Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear

yildirim, deniz; Şeker, Ahmet Efe; celik, bayram; SAKACI, EGEMEN ASLAN; Deniz, Arif

doi:10.5152/electrica.2022.22029

Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear

Ahmet Efe ŞEKER, (İstanbul Teknik Üniversitesi, Uçak ve Uzay Mühendisliği Programı, İstanbul, Türkiye)

Bayram ÇELİK, (İstanbul Teknik Üniversitesi, Uzay Mühendisliği Bölümü, İstanbul, Türkiye)

deniz yildirim, (İstanbul Teknik Üniversitesi, Elektrik Mühendisliği Bölümü, İstanbul, Türkiye)

Egemen Aslan SAKACI, (Siemens, Gebze Araştırma ve Geliştirme Merkezi, Kocaeli, Türkiye)

Arif DENİZ (Siemens, Gebze Araştırma ve Geliştirme Merkezi, Kocaeli, Türkiye)

Electrica

3 2

Yıl: 2023 Cilt: 23 Sayı: 1 Sayfa Aralığı: 107 - 120 Metin Dili: İngilizce DOI: 10.5152/electrica.2022.22029 İndeks Tarihi: 23-05-2023

Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear

Öz:

The main goal of the present study is to carry out one-way coupled computations of electromagnetics and heat transfer for a simplified version of a switchgear and to reveal the applicability of the computational approach. In our computation, we introduce the joule losses that we obtain from the electromagnetic computations to a thermal solver as heat load. In order to reach the goal, we compare the temperature values that we obtained at eight different measurement points by performing computations and experimental measurements. In general, the distributions of the obtained temperature values are quite similar. The notable difference in the mean values of the obtained temperatures might result from limitations of one-way coupled approach where we have to neglect temperature dependency of the electrical properties during the electromagnetic computations.

Anahtar Kelime:

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

1. M. Kazimierczuk, High-Frequency Magnetic Components. Chichester: Wiley, 2014.
2. A. Seker, Modeling and thermal analysis of simplified medium voltage switchgear using computational methods. M.Sc. National Defense University, 2020. Available: https://tez.yok.gov.tr/UlusalTezMerkezi/ TezGoster?key=_F5QEpayDXGqGZlp9XiFtOTDFUWAXxmqXyVvvKvoOnZm2C46cuc4oaWtCuUJMbKe
3. T. Radeva, I. Yatchev, D. Karastoyanov, N. Stoimenov, and S. Gyoshev, “Coupled electromagnetic and thermal field modeling of a laboratory busbar system,” Int. J. Electr. Comput. Eng., 2014. [CrossRef]
4. M. Bedkowski et al., “Coupled numerical modelling of power loss generation in busbar system of low-voltage switchgear,” Int. J. Therm. Sci., vol. 82, pp. 122–129, 2014. [CrossRef]
5. M. Bedkowski, J. Smolka, Z. Bulinski, A. Ryfa, and M. Ligeza, “Experimentally validated model of coupled thermal processes in a laboratory switchgear,” IET Gener. Transm. Distrib., vol. 10, no. 11, pp. 2699–2709, 2016. [CrossRef]
6. M. Bedkowski, J. Smolka, Z. Bulinski, and A. Ryfa, “Simulation of cooling enhancement in industrial low-voltage switchgear using validated coupled CFD-EMAG model,” Int. J. Therm. Sci., vol. 111, pp. 437–449, 2017. [CrossRef]
7. J. Qu, F. Chong, G. Wu, X. Li, and Q. Wang, “Application of computational fluid dynamics to predict the temperature-rise of low voltage switchgear compartment.” 60th Holm Conference on Electrical Contacts (Holm). IEEE Publications, 2014. [CrossRef]
8. X. Zheng et al., “Optimization on airflow distribution for anti-condensation of high-voltage switchgear using CFD method,” Case Stud. Therm. Eng., vol. 28, p. 101479, 2021. [CrossRef]
9. X. Guan, N. Shu, and H. Peng, “LBM simulation of heat transfer processes inside GIS capsule filled with different insulation gas mixtures,” Math. Comput. Simul., vol. 188, pp. 212–225, 2021. [CrossRef]
10. C. Gramsch, A. Blaszczyk, H. Löbl, and S. Grossmann, “Thermal network method in the design of power equipment,” Sci. Comput. Electr. Eng., pp. 213–219, 2007. [CrossRef]
11. X. Dong, R. Summer, and U. Kaltenborn, “Thermal network analysis in MV GIS design.” IET Conference Publications, 2009. [CrossRef]
12. S. Singh, R. Summer, and U. Kaltenborn, “A novel approach for the thermal analysis of air insulated switchgear, CIRED.” 21st International Conference on Electricity Distribution. Germany: Paper Publications, 2011, p. 0492.
13. R. Nowak, J. Duc, B. Samul, and A. P. Manjunatha, “A thermal network approach for a quick and accurate study of multiple connected switchgears,” Heat Transf. Eng., vol. 43, no. 3–5, pp. 183–197, 2022. [CrossRef]
14. A. Seker, E. Sakaci, A. Deniz, B. Celik, and D. Yildirim, “Thermal analyses for a simplified medium-voltage switchgear: Numerical and experimental benchmark studies.” 11th International Conference on Electrical and Electronics Engineering (ELECO), 2019. [CrossRef]
15. High-Voltage Switchgear and Controlgear - Part 1: Common Specifications for Alternating Current Switchgear and Controlgear, IEC 62271- 1:2017, 2017.
16. Magnetics for NX, Dr. Binde Ingenieure. Design & Engineering GmbH. Available: https://magnetics.de. 17. R. Anderl, and P. Binde, Simulations with NX. Cincinnati: Hanser Publications, 2018.
18. European Commission, “Online material characterisation at strip production,” 2013. Available: http: //www .gotr awama .eu/s ideru rgia/ Onlin e%20m ateri al%20 chara cteri satio n%20a t%20s trip% 20pro ducti on%20 (OMC).pdf.
19. H. