simpow integrated in neplan
Post on 17-Dec-2016
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
SIMPOW integrated in NEPLAN
BCP (Busarello+Cott+Partner Inc.) and STRI have integrated the Simpow dynamic analysis modules in the NEPLAN planning and optimization software. Simpow users are now profiting from one of the best planning and optimization software, which provides an advanced graphical interface and the possibility to expand the program package with a lot of different calculation modules such as relay selectivity analysis, reliability analysis and optimal maintenance planning, see the list of modules below. The new integrated version of Simpow in NEPLAN is available from September 2005. The combined package is one of the most complete power system planning and optimization tools on the market. BCP and STRI are also collaborating with support, marketing and sales of their respective software. For further information, please contact BCP or STRI.
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Modules included in NEPLAN:
• Graphical Database Editor
• Load Flow • Short Circuit
• Motor Starting
• Overcurrent Protection (Selectivity Analysis) • Distance Protection
• Arc Flash Calculation • Harmonic Analysis
• Optimal Separation Points and Network re-supply
• Load Profile Time Simulation
• Optimization of Distribution Networks • Optimal Capacitor Placement
• Network Reduction • Optimal Power Flow
• Simpow Phasor Mode (Transient Stability)
• Simpow Instantaneous value Mode (EMT Simulation)
• Simpow DSL for Primary Components • Simpow Linear Analysis, phasor mode
• Simpow Linear Analysis, instantaneous value mode
• Simpow DSL Basic and Commands • Voltage Stability
• Available Transfer Capability Analysis (ATC)
• Cable Sizing (requires modules LF+SC+OCP) • Investment Analysis
• Fault Finding • SQL Database Driver
• SQL Database Converter
• Interface to SCADA and GIS systems • PSS/E – Import/Export
• UCTE Interface
• Reliability Analysis • Optimal Maintenance Planning
Below, see some examples from the integrated version of NEPLAN/Simpow.
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Single line diagram of an HVDC system Dialog for the predefined HVDC controllers
VVIK02VVIKP=139.673 MWQ=41.935 Mvar
I=0.548 kAPloss=3.601 MW
Qloss=35.559 Mvar
T1Tap=0
T2Tap=0
ShuntP=0.000 MW
GVVIKP=-139.673 MWQ=-41.935 Mvar
VVIK0135 kV
u=113.85 %Uang=0.00 °
G14P=0.895 MW
Q=-18.922 MvarG12
P=0.000 MWQ=-15.000 Mvar
P=-135.168 MWQ=0.000 Mvar
I=0.900 kAPloss=0.903 MW
Qloss=64.846 Mvar
P=133.143 MWQ=0.000 Mvar
I=0.900 kAPloss=0.903 MW
Qloss=47.863 Mvar
DCLine1P=135.168 MW
I=0.900 kAPloss=1.013 MW
DCLine2P=134.155 MW
I=0.900 kAPloss=1.012 MW
P=0.000 MWQ=15.000 Mvar
I=0.684 kAPloss=0.015 MW
Qloss=0.308 Mvar
P=0.015 MWQ=-14.692 Mvar
I=0.113 kAPloss=0.015 MW
Qloss=0.308 Mvar
P=-0.895 MWQ=18.922 Mvar
I=0.773 kAPloss=0.024 MW
Qloss=0.486 Mvar
NG1415.2 kV
u=93.14 %Uang=0.00 °
P=0.919 MWQ=-18.435 Mvar
I=0.142 kAPloss=0.024 MW
Qloss=0.486 Mvar
NG1213.8 kV
u=91.70 %Uang=0.09 °
LoadYP=131.304 MWQ=0.000 Mvar
VVIK1P=0.000 MW
Q=-37.437 Mvar
VVIK2P=0.000 MW
Q=-39.925 Mvar
YGNE1P=0.000 MW
Q=-15.488 Mvar
YGNE2P=0.000 MW
Q=-18.086 Mvar
CFC_VVIK CCA_VVIK CFC_YGNE CCA_YGNEMC_VVIKCOL_VVIK COL_YGNE
