF 16 (0X10) Write Multiple Registers TCP&RTU 16bit 40000 - 4FFFF 23 (0X17) Read/Write Multiple Registers TCP&RTU 16bit 40000 - 4FFFF NOTE: Broadcasting is not supported in TCP.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 112: Defined Modbus Input and Holding Registers. Register number Purpose Access type See the Table...
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Address 16-bit* Name 32-bit Range/Type 2003 2053 = High data 2054 = Low data FB Speed Reference 0 through 100.00% unit 0.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Address 16-bit Name 32-bit Range/Type 2106 2159 = High data 2160 = Low data FB Process Data Out 3 User-definable. 2107 2161 = High data 2162 = Low data FB Process Data Out 4 User-definable. 2108 2163 = High data 2164 = Low data FB Process Data Out 5 User-definable. 2109 2165 = High data 2166 = Low data FB Process Data Out 6 User-definable. 2110 2167 = High data 2168 = Low data FB Process Data Out 7 User-definable.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) ID Map Using the ID map, you can read consecutive memory blocks that contain parameters whose IDs are not in a consecutive order. The address range 10501 through 10530 is called IDMap, and includes an address map in which you can write your parameter IDs in any order. The address range 10601 through 10630 is called IDMap Read/Write, and includes values for parameters written in the ID map.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Example of 32-Bit IDMap Table 121: Example of Parameter Values in 32-bit IDMap Read/Write Registers. Address Data 410701 Data High, parameter ID700 410702 Data Low, parameter ID700 410703 Data High, parameter ID702 410704 Data Low, parameter ID702 Operation Day Counter Table 122: Operation Day Counter.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 124: Energy Counter. Address Register Purpose 40201 440201 Energy 40202 440202 Format 40203 440203 Unit 1 = kWh 2 = MWh 3 = GWh 4 = TWh Resettable Energy Counter Reset the counter by writing 1 for Parameter ID2312. Table 125: Resettable Energy Counter.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Example messages Example 1 Write the process data 42001 through 42003 with command 16 (Preset Multiple Registers). Command Master - Slave: ADDRESS 01 hex Slave address 1 hex (= 1) FUNCTION 10 hex Function 10 hex (= 16) DATA Starting address HI 07 hex Starting address 07D0 hex (= 2000) Starting address LO D0 hex No. of registers HI 00 hex No.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Command Master - Slave: ADDRESS 01 hex Slave address 1 hex (= 1) FUNCTION 04 hex Function 4 hex (= 4) DATA Starting address HI 08 hex Starting address LO 36 hex No. of registers HI 00 hex Number of registers 0002 hex (= 2) No.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) No. of registers HI 00 hex Invalid number of registers 0005 hex (= 5) No.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) 9. Select: Main Menu > I/O and Hardware (M5) > RS-485 (M5.8) > ModBus RTU (M5.8.3) > Parameters (M5.8.3.1) > Stopbits (M5.8.3.1.4) > Edit. 10. Select desired stop bits. For commanding of Run/Stop using ModBus RTU complete the following steps (in addition to the Monitoring steps above): 1. Select: Main Menu > Quick Setup (M1) > Ctrl. Place Auto (M1.15) > Edit. 2. Select FieldBusCTRL.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Ethernet (M.5.9) Ethernet settings are used to define and configure the fieldbus protocol. The wiring is the same for all Ethernet protocol, as shown below. Figure 36: Etherenet Connection. Common Settings (M5.9.1) Table 127: Ethernet Common Settings (M5.9.1). Structure Parameter Min Max DHCP with AutoIP ID 2482 Description Defines the IP addressing mode as follows: 0 = Fixed IP 1 = DHCP with AutoIP IP Address Mode P5.9.