ENERGY: MODULAR POWER SYSTEM SIMULATOR. BASIC MODULE

issue:01/11 ENERGY: MODULAR POWER SYSTEM SIMULATOR. BASIC MODULE Ref: 0510 1 / 2 ITEM REFERENCE DESCRIPTION QTY. 1 MPSSC MODULAR POWER SYSTEM SIMULATOR WITH SCADA 1 CONTROL SYSTEM, FORMED BY: SCADA SCADA CONTROL SYSTEM 1 BASB BASIC FRAME 1 EGMG/P GENERATION GROUP 1 AVR/P AUTOMATIC VOLTAGE REGULATOR 1 VVCA/MP AC MOTORS SPEED CONTROLLER 1 TRANS/3A STEP-UP TRANSFORMER 1 TRANS/3B STEP-DOWN TRANSFORMER 1 AE1. TRANSMISSION LINES SIMULATION UNIT 1 AE11 ENERGY CONSUMPTION MODULE 1 BUS01 BUSBAR MODEL 1 (GENERATION) 1 BUS02 BUSBAR MODEL 2 (TRANSPORT) 1 BUS03 BUSBAR MODEL 3 (COUPLING) 1 BUS04 BUSBAR MODEL 4 (CONSUMPTION) 1 BUS05 BUSBAR MODEL 5 (TRANSPORT) 1 ALI01 INDUSTRIAL MAIN POWER SUPPLY. 1 IND05 SYNCHRONISMS MODULE 1 INX20/P GENERATOR PROTECTION MODULE 1 ERP-PGC GENERATORS PROTECTION AND CONTROL DEVICE 1 UNIT ERP-PD. DISTANCE PROTECTION RELAY UNIT 1 ERP-PDF. DIFFERENTIAL PROTECTION RELAY UNIT 1 ERP-MF FAULT INJECTION MODULE 1 2 0510PARTS COMPONENTS AND SPARE PARTS 1 3 0510PA COMPLEMENTARY ITEM 1 4 0510IYPM INSTALLATION AND STARTING-UP 1 5 0510CAPRO TRAINING AND BRINGING UP TO DATE OF TEACHERS 1 6 0510TD TEACHING TECHNIQUES "KNOW-HOW" 1 7 0510MANU DOCUMENTATION AND MANUALS 1

Ref: 0510 2 / 2 Notes: 1) Multipost option: This module has only one unit in each item, but we can recommend the number of units for 10 or 30 students working simultaneously. 2)Supply conditions: a) Technical conditions included: - Laboratories adaptation. - Installation of all units supplied. - Starting up for all units. - Training about the exercises to be done with any unit. - Teacher training related with t and the teaching unit and the teaching techniques uses. - Technology transfer. b) Commercial conditions: - Packing. - Financing charges. - C.I.F. charges. c) Others conditions: - 8 Manuals for each EDIBON teaching unit:. Required services manual.. Assembly and installation manual.. Interface and software/control console manual.. Set in operation manual.. Safety norms manual.. Practices manual.. Maintenance manual.. Calibration manual. See Catalogues in next pages

Technical Teaching Equipment Modular Power System Simulator with SCADA Control System MPSSC SCADA GENERAL DESCRIPTION The MPSSC is a modular Power System Simulator with SCADA Control System, specially designed for Technicians at Technical and Vocational level. The simulator will include the main parts of a Power System as: Generation. Transformation. Transport. Distribution. Consumption. It will include important and key elements that play a very important roll in a Power System control and protection, as: - Automatic voltage regulator. - Automatic frequency control. - All the main protection relays involved. - Automatic and Manual synchronization. The simulator includes the following modules: - SCADA Control System. - BUS05. Busbar model 5 (Transport). - EGMG/P. Generation Group. - BUS03. Busbar model 3 (Coupling). - AVR/P. Automatic Voltage Regulator. - BUS04. Busbar model 4 (Consumption). - VVCA/MP. AC Motors Speed Controller. - ALI01. Power Supply. - TRANS/3A. Step-up Transformer. - IND05. Synchronims Module. - TRANS/3B. Step-down Transformer. - INX20/P. Generator Protection Module. - AE1. Transmission Lines Simulation Unit. - ERP-PGC. Generators Protection and Control Device Unit. - AE11. Energy Consumption Module. - ERP-PD. Distance Protection Relay Unit. - BUS01. Busbar model 1 (Generation). - ERP-PDF. Differential Protection Relay Unit. - BUS02. Busbar model 2 (Transport). - ERP-MF. Fault Injection Module. Worlddidac Member ISO 9000: Quality Management (for Design, Manufacturing, Commercialization and After-sales service) European Union Certificate (total safety) Page 1 Certificates ISO 14000 and ECO-Management and Audit Scheme (environmental management) Worlddidac Quality Charter Certificate (Worlddidac Member)

