DTU3005-B Intelligent Data Transfer Device for Connection to PLCs and Modbus Networks Operator’s Manual
DANGER Hazardous voltages and high-speed moving parts in electrical devices communicating with WinPM. Can cause death, serious injury or property damage. See safety instruction contained herein. Restrict use to qualified personnel. The use of unauthorized parts in the repair of the equipment or tampering by unqualified personnel will result in dangerous conditions that can cause death, serious injury or property damage.
Table of Contents 1 Introduction ....................................... 1 1.1 1.2 1.3 1.4 Product Overview ................................. 1 Software Overview ............................... 1 Features................................................. 1 Applications .......................................... 1 1.4.1 PLC to SEAbus ......................... 2 1.4.2 Modbus Master to SEAbus..... 3 1.4.3 SEAbus Port Expander ............ 5 2 Installing the Software .....................
Table of Contents E.2 E.3 E.4 E.5 E.6 E.7 E.8 E.9 E.10 E.11 E.12 E.13 E.14 E.15 E.16 E.17 E.18 E.19 E.20 E.21 Device Type: 4300 Power Meter ..........79 Device Type: 4700 Power Meter...........80 Device Type: 4720 Power Meter...........82 Device Type: Static Trip III ....................84 Device Type: SensiTrip III ......................86 Device Type: SB-TL ..............................87 Device Type: Pulse Reading Meter (PRM) 88 Device Type: ISGS ................................
1 Introduction 1 Introduction 1.1 Product Overview The Panel-Tec DTU3005 is an intelligent, multiplefunction data transfer unit that enables communications between Siemens communicating power meters, trip units, and protective relays, and PLCs or Modbus networks. The device is designed for the harsh industrial environment and is suited for use in switchgear. The device is shown below in Figure 1.1. The device is powered from an external power supply.
1 Introduction 1.4.1 PLC to SEAbus The basic configuration is a PLC attached to port 1 of the DTU3005, and the Siemens ACCESS devices attached to port 2. This is shown below in Figure 1.2. Port 3 can be configured as a passthrough to the SEAbus devices. This allows a personal computer running Siemens WinPM™ or other supervisory software to connect directly to the SEAbus devices at the same time as the PLC. This is shown in Figure 1.3. An additional DTU3005 device can be attached to port 3.
1 Introduction 1.4.2 Modbus Master to SEAbus The DTU3005 unit can be configured as a Modbus (RTU) slave. In this configuration, a Modbus master device (usually a SCADA system) is connected to port 1. The Modbus master uses the DTU3005 to monitor and/or control Siemens ACCESS devices. A typical Modbus application is shown below in Figure 1.5. The passthrough port (port 3) can be used to connect to a supervisory computer running WinPM software.
1 Introduction Multi-Drop Modbus Master to SEAbus By using a Siemens Isolated Multi-Drop Converter, you can connect your Modbus Master device to four DTU3005 devices. Each DTU3005 can connect to up to 32 Siemens ACCESS devices, as well as be daisy chained to up to 32 additional DTU3005 devices. An example configuration is shown below in Figure 1.8. Figure 1.8 Multi-Drop Configuration Figure 1.7 Connection to Modbus Master using a Multidrop Cable 4 Siemens Energy & Automation, Inc.
1 Introduction 1.4.3 SEAbus Port Expander The DTU3005 can be used as a SEAbus port expander for ACCESS devices, allowing two personal computers running WinPM (or other supervisory software) to communicate with up to 32 ACCESS devices. This configuration is shown below in Figure 1.9. Figure 1.9 SEAbus Port Expander Siemens Energy & Automation, Inc.
2 Installing the Software 2 Installing the Software The DTU3005 Editor software can be installed from the DOS prompt onto a PC running Microsoft® Windows version 3.1, 95, or 98. The PC processor must be less than 300 MHz (or have a utility program installed to slow down the processor speed) for the Editor software to work properly. Note: The DTU3005 Editor software does not work in a Windows NT environment. insert the installation diskette into your computer and follow the steps listed below.
2 Installing the Software returns you to the DOS prompt as shown in the example screen below. 7. 7 If you are running Windows, type exit to close the DOS window. Siemens Energy & Automation, Inc.
3 Starting the Software 3 Starting the Software To start the DTU3005 Editor software, follow these steps: 1. 2. 3.1 If you are running Windows 3.1, double click the MS-DOS Prompt icon in the Main window of Program Manager. For Windows 95/98, select MSDOS Prompt from the Start menu. At the DOS prompt, which is usually C:\> (or C:\WINDOWS> if you are running a DOS prompt from Windows) type CD \DTU3005B, where 3.
3 Starting the Software 3.2 Main Menu The main menu is located on the top line of the screen. In addition to the menu selections, the name of the current project and the time of day is displayed on the top line. There are five main menu selections. They are • ≡, or the Program Information menu. Selecting it displays the program information screen. • The Project menu enables you to create, load, save, view and print project files. It also allows you to switch to a DOS prompt or quit the program.
3 Starting the Software 3. Type in a name for the project up to eight letters and numbers in the Project Name: field and press Enter. The Project Type: field will then be highlighted. Press the spacebar to display the project types, which are: • 10 PLCs to Devices—allows a PLC to control and/or monitor up to 32 supported Siemens devices. See Chapter 4 for configuring this project type.
3 Starting the Software 4. 5. To select a project type, highlight the type and either press Enter or click the left mouse button. Then highlight the Ok button on the dialog box and either press Enter or click the left mouse button. When the screen refreshes, the Project menu is displayed with additional menu options now available. These options apply to the open project file that is active (i.e., the project name appears in the top line of the screen). • • 6. Close—allows you to close a project file.
4 Creating Project Files—PLC to Devices 4 Creating Project Files—PLC to Devices This chapter covers configuration of the DTU3005 for PLC communications with Siemens devices. Once you have created a PLC to Devices project (see Chapter 3), follow the directions in this chapter to configure the project file. Then see Chapter 7 for directions on downloading the project to the DTU3005. See also Appendix D for wiring diagrams for your particular PLC, as required. 4.
4 Creating Project Files—PLC to Devices • Device Command Registers—allows you to indicate which PLC registers will be used for device commands. • Device Defaults—allows you to set the default data registers for more than one device of a certain type, e.g., set the defaults for all 4720 power meters or all S7-I/O units. The data registers can still be customized for each device, as required. See Section 4.7.2 for more information.
4 Creating Project Files—PLC to Devices To select the PLC connected to port 1, highlight PLC Protocol and press Enter. The PLC Protocols selection menu appears: PLC Protocol Use the Down Arrow and Up Arrow keys to scroll through the list of available PLC Protocols, since not all choices are visible at one time. To select a protocol, highlight the selection and press Enter. PLC Number After you have selected your PLC, the PLC Number selection box is highlighted.
4 Creating Project Files—PLC to Devices program displays an entry box for the RTS delay time. Enter the time in milliseconds. passes with no response being received, the DTU will assume that no response is coming and will retry the request. Enter the time in milliseconds. Saving Port 1 Configuration Information Once you have entered all the configuration information, select Save to save the configuration to the project file. Then select Ok or press the Esc key to close the configuration screen.
