Agenda… Slide 3II.. Introduction… Slide 5III.. Overview of EMTPWorks… Slide 19IV.Simulation Options… Slide 64V.. System Modeling… Slide 76VI.Switching Analysis… Slide 127VII.Surge arrest
EMTP-RV 2-Day Training EMTP-RV - 2-Day Training Sommaire I Agenda … Slide II Introduction … Slide III Overview of EMTPWorks … Slide 19 IV.Simulation Options … Slide 64 V System Modeling … Slide 76 VI.Switching Analysis … Slide 127 VII.Surge arresters modeling … Slide 141 EMTP-RV - 2-Day Training Agenda – Day 9:00 am: Introduction 1:30 pm: types of simulations • Powersys • Load-Flow solution • EMTP-RV and EMTPWorks • Steady-state solution 9:30 am: Overview of EMTPWorks 3.5 • Time domain analysis • Graphical Interface • Frequency scan • Creation of a circuit 2:30 pm: Models • Signal • Transformers • Run a simulation ➢ Labs: Transformer Switching Analysis (BCTRAN & Saturation) • ScopeView and MPLOT • Generators • Initialization ➢ Labs: Generators modeling ➢ Labs: Trivial TRV analysis 5:30 pm : End • Subcircuit and Masks ➢ Labs: LLG Fault 12:30 pm/1:30 pm : Lunch break Pauses 10H30 et 15H EMTP-RV - 2-Day Training Agenda – Day 9:00 am: Models 1:30 pm : Surge arresters • Induction machine • IEEE WG model 3.4.11 ➢ Labs: Motor starting ➢ Labs: IEEE MO arrester for fast front transients • Lines/Cables 5:30 pm : End 10:30 am: Statistical analysis ➢ Labs: Single-Phase fault and statistical analysis 12:30 am/1:30 pm : Lunch break Pauses 10H30 et 15H EMTP-RV - 2-Day Training Introduction EMTP-RV - 2-Day Training POWERSYS Solutions for Power Systems Engineering Simulation EMTP-RV - 3-Day Training POWERSYS Solutions POWERSYS ENGINEERING POWERSYS SOFTWARE POWERSYS INNOVATION Engineering Consulting Software Distribution Software Development EMTP-RV - 2-Day Training POWERSYS Engineering Engineering Services Catalog of studies • Transient analysis in Power Systems • FEA analysis of EM equipment POWERSYS ENGINEERING Engineering Consulting Customized Services • Model creation, • DLL, • Scripts realization Sales, Marketing and Promotion Worldwide EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide POWERSYS Software Engineering Simulation Software Power Systems Transients POWERSYS SOFTWARE Software Distribution Electromechanical Design Power Electronics & Drive Power System Analysis Sales, Marketing, Promotion and Events Worldwide Technical Support Training EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide POWERSYS Innovation Software development Product lifecycle management Road-map management & software development • EMTP-RV Software • PEMBA Software POWERSYS INNOVATION Software Development Tailored development • On demand specific developments EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide 10 emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide MPLOT MPLOT Matlab Based Application (no need to have Matlab to run it) Quick Way to display your results Compatible with Statistic analysis • Plot : All the curves on one figure • Subplot : A figure pear curves EMTP-RV - 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2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide 144 emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide Surge arresters modeling IEEE Working Group model 3.4.11 The “per-unit” V-I curves of A0 and A1 are given and must be adapted to the actual arrester (the “ZNO data function” of EMTP-RV does that automatically) The procedure proposed by the IEEE working group to determine all parameters can be summarized as follows: ➢ Determine the linear parameters (L0, R0, L1, R1, and C) and derive A0 and A1 ➢ Adjust A0 and A1 to match the switching surge discharge voltage ➢ Adjust L1 to match the lightning surge discharge voltage (8/20us) Source: Power System Transients – Parameter Determination edited by Juan A Martinez-Velasco EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide 145 emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide Labs: Arrester modeling Use the surge arrester model for fast front surges developed by the IEEE Working Group 3.4.11 on Surge Arrester described in the previous section to model an arrester The arrester datasheet indicates that: ➢ the height of the arrester is 3901 mm (d) ➢ the number of parallel columns of MO disks is (n) ➢ the maximum continuous operating voltage (MCOV) is 318kV ➢ the maximum switching surge discharge voltage 2kA 45µs is 809kV ➢ the maximum discharge voltage using an 8/20µs 10kA is 922kV EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide 146 emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide Labs: Arrester modeling Use the previously given formulas to calculate the linear parameters of the model (L0, R0, L1, R1, C0) Device Values of linear parameters L0 0.780 µH L1 58.5 µH R0 390 Ω R1 253.5 Ω C0 25.6 pF Figure: IEEE MO surge arrester for fast front transients EMTP-RV - 2-Day Training emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide 147 emtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slideemtp.rv.training.slide Labs: Arrester modeling • • Use the ZnO Data Function of EMTP-RV to derive A0 and A1 Use the pre-defined table and set the desired voltage rating to the 8/20μs -10kA residual voltage of the arrester (922kV) to generate the V-I curves of A0 and A1 + ZnO ZnO Data function 100kV ZnO1 EMTP-RV - 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