Simulation of Wind-solar Complementary Distribution Power Generation System Based on PSCAD

Authors

  • Yangbing Zheng 1College of Mechanical and Electronic Engineering, Nanyang Normal University, Nanyang 473061, Henan, China 2Qinghai Wandong Ecological Environment Development Co.LTD, Geermu 816000, Qinghai, China
  • Xiao Xue School of Electronic and Electrical Engineering, Nanyang Institute of Technology, Nanyang 474304, Henan, China

DOI:

https://doi.org/10.13052/dgaej2156-3306.3523

Keywords:

Wind power generation, photovoltaic power generation, wind- solar complementary, PSCAD (power system computer aided design), distri- bution power generation.

Abstract

Toward to the situation that the overall model and simulation research of
complementary power generation system is less recently, a new structure
model of the wind-solar complementary distribution power generation sys-
tem is proposed. According to the models of wind power generation and
photovoltaic power generation, the PSCAD is used for building a three-phase
photovoltaic grid-connected power generation system. Through the model,
the systm performance is analyzed, and the correctness of the developed
control element and the usability of the engineering simulation analysis are
verified.

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Author Biographies

Yangbing Zheng, 1College of Mechanical and Electronic Engineering, Nanyang Normal University, Nanyang 473061, Henan, China 2Qinghai Wandong Ecological Environment Development Co.LTD, Geermu 816000, Qinghai, China

Yangbing Zheng, Associate Professor of control science and engineering,
with Nanyang Normal University, Nanyang, China. She received her Bach-
elor of Engineering Science in Electronic Information Engineering from
Nanyang Institute of Technology, Henan, China, in 2006; and the Doctor
Degree of Engineering in detection technology and automatic equipment
from China University of Mining and Technology, Beijing, China, in 2013,
respectively. Her current research interests include active robot control, and
nonlinear control.

Xiao Xue, School of Electronic and Electrical Engineering, Nanyang Institute of Technology, Nanyang 474304, Henan, China

Xiao Xue, Associate Professor of School of Electronic and Electrical Engi-
neering in Nanyang Institute of Technology, Nanyang, China. He received
his Bachelor of Engineering Science in Electronic Information Engineering
from Nanyang Institute of Technology, Henan, China, in 2003; the Doctor
Degree of Engineering in detection technology and automatic equipment
from China University of Geosciences, Wuhan, China, in 2015. His current
research interests include Detection technology, and intelligent control

References

A.B. Oskouei, M.R. Banaei, M. Sabahi. (2016). Hybrid PV/wind system

with quinary asymmetric inverter without increasing DC-link number.

Ain Shams Engineering Journal, 7, 579–592.

Ayas Shaqoura, Hooman Farzanehab, Yuichiro Yoshidaa, Tatsuya

Hinokuma. (2020). Power control and simulation of a building inte-

grated stand-alone hybrid PV-wind-battery system in Kasuga City,

Japan. Energy Reports, 6, 1528–1544.

A. Parida, D. Chatterjee. (2016), An improved control scheme for grid

connected doubly fed induction generator considering wind-solar hybrid

system. International Journal of Electrical Power & Energy Systems, 77,

–122.

A.T. Bektimirov, K.K. Tokhtibakiyev, A.A. Saukhimov, N.N. Nurtaza.

(2019). Analysis of the Kazakhstan’s Grid Oscillation Instability by

using Wams System and PSCAD Program. 2019 54th International

Universities Power Engineering Conference (UPEC).

Simulation of Wind-solar Complementary Distribution 147

Calise F., Accadia M.D., Libertini L., Vicidomini M. (2018). Thermoe-

conomic analysis of an integrated solar combined cycle power plant.

Energy Conversion and Management, 171, 1038–1051.

Dahbi A., Nait-Said N., Nait-Said M.S. (2016). A novel combined

MPPT-pitch angle control for wide range variable speed wind turbine

based on neural network. International Journal of Hydrogen Energy,

(22): 9427–9442.

Ding Zeyu, Hou Hongjuan, Yu Gang. (2019). Performance analysis of

a wind-solar hybrid power generation system. Energy Conversion and

Management, 181:223–234.