4 Creating Project Files—PLC to Devices Saving Port 2 Configuration Information Once you have entered all the configuration information, select Save to save the configuration to the project file. Then select Ok or press the Esc key to close the configuration screen. If you have changed the configuration and have not saved it to the project file, you will be prompted to either save or discard the changes. Select Revert to return to the last previously saved configuration without saving any changes. 4.
4 Creating Project Files—PLC to Devices 4.6 Device List Setup The Device List menu item enables you to indicate which registers on the PLC will receive data from the devices. In this screen, you will enter the device type and address for each Siemens device connected to port 2. You will also indi- cate to which registers on the PLC you want the DTU3005 to write device data.
4 Creating Project Files—PLC to Devices 3. 4. 18 Select the device from the list by pressing Enter or the spacebar. The highlight moves to the Address field, and the PLC register fields now display as shown in the example screen below. With the Address field highlighted, enter the device’s address. This number should be between 1 and 254, and match the number programmed into the device itself. Press the Tab key twice to go to the Real-Time Data Registers field. 5.
4 Creating Project Files—PLC to Devices 6. 7. 8. 9. Enter the beginning register number in the Real-Time Data Registers field. Refer to Appendix A for valid register numbers for your PLC application. The DTU3005 Editor software supplies the last register number after you enter the first. In the example above, the 4700 Power Meter uses 41 registers for its data. When you enter 1 for the first register, the last register becomes 42.
4 Creating Project Files—PLC to Devices 4. 20 Select a data register on the list and press Enter to see a list of available real time data. These data items are identical to the standard data items listed in Appendix E. Not all data items are visible on the screen at one time. Use the mouse and the scroll bar, or the Page Up and Page Down keys to view all of the data items. Siemens Energy & Automation, Inc.
4 Creating Project Files—PLC to Devices 5. Select the data word (16 bit data) from the list and press Enter. Continue to set the other data words in the same manner. Many data items consist of two words (32 bit data). It is important that you configure both words in order to transmit useful information to the DTU3005’s registers. To conserve registers when using VDEW devices, you should set all unused registers to “Not Used” and place them at the end of the list.
4 Creating Project Files—PLC to Devices 3. Select a data item and press Enter to see a list of device real time data that can be assigned to that data word. Select Not Used if you do not want that data word to be used. Not all of the entries are visible on the menu. Use the scroll bar or the Page Up and Page Down keys to view all the entries. Select Clear All to set all data words to “Not Used.
4 Creating Project Files—PLC to Devices To conserve registers when using VDEW devices, you should set all unused registers to “Not Used” and place them at the end of the list. The DTU3005 will then only allocate registers for those containing device data. (This does not apply to SEAbus devices, for which the DTU3005 allocates 16 registers regardless if they are used or not.) 4.8 Device Text Setup (7SJ600 Only) The Device Text to Values Table menu item is only available for configuring the 7SJ600 relay.
4 Creating Project Files—PLC to Devices The relevant status codes (Text #) are listed below. Table 4.
4 Creating Project Files—PLC to Devices Table 4.1 7SJ600 Relay Information (Continued) 1372 L2,3,4 On : L1 Off 1373 L1 On : L2,3,4 Off 1374 L1,4 On : L2,3 Off 1375 L1,3 On : L2,4 Off 1376 L1,3,4 On : L2 Off 1377 L1,2 On : L3,4 Off 1378 L1,2,4 On : L3 Off 1379 L1,2,3 On : L4 Off 1380 L1,2,3,4 On Once you are finished entering data, select Save to save your configuration, then select Ok to exit the dialog box. Select Revert to bring back the previous settings. 4.
4 Creating Project Files—PLC to Devices parameter is used only with Allen-Bradley PLCs. It specifies the file number in the PLC that contains the register values that are transferred to or from the device. 4. Select Save to save the information to the project file, and then select Ok or press Esc to exit the device diagnostic registers screen. If at any time you want to return to the last saved version of the device diagnostics registers, select Revert without saving any changes. 4.
4 Creating Project Files—PLC to Devices 4. Enter the value for the Command Block Read Delay. This is the delay between times that the DTU3005 reads the data from the PLC’s command registers. This controls the frequency that the registers are read to allow for critical PLC scan times. 5. Select Save to save the device information to the project file, and then select Ok or press Esc to exit the device command registers screen.
5 Creating Project Files—Modbus Master to Devices 5 Creating Project Files—Modbus Master to Devices This chapter covers configuration of the DTU3005 for Modbus master device communications with Siemens devices. Once you have created a Modbus Master to Devices project (see Chapter 3), follow the directions in this chapter to configure the project file. Then see Chapter 7 for directions on downloading the project to the DTU3005. 5.
5 Creating Project Files—Modbus Master to Devices 5.2 Configuring the Project File Once you have created or opened the project file, select Edit from the main menu. When the Device Protocol for port 2 is set to SEAbus (see Section 5.4), the following menu items appear: • Port 1 (Modbus Master)—allows you to select the protocol (RTU or ASCII) and configure the communications settings for the Modbus Master device connected to port 1.
5 Creating Project Files—Modbus Master to Devices 5.3 Modbus Setup—Port 1 You must have a Modbus Master to Devices project file open to configure port 1 using the instructions in this section. Select Port 1 (Modbus Master) from the To select the protocol for the Modbus Master device connected to port 1, highlight Modbus Protocol and 30 Edit menu, and the Port 1 Modbus Master configuration screen appears. press Enter. The Modbus Master Protocol selection menu appears: Siemens Energy & Automation, Inc.
5 Creating Project Files—Modbus Master to Devices Select either ASCII or RTU as your Modbus protocol, then press the Tab key to highlight the Modbus ID selection box. The Modbus ID is used to identify the address of the DTU. Type in the Modbus ID number and press Enter. 2-Wire RS422 or RS485 Communications After you have entered the Modbus ID number, highlight the 2-Wire RS422 or RS485 Communications selection box.
5 Creating Project Files—Modbus Master to Devices 5.4 Device Setup—Port 2 One or more Siemens devices may be connected to port 2. You must have a Modbus Master to Devices project file open to configure port 2 using the instructions in this section. Select Port 2 (Devices) from the Edit menu, and the Port 2 configuration screen appears. Device Protocol Saving Port 2 Configuration Information The Device Protocol indicates which Siemens devices can be connected to port 2.
5 Creating Project Files—Modbus Master to Devices 5.5 Modbus/Passthrough Setup—Port 3 any messages received on port 3 of the DTU are simply “passed through” to the devices. Port 3 can be used for passthrough communications to your Siemens SEAbus devices or for connection to a second Modbus Master device. Passthrough communications enables a PC running WinPM, or other supervisory software connected to port 3 of the DTU3005 to communicate directly with the SEAbus devices connected to port 2.
5 Creating Project Files—Modbus Master to Devices Passthrough to Port 2 (SEAbus) If you select Passthrough to Port 2 (SEAbus), the screen appears as shown below. 2-Wire RS422 or RS485 Communications After you have selected Passthrough to Port 2 (SEAbus), press Tab or select 2-Wire RS422 or RS485 Communications. This box will only need to be checked if the communications with your SEAbus devices use a 2-wire RS485 or RS422 interface. This is the usual method of connecting SEAbus devices.
5 Creating Project Files—Modbus Master to Devices 5.6 Device List Setup The device list menu which registers on the devices. In this menu, and address for each item enables you to indicate PLC will receive data from the you will enter the device type Siemens device connected to This screen is divided into two parts: • On the left side of the screen is a list of the devices connected to port 2 (the list is initially empty).
5 Creating Project Files—Modbus Master to Devices 3. Select the device from the list by pressing Enter or the spacebar. The highlight moves to the Address field, and the PLC register fields now display as shown in the example screen below. 5. Enter the beginning register number in the RealTime Data Registers field. Refer to Appendix A for valid register numbers for your PLC application. The DTU3005 Editor software supplies the last 36 4. With the Address field highlighted, enter the device’s address.
5 Creating Project Files—Modbus Master to Devices change the starting register to 10, the last register will automatically change to 51. Note: The Modbus Master must read these register numbers to be able to access the realtime data for this device. 6. 7. Press Shift+Tab, or click the left mouse button to highlight the File field and enter the file number.
5 Creating Project Files—Modbus Master to Devices 4. 38 Select a data register on the list and press Enter to see a list of available real time data. The data items are identical to the standard data items listed in Appendix E. Not all data items are visible on the screen at one time. Use the mouse and the scroll bar, or the Page Up and Page Down keys to view all of the data items. Siemens Energy & Automation, Inc.
5 Creating Project Files—Modbus Master to Devices 5. Select the data word (16 bit data) from the list and press Enter. Continue to set the other data words in the same manner. Many data items consist of two words (32 bit data). It is important that you configure both words in order to transmit useful information to the DTU3005’s registers. 6.
5 Creating Project Files—Modbus Master to Devices 3. Select a data item and press Enter to see a list of device data items that can be assigned to that data word. Select Not Used if you do not want that data word to be used. Not all of the entries are visible on the menu. Use the scroll bar or the Page Up and Page Down keys to view all the entries. Select Clear All to set all data words to “Not Used.
5 Creating Project Files—Modbus Master to Devices To conserve registers when using VDEW devices, you should set all unused registers to “Not Used” and place them at the end of the list. The DTU3005 will only allocate registers for those containing device data. (This does not apply to SEAbus devices, for which the DTU3005 allocates 16 registers regardless if they are used or not.) 5.
5 Creating Project Files—Modbus Master to Devices The relevant status codes (Text #) are listed below. Table 5.
5 Creating Project Files—Modbus Master to Devices Table 5.1 7SJ600 Relay Information (Continued) 1372 L2,3,4 On : L1 Off 1373 L1 On : L2,3,4 Off 1374 L1,4 On : L2,3 Off 1375 L1,3 On : L2,4 Off 1376 L1,3,4 On : L2 Off 1377 L1,2 On : L3,4 Off 1378 L1,2,4 On : L3 Off 1379 L1,2,3 On : L4 Off 1380 L1,2,3,4 On Once you are finished entering data, select Save to save your configuration, then select Ok to exit the dialog box. Select Revert to bring back the previous settings. 5.
5 Creating Project Files—Modbus Master to Devices register 40001, etc. Be sure that the registers you specified are not being used by other devices. 3. Select Save to save the information to the project file, and then select Ok or press Esc to exit the device diagnostic registers screen. If at any time you want to return to the last saved version of the device diagnostics registers, select Revert without saving any changes. 5.
6 Creating Project Files—SEAbus Port Expander 6 Creating Project Files—SEAbus Port Expander This chapter covers configuration of the DTU3005 as a SEAbus port expander. Once you have created a SEAbus port expander project (see Chapter 3), follow the directions in this chapter to configure the project file. Then see Chapter 7 for directions on downloading the project to the DTU3005.
6 Creating Project Files—SEAbus Port Expander 6.1 Passthrough Setup—Port 1 You must have a SEAbus Port Expander project file open to configure port 1 using the instructions in this section. Select Port 1 (Passthrough) from the Edit 2-Wire RS422 or RS485 Communications The 2-Wire RS422 or RS485 Communications selection box will only need to be checked if the communi- 46 menu, and the Port 1 (Passthrough) configuration screen appears.
6 Creating Project Files—SEAbus Port Expander When 2-wire communications are being used, RTS must be looped back to CTS on the DTU side of the cable. This can be done on the RS232 side by looping pins 4 and 5 or on the RS422/485 side by looping 16 to 18 and 17 to 19. See Appendix D for wiring diagrams for your particular PLC, and whether it uses a 2-wire connection. To select the checkbox, click on it with the mouse or, with the 2-Wire RS422 or RS485 Communications selection highlighted, press the spacebar.
6 Creating Project Files—SEAbus Port Expander 6.2 SEAbus Device Setup—Port 2 One or more Siemens devices may be connected to port 2. You must have a SEAbus Port Expander project file open to configure port 2 using the instructions in this section. Select Port 2 (SEAbus Devices) from the Edit menu, and the Port 2 configuration screen appears. Configuration Information 6.3 The configuration selections with the exception of Response Time-Out are the same as those for port 1. Refer to Section 6.
7 Transferring Project Files 7 Transferring Project Files Once you have configured and saved your project file for your particular application, you need to download it to the DTU3005 unit. First verify which COM port on your computer is used to upload and download projects to the DTU3005 unit (see Chapter 8).
7 Transferring Project Files DTU3005B Port 3 2 3 7 DB-25 Male 1 TXD RXD Ground 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 Port 3 Personal Computer RS-232 Port 1 2 3 4 5 6 7 8 DB-9 Female DCD RXD TXD DTR Ground DSR CTS RTS 5 4 9 3 8 2 7 1 6 Cable Type: 4 Conductor Round . Figure 7.1 Null Modem Cable connection The null modem cable will cross pins 2 and 3 (RXD and TXD). On the computer end of the cable, pins 7 and 8 (RTS and CTS) should be connected together.
7 Transferring Project Files 7.2 Uploading Projects Select Upload project from DTU3005 from the Transfer menu, and the confirmation screen shown above appears. Select Ok and the DTU3005 Editor software transfers the project from the DTU3005 unit to your computer. The computer will upload the project file under the name “NONAME.” You must save this uploaded project file using the Save As command from the Project menu and enter your own file name. 7.3 7.
8 Setting Options 8 Setting Options The Options menu allows you to configure settings for the DTU3005 Editor software and to load and save these settings. Options include the directory to which the program stores its project files, which COM port and printer port the program uses, and printer settings. Until you save the Options to the PC hard drive (i.e., disk), any changes you make using the Options menu are only effective while you are running the Editor software.
8 Setting Options 2. The current directory path is shown in the Directory Name field, and a graphical representation of the directory path is shown in the Directory Tree field. You may type in a new directory in the Directory Name field, or select an existing directory from the Directory Tree list. b. Select Yes to create the new directory, or select No if the new directory name is not what you wanted. Siemens Energy & Automation, Inc. a. 3.