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Table 128: Fixed IP (M5.9.1.2) Structure Parameter Min Max Unit Default ID Description P5.9.1.2.1 IP Address 192.168.0.10 2529 Defines the maximum number of clients (master) can access the server (slave) simultaneously. P5.9.1.2.2 Subnet Mask 255.255.0.0 2530 Defines the Modbus TCP unique device address. P5.9.1.2.3 Default Gateway 192.168.0.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Modbus TCP Parameters and Monitoring Values Modbus TCP Settings Table 129: Parameters Related to Modbus TCP. Code Parameter Min Max Unit Default ID Description PARAMETERS (Common Settings ) P5.9.2.1.1 Connection limit 0 3 2 2446 Number of allowed connections P5.9.2.1.2 Unit identifier number 0 255 1 2447 See the Modbus TCP Settings section. P5.9.2.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Code Parameter Min Max Unit Default ID Description P5.9.2.2.1.5 Illegal data values 0 2464 See Illegal data values (P5.9.2.2.1.5). P5.9.2.2.1.6 Slave device busy 0 2465 See Slave device busy (P5.9.2.2.1.6). P5.9.2.2.1.7 Memory parity error 0 2466 See Memory parity error (P5.9.2.2.1.7). P5.9.2.2.1.8 Slave device failure 0 2467 See Slave device failure (P5.9.2.2.1.8). P5.9.2.2.1.9 Last fault response P5.9.2.2.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Connection 1 Fieldbus protocol status (P5.9.2.2.1.1) The Fieldbus Protocol Status provides the status of the protocol. Table 130: FB Protocol Status. INITIALIZING Protocol is starting up. STOPPED Protocol is timed out or not used. OPERATIONAL Protocol is running. FAULTED Major fault in protocol, requires restarting. If fault remains contact your local Siemens Industry office or Technical Support. Communication status (P5.9.2.2.1.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Control word (P5.9.2.2.1.10) Displays the Control Word received from the bus. Status word (P5.9.2.2.1.11) Displays the current Status Word that is sent to the bus. Connection 2 The monitoring values display the same pieces of information as for Connection 1 [➙ 163], for the 2nd and 3rd connections. Connection 3 The monitoring values display the same pieces of information as for Connection 1 [➙ 163], for the 2nd and 3rd connections.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) 6. Enter the desired subnet mask. 7. Select: Main Menu > I/O and Hardware (M5) > Ethernet (M5.9) > Common settings (M5.9.1) >Default Gateway (M5.9.1.4) > Edit. 8. Enter the desired default gateway. For either DHCP or Fixed, the following steps must be completed: 1. Select: Main Menu > I/O and Hardware (M5) > Ethernet (M5.9) > ModBusTCP (M5.9.2) > Common Settings (M5.9.2.1) > Connection Limit (M5.9.2.1.1) > Edit. 2.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) BACnet IP Settings Table 132: Parameters Related with BACnet Used Through Ethernet. Code Parameter Min Max Unit Default ID Description 0 2406 Device object’s instance number 0 = Serial number 0 2407 0 = Not used NOTE: This setting is in minutes. 1 0 2408 0 = Not used 1 = Used 0.0.0.1 255.255.2 55.255 192.168.0.1 2409 Network BBMD IP address. BBMD Port 1 65535 47808 2410 BBMD UDP Port number.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Subnet mask (P5.9.1.4) The network mask marks all the bits of an IP address for the identification of the network and the subnetwork. Default gateway (P5.9.1.5) Gateway address is the IP address of a network point that acts as an entrance to another network. MAC address (P5.9.1.6) ● MAC address (Media Access Control) is a unique address given to each network host. ● The MAC address of the control board.
Chapter 4 - Parameters and Menu Structure I/O and Hardware (M5) Quick Setup For monitoring objects using BACnet IP, complete the following steps: NOTICE The DHCP settings must be set properly. Otherwise, a Fixed IP address may have to be set up. If using DHCP, complete the following steps: 1. Select: Main Menu > I/O and Hardware (M5) > Ethernet (M5.9) > Common settings (M5.9.1) >IP Address Mode (M5.9.1.1). 2. Verify this is set to DHCP with AutoIP. 3.
