ELECTRIC SHIP TECHNOLOGY SYMPOSIUM EXPERIMENTAL TESTBED TO DE-RISK THE NAVY ADVANCED DEVELOPMENT MODEL Shannon Strank Center for Electromechanics The University of Texas at Austin 8/16/2017
CEM Microgrid Facilities: Spin Test Bunker Turbine Test Cell High Bay Low Lab Screen Room - EMI Shielded
Sources Utility Connections: 480 Volt, 3 Phase 1000 A 480 Volt, 3 Phase 400 A 2 Additional Medium Voltage Services can be made available at 4160 Volt Diesel Generator can connect directly to transformer HFAC Distribution allows for high speed and frequency generators driven by turbine prime movers
Loads Electromagnetic Rail Gun 5 MW Dynamometer 2 MW Induction Motor 1.3 MW Resistive Load Bank 3 250 KW Resistive Load Banks
Energy Storage Capacitors Rotating Machines Composite FWs/ Various Sizes
Power Electronics 10 Semikron 1.6 MVA 3 Phase Full Bridge Power Converters 3 Semikron 30 kva 3 Phase Full Bridge Power Converters Semikron 250 kva 3 Phase Full Bridge Power Converter 2 MW Passive Rectifier 2 MW SCR Active Rectifier 1 MW Variable Frequency Drive 250 kw Variable Frequency Drive 2 MW ARCP 3 Phase Full Bridge Power Converter with Chopper
Controls Opal RT Real Time Simulator / NI FPGA Stack 5 National Instruments PXI Controllers 12 National Instruments Single Boards RIOs 8 National Instruments Compact RIOs 2 National Instruments Compact Fieldpoint Controllers
Power Electronic Building Block (PEBB) Semikron Power Module and sbrio controller AC DC Passive or active rectifier (battery charger) DC AC Inverter (Solar power) DC DC Buck or Boost (Step up or Step down voltage) AC-DC-AC Four quadrant Power Convertor (Variable Frequency Drive)
Real-Time Simulator Opal RT OP 5600 Real Time Simulator 2 six-core Intel Xeon 3.46 GHz processors Xilinx Virtex-6 FPGA Solvers emegasim and efpgasim ehs by Opal-RT 16 analog inputs OP-5340 16 analog outputs OP-5330 32 digital inputs OP-5353 32 digital outputs OP-5360-2 Spectracom TSync-PCIe Precision Time Code Synch 6 Gigabit Ethernet ports IEC 61850 GOOSE IEC 61850 Sample Value Additional NI/Opal-RT Hardware 12 Processor cores 11 Xilinx Kintex-7 FPGAs 48 analog inputs 96 analog outputs 108 digital inputs / Outputs 3 Gigabit Ethernet ports 4 SFP+ High speed serial ports
3 Zone ADM Setup
Reduced ADM Setup
Reduced ADM Setup Low Lab PGM 480 V Source 2 AC AC Breaker 2 400A 480:808 V 490 kva AC AC Breaker 5 Semikron Controlled DC-DC Rectifier (808 Vac 1120 Vdc) DC 1.3 MW Load ALPS Chopper DC Disconnect 1 Semikron DC-DC Loads Low Lab UT-CEM capacitor-based Pulse Forming Network and EM Gun Existing DC Power Supply 0.69:13.5 kv Semikron Charge Controller Rectifier 1.7 MVA Capacitor 400 ka Bank(s) High Bay Switch Rail Gun 480 V Source 1 AC AC Breaker 1 1200 A 480:808 V 1.2 MVA Bunker PGM AC Toshiba AC Breaker3 ALPS Diode Rectifier (808 Vac 1120 Vdc) DC DC Disconnect 2 Bunker Toshiba Diode Rectifier 1 MW Toshiba (Motor Drive) M 2 MW Motor Propulsion Load D 5 MW Dynamometer
Fault Testing PMM M 1.1 kv 2 MW 200 Hz 3 NC PROPULSON LOAD Toshiba 1 & 4 NC = Normally closed CL = Current Limit 1 = Capacitor 2 = Mechanical Circuit Breakers 3 = Contactors 4 = Line Reactor 3 1.15 kv main dc bus 2 2 NC NC 850 V, 0.8 MW 60 Hz, 3-phase Lab Power CL = = PGM CL = = 1 & 4 NC NC PGM 850 V, 1.2 MW 60 Hz, 3-phase Lab Power 3 3 3 NC NC Equivalent DC zonal Load PCM MISSION LOAD PFN Railgun
Fault Simulation AC source and rectifier FCL controller Inductor 1 Line Reactor Contactor DC Breaker PGM 1 i 1 + - i 3 Current sensor Voltage sensor Differential Protection Zone for main dc bus PGM 2 i 2 + - i 4 AC source and rectifier FCL controller Inductor 1 Line Reactor Contactor DC Breaker
SLD of MATLAB/Simulink Model PGM 1 Reactor 1 CB1 = = 0.39 mh 0.39 mh 950 V 60 Hz 3-Ph ac 5 mf 0.5 mf Load 1 0.6 MW 80 µh 9 mω 1 MW Load 2 80 µh PGM 2 Reactor 2 9 mω 950 V 60 Hz 3-Ph ac = = 5 mf 0.39 mh 0.39 mh 0.5 mf Main CB2 dc bus 1150 V dc
Simulation Results #1
Simulation Results #2
PHIL Generator Emulation PXIe Real-Time/ FPGA HIL System Switching devices in NI PXI simulator Simulated generation unit Engine thermal dynamics Generator electromagnetic transients Accessory loads Electromechanical dynamics Generator 3-ph voltage signals Communication (50 us) DC bus voltage Switching control signals DC bus current PGM Controller Generator 3-ph current signals Current & voltage measurements Control set-points Speed, voltage and current measurements Opal-RT Simulator PHIL emulator for a MW-generation unit switching control ~ 3-ph ac source Power amplifier Voltage/current measurement Main dc bus (1.15 kv) AC/DC power converter CEM hardware dc microgrid
PHIL PCM1-A Emulation 2 1.15 kv dc 2 3 3 3 3 3 Simulated PCM1-A PGM = = 1 & 4 850 V, 1.2 MW 60 Hz, 3-Ph ac OPAL-RT simulator 1.1 kv 2 MW 200 Hz M PCM PFN 60 Hz AC Distribution 60 Hz AC Distribution 1 = Capacitor 2 = DC Breakers 3 = Contactors 4 = Line Reactor Toshiba PMM PROPULSON LOAD = = 1 & 4 PGM Railgun MISSION LOAD 60 Hz Loads = = PCM1-A = = 1.15 kvdc/ 1.0 kvdc 3 850 V, 0.8 MW 60 Hz, 3-Ph ac 3 3 1.15 kv dc
Summary CONCLUSIONS Pulsed load (EMRG) Integration was successful Hybrid DC protection approach combining converter FCL and differential protection was illustrated in numerical simulation. PHIL simulation with the Opal-RT MRTS platform was introduced to emulate a variety of sources and power converters to argument the capability of the subscale ADM system. FUTURE WORK Conduct hardware test for the dc fault protection on subscale ADM configuration. Demonstrate multiple charge and discharge cycles of the pulsed load and integrate hybrid energy storage in the dc microgrid