8 Setting Options move up and down the directory tree. Press Enter, or select Ch Dir to see a list of all the subdirectories within the highlighted directory. To see a list of all the available drives, including diskettes and network drives, highlight Drives and press the Enter key. 4. 5. When you select a directory, its full path name appears in the Directory Name field.
8 Setting Options 2. To select the printer port, or to direct the printouts to a file, use the Left and Right Arrow keys to move the highlight between File, LPT1, and LPT2. With the desired selection port highlighted, press the spacebar to select it. The dot at the cursor indicates which choice is selected. a. b. 3. 8.4 If you have selected File, use the Tab key to move the highlight to the File Name field. Enter a name for the file of up to eight letters and numbers.
8 Setting Options 2. If you have not previously saved your option settings, the following screen appears: 3. Select Ok to continue. 4. To save your options settings to the hard drive, select Save Options to Disk form the Options menu. The following screen appears, indicating that the options were successfully saved. 56 Siemens Energy & Automation, Inc.
8 Setting Options 5. Select Ok to continue. The options settings will remain in effect the next time you run the DTU3005 Editor software. If you wish to return to the default options that were in effect when you ran the program for the first time, select Default Options from the Options menu. The following screen appears, indicating that the original settings were restored: Select Ok to continue.
Appendix A: Supported PLCs A Supported PLCs configuration screen in the DTU3005 Editor software must be “AB SLC500 (CRC)”. Table A.1 Supported PLCs and Protocols App. No. Manufacturer Model Protocol A.1 Allen-Bradley PLC-5 4 SLC 503, SLC 50 Micrologix DF1 Full-Duplex A.2 GE Fanuc 90/20, 90/30 and 90/70 PLCs Registers Accessed The DTU3005 will only access registers in the Data Register Area of PLC memory (%R1 to %R9999).
Appendix A: Supported PLCs Table A.2 Koyo/PLC Direct 205 Registers (Continued) V-Memory Address Table A.
Appendix A: Supported PLCs configured to do so by performing the following steps when configuring the PLC Port in the DTU3005 Editor Program: 1. Select “RTS Delay” in the RTS Control selection box. 2. Set the RTS Delay time to 2 ms. A.9 Modbus PLCs and Devices Registers Accessed The DTU3005 will only access registers in the Holding Area of PLC memory (40001 to 49999). When entering register numbers, only the offset into this area (1-9999) should be entered.
Appendix A: Supported PLCs p1 T0 0 (for PC COM Port 1) or p2 T0 0 (for PC COM Port 2) For example, if you are using a 545 PLC and you are using COM2 on your PC, you would invoke TISOFT as follows: TI545 p2 T0 0 These parameters will prevent the programming software from switching over to the Transparent Byte Protocol, which is not supported by the DTU3005. A.15 Toshiba EX and M Series PLCs Registers Accessed The DTU3005 will only access registers in the Data Register of PLC memory (D0 to D9999).
Appendix B: Supported Devices B Supported Devices B.1 The following Siemens ACCESS devices are supported by the DTU3005B. Table B.1 Supported Siemens Devices Application Notes— Communication Port Settings for 7-Series Protective Relays The following are the required settings in the relays for communications. Device 4720 Power Meter All relays (except 7SJ600) 4700 Power Meter Table B.
Appendix C: Installing the Hardware C Installing the Hardware The DTU3005 device is a compact, low-power, sealed device designed for use in an industrial environment. It can be mounted on any flat surface inside equipment cabinets requiring only nominal ventilation for convection cooling. Four inches clearance in front of the unit is required for attachment of communication cables. A modular connector is supplied for unit power. C.1 Dimensions 5.22" (133 mm) 1.00" (25.4 mm) 3.22" (82 mm) 0.50" (12.
Appendix C: Installing the Hardware C.3 Connector Pinouts All of the DTU3005B ports, 1 through 3, support both RS-232 and RS-422/485 signals. Connection should be made to one set of signals at a time. Table C.1 contains the cable pinouts for the RS-422/485 connector. Table C.2 contains the cable pinouts for the RS-232 connector. Refer to Appendix D for cable connection diagrams for specific PLC devices. Table C.
Appendix D: Cable Connection Diagrams D Cable Connection Diagrams Allen Bradley PLC5 DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 Allen Bradley PLC5 Channel 0 2 3 4 5 7 TXD RXD RTS CTS Ground 12 24 13 25 DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 Cable Type: 3 or 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Allen Bradley SLC5/03 & 04 DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male
Appendix D: Cable Connection Diagrams Allen Bradley Micrologix DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 Allen Bradley MicroLogix 2 4 7 7 18 19 6 Ground RXD TXD 3 8 20 7 9 21 10 22 12 24 13 25 Mini DIN 8 4 11 23 5 1 2 Cable Type: 4 Conductor Round 2-Wire RS422 or RS485 Communications: No GE Fanuc 90/20, 30, 70 DTU 3005B 21 22 23 24 TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 GE Fanuc 90/20, 30, 70 10
Appendix D: Cable Connection Diagrams Idec FA with Link Adapter DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 11 10 22 21 20 19 18 17 16 15 14 9 8 7 6 5 4 3 2 1 24 23 Idec FA with Link Adapter 2 3 7 TXD RXD Ground 12 13 25 DB-25 Male 11 10 22 21 20 19 18 17 16 15 14 9 8 7 6 5 4 3 2 1 12 24 23 13 25 Cable Type: 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Idec Micro-3 DTU 3005B 4 5 21 22 23 24 RTS CTS TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16
Appendix D: Cable Connection Diagrams Koyo 205 (PLC Direct) DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 RJ11 Koyo 205 1 3 4 6 Ground RXD TXD 5 4 3 2 1 Cable Type: Round Phone Cable 2-Wire RS422 or RS485 Communications: No Koyo 305 (PLC Direct) DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 11 23 12 24 13 25 RJ04 Koyo 305 1 2 4 10 22 RXD TXD Ground 4 3 2 1 Cabl
Appendix D: Cable Connection Diagrams Koyo 405 (PLC Direct) DTU 3005B 2 3 7 DB-25 Male TXD RXD Ground 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 DB-15 Male Koyo 405 2 3 4 13 14 15 1 TXD RXD Ground 2 9 3 10 4 11 5 12 6 13 7 14 8 15 Cable Type: 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Mitsubishi FX DTU 3005B 18 19 21 22 23 24 RTSRTS+ TXRXTX+ RX+ DB-25 Male 11 10 22 21 20 19 18 17 16 15 14 9 8 7 6 5 4 3 2 1 24 23 Mit
