Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads
This paper investigates the interaction between two Static var Compensators (SVCs) to verify dynamic grid voltage support is maintained and that the SVC controllers do not negatively interact with each other. For this purpose, the controls of the SVCs with all of the remotely controlled Mechanically...
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2020
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oai:doaj.org-article:5c28fe291d6b4d7cba206a4870ae7eec2021-11-19T00:07:17ZHardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads2687-791010.1109/OAJPE.2020.3013803https://doaj.org/article/5c28fe291d6b4d7cba206a4870ae7eec2020-01-01T00:00:00Zhttps://ieeexplore.ieee.org/document/9154415/https://doaj.org/toc/2687-7910This paper investigates the interaction between two Static var Compensators (SVCs) to verify dynamic grid voltage support is maintained and that the SVC controllers do not negatively interact with each other. For this purpose, the controls of the SVCs with all of the remotely controlled Mechanically-Switched Capacitors (MSCs) have been tested in a closed-loop real-time simulator environment using SVC replicas (physical controllers) of the actual field installations. To accurately capture the power system’s response to phenomenon such as potential Fault Induced Delayed Voltage Recovery (FIDVR), the dynamics of the generators and the motor loads are modeled in the simulations. A hybrid model consisting of real and reactive power (P-Q) loads and aggregated motor load of a single-phase induction motor suitable for three-phase time-domain simulation was developed and connected to the power system. The developed aggregate motor load model includes details such as the main winding, auxiliary winding, starting capacitor, motor inertia, and distribution transformers. It is observed that dynamic grid voltage support can be maintained and the SVC controllers do not negatively interact with each other if all the SVC control blocks are enabled and function normally.Bikrant PoudelEbrahim AmiriJayanth R. RamamurthyIttiphong LeevongwatThomas E. FieldRastin RastgoufardParviz RastgoufardIEEEarticleAggregate motor modelFACTSFIDVRhardware-in-the-loopsingle-phase induction motorSVCDistribution or transmission of electric powerTK3001-3521Production of electric energy or power. Powerplants. Central stationsTK1001-1841ENIEEE Open Access Journal of Power and Energy, Vol 7, Pp 307-319 (2020) |
| institution |
DOAJ |
| collection |
DOAJ |
| language |
EN |
| topic |
Aggregate motor model FACTS FIDVR hardware-in-the-loop single-phase induction motor SVC Distribution or transmission of electric power TK3001-3521 Production of electric energy or power. Powerplants. Central stations TK1001-1841 |
| spellingShingle |
Aggregate motor model FACTS FIDVR hardware-in-the-loop single-phase induction motor SVC Distribution or transmission of electric power TK3001-3521 Production of electric energy or power. Powerplants. Central stations TK1001-1841 Bikrant Poudel Ebrahim Amiri Jayanth R. Ramamurthy Ittiphong Leevongwat Thomas E. Field Rastin Rastgoufard Parviz Rastgoufard Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| description |
This paper investigates the interaction between two Static var Compensators (SVCs) to verify dynamic grid voltage support is maintained and that the SVC controllers do not negatively interact with each other. For this purpose, the controls of the SVCs with all of the remotely controlled Mechanically-Switched Capacitors (MSCs) have been tested in a closed-loop real-time simulator environment using SVC replicas (physical controllers) of the actual field installations. To accurately capture the power system’s response to phenomenon such as potential Fault Induced Delayed Voltage Recovery (FIDVR), the dynamics of the generators and the motor loads are modeled in the simulations. A hybrid model consisting of real and reactive power (P-Q) loads and aggregated motor load of a single-phase induction motor suitable for three-phase time-domain simulation was developed and connected to the power system. The developed aggregate motor load model includes details such as the main winding, auxiliary winding, starting capacitor, motor inertia, and distribution transformers. It is observed that dynamic grid voltage support can be maintained and the SVC controllers do not negatively interact with each other if all the SVC control blocks are enabled and function normally. |
| format |
article |
| author |
Bikrant Poudel Ebrahim Amiri Jayanth R. Ramamurthy Ittiphong Leevongwat Thomas E. Field Rastin Rastgoufard Parviz Rastgoufard |
| author_facet |
Bikrant Poudel Ebrahim Amiri Jayanth R. Ramamurthy Ittiphong Leevongwat Thomas E. Field Rastin Rastgoufard Parviz Rastgoufard |
| author_sort |
Bikrant Poudel |
| title |
Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| title_short |
Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| title_full |
Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| title_fullStr |
Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| title_full_unstemmed |
Hardware-in-the-Loop Testing of Dynamic Grid Voltages for Static Var Compensator Controllers With Single-Phase Induction Motor Loads |
| title_sort |
hardware-in-the-loop testing of dynamic grid voltages for static var compensator controllers with single-phase induction motor loads |
| publisher |
IEEE |
| publishDate |
2020 |
| url |
https://doaj.org/article/5c28fe291d6b4d7cba206a4870ae7eec |
| work_keys_str_mv |
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| _version_ |
1718420611049455616 |