FASE_Workflow_Descriprion_130130.docx Page: 1 / 51 Workflow description for Feeder Automation with FASE Author Name Department Version Date Markus Spangler / Leonid Borisuk IC SG EA PRO LM2 / SYS OP TRC V1.00 2013-01-30 Updates Chapter / Pages changed Version Object and reason of change/ Reference to change requirements 1
FASE_Workflow_Descriprion_130130.docx Page: 2 / 51 Table of contents 1. INTRODUCTION 3 2. FASE V2.00: INSTALLATION 4 2.1. DIGSI INSTALLATION 4 2.2. DIGSI DEVICE DRIVER INSTALLATION 4 2.3 FASE INSTALLATION PROCESS 4 2.4 FASE: TOPOLOGY 5 3. FASE - DECENTRALIZED LOGIC 7 3.1. FASE - PROTECTION AND COMMUNICATION SETTINGS 10 3.2. FASE - DEFINITION OF SEQUENCES 12 3.3. FASE - CREATE DIGSI PROJECT 16 3.4. DIGSI - CHANGES IN THE DIGSI PROJECT 18 4. FASE V2.00 - CENTRALIZED LOGIC 19 4.1. PREPARATION AND SW REQUIREMENTS 19 4.2. CREATION OF PROJECT IN FASE 19 4.3. ACTIONS REQUIRED IN DIGSI PROJECT 24 4.4. CREATION OF SICAM PAS PROJECT 28 4.5. CREATION OF SICAM SCC PROJECT 51 2
FASE_Workflow_Descriprion_130130.docx Page: 3 / 51 1. Introduction Feeder Automation Sequence Editor (FASE) offers the following features: - Automatic creation of DIGSI project with all SIPROTEC devices for your feeder arrangement - Automatic creation of IEC61850 station - Automatic creation GOOSE messages necessary to perform the configured Feeder Automation Apps - Automatic creation of CFC (PLC) logic used to perform the configured Feeder Automation Apps For using of decentralized logic, where the information exchange is done by GOOSE messages between the devices please follow description in the Chapter 2 of this document. Since the FASE V2.00 the user of FASE can transfer the Feeder Automation logic to the substation automation system like SICAM PAS and control and monitor your feeders using SICAM SCC. The necessary steps for configuring of centralized logic of Feeder Automation are described in the Chapter 3 of this document. After the use of FASE you will be able to initialize your SIPROTEC devices and to start the test of the Feeder Automation Apps in your feeder arrangement. In case of centralized solution the necessary files with logic for importing in the SoftPLC of SICAM PAS will be generation by FASE. 3
FASE_Workflow_Descriprion_130130.docx Page: 4 / 51 2. FASE V2.00: Installation 2.1. DIGSI Installation FASE V2.00 is a standalone software. With FASE you can prepare your feeder automation project with most of the needed settings and applications. Created FASE projects can be saved, exported and imported to other FASE PCs. To create a final DIGSI project, including all devices with necessary FA logic and GOOSE messages (for decentralized logic) you need a installed DIGSI 4 at the same hardware. You need at least DIGSI 4.87 to run FASE V 2.0 successfully. 2.2. DIGSI Device Driver Installation Install the DIGSI device driver for 7SC80 for FASE 2.00 firmware version V4.01 is needed. Newer FASE versions or additional service pack may need newer device firmware versions. 2.3 FASE Installation Process 4
FASE_Workflow_Descriprion_130130.docx Page: 5 / 51 Please copy the FASE license key file ( FASE.LIC ) file in the FASE.exe folder (e.g. C:\Program Files\Siemens Energy\FASE). Please order the necessary license via MLFB in Berlin or ask the Lifecycle Manager markus.spangler@siemens.com if not yet available. 2.4 FASE: Topology As the result out of FASE a complete DIGSI project will be created (including a mode switch controlling the modes of the feeder arrangement and two HMI devices for decentralized logic. Mode switch is necessary for the Feeder Automation function, the one or both HMI devices can be deleted in the newly created DIGSI project, if not needed). Before using FASE, please ensure the correct device templates are used in the project. The following MLFB number for mode switch and HMI devices are predefined in FASE: - Mode Switch (MS): 7SC80221AB973FA0+L0R - HMI: 7SJ64155EC923FG7+L0R For any reasons you can exchange the dex and xml-files in the following folders: Pls. ensure that the new dex and xml-files still contain all necessary predefinitions (matrix, CFC) for the decentralized feeder arrangement. 5