Appendix D: Cable Connection Diagrams Mitsubishi FXo/FXon DTU 3005B 21 22 23 24 TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 Mini DIN Mitsubishi FXo/FXon 1 2 4 7 6 6 3 RXRX+ TXTX+ 7 8 4 5 1 2 Cable Type: 3 or 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Modicon 984/Compact 984 DTU 3005B 2 3 7 TXD RXD Ground Modicon 984/Compact 984 2 3 5 RXD TXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22
Appendix D: Cable Connection Diagrams Modicon Micro 984 DTU 3005B 1 2 3 4 7 CGND TXD RXD RTS Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 22 Modicon Micro 984 2 3 4 5 8 10 11 23 12 24 13 25 RJ45 CTS TXD RXD Ground CGND 8 7 6 5 4 3 2 1 Cable Type: Flat Phone Cable 2-Wire RS422 or RS485 Communications: No Omron 232 Host Link DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 11 10 22 21 20 19 18 17 16 15 14 9 8 7 6 5 4 3 2 1 24 23 Omron 232 Host Link 2
Appendix D: Cable Connection Diagrams Omron C28H DTU 3005B 2 3 7 TXD RXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 Omron C28H 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 DB-9 Male 2 3 7 1 RXD TXD Ground 2 6 3 7 4 8 5 9 Cable Type: 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Omron CQM1 DTU 3005B Omron CQM1 2 3 7 TXD RXD Ground 2 3 9 RXD TXD Ground DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 DB-9 Male 1 2 6 3 7 4 8
Appendix D: Cable Connection Diagrams Siemens S7 DTU 3005B 4 5 7 21 22 23 24 RTS CTS Ground TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 Siemens S7 PLC or Motor Drive 3 5 8 7 8 9 10 18 19 20 21 22 1 2 3 4 5 11 23 12 24 13 25 DB-9 Male D+ Ground D- 9 8 7 6 Siemens S7 PLC or Motor Drive DB-9 Male 5 9 8 7 6 4 3 2 1 (Optional, Daisy Chained) 3 5 8 6 D+ Ground D- Cable Type: 3 or 4 Conductor Round 2-Wire RS422 or RS485 Communications: Yes Simatic TI5 RS-232 Port DTU
Appendix D: Cable Connection Diagrams Simatic TI5 RS-422 Port DTU 3005B 7 21 22 23 24 Ground TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 Simatic TI5 RS-422 Port 1 5 6 7 8 TX+ RX+ Ground TXRX- 11 23 12 24 13 25 DB-9 Male 1 2 6 3 7 4 8 5 9 Cable Type: 6 Conductor Round 2-Wire RS422 or RS485 Communications: No Square D Model 100-700 PLC DTU 3005B 21 22 23 24 TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 Square D Model 100-700 PLC
Appendix D: Cable Connection Diagrams Square D TSX07 DTU 3005B 4 5 21 22 23 24 RTS CTS TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 8 19 20 9 21 10 22 11 23 12 24 13 25 Mini DIN 6 3 Square D TSX07 1 2 7 5 2 1 D+ D- 8 4 Cable Type: 3 or 4 Conductor Round 2-Wire RS422 or RS485 Communications: Yes Toshiba EX & M Series DTU 3005B 21 22 23 24 TXRXTX+ RX+ Toshiba EX & M Series DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 Stripped W
Appendix D: Cable Connection Diagrams Toshiba T Series DTU 3005B 21 22 23 24 TXRXTX+ RX+ DB-25 Male 1 2 14 3 15 4 16 5 17 6 18 7 19 8 20 9 21 10 22 11 23 12 24 13 25 Toshiba T Series 2 3 4 5 10 11 12 13 76 RXA TXA CTSA RTSA RXB TXB CTSB RTSB DB-15 Male 1 2 9 3 10 4 11 5 12 13 6 7 14 8 15 Cable Type: 4 Conductor Round 2-Wire RS422 or RS485 Communications: No Siemens Energy & Automation, Inc.
Appendix E: Device Data Format E Device Data Format This appendix contains the real-time device data and command registers for each of the supported Siemens devices. E.1 Device Type: SAMMS LV and MV Real-Time Device Data Stored in PLC (SAMMS LV and MV) Real-Time Data Register Location in PLC Block 1 Range or Contents Motor Run Time 0 0...65535 hours # of Motor Starts 1 0...65535 starts # of Trips 2 0...9999 trips Time to Restart 3 0...3425 seconds Winding Temperature 4 0...
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (SAMMS LV and MV) (Continued) Real-Time Data Register Location in PLC Block 1 Range or Contents Control Parameters 18 Bit 7 6 5 4 3 2 1 0 Ambient Temperature 19 0...70 Degrees C Reserved 20 –23 For Future Expansion 1. Contents Ground Fault Enable Service Factor (0 = 1.
Appendix E: Device Data Format E.2 Device Type: 4300 Power Meter Real-Time Device Data Stored in PLC (4300 Power Meter) Real-Time Data Register Location in PLC Block 1 Range or Contents Power Factor 0 0...1000, 0.1 percent PF Lag/Lead 1 0 = Unity, 1 = Lag, 2 = Lead Voltage L-N Phase A 2–3 0...999999 V Voltage L-N Phase B 4–5 0...999999 V Voltage L-N Phase C 6–7 0...999999 V Voltage L-L Phase AB 8–9 0...999999 V Voltage L-L Phase BC 10–11 0...999999 V Voltage L-L Phase CA 12–13 0.
Appendix E: Device Data Format E.3 Device Type: 4700 Power Meter Real-Time Device Data Stored in PLC (4700 Power Meter) Real-Time Data Register Location in PLC Block 1 Range or Contents Voltage L-N Phase A 0–1 0...999999 V Voltage L-N Phase B 2–3 0...999999 V Voltage L-N Phase C 4–5 0...999999 V Voltage L-L Phase AB 6–7 0...999999 V Voltage L-L Phase BC 8–9 0...999999 V Voltage L-L Phase CA 10–11 0...999999 V Current Phase A 12 0...9999 A Current Phase B 13 0...
Appendix E: Device Data Format Device Command Data Retrieved From PLC (4700 Power Meter) First Command Word (Command Word) Second Command Word (Data or Value) 0 = No Command to Perform Unused for Command 0 1 = Reset all Demand Min/Max Unused for Command 1 2 = Reset kW and kVAR Hours Unused for Command 2 3 = Close Relay Relay Number (1–3) 4 = Open Relay Relay Number (1–3) Siemens Energy & Automation, Inc.
Appendix E: Device Data Format E.4 Device Type: 4720 Power Meter Real-Time Device Data Stored in PLC (4720 Power Meter) Real-Time Data Register Location in PLC Block 1 Range or Contents Voltage L-N Phase A 0–1 0...99999999 V Voltage L-N Phase B 2–3 0...99999999 V Voltage L-N Phase C 4–5 0...99999999 V Voltage L-L Phase AB 6–7 0...99999999 V Voltage L-L Phase BC 8–9 0...99999999 V Voltage L-L Phase CA 10–11 0...99999999 V Auxiliary Voltage 12–13 0...999999 V Current Phase A 14 0..
Appendix E: Device Data Format Device Command Data Retrieved From PLC (4720 Power Meter) First Command Word (Command Word) Second Command Word (Data or Value) 0 = No Command to perform Unused for Command 0 1 = Reset all Demand Min/Max Unused for Command 1 2 = Reset all Hours Counters Unused for Command 2 3 = Close Relay Relay Number (1–3) 4 = Open Relay Relay Number (1–3) Siemens Energy & Automation, Inc.