MODULES IN DETAIL SCADA SCADA Control System Generation Transformation Transport/Lines Consumption EGMG/P. Generation Group TRANS/3A. Step-up Transformer AE1. Transmission Lines Simulation Unit AE11. Energy Consumption Module TRANS/3B. Step-down Transformer AVR/P. Automatic Voltage Regulator VVCA/MP. AC Motors Speed Controller Busbars Control and Protections -ALI01. Power Supply. -BUS02. Busbar model 2 (Transport). -INX20/P. Generator Protection Module. -BUS05. Busbar model 5 (Transport). -IND05. Synchronims Module. -BUS03. Busbar model 3 (Coupling). -BUS01. Busbar model 1 (Generation). -BUS04. Busbar model 4 (Consumption). ERP-PGC. Generators Protection and Control Device Unit ERP-PD. Distance Protection Relay Unit ERP-PDF. Differential Protection Relay Unit Faults ERP-MF. Fault Injection Module Page 2

SCADA Control System SCADA is an industry-standard supervisory control and data acquisition (SCADA) software for realistic experience of power system control. For use with MPSSC Simulator to increase students understanding of power systems. It can connect to multiple generation systems for remote control and supervision of local generation and distributed generation. It includes alarms and logs data for detailed analysis of MPSSC during stable and transient operation. It communicates with programmable logic controllers (PLCs), numerical protection relays, automatic voltage regulators and prime-mover simulation device of the Power System Simulator to control and collect information from the power system. Includes high performance computer with integrated communication interface to exchange information with all devices. Remotely controls the generator and prime-mover of the MPSSC Simulator in different power system operation control methods (frequency control, voltage control, active power control, reactive power control, power factor control, generators load exchange). The SCADA connects to MPSSC to train students in supervision and control of power systems. The package includes industrial-standard SCADA software, a computer, colour printer and communications hardware. EDIBON supplies the software already installed on the computer. The software does several jobs, including remote control and data display and logging. It includes programs written by EDIBON to match experiments which students have done directly with the MPSSC Simulator. The software s on-screen display or user interface shows real-time data and mimics the circuit-breakers (opening and closing). It also mimics the adjustment of the loads and any faults applied by the user. Other screens give details about the settings and data collected at each protection relay or instrument on the simulator. Students select the correct screen for the experiment they want to perform. They then use the computer to close circuit-breakers, set and adjust any loads and connect the grid supply (or start the generator) by mean of touch screens, in others words, they configure the topology of the Simulator. The generators synchronization can be performed in manual and automatic mode with the help of SCADA. Students can use the software to log data from the simulator and analyse it, compare conditions before and after faults, and see the effects of faults. They can use this information to predict power system problems and change the power system protection to prevent future problems. The software includes the experiments already given with the MPSSC Simulator. contiue... Page 3

SCADA Control System (continuation) The experiments include: - Generator characteristics and performance. - Transformers. - Transmission, distribution and consumption. - Power system protection. - Power system operation and control in different modes. - Power flow control. - etc. SCADA allows the control and supervision of the operations related to the generation, transformation, transmission and distribution of the electrical energy made by the MPSSC Simulator. Through a sophisticated human-machine interface, executed in a computer, it is possible to monitor and control a lot of events and alarms as well as analyse, display and control the information acquired from all Programmable Logic Controllers (PLCs), Automatic Voltage Regulators (AVRs), protection relays and prime mover simulation device. SCADA system is connected to the PLCs communication networks, protection relays and the rest of the units of the MPSSC Simulator, allowing the data acquisition and control in real time from all the elements of the MPSSC Simulator. The acquired data are stored for their future analysis or they are directly sent to screens connected to the computer as a visual information. The objective of the SCADA developed architecture is centralising and automating all the control tasks, monitoring, protection and data acquisition of the MPSSC Simulator is operated similar to local or central load dispatch center of Real Electrical Power System. The equipments connected to the SCADA I make one or some of the following functions: 1.- Respond to the commands of the control computer, in order to close or open all the circuit breaker contacts, power isolator and the rest of the equipments that conform the topology of the Power System Simulator. 2.- Transmit to SCADA the ON/OFF state of the electrical equipment that conform the Simulated Electrical Power System. 3.- Vary all the set points of the controlled parameters, for example, the frequency control, active power, reactive power, power factor and voltage control set point. 4.- Measurement and management of all the acquired electrical parameters in different nodes and points of the simulated power system. 5.- Protection of the electrical circuits and the equipments that conform the MPSSC Simulator. SCADA allows making a control, supervision and data acquisition in a centralised and remote way, simulating a central generation dispatch center. With help of SCADA, students can observe the real time state of the electrical equipment of the MPSSC by means of graphical and state screens. With SCADA, the operator of the electrical power system can monitor its state and consequently, it can act and make decisions about how to operate in different conditions. For example, when there is a sound or visual alarm, the operator can see what is happening in a SCADA screen, because the monitoring system includes an alarm sequences and events list of all the equipment operation, recordered throughout the practice period and can done, reports about a determined operation or about the complete practice. Another SCADA facility is that it allows visualise in a central way all the instrumentation of the MPSSC. Simulator through several screens with digital and analogical virtual instruments. In the MPSSC. Simulator, several multifunctional and numeric protection relays are used, because the study of the electrical protections is an essential point for a electrical power system. The protection relays include measurement, communication and programmable logic possibilities to done functions of monitories and control of the equipment that are protecting. Thanks to these facilities, the protection functions are incorporated and managed from SCADA, making the teaching of this subject easier in a automated and centralised way, because the students can communicate with each protection relay and managed it remotely. Page 4