FASE_Workflow_Descriprion_130130.docx Page: 6 / 51 If you change the mode switch or HMI device you have to export the changed *.dex and *.xml files from DIGSI in the folder C:\Program Files\Siemens Energy\DIGSI 4\FASE\ControlDevices\HMI or C:\Program Files\Siemens Energy\DIGSI 4\FASE\ControlDevices\ModeSwitch. 6
FASE_Workflow_Descriprion_130130.docx Page: 7 / 51 3. FASE - Decentralized Logic Create a new project Add device templates into the device template section if needed. 7
FASE_Workflow_Descriprion_130130.docx Page: 8 / 51 Use predefined templates for your switching devices, which are available in SIPROTEC compact Sharepoint/Internet. You can manipulate the predefined templates (*.dex files) in DIGSI with regards to your needs. But do not delete any Feeder Automation related settings in the predefined templates (CFC logic and matrix indications). After adapting the templates to your needs, please export the dex and the xml-file out of DIGSI to import it to FASE. 8
FASE_Workflow_Descriprion_130130.docx Page: 9 / 51 Insert switching devices in your power grid per Drag&Drop, which are corresponding to your feeder topology. After completion check the box Complete topology. 9
FASE_Workflow_Descriprion_130130.docx Page: 10 / 51 Define the Normally Open Point (NOP) in your grid. Press Add NOP and then choose with double click the NOP. If you need several NOPs, press Add NOP once more again. Up to four NOPs are possible. Red is always the colour for switch closed or source energized, green is always the colour for switch opened or source deenergized. After choosing check the box Complete NOP. 3.1. FASE - Protection and communication settings Press Properties to go to protection and communication settings of your SIPROTEC devices. 10
FASE_Workflow_Descriprion_130130.docx Page: 11 / 51 Here you can set the most relevant protection and communication parameters of used devices. Copy and paste amongst the devices is very easy possible (see pictures below). With the right click on the device you can copy or export the settings and then paste or import in the other one. You can also select the group of settings and transfer it to neighbour devices by pulling of the selection corner like in MS Excel application. 11
FASE_Workflow_Descriprion_130130.docx Page: 12 / 51 In the Communication Settings you can define the IP addresses of your SIPROTEC devices ( IP Address ). For the Communication device IP Address insert the IP addresses of dedicated communication equipment, e.g. WIMAX subscriber units or WiFi access points. In the Project settings tab you decide to work with traditional over current or with new selective and adaptive differential protection. 3.2. FASE - Definition of sequences Here you define the sequences for the application you want to use in the feeder arrangement. There are two default folders to define the isolation and restoration sequences. Isolation: there are two already defined steps in each isolation sequence Normal step and Trigger step. Press Add step and define the next steps for your grid until the fault has been isolated. In each step you can define by double click only one position change of switching device. After definition of the last step check the box Complete sequence. 12
FASE_Workflow_Descriprion_130130.docx Page: 13 / 51 Define isolation sequences for all possible locations of a fault (A, B,C, etc.). Restoration: there is one already defined step Trigger step, which is the last step in corresponding isolation sequence. Use the buttons Add step, Delete last step and Reset steps to configure the restoration sequences for the case the fault has been eliminated and you wish to go back to the initial configuration of your grid. After the sequence has been created press Complete sequence. 13