Appendix E: Device Data Format E.5 Device Type: Static Trip III Real-Time Device Data Stored in PLC (Static Trip III) Real-Time Data Register Location in PLC Block 1 Range or Contents Current Phase A 0 0...65000 A Current Phase B 1 0...65000 A Current Phase C 2 0...65000 A Current Ground 3 0...65000 A Voltage L-N Phase A 4 0...400 V Voltage L-N Phase B 5 0...400 V Voltage L-N Phase C 6 0...400 V Voltage L-L Phase AB 7 0...660 V Voltage L-L Phase BC 8 0...
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (Static Trip III) (Continued) Real-Time Data Register Location in PLC Block 1 Range or Contents Alarm Status 22 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Reserved 23–25 For Future Expansion 1. Contents Overvoltage Setpoint Voltage Unbalance Setpoint Undervoltage Setpoint Current Unbalance Setpoint Neutral Overcurrent Ground Overcurrent Overcurrent Setpoint Aux.
Appendix E: Device Data Format E.6 Device Type: SensiTrip III Real-Time Device Data Stored in PLC (SensiTrip III) Real-Time Data Register Offset Range or Contents MT Status 0 2 Byte ASCII string Zone Interlock Status 1 High Order Byte: Ground Fault Zone Low Order Byte: Short Time Zone Device Type 2 00h = No Device 01h = MCCB/ICCB 02h = STIIIC/CP Phase A Current (Gain Off) 3 0...65535 (must be scaled) Phase B Current (Gain Off) 4 0...
Appendix E: Device Data Format E.7 Device Type: SB-TL Real-Time Device Data Stored in PLC (SB-TL) Real-Time Data Register Offset Range or Contents MT Status 0 2 Byte ASCII string Zone Interlock Status 1 High Order Byte: Ground Fault Zone Low Order Byte: Short Time Zone Device Type 2 00h = No Device 01h = MCCB/ICCB 02h = STIIIC/CP Phase A Current (Gain Off) 3 0...65535 (must be scaled) Phase B Current (Gain Off) 4 0...65535 (must be scaled) Phase C Current (Gain Off) 5 0...
Appendix E: Device Data Format E.8 Device Type: Pulse Reading Meter (PRM) Real-Time Device Data Stored in PLC (PRM) Real-Time Data Register Location in PLC Block 1 Range or Contents Instantaneous kW 0-1 0...4294967295 kW kW demand (30 minutes) 2-3 0...4294967295 kW Peak kW (30 minutes) 4-5 0...4294967295 kW kW Hours 6-7 0...4294967295 kWh kW demand (5 minutes) 8-9 0...
Appendix E: Device Data Format E.9 Device Type: ISGS Real-Time Device Data Stored in PLC (ISGS) Real-Time Data Register Location in PLC Block 1 Range or Contents Current Phase A 0 0...32000 A Current Phase B 1 0...32000 A Current Phase C 2 0...32000 A Current Neutral 3 0...32000 A Current Demand Phase A 4 0...32000 A Current Demand Phase B 5 0...32000 A Current Demand Phase C 6 0...32000 A Voltage L-N Phase A 7–8 0...9999999 V Voltage L-N Phase B 9–10 0...
Appendix E: Device Data Format Device Command Data Retrieved From PLC (ISGS Switchgear) First Command Word (Command Word) Second Command Word (Data or Value) 0 = No Command to Perform Unused for Command 0 1 = Clear Min/Max Log Unused for Command 1 2 = Reset Kilowatt and Kilovolt-Amperes Reactive Hours Unused for Command 2 3 = Assert Comm Event1 Comm Event to Assert (1–5) 4 = Release Comm Event1 Comm Event to Release (1–5) 5 = Reset Local Targets Unused for Command 5 6 = Reset Breaker Operation
Appendix E: Device Data Format E.10 Device Type: Sentron SB Energy Comm Trip Unit Real-Time Device Data Stored in PLC (Energy/Comm) Real-Time Data Register Location in PLC Block 1 Range or Contents Current Phase A 0 0...65535 A Current Phase B 1 0...65535 A Current Phase C 2 0...65535 A Current Ground 3 0...65535 A Voltage L-N Phase A 4 0...65535 V Voltage L-N Phase B 5 0...65535 V Voltage L-N Phase C 6 0...65535 V Voltage L-L Phase AB 7 0...65535 V Voltage L-L Phase BC 8 0...
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (Energy/Comm) (Continued) Real-Time Data Register Location in PLC Block 1 Range or Contents Alarm Function Status 46 Bit 15–10 9 8 7 6 5 4 3 2 1 0 Contents Unused Harmonic Distortion Alarm Under PF Lag Alarm Over PF Lead Alarm Over kVAR Alarm Over kVA Alarm Over kW Demand Alarm Over kW Alarm Over Amp Demand Alarm Grnd Over Amp Alarm Over Amp Alarm Protective Relay Status 47 Bit 15–8 7 6 5 4 3 2 1 0 Contents Unused Under Frequency A
Appendix E: Device Data Format E.11 Device Type: S7-I/O Real-Time Device Data Stored in PLC (S7-I/O) Function Register Location in PLC Block 1 Range or Contents Inputs 1–16 0 Bits 0–15: Inputs 17–32 1 Bits 0–15: Inputs 18–48 2 Bits 0–15: Inputs 49–64 3 Bits 0–15: Outputs 1–16 4 Bits 0–15: Outputs 17–32 5 Bits 0–15: Outputs 18–48 6 Bits 0–15: Outputs 49–64 7 Bits 0–15: Event Counter 1 8 I0.0 Event Counter Event Counter 2 9 I0.1 Event Counter Event Counter 3 10 I0.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA511) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 32 16 Bit 6–15 5 4 3 2 1 0 Number of last fault 17 0…32767, 0 = no faults Contents Not used Dist. teleprotection: Carrier faulty (Valid) Dist.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA511) (Continued) Function Register Location in PLC Block 1 Range or Contents Fault in the power system 49 ms since fault (-1 = no fault) General Trip for Fault in Forward Direction 50 ms since fault (-1 = no occurance) General Trip for Fault in Reverse Direction 51 ms since fault (-1 = no occurance) Trip by earth fault det. (isol./comp.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA511) (Continued) Function Register Location in PLC Block 1 Range or Contents Dist.: Fault detection phase L1,3,E 83 ms since fault (-1 = no occurance) Dist.: Fault detection only phase L2,3 84 ms since fault (-1 = no occurance) Dist.: Fault detection phase L2,3,E 85 ms since fault (-1 = no occurance) Dist.: Fault detection only phase L1,2,3 86 ms since fault (-1 = no occurance) Dist.
Appendix E: Device Data Format Device Command Data Retrieved From PLC (7SA511) First Command Word (Command Word) Additional Command Words (Data or Value) 2 = Reset LEDs Unused 3 = Activate Parameter Set A Unused 4 = Activate Parameter Set B Unused 5 = Activate Parameter Set C Unused 6 = Activate Parameter Set D Unused 10 = General Command 2nd Word: [Typ] in high byte, [Inf] in low byte 98 Siemens Energy & Automation, Inc.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA513) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 32 16 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Contents AR: Auto-reclose is blocked (Valid) AR: Auto-reclose is blocked (Status) Back-up Overcurrent prot. Is active (Valid) Back-up Overcurrent prot.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA513) (Continued) Function Register Location in PLC Block 1 Range or Contents Interrupted current: Phase L2 (I/In) 27 ms since fault (-1 = no occurance) Interrupted current: Phase L2 (I/In) 28 Low word Interrupted current: Phase L2 (I/In) 29 High word Interrupted current: Phase L3 (I/In) 30 ms since fault (-1 = no occurance) Interrupted current: Phase L3 (I/In) 31 Low word Interrupted current: Phase L3 (I/In) 32 High w
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA513) (Continued) Function Register Location in PLC Block 1 Range or Contents Trip by Breaker Failure Protection 59 ms since fault (-1 = no occurance) Emerg. O/C fault detection L1 only 60 ms since fault (-1 = no occurance) Emerg. O/C fault detection L1E 61 ms since fault (-1 = no occurance) Emerg. O/C fault detection L2 only 62 ms since fault (-1 = no occurance) Emerg.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SA513) (Continued) Function Register Location in PLC Block 1 Range or Contents Dist.: Time T3 (Zone Z3) expired 95 ms since fault (-1 = no occurance) Dist.: Time T4 (direct. zone) expired 96 ms since fault (-1 = no occurance) Dist.: Time T5 (non-direct. zone) expired 97 ms since fault (-1 = no occurance) Dist.: Time T1B (Zone Z1B) expired 98 ms since fault (-1 = no occurance) Dist.
Appendix E: Device Data Format Device Command Data Retrieved From PLC (7SA513) First Command Word (Command Word) Additional Command Words (Data or Value) 5 = Activate Parameter Set C Unused 6 = Activate Parameter Set D Unused 10 = General Command 2nd Word: [Typ] in high byte, [Inf] in low byte 104 Siemens Energy & Automation, Inc.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SD511) (Continued) Function Register Location in PLC Block 1 Range or Contents Interrupted current: Phase L1 (I/In) 15 High word Interrupted current: Phase L2 (I/In) 16 ms since fault (-1 = no occurance) Interrupted current: Phase L2 (I/In) 17 Low word Interrupted current: Phase L2 (I/In) 18 High word Interrupted current: Phase L3 (I/In) 19 ms since fault (-1 = no occurance) Interrupted current: Phase L3 (I/In) 20 Low w
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SD511) (Continued) Function Register Location in PLC Block 1 Range or Contents Emerg. O/C protection: Trip 3pole 46 ms since fault (-1 = no occurance) General Trip Signal of current compare prt. 47 ms since fault (-1 = no occurance) Trip L1 (1-pole) of current comp. prot. 48 ms since fault (-1 = no occurance) Trip L2 (1-pole) of current comp. prot. 49 ms since fault (-1 = no occurance) Trip L3 (1-pole) of current comp. prot.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SD512) (Continued) Function Register Location in PLC Block 1 Range or Contents Fault Date/Time (y) 12 Year: YY (00…99) Interrupted current: Phase L1 (I/In) 13 ms since fault (-1 = no occurance) Interrupted current: Phase L1 (I/In) 14 Low word Interrupted current: Phase L1 (I/In) 15 High word Interrupted current: Phase L2 (I/In) 16 ms since fault (-1 = no occurance) Interrupted current: Phase L2 (I/In) 17 Low word Inter
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SD512) (Continued) Function Register Location in PLC Block 1 Range or Contents Emerg. O/C protection: Trip 1pole L2 44 ms since fault (-1 = no occurance) Emerg. O/C protection: Trip 1pole L3 45 ms since fault (-1 = no occurance) Emerg. O/C protection: Trip 3pole 46 ms since fault (-1 = no occurance) 79-A/R CLOSE command 47 ms since fault (-1 = no occurance) General Trip Signal of current compare prt.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ511) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 3:2 17 Bit 14–15 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Number of Last Fault 18 0…32767, 0 = no faults Contents Not Used Non-dir. ground O/C prot. PICKUP (Valid) Non-dir. ground O/C prot. PICKUP (Status) Non-dir. phase C O/C prot. PICKUP (Valid) Non-dir. phase C O/C prot. PICKUP (Status) Non-dir. phase B O/C prot. PICKUP (Valid) Non-dir.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ511) (Continued) Function Register Location in PLC Block 1 Range or Contents O/C Fault Detection L1-L3 44 ms since fault (-1 = no occurance) O/C Fault Detection L1-L3-E 45 ms since fault (-1 = no occurance) O/C Fault Detection L2-L3 46 ms since fault (-1 = no occurance) O/C Fault Detection L2-L3-E 47 ms since fault (-1 = no occurance) O/C Fault Detection L1-L2-L3 48 ms since fault (-1 = no occurance) O/C Fault Detection
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ512) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 3:2 15 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Contents Non-dir. ground O/C prot. is ACTIVE (Valid) Non-dir. ground O/C prot. is ACTIVE (Status) Non-dir. phase O/C prot. is ACTIVE (Valid) Non-dir. phase O/C prot.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ512) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 6:2 18 Bit 14–15 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Number of Last Fault 19 0…32767, 0 = no faults Fault Date/Time (ms) 20 0…59999 (ms ) Fault Date/Time (h/m) 21 High byte: HH (0…23), Low byte: MM (0…59) Fault Date/Time (m/d) 22 High byte: MM (1…12); Low byte: DD (1…31) Fault Date/Time (y) 23 Year: YY (00…99) Interrupted cur
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ512) (Continued) Function Register Location in PLC Block 1 Range or Contents 51-Phase time element TRIP 45 ms since fault (-1 = no occurance) 50NHS-Ground high-set element TRIP 46 ms since fault (-1 = no occurance) 50N-Ground inst. element TRIP 47 ms since fault (-1 = no occurance) 51N-Ground time element TRIP 48 ms since fault (-1 = no occurance) 67-Dir. phase inst.