Chapter 4 - Parameters and Menu Structure User Settings (M6) 3. Select: Main Menu > I/O and Hardware (M5) > Ethernet (M5.9) > BACnet IP (M5.9.3) > Settings (M5.9.3.1) > Protocol in use (M5.9.3.1.3) > Edit. 4. Set to a value of 1. 5. Select: Main Menu > I/O and Hardware (M5) > RS-485 (M5.9) > BACnetMSTP (M5.9.3) > Parameters (M5.9.3.1) > Instance Number (M5.9.3.1.4) > Edit. 6. Enter the desired device instance number between 0 and 4194303.
Chapter 4 - Parameters and Menu Structure Favorites (M7) Table 135: Parameter Backup. Structure Parameter ID Description P6.5.1 Restore Factory Default 831 Activation parameter for restoring parameters to the factory settings. NOTE: Does not reset: Time (P5.5.2), Date (P5.5.3), Year (P5.5.4), Daylight Saving (P5.5.5) P6.5.2 Save to Keypad 2487 Initiates a copy of the active set of parameters to the keypad's storage location. P6.5.
Chapter 4 - Parameters and Menu Structure User Levels (M8) 1. Set Access Code (P8.2) to a value other than 0. NOTE: Store this access code in a safe place. If the code is lost, the only method to recover is to reload firmware and re-commission the drive. 2. Set User Level (P8.1) to a value of Monitoring. When in the monitoring user level, only the Monitor (M2), Favorites (M7), and User Levels (M8) menu options are available through the keypad.
Chapter 5 - Fault Tracing Fault Displays Chapter 5 - Fault Tracing When the drive control diagnostics detect an unusual operating condition, the drive initiates a visible notification on the keypad. The keypad displays the code, the name and a short description of the fault or alarm. Notifications vary in consequence and required action. Faults make the drive stop and require a reset of the drive. Alarms inform of unusual operating conditions, but the drive will continue to run.
Chapter 5 - Fault Tracing Fault Codes Fault Codes Table 138: Fault Codes and Descriptions. Fault Code Fault ID 1 1 2 2 10 11 3 5 7 Fault Name Possible Cause Remedy Over-current (hardware fault) The drive has detected too high a current (>4*IH) in the motor cable: Check loading. Over-current (software fault) ● sudden heavy load increase Check cables and connections. ● short circuit in motor cables Make identification run. ● unsuitable motor Check ramp times. Check motor.
Chapter 5 - Fault Tracing Fault Codes Fault Code Fault ID 8 600 9 Fault Name System fault Possible Cause Communication between control board and power unit has failed. Remedy Reset the fault and restart. Should the fault re-occur, contact your distributor. 602 Watchdog has reset the CPU. 603 Voltage of auxiliary power in power unit is too low. 604 Phase fault: Voltage of an output phase does not follow the reference. 605 CPLD has faulted but there is no detailed information about the fault.
Chapter 5 - Fault Tracing Fault Codes Fault Code Fault ID 14 130 AC drive overtemperature (fault, heatsink) 131 AC drive overtemperature (alarm, heatsink) Fault Name Possible Cause Too high temperature measured in power unit’s heatsink or board. Remedy Check the correct amount and flow of cooling air. Heatsink temperature is over 100°C (212°F). Check the heatsink for dust. Check the ambient temperature.
Chapter 5 - Fault Tracing Fault Codes Fault Code Fault ID 32 312 33 Fault Name Possible Cause Fan cooling Fan life time is up. Fire mode enabled Fire mode of the drive is enabled. The drive's protections are not in use. Remedy Change fan and reset fan life time counter. 37 360 Device changed (same type) Option board changed for one previously Device is ready for use. Old inserted in the same slot. The board’s parameter parameter settings will be used. settings are saved.