FASE_Workflow_Descriprion_130130.docx Page: 14 / 51 Define restoration sequences for all possible locations of a fault (A, B, C etc.) To define a new folder for your own sequences/applications click rights on Sequences and then Add folder. In the properties window you decide which operation inputs have to be considered for this specific application: 14
FASE_Workflow_Descriprion_130130.docx Page: 15 / 51 Add a sequence to the created application: In the section Sequence modes set the modes which should be valid for your sequence. Then define your sequences Save your FASE project. 15
FASE_Workflow_Descriprion_130130.docx Page: 16 / 51 3.3. FASE - Create DIGSI project Choose the name of future DIGSI project and their location on your hard drive and press Create. If you check the box Create communication devices the FASE will create ICD files for all communication devices in the DIGSI project. These will be also included in the SCD file of the IEC61850 station. If you did not save the FASE project before you get the message to save the project. In the window DIGSI project creation progress you see the report or error messages while creation of DIGSI project. 16
FASE_Workflow_Descriprion_130130.docx Page: 17 / 51 17
FASE_Workflow_Descriprion_130130.docx Page: 18 / 51 3.4. DIGSI - Changes in the DIGSI project In the DIGSI project delete HMI1 or HMI2 device if it is not needed and you use SICAM PAS and SCC for monitoring and controlling of your grid. If HMI devices are used open the parameter set and manipulate the predefined display settings with regards to your needs. Go the normal DIGSI workflow if needed, e. g. make other changes in DIGSI files or IEC61850 station. It is recommended not to change any FA related settings (incl. IED names and addresses) like CFC, GOOSE, Indications in the matrix etc. The created ICD files for communication devices are available in SCD as well. In that way you can monitor all communicating devices in diagnostic tools like Netview. Afterwards you can download the parameter set to the devices and test the feeder arrangement with all configured applications with FAST for the decentralized logic using GOOSE. 18
FASE_Workflow_Descriprion_130130.docx Page: 19 / 51 4. FASE V2.00 - Centralized Logic 4.1. Preparation and SW requirements You need at least DIGSI V4.87 and DIGSI driver V4.01.03 for 7SC80 device to run FASE V 2.00 successfully. If older versions of DIGSI or FASE are already installed, please uninstall it before using of centralized solution with FASE V2.00. 4.2. Creation of project in FASE Drag&Drop the switching devices from the folder with templates into your topology. 19
FASE_Workflow_Descriprion_130130.docx Page: 20 / 51 After completing of topology confirm with Validate and complete topology. After that, each switching device gets the name like P1, P2 etc and line section gets the designation like C1, C2 etc. The next step is defining of Normal Open Point (NOP). 20
FASE_Workflow_Descriprion_130130.docx Page: 21 / 51 In the tab Properties you can configure protection and communication settings of all devices in your topology (please refer to Chapter 3.1). 21
FASE_Workflow_Descriprion_130130.docx Page: 22 / 51 In the tab Sequences you define the automatic switching sequences for Isolation of fault on sections, ILS, Source Transfer and Restoration etc. (please refer to Chapter 3.2). After configuring the sequences, save the project and go to the tab Create project. Define the location of DIGSI project and SICAM files and start creation with Create button. 22
FASE_Workflow_Descriprion_130130.docx Page: 23 / 51 In the progress window you can see warnings and errors during the creation of DIGSI and SICAM data. 23
FASE_Workflow_Descriprion_130130.docx Page: 24 / 51 4.3. Actions required in DIGSI project After creation of DIGSI project by FASE without warnings or errors open the newly created DIGSI project. Add the time master in the DIGSI project, if necessary. 24
FASE_Workflow_Descriprion_130130.docx Page: 25 / 51 Open the properties page of IEC61850 station. Add the time master to the station. 25