SCADA Control System (continuation) Examples of some possibilities Page 5

ALI01. Power Supply This module has the followings elements: One three-phase power supply output connector. One three-phase power supply output with red, yellow and green connectors. Two single-phase power supply output. One single-phase standard type power supply output. Ground terminal. One security key. One emergency stop switch. Module state indicators. A removable key 6 with two positions (ON and OFF) acts as main switch. EGMG/P. Generation Group This group has the followings elements: 1.One three-phase AC squirrel cage induction motor acting as generation prime mover. 2.One three-phase Synchronous generator with DC field excitation. The induction motor is controlled from the VVCA/MP. AC Motors Speed Controller. INX20/P. Generator Protection Module Page 6

VVCA/MP. AC Motors Speed Controller The VVCA/MP is an AC motor speed regulator. The numerous inputs and outputs allow you to use the VVCA/MP for power supply standard asynchronous ac motor for simulation of prime mover of generation system. Each part of the VVCA/MP is correctly identified in order to facilitate the operation and fast identification. Elements of the AVR/P: Ground protection connector. Three-Phase power output supply connectors. Control enable/disable switch. Remote/Local mode switch. Local control set-point slider. Input/Output ERP-PGC signal connector. Input/Output AVR signal connector. Power supply Switch. The capacity range of VVCA/MP is for 3 ph 400 V supply from 0.4 kw to 7 kw. The overload capacity of VVCA/MP is 150% for 1 min and 200% for 3s (in High Duty mode). The inverters with capacities of 5.5 kw and above can be used in dual rating; this means that the same inverter can be used for next higher capacity (in Low Duty mode). For example a 5.5 kw inverter can be used for a 7.5 kw motor; in this case the overload is 120% for 1 min. The braking transistor is included as standard. The braking resistor is included as standard up to 7.5 kw units. The main features of VVCA/MP are: Safety enables input (compliant to EN954-1 category 3). Built-in EMC filter for all capacities (compliant to EN 61800-3, category C3). Sensorless vector control mode (100% torque at 0 Hz). Advanced PID functions (dancer control). Brake control function. Logic gates for logic combination of input and output functions and delay timer (10steps). Positioning function (when encoder option is used). 3 slots for 3 different options at the same time (encoder, fieldbus, I/O expansion). Removable control terminals (cage clamp type). AVR/P. Automatic Voltage Regulator The AVR/P is an Automatic Voltage Regulator that works in conjunction with the ERP-PGC. Generators Protection and Control Device Unit. The numerous inputs and outputs allow you to use the AVR/P for voltage, reactive power and power factor regulation of generation system. Each part of the AVR/P is correctly identified in order to facilitate the operation and fast identification. Elements of the AVR/P: Ground protection connector. Generator output voltage measurement connectors. Generator Field excitation output supply connectors. Voltage Control enable/disable switch. Remote/Local mode switch. Input/Output signal connector. Local control set-point slider. Serial Port connector( Software HMI is optional product). Power supply Switch. The AVR/P is an automatic voltage regulator of the latest design for synchronous generators and synchronous motors. The unit contains the most advanced microprocessor technology together with IGBT semiconductor technology (Insulated Gate Bipolar Transistor). This advanced-design automatic voltage regulator is used for the excitation of indirectly excited synchronous machines. This unit is only suitable for this one area of application. The regulator can also be switched over to function as a reactive power, power factor and field current regulator. Page 7