WikFir.=24.26 degRatio=0.000
Cntrl=
YngedFir.=145.35 degRatio=0.000
Cntrl=
GDC1150 kV
u=100.12 %
GDC2150 kV
u=99.37 %
DC-75898P=0.001 MW
Q=0.000 Mvar DC-75911P=0.001 MW
Q=0.000 Mvar
P=-0.001 MWQ=0.000 Mvar
I=0.900 kAPloss=0.903 MW
Qloss=47.863 Mvar
TUR-33777
TUR-33781
Exiter-33776
TR2_YGNETap=1
P=-132.239 MWQ=66.701 Mvar
I=1.141 kAPloss=0.000 MW
Qloss=18.838 Mvar
YGNE75 kV
u=99.96 %Uang=0.15 °
P=132.239 MWQ=-47.863 Mvar
I=0.699 kAPloss=0.000 MW
Qloss=18.838 Mvar
P=136.072 MWQ=64.846 Mvar
I=0.700 kAPloss=0.903 MW
Qloss=64.846 Mvar
TR2_VVIKTap=0
P=-132.239 MWQ=47.863 Mvar
I=0.699 kAPloss=0.903 MW
Qloss=47.863 Mvar
P=-136.072 MWQ=-64.846 Mvar
I=0.700 kAPloss=0.000 MW
Qloss=18.892 Mvar
VVG2AC123.9 kV
u=100.33 %Uang=-20.16 °
P=136.072 MWQ=83.738 Mvar
I=0.643 kAPloss=0.000 MW
Qloss=18.892 Mvar
VVIK135 kV
u=106.35 %Uang=-14.03 °
YGG2AC123.9 kV
u=93.74 %Uang=7.02 °
GDC_E2150 kV
u=0.00 %
GDC3150 kV
u=98.62 %
P=-0.001 MWQ=0.000 Mvar
I=0.900 kAPloss=0.903 MW
Qloss=64.846 Mvar
GDC_E1150 kV
u=-0.00 %
Gov-76506
Gov-795070
HVDC Control System
Turbine and Exiter
Rectifier Inverter
Rectifier Inverter
HVDC-Example designed by STRI (Sweden) and BCP (Switzerland)
Master
Turbine and Governor
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Results of the above HVDC simulation Results displayed in the NEPLAN chart manager
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
NEPLAN single line diagram of the SSR IEEE Benchmark NEPLAN Dialog for the Exciter and the Inertia of the Turbine.
BUSGENP=-720.0 MWQ=-52.6 Mvar
TRAFTap=0
BUSCBUSAP=709.4 MWQ=-321.0 Mvar
RLC
P=709.4 MWQ=-321.0 Mvar
BUSC500 kV
U=539.3 kVUang=-13.21 °
BUSFBUSBP=0.0 MWQ=0.0 Mvar
BUSF500 kV
U=495.9 kVUang=2.75 °
P=-708.3 MWQ=104.5 Mvar
BUSGEN12 kV
U=12.0 kVUang=15.32 °
P=720.0 MWQ=52.6 Mvar
BUSA500 kV
U=499.1 kVUang=8.82 °
P=-720.0 MWQ=29.1 Mvar
INFP=708.3 MW
Q=-104.5 Mvar
INERTIA-Turbine
INERTIA-ExciterBUSB500 kV
U=495.9 kVUang=2.75 °
Subsynchronous Resonance IEEE Benchmark designed by STRI (Sweden) and BCP (Switerland)
EMT Simulation
Turbine and Inertia
Exciter and Inertia
RLC-Element
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Results of the SSR IEEE Benchmark of the simulation in Simpow EMT Simulation mode. FFT (Fast Fourier Transformation) of the above SSR Result Curve
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
NEPLAN Block Diagram of an user defined Exciter and Simpow DSL Language NEPLAN Dialog for the Simpow Simulation Parameters
IF(START.AND.(.NOT.START0).AND.IDC.EQ/0./.0.)THEN IF(DI.EQ/0./.0.)THEN UCR=UPRE(NODE1) UCI=UPIM(NODE1) UC=SQRT(UCR0**2+UCI0**2) UDIO0=FACY*UC FAC=(U(NODE2)-U(NODE3))/UDIO0 IF(1.-FAC*FAC.LE.0.)THEN FAC1=0. ELSE
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Overcurrent protection example designed by BCP (Switzerland )
Selectivity diagram
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STRI AB Box 707 SE-771 80 LUDVIKA Sweden
Business address: Lyviksvägen 8
SE-771 31 LUDVIKA Sweden
Reg.No/VAT SE556314-821101Phone +46(0)240 – 795 00
Fax +46(0)240 – 150 29www.stri.se info@stri.se
Reliability example designed by BCP (Switzerland )
Frequency and probability of supply interruptions.
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