FASE_Workflow_Descriprion_130130.docx Page: 26 / 51 Update all parameter sets in the station. After that open each device, compile the CFC charts, save and close it. Open the IEC61850 station and define the time master as First timer. 26
FASE_Workflow_Descriprion_130130.docx Page: 27 / 51 Update all parameter sets in the properties of IEC61850 station. Save and export the IEC61850 station (SCD file) for importing in the SICAM PAS. 27
FASE_Workflow_Descriprion_130130.docx Page: 28 / 51 4.4. Creation of SICAM PAS project Create a new PAS project. Create a system. Insert an IEC 61850 Client application. 28
FASE_Workflow_Descriprion_130130.docx Page: 29 / 51 Insert a new interface under this application. Import the SCD file, which you exported by DIGSI. 29
FASE_Workflow_Descriprion_130130.docx Page: 30 / 51 Create an application for HMI (SCC), interface and control center. 30
FASE_Workflow_Descriprion_130130.docx Page: 31 / 51 31
FASE_Workflow_Descriprion_130130.docx Page: 32 / 51 Create an application for automation, Soft PLC and devices Info. from - / Cmd. to SoftPLC and Info. to - / Cmd. from SoftPLC. Go to Templates and create the commands and indications for SoftPLC, which you will use in the HMI (DC Pulse Double Command, DP Double Point Indication, SE_AI Set Point Integer Command, ME_I Measurand Integer). - CBx_ON_OFF_CMD (DC) and CBx_ON_OFF_IND (DP) for command and feed back for switches P1 to P20. - STM_MODE (DC) and STM_IND (DP) for command and feed back for Sequence Test Mode. - RESTORE_MODE (DC) and RESTORE_IND (DP) for command and feed back for Restoration Mode. - SIM_MODE (DC) and SIM_IND (DP) for command and feed back for Simulation Mode. - STORM_MODE (DC) and STORM_IND (DP) for command and feed back for Simulation Mode. - ILS_MODE (DC) and ILS_MODE_IND (DP) for command and feed back for Isolate Line Section Mode. - AUTO_MODE (DC) and AUTO_IND (DP) for command and feed back for Automatic Mode. - FAULT (SE_AI) and FAULT_IND (ME_I) for command and feed back for Fault on the section. - NOP (SE_AI) and NOP_IND (ME_I) for command and feed back for Normally Open Point (NOP). 32
FASE_Workflow_Descriprion_130130.docx Page: 33 / 51 - ILS (SE_AI) and ILS_IND (ME_I) for command and feed back for number of Isolate Line Section. - Sx _CMD (DC) and Sx _IND (DP) for command and feed back for sources S1 to S4. 33
FASE_Workflow_Descriprion_130130.docx Page: 34 / 51 Go to Mapping and map all newly created information to Use. 34
FASE_Workflow_Descriprion_130130.docx Page: 35 / 51 35
FASE_Workflow_Descriprion_130130.docx Page: 36 / 51 Go to Topology, create a folder HMI and move all HMI commands and indications into this folder. 36
FASE_Workflow_Descriprion_130130.docx Page: 37 / 51 Go to the device folder in the Mapping and map following indications and commands to Use for device P1. - Control/79 ON_OFFGAPC.Reclose ON_OFF Command - Control/cdcb_1.Position - Control/CenSolGGIO1.Inrush Current Ph_Gnd - Control/cdhltGGIO1.Hot Line Tag ON goose - Control/fcLOGGIO1.Own Lockout goose - Control/HLT ON_OFFGAPC.Hot Line Tag ON_OFF - Control/LockoutGAPC.Own Lockout - Control/stownSGGIO1.Own Source Status is ON - Control/stownSGGIO2.Own Source Status is OFF - Measurement/Op meas value.i.phsa - Measurement/Op meas value.i.phsb - Measurement/Op meas value.i.phsc - Measurement/Op meas value.f - Measurement/sym comp value.current.c1 - Measurement/sym comp value.current.c2 - Measurement/sym comp value.current.c3 - Protection/50 General.Pickup - c_control/cdcb_1.position - c_control/79 ON_OFFGAPC.Reclose ON_OFF Command - c_control/hlt ON_OFFGAPC.Hot Line Tag ON_OFF - c_control/lockoutgapc.own Lockout 37
FASE_Workflow_Descriprion_130130.docx Page: 38 / 51 To copy the mapping information to another devices use mapping export function in the SICAM PAS. For this export the mapping information from the device P1. Change to configuration view and go to the IEC61850 interface. 38
