Dynamic Response Verification of Vector Controlled Induction Machines for Hydropower Emulation

Bidur Poudel; Mayank Panwar; Rob Hovsapian

doi:10.1109/KPEC61529.2024.10676231

Dynamic Response Verification of Vector Controlled Induction Machines for Hydropower Emulation

Bidur Poudel, Mayank Panwar, Rob Hovsapian

Research output: Contribution to conference › Paper

3 Scopus Citations

Abstract

Hydropower emulation aims to replicate the dynamics of a hydropower plant in a laboratory environment. It utilizes two direct-coupled induction machines driven by variable frequency drives (VFD) for mimicking the hydro-turbine and hydro-generator. VFD control parameter tuning is essential for the robust performance of the emulation setup. Detuning can result in a degradation of both steady-state and transient dynamics. This paper utilizes simulation-based verification of the impacts on dynamic response due to detuning. Specifically, we study the impact of temperature change on induction machine parameters and resulting dynamics when using indirect field-oriented control (IFOC). The results demonstrate that IFOC does not require parameter tuning in the presence of slower changes in hydro shaft dynamics. However, when the dynamics change rapidly, the performance deteriorates and requires compensation for acceptable performance.

Original language	American English
Number of pages	5
DOIs	https://doi.org/10.1109/KPEC61529.2024.10676231
State	Published - 2024
Event	2024 IEEE Kansas Power and Energy Conference - Manhattan, Kansas Duration: 25 Apr 2024 → 26 Apr 2024

Conference

Conference	2024 IEEE Kansas Power and Energy Conference
City	Manhattan, Kansas
Period	25/04/24 → 26/04/24

NREL Publication Number

NREL/CP-5D00-89157

Keywords

hydropower emulation
indirect field-oriented control
induction machine
thermal behavior

Access to Document

10.1109/KPEC61529.2024.10676231

Cite this

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title = "Dynamic Response Verification of Vector Controlled Induction Machines for Hydropower Emulation",

abstract = "Hydropower emulation aims to replicate the dynamics of a hydropower plant in a laboratory environment. It utilizes two direct-coupled induction machines driven by variable frequency drives (VFD) for mimicking the hydro-turbine and hydro-generator. VFD control parameter tuning is essential for the robust performance of the emulation setup. Detuning can result in a degradation of both steady-state and transient dynamics. This paper utilizes simulation-based verification of the impacts on dynamic response due to detuning. Specifically, we study the impact of temperature change on induction machine parameters and resulting dynamics when using indirect field-oriented control (IFOC). The results demonstrate that IFOC does not require parameter tuning in the presence of slower changes in hydro shaft dynamics. However, when the dynamics change rapidly, the performance deteriorates and requires compensation for acceptable performance.",

keywords = "hydropower emulation, indirect field-oriented control, induction machine, thermal behavior",

author = "Bidur Poudel and Mayank Panwar and Rob Hovsapian",

year = "2024",

doi = "10.1109/KPEC61529.2024.10676231",

language = "American English",

note = "2024 IEEE Kansas Power and Energy Conference ; Conference date: 25-04-2024 Through 26-04-2024",

}

TY - CONF

T1 - Dynamic Response Verification of Vector Controlled Induction Machines for Hydropower Emulation

AU - Poudel, Bidur

AU - Panwar, Mayank

AU - Hovsapian, Rob

PY - 2024

Y1 - 2024

N2 - Hydropower emulation aims to replicate the dynamics of a hydropower plant in a laboratory environment. It utilizes two direct-coupled induction machines driven by variable frequency drives (VFD) for mimicking the hydro-turbine and hydro-generator. VFD control parameter tuning is essential for the robust performance of the emulation setup. Detuning can result in a degradation of both steady-state and transient dynamics. This paper utilizes simulation-based verification of the impacts on dynamic response due to detuning. Specifically, we study the impact of temperature change on induction machine parameters and resulting dynamics when using indirect field-oriented control (IFOC). The results demonstrate that IFOC does not require parameter tuning in the presence of slower changes in hydro shaft dynamics. However, when the dynamics change rapidly, the performance deteriorates and requires compensation for acceptable performance.

AB - Hydropower emulation aims to replicate the dynamics of a hydropower plant in a laboratory environment. It utilizes two direct-coupled induction machines driven by variable frequency drives (VFD) for mimicking the hydro-turbine and hydro-generator. VFD control parameter tuning is essential for the robust performance of the emulation setup. Detuning can result in a degradation of both steady-state and transient dynamics. This paper utilizes simulation-based verification of the impacts on dynamic response due to detuning. Specifically, we study the impact of temperature change on induction machine parameters and resulting dynamics when using indirect field-oriented control (IFOC). The results demonstrate that IFOC does not require parameter tuning in the presence of slower changes in hydro shaft dynamics. However, when the dynamics change rapidly, the performance deteriorates and requires compensation for acceptable performance.

KW - hydropower emulation

KW - indirect field-oriented control

KW - induction machine

KW - thermal behavior

U2 - 10.1109/KPEC61529.2024.10676231

DO - 10.1109/KPEC61529.2024.10676231

M3 - Paper

T2 - 2024 IEEE Kansas Power and Energy Conference

Y2 - 25 April 2024 through 26 April 2024

ER -

Dynamic Response Verification of Vector Controlled Induction Machines for Hydropower Emulation

Abstract

Conference

NREL Publication Number

Keywords

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