TRANS/3A. Step-up Transformer Three-phase power transformer with group connection YyN0, 400/400V, 2kVA, 50-60Hz. This unit simulates the STEP-UP transformer located in the transmission substation. TRANS/3B. Step-down Transformer Three-phase power transformer with group connection YyN0, 400/230V, 2kVA, 50-60Hz. This unit simulates the STEP-DOWN transformer located in the distribution substation. IND05. Synchronims Module This module has the followings elements: Phase Synchronization Lamps. Phase RST sequences test connectors. Page 8

Busbars BUS01. Busbar model 1 (Generation) BUS02. Busbar model 2 (Transport) BUS05. Busbar model 5 (Transport) BUS03. Busbar model 3 (Coupling) BUS04. Busbar model 4 (Consumption) The finality of these modules is to represent the generation, transmission, distribution and subtransmission substations busbars and it included the main commutation elements as power circuit breaker, isolating switches, double busbar. With the aid of these modules is possible to coupling or decoupling all necessary elements of the power system simulator. Basically the busbars modules have similar elements, as: - Input/Outputs double BusBar power connectors. - Single-phase power supply input. - 89L-1 and 89L-2 isolators open/close selectors. - 52L circuit breaker open/close selector. - 89L-3 isolator open/close selector. - Manual/Remote operation enable switch. - Input/Output signals control connector. Page 9

AE1. Transmission Lines Simulation Unit This unit represents basic concepts of the Electric Energy high-voltage three-phase transmission lines operation. It simulates a value modifying concentrated parameter line that allows different configurations and consists on three conductorline (R, S, T) and a Neutral or return line (N). Each of the phases is represented, following the concentrated parameters theoretical model, through a resistance series association and inductance, along with a parallel association between each one of them in a capacitance effect. A way to reduce the earth short circuit current is to have impedance in the neutral-to-ground connections. This impedance has no repercussion in the normal functioning of the network but they introduce a repercussion in the increase of 3x Z (impedance on the zero sequence component), o which reduces the short circuit current. The return line is simulated through small value impedance that has a resistive-indicative characteristic. To simplify the effect, being a despicable inductance, it will be simulated with a pure 10 resistance. The phases have two terminals at the input and two at the output, and they are connected at the interior. Through one of them the module will be supplied. Through the last one the natural circuit will continue to the load module, the bar module, the transformer, etc. The two terminals left en every phase is left for assembly of protection relay or other parallel configurations. The supply of this unit will be done through line terminals (R, S, and T) and the neutral (N) through a 400V three-phase supply and it will be controlled by an interrupter-circuit breaker of 4 poles placed between the supply and the lines module. In the phases we can distinguish different resistance and inductance values, being able to simulate different length transport lines. The resistive part is formed by two resistance values of 15 and 33, with the possibility of making parallel-series connections between them, obtaining two additions resistive values of 10.31 and 48. The inductive part consists on a multistage coil of despicable resistance. In which it is possible to choose one of the following values: 33 mh, 78 mh, 140 mh, 193 mh, 236 mh The capacitive part will be divided into capacitance between conductors and capacitance between line and ground. The capacitance between conductors is simulated with a pair of capacitors at the beginning and at the end of the line with different values: 0.5 F and 1 F for each conductor. The capacitance between conductor and ground is 1 F and 2 F, also at the beginning and at the end of the line. With all this values it is possible to simulate a great number of line configurations, beginning with different line distances with different types of conductor, through the unbalanced lines with different conductors groups (Simplex, Duplex, Triplex and Cuadruplex). At the same time it is possible to simulate transient state with different short-circuits injection using a fault injection module. The unit is protected with a grounding connection that comes from the metallic caging and that is accessible through a terminal in the front of the module. Page 10

AE11. Energy Consumption Module With this module is possible to simulate any proper consumption in the power system or we can test any element of the power system separately under different load conditions. It has differentiated part on resistive, inductive and capacitive zones and it allows all types of combinations between them, so we can simulate pure resistive, inductive and capacitive load as well as different series-parallel combination of them. Metallic box. Diagram in the front panel. Variable resistive loads: 3 x [ 150 (500 W) ]. Fixed resistive loads: 3 x [ 150 (500 W) + 150 (500 W) ]. Inductive loads: 6 x [ 0, 33, 78, 140, 193, 236 mh ].(2 A Max.). Capacitive loads: 3 x [ 3 x 3.5 F ] + 3 x [ 3 x 7 F ] + 3 x [ 3 x 14 F ]. Ground connector. Page 11