FASE_Workflow_Descriprion_130130.docx Page: 39 / 51 Select all devices, which should get the same mapping information. The file with mapping information will also be available in the sharenet. After the mapping of necessary information create the topology for HMI tags. For each device create the folder (P1-P20), so you can use Tag Prefix function in the SICAM SCC. Move all information from SICAM PAS PQS folder to the correspondent folders. 39
FASE_Workflow_Descriprion_130130.docx Page: 40 / 51 Go to the Mapping and Info. to - / Cmd. from SoftPLC and map device information and command for using in SoftPLC. - Control/cdcb_1.Position - Control/fcLOGGIO1.Own Lockout goose - Control/CenSolGGIO1.Inrush Current Ph_Gnd - Control/cdhltGGIO1.Hot Line Tag ON goose - c_control/cdcb_1.position For devices on sources the source status information should be also mapped. - Control/stownSGGIO1.Own Source Status is ON - Control/stownSGGIO2.Own Source Status is OFF 40
FASE_Workflow_Descriprion_130130.docx Page: 41 / 51 Map all required information and commands to the SICAM Control Center (SCC). These are all information in the folders P1 to P20 and HMI. 41
FASE_Workflow_Descriprion_130130.docx Page: 42 / 51 Replace the SCC variable names with names from Topology. Open the SoftPLC application. 42
FASE_Workflow_Descriprion_130130.docx Page: 43 / 51 Import all logic files, which have been generation by FASE. - F20_DEVICE.ST - F20_EXEC_STEP.ST - F20_GLOBAL.POE - F20_HMI.ST - F20_LOGIC.ST - F20_SEQSTEPS_1.ST - F20_SEQSTEPS_2.ST - F20_Types.TYP After importing open each file and click on Check. 43
FASE_Workflow_Descriprion_130130.docx Page: 44 / 51 After that all files should appear in the project folder and can be inserted into the new CFC chart. Create a new CFC chart. 44
FASE_Workflow_Descriprion_130130.docx Page: 45 / 51 Insert the DEVICE.ST block so many times you have nodes in your grid (P1 to P20). E.g. for 20 devices, which are using in your project, you should insert 20 blocks. Give the number to the block (1-20) and connect the information you mapped to the SoftPLC (see picture below). Insert the HMI.ST block and connect it with commands and indications, how it shown in the pictures below. 45
FASE_Workflow_Descriprion_130130.docx Page: 46 / 51 This block receives the commands from SCC to control the modes and switching devices and gives the feedback information back to the SCC. Insert the LOGIC.ST block and connect it with commands and indications, how it shown in the pictures below. 46
FASE_Workflow_Descriprion_130130.docx Page: 47 / 51 This block receives the status of all sources and send commands to the real devices in order to run the defined sequences for isolation, restoration, manually control etc. All other blocks should not be inserted by user and are responsible for internal functionality. Compile the Soft PLC logic and, if no errors or warnings were appeared, close it. Go to Mapping and map commands and information for using it in SCC. Monitoring direction for information from each device 47
FASE_Workflow_Descriprion_130130.docx Page: 48 / 51 Monitoring direction for logical information Command direction for commands to each device 48
FASE_Workflow_Descriprion_130130.docx Page: 49 / 51 Command direction for logical commands 49
FASE_Workflow_Descriprion_130130.docx Page: 50 / 51 In Mapping replace the variable names for the SCC with the topological names. In Configuration export the PXD file for importing in SICAM SCC. 50
FASE_Workflow_Descriprion_130130.docx Page: 51 / 51 4.5. Creation of SICAM SCC project For saving of configuration time you can take the example SCC project for the topology consisting of 20 devices, which has been tested in Nuremberg or only the picture with switching devices and devices information shown below. Create new driver connection to the SICAM PAS and import the PXD file, which you exported in the PAS project. After that adapt the picture to your own topology and check the tag connections for all objects located in the picture. 51