Chapter 5 - Fault Tracing Fault Codes 66 1066 Thermistor fault The thermistor input has detected an increase of Check motor cooling and load. motor temperature. Check thermistor connection (If thermistor input is not in use it must be short circuited) 69 80 1310 Fieldbus mapping error Non-existing ID number is used for mapping values to Fieldbus Process Data Out. Check parameters in Fieldbus Data Mapping menu. 1311 Not possible to convert one or more values for Fieldbus Process Data Out.
Chapter 6 - Technical Information Product Numbers Chapter 6 - Technical Information This chapter provides general technical information for the BT300 Variable Frequency Drive. Product Numbers Figure 37: 178 | 187 Siemens Industry, Inc.
Chapter 6 - Technical Information Power Ratings Power Ratings The following chart shows the BT300 HVAC Drive power ratings in accordance with frame sizes: Interpreting Serial Numbers and Date Codes Each BT300 HVAC Drive has a manufacturing/serial number. The date code is part of the serial number. The following example shows how to interpret the date code and serial number: Siemens Industry, Inc.
Chapter 6 - Technical Information Technical Data Technical Data Table 139: Drive Specifications. Specification Description Input Voltages and Power Ranges (3-phase) 208 to 240 Vac (-10% to +10%): 1 hp to 125 hp (0.75 kW to 90 kW) 380 to 500 Vac (-10% to +10%): 1.5 hp to 250 hp (1.1 kW to 160 kW) 525 to 600 Vac (-10% to+10%): 3 hp to 200 hp (2.
Chapter 6 - Technical Information Technical Data Specification Description Seismic 2012 International Building Code (IBC), OSHPD Shock EN61800-5-1 EN60068-2-27 Enclosure Class UL Type 1/IP 21 standard in entire HP/kW range. UL Type 12/IP 54 options EMC Immunity Fulfills IEC 61800-3 (2004), first and second environment EMC Emissions EN61800-3 (2004) Category C2 Can be field modified for IT networks for C3 or C4 ratings.
Chapter 6 - Technical Information Control Board Technical Specifications Specification Description Embedded Protocols RS-485: APOGEE P1, BACnet MS/TP, Modbus RTU, Metasys N2 Ethernet: BACnet IP, Modbus TCP Over voltage trip limit 208 to 240 Vac: 456 Vdc 380 to 500 Vac: 911 Vdc 525 to 600 Vac: 1094 Vdc Under voltage trip limit Depends on supply voltage (0.8775* supply voltage): 208 Vac: 182.5 Vdc 240 Vac: 210.6 Vdc 380 Vac: 333.5 Vdc 480 Vac: 421.2 Vdc 575 Vac: 504.
Chapter 6 - Technical Information Fieldbus Technical Data Terminal Signal/Description Specification 17 Common for DI 1 - DI 6 18 Analog Output 1 Signal (+) 19 Analog Output 1 Common (-) 30 24 Vdc Input Voltage ±10%; Maximum 250 mA; Used for power backup of control unit. A RS-485 - Fieldbus Negative B RS-485 + Fieldbus Positive 0 through 10 Vdc or 0 through 20 mA (selection with DIP switch) Resolution: 0.
Chapter 6 - Technical Information Accessories and Replacement Parts Accessories and Replacement Parts Table 141: BT300 HVAC Drive Accessories and Replacement Parts (Frame Size-Specific).
Chapter 6 - Technical Information Accessories and Replacement Parts Part Number Description BT300-OPT-B1-V Option board with six bi-directional terminals (digital input or digital output) BT300-OPT-B2-V Option board with one thermistor input and two relay outputs BT300-OPT-B4-V Option board with one analog input and two analog outputs BT300-OPT-B5-V Option board with three relay outputs BT300-OPT-B9-V Option board with five digital inputs and one relay output BT300-OPT-BF-V Option board with o
Issued by Siemens Industry, Inc. Smart Infrastructure 1000 Deerfield Pkwy Buffalo Grove IL 60089 +1 847-215-1000 Document ID: DPD01809 Edition: 2019-05-29 © Siemens Industry, Inc., 2019 Technical specifications and availability subject to change without notice.