ERP-PGC. Generators Protection and Control Device Unit The ERP-PGC is a control unit for engine-generator simulator system. The numerous inputs and outputs, along with a modular software structure, allow you to use the ERP-PGC for a wide range of applications with only a single part number. This includes stand-by, AMF (automatic mains failure), peak shaving, import-export or distributed generation, among others. Also the ERP-PGC is compatible for island, island parallel, mains parallel and multiple unit mains parallel operations. Each part of the ERP-PGC is correctly identified in order to facilitate the operation and fast identification. All the adjustments are executed with the management software from a PC. Elements of the ERP-PGC: Power input/output connectors. Multifunction control and protection device. Generator group control inputs and outputs connector. Generator rotor to ground protection Relay. Isolated operation connector(52gt state and 52G trip command). Functions: Prime mover control. Engine, mains and generator protection. Engine data measurement : Oil pressure and temperature, coolant temperature, battery voltage, speed, service hours, etc. Generator and mains data measurement: Voltage, current, power, kvar, kw, kwh, etc. Load/Var sharing for up to 32 participants. Load-dependent start/stop. Automatic, Manual, and Stop operating modes. Application modes: 1.No CB (Circuit Breaker) operation. 2.Open GCB (Generator Circuit Breaker). 3.Open/close GCB. 4.Open/close GCB/MCB (Generator CB/Main Circuit Breaker). Logics Manager for processing measured values, discrete inputs, and internal states. Engine starter sequencing. Alarm display with circuit breaker trip and engine shutdown. AMF (automatic mains failure) standby genset control, with automatic engine start on mains failure detection and open transition breaker control. Critical mode operation. Synchronizing (phase matching and slip frequency) and mains parallel operation. External frequency, voltage, power, and power factor set point control via analogue input or interface. FIFO (First Input First Output) event history with 300 entries. ECU data visualization via J1939. CAN bus communication to engine controllers, plant management systems, expansion boards, and Toolkit configuration and visualization software. RS-485 Modbus communication with plant management systems. RS-232 Modbus communication with plant management systems. Page 12

ERP-PD. Distance Protection Relay Unit The ERP-PD is a transmission line protection device. The numerous inputs and outputs, along with a modular software structure, allow you to use the ERP-PD for study and analyze the performance of different transmission line protection system. Each part of the ERP-PD is correctly identified in order to facilitate the operation and fast identification. All the adjustments are executed with the management software from a PC. Elements of the ERP-PD: Power input/output connectors. Protection device. Outputs connector for trip command. Functions: Protection:Optimize line protection with a system of sensitive, secure, and dependable three-pole trip relay elements. Monitoring: Simplify fault and system disturbance analyses with event reports and Sequential Events Recorder. Fault Locator: Isolate line problems, and restore service faster. Automation. Remote communications capabilities and elimination of external control elements. ERP-PDF. Differential Protection Relay Unit The ERP-PDF is a differential protection device. The numerous inputs and outputs, along with a modular software structure, allow you to use the ERP-PDF for study and analyze the performance of different differential protection system. Each part of the ERP-PDF is correctly identified in order to facilitate the operation and fast identification. All the adjustments are executed with the management software from a PC. Elements of the ERP-PDF: Power input/output connectors. Protection device. Outputs connector for trip command. Functions: It provides current differential protection plus two complete groups of overcurrent elements in one compact package. The relay measures high- and low-side currents, differential operate and restraint quantities, as well as second and fifth harmonics of the applied currents. The unit provides two optoisolated inputs, four programmable output contacts, and one alarm output contact. This relay can protect two-winding power transformers, reactors, generators, large motors, and other two-terminal power apparatus. The relay settings permit you to use wye or delta connected high- and low-side current transformers. The relay compensates for various equipment and CT connections to derive appropriate differential operating quantities. The ERP-PDF provides three differential elements with dual slope characteristics. The second slope provides security against CT saturation for heavy through faults. Page 13

ERP-MF. Fault Injection Module The fault injection module have the possibility to inject different kind of short-circuits, in any point of the power system simulator including line module, directly or through a pure resistive element. Employing this element we can analyze line performance during transient state as well as analyze the line protection elements functionality. The short-circuit injection possibility are: Three-pole short-circuit. Two-pole short-circuit. Two-pole-ground short-circuit. Single-pole-ground short-circuit. Page 14