Appendix E: Device Data Format E.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ531) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 3:2 18 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Contents Non-dir. phase O/C prot. is ACTIVE (Valid) Non-dir. phase O/C prot. is ACTIVE (Status) Thermal overload prot.: Current warning (Valid) Thermal overload prot.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ531) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 6:2 21 Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Contents DC-Q10 pos (Valid) DC-Q10 pos (Status) DC-Q8 pos (Valid) DC-Q8 pos (Status) DC-Q6 pos (Valid) DC-Q6 pos (Status) DC-Q5 pos (Valid) DC-Q5 pos (Status) DC-Q01 pos (Valid) DC-Q01 pos (Status) DC-Q1 pos (Valid) DC-Q1 pos (Status) CB-Q0 pos (Valid) CB-Q0 pos (Status) Error DC pos Q2 (
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ531) (Continued) Function Register Location in PLC Block 1 Range or Contents Interrupted current: Phase L3 (I/In) 36 Low word Interrupted current: Phase L3 (I/In) 37 High word Fault Reactance, Ohm sec. 38 ms since fault (-1 = no occurance) Fault Reactance, Ohm sec. 39 Low word Fault Reactance, Ohm sec.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ531) (Continued) Function Register Location in PLC Block 1 Range or Contents O/C Fault Detection L2-E 73 ms since fault (-1 = no fault) O/C Fault Detection L1-L2 74 ms since fault (-1 = no fault) O/C Fault Detection L1-L2-E 75 ms since fault (-1 = no fault) O/C Fault Detection L3 76 ms since fault (-1 = no fault) O/C Fault Detection L3-E 77 ms since fault (-1 = no fault) O/C Fault Detection L1-L3 78 ms since fault (-1
Appendix E: Device Data Format Device Command Data Retrieved From PLC (7SJ531) First Command Word (Command Word) Additional Command Words (Data or Value) 0 = No command Unused 1 = Time Sync 2nd Word: Time [ms] - (0-59999) 3rd Word: Time [h/m] - high byte: HH (1-24), low byte: MM (0-59) 4th Word: Date [m/d] - high byte: MM (1-12), low byte: DD (1-31) 5th Word: Date [y] - YY (00-99) 2 = Reset LEDs Unused 3 = Activate Parameter Set A Unused 4 = Activate Parameter Set B Unused 5 = Activate Parameter
Appendix E: Device Data Format E.19 Device Type: 7SJ600 Real-Time Device Data Stored in PLC (7SJ600) Function Register Location in PLC Block 1 Range or Contents Phase A current (IL1) 0 % Phase B current (IL2) 1 % Phase C current (IL3) 2 % Operating Temperature (Theta) 3 % Binary Inputs 1-3 4 Refer to Section 5.8 Signal Relays and Trip Relays 5 Refer to Section 5.8 LED Indicators 1-4 6 Refer to Section 5.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ600) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 4:2 10 Bit 2–15 1 0 Number of Last Fault 11 0…32767, 0 = no faults Contents Not Used Trip circuit supervision active (Valid) Trip circuit supervision active (Status) Fault Date/Time (ms) 12 0…59999 (ms ) Fault Date/Time (h/m) 13 High byte: HH (0…23), Low byte: MM (0…59) Fault Date/Time (m/d) 14 High byte: MM (1…12); Low byte
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7SJ600) (Continued) Function Register Location in PLC Block 1 Range or Contents O/C protection I>> phase Trip 44 ms since fault (-1 = no occurance) O/C protection I> phase Trip 45 ms since fault (-1 = no occurance) O/C protection Ip phase Trip 46 ms since fault (-1 = no occurance) O/C protection IE>> earth Trip 47 ms since fault (-1 = no occurance) O/C protection IE> earth Trip 48 ms since fault (-1 = no occurance) O/C pro
Appendix E: Device Data Format E.20 Device Type: 7UT512 Real-Time Device Data Stored in PLC (7UT512) Function Register Location in PLC Block 1 Range or Contents Operat. meas. current L1 side 1 (I1_L1) 0 % Operat. meas. current L2 side 1 (I1_L2) 1 % Operat. meas. current L1 side 3 (I1_L3) 2 % Operat. meas. current L1 side 2 (I2_L1) 3 % Operat. meas. current L2 side 2 (I2_L2) 4 % Operat. meas. current L3 side 2 (I2_L3) 5 % Operat. meas. current L1 side 3 (I3_L1) 6 % Operat. meas.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7UT512) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 3:2 13 Bit 8–15 7 6 5 4 3 2 1 0 Contents Not Used Differential protection is active (Valid) Differential protection is active (Status) External trip 2 is active (Valid) External trip 2 is active (Status) External trip 1 is active (Valid) External trip 1 is active (Status) Back-up overcurrent prot.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7UT512) (Continued) Function Register Location in PLC Block 1 Range or Contents General Trip of Device 38 ms since fault (-1 = no occurance) Trip by thermal overload protection 1 39 ms since fault (-1 = no occurance) Trip by thermal overload protection 2 40 ms since fault (-1 = no occurance) Back-up Overcurrent: General Trip 41 ms since fault (-1 = no occurance) External Trip 1: General Trip 42 ms since fault (-1 = no occur
Appendix E: Device Data Format E.21 Device Type: 7UT513 Real-Time Device Data Stored in PLC (7UT513) Function Register Location in PLC Block 1 Range or Contents Operat. meas. current L1 side 1 (I1_L1) 0 % Operat. meas. current L2 side 1 (I1_L2) 1 % Operat. meas. current L1 side 3 (I1_L3) 2 % Operat. meas. current L1 side 2 (I2_L1) 3 % Operat. meas. current L2 side 2 (I2_L2) 4 % Operat. meas. current L3 side 2 (I2_L3) 5 % Operat. meas. current L1 side 3 (I3_L1) 6 % Operat. meas.
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7UT513) (Continued) Function Register Location in PLC Block 1 Range or Contents General Status Word 3:2 13 Bit 12–15 11 10 9 8 7 6 5 4 3 2 1 0 Contents Not Used Transformer tank protection is active (Valid) Transformer tank protection is active (Status) Restricted earth fault is active (Valid) Restricted earth fault is active (Status) Differential protection is active (Valid) Differential protection is active (Status) External trip 2
Appendix E: Device Data Format Real-Time Device Data Stored in PLC (7UT513) (Continued) Function Register Location in PLC Block 1 Range or Contents Restr. Curr. Of L3 at Trip (average DC) 36 High word Restr. Earth Flt.: Value D at Trip 37 ms since fault (-1 = no occurance) Restr. Earth Flt.: Value D at Trip 38 Low word Restr. Earth Flt.: Value D at Trip 39 High word Restr. Earth Flt.: Value S at Trip 40 ms since fault (-1 = no occurance) Restr. Earth Flt.
Appendix E: Device Data Format Device Command Data Retrieved From PLC (7UT513) First Command Word (Command Word) Additional Command Words (Data or Value) 0 = No command Unused 1 = Time Sync 2nd Word: Time [ms] - (0-59999) 3rd Word: Time [h/m] - high byte: HH (1-24), low byte: MM (0-59) 4th Word: Date [m/d] - high byte: MM (1-12), low byte: DD (1-31) 5th Word: Date [y] - YY (00-99) 2 = Reset LEDs Unused 3 = Activate Parameter Set A Unused 4 = Activate Parameter Set B Unused 5 = Activate Parameter
Appendix F: Diagnostic Data Format F Diagnostic Data Format When users select Diagnostic Information to be written to the PLC, 6 registers will automatically be updated in the PLC with the diagnostic information. The location of this block of 6 consecutive registers in the PLC is specified by the user. The format of this register block follows: Table F.
Appendix G: Warranty G Warranty ICP PANEL-TEC, INC. warrants that all equipment purchased hereunder is warranted on a “RETURN TO FACTORY” basis against all defects in workmanship and materials under normal and proper use and service in its unmodified condition for a period of one (1) year from the date of initial shipment. ICP PANEL-TEC, INC. sole obligation under this warranty shall be limited to furnishing parts and labor to remedy such defects; either, at the option of ICP PANEL-TEC, INC.
Appendix G: Warranty 136 Siemens Energy & Automation, Inc.
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