Power System Dynamics and Stability TERM PROJECT In your project prepare a report about the analysis and simulation of the two-machine transmission test system "SVC and PSS (Phasor Model)" that is given as an example in MATLAB/Simscape™ Electrical™: "This example shows the use of the phasor solution for transient stability analysis of multi-machine systems. It analyzes transient stability of a two-machine transmission system with Power System Stabilizers (PSS) and Static Var Compensator (SVC)." 500 kV Transmission System M1 13.8 kV/500 kV 1000 MVA D/Yg line 1 350 km line 2 350 km 500 kV/13.8 kV M2 Yg/D 5000 MVA +4 950 MW B1 ☑ 944 MW B2 B3 4046 MW SVC | 200 Livar 5000 MW https://www.mathworks.com/help/sps/powersys/ug/improve-transient-stability-using-svc-and-pss.html https://www.mathworks.com/help/releases/R2022b/pdf doc/sps/sps ug.pdf To prepare your report follow the instructions below: 1. Begin by thoroughly describing the system. Utilize the User's Guide and corresponding files to tabulate parameters for each component within the system. Define the steady-state condition (default power flow solution and initial values). 2. Given the initial condition, experiment and find the responses of the system to both small and large disturbances. Show and utilize time-domain solutions to explain the outcomes obtained from these experiments. 3. As you change the generator output powers (distribution of load) to supply the same constant load given, repeat the experiments you performed previously and compare. 4. Conduct research on Power System Stabilizers (PSS) and/or Static Var Compensators (SVC) and their potential to enhance system stability and report. Relate these enhancements to your test system and provide commentary on your experimental observations. 5. For the system without PSS and SVC, create mathematical models for each component using the simplest possible representations. Analyze the system's behavior using tools, such as linearization, energy function method, etc. and compare your analysis with simulation results. 6. Optionally, prepare a presentation to share your findings with the class and earn bonus points. M1 13.8e3V 1pu 49.34deg. B1 500e3V 1pu 72.81deg. B1 M1 1000 MVA 1000 MVA L1 350 km 13.8 kV/500 kV Pm SVC Fault Breaker SVC (Phasor Type) Vt Pref 0.95 Preft Turbine & Regulators M1 Generic Multiband o No PSS Phasor 60 Hz powergui PSS PV Measurements B2 B3 500e3V 0.9925pu 24.42deg. M2 13.8e3V 1pu Odeg. M2 5000 MVA B3 500e3V 1.01pu 48.39deg. B2 L2 350 km <Vm (pu <8 (pu)> SVC 5000MVA 13.8 kV/500 kV <фо m Load 5000 MW 0.809094 Pre 2 Prof VT Turbine & Regulators M2 Show comparison Detailed vs Phasor simulation V pos, seq. d theta1 2 81 82 83 (pu) d_theta1 2 (deg) w1 w2 w1w2 (pu) Line power (MW) System V11 V12 stop Machine Signals Show impact of SVC for 3-phase fault V11 V12(pu) Machines STOP Show impact of PSS Stop Simulation for 1-phase fault if loss of synchronism Transient stability of a two-machine transmission system with Power System Stabilizers (PSS) and Static Var Compensator (SVC) ت