Eel-Hwan Kim, Jae-Hong Kim, Se-Ho Kim, Jaeho Choi, Kwang Y. Lee,

Ho-Chan Kim. (2011). Impact Analysis of Wind Farms in the Jeju Island

Power System. IEEE Systems Journal, 6(1):134–139.

Giancarlo Aquila,Anderson Rodrigo De Queiroz,Luana Medeiros

Marangon Lima,Pedro Paulo Balestrassi,Edson de Oliveira Pamplona.

(2020). Modeling and Design of Wind-Solar Hybrid Generation

Projects in Long-term Energy Auctions: A Multi-objective Optimization

Approach. IET Renewable Power Generation, 1:17–19.

H.R. Fallah Kohan, F. Lotfipour, M. Eslami. (2018). Numerical simula-

tion of a photovoltaic thermoelectric hybrid power generation system.

Solar Engery, 174:537–548.

Jana K., Ray A., Majoumerd M.M., Assadi M., De S. (2017). Polygen-

eration as a future sustainable energy solution-A comprehensive review.

Applied Energy, 202: 88–111.

Kong Libo, Cui Lilun, Ding Zhao, et al. (2015). Short term power

prediction based on hybrid wind-PV forecasting model. Power System

Protection and Control, (18): 62–66.

M. Chen, D. Fan, H. Fang, Y. Zhu, and P. Chen. (2017). Control strategy

of excitation converter in Doubly-Fed Induction Generator wind power

generation system. IEEE Conference on Energy Internet and Energy

System Integration (EI2), 1–5.

M. Izadbakhsh, A. Rezvani, M. Gandomkar. (2015). Dynamic response

improvement of hybrid system by implementing ANN-GA for fast vari-

ation of photovoltaic irradiation and FLC for wind turbine. Archives of

Electrical Engineering, 64: 291–314.

Omprakash Ramalingam Rethnam, Sivakumar Palaniappan. (2020).

Velmurugan Ashokkumar Life cycle cost analysis of 1 MW power

generation using roof-top solar PV panels. Built environment project and

asset management, 1(10):24–139.

Y. Zheng and X. Xue

Onol A.O., Yesilyurt S. (2017). Effects of wind gusts on a vertical

axjs wind turbine with high solidity. Journal of Wind Engineering &

Industrial Aerodynamics, 162(3): 1–11.

Rong A., Lahdelma R. (2016). Role of polygeneration in sustainable

energy system development challenges and opportunities from opti-

mization viewpoints. Renewable and Sustainable Energy Reviews, 53:

–372.

Su Shaoze, Yang Honggeng, Wu Chuanlai. (2015). A single-phase grid-

connected inverter with power quality regulatory function. Electrical

Measurement & Instrumentation, (2): 68–73.

Tazay, Z. Miao. (2018). Control of a Three Phase Hybrid Converter

for a PV Charging Station. IEEE Transaction on Engergy Convertsion,

:1002–1014.

Tim Mareda, Ludovic Gaudard, Franco Romerio. (2017). A parametric

genetic algorithm approach to assess complementary options of large

scale windsolar coupling. IEEE/CAA Journal of Automatica Sinica,

(2):260–272.

Xiangyang Yu, Yuyu Liu, Biao Wang, Zekai Lu. (2019). Optimized

Scheduling of Seawater Pumping-Storing/Wind/Solar Hybrid Power

Generating System. 2019 IEEE 3rd Advanced Information Manage-

ment, Communicates, Electronic and Automation Control Conference

(IMCEC).

Zhongfei Gao, Yanjiang Li, Mengbi Zhao, Chengli Zhou, Kai Lv.

(2020). Design and Simulation of 500 kw Wind-solar Complementary

Microgrid. 2020 Chinese Control And Decision Conference (CCDC).

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Published

2021-04-12

How to Cite

Zheng, Y. ., & Xue, X. . (2021). Simulation of Wind-solar Complementary Distribution Power Generation System Based on PSCAD. Distributed Generation &Amp; Alternative Energy Journal, 35(2), 139–150. https://doi.org/10.13052/dgaej2156-3306.3523

Issue

2020: Vol 35 Iss 2

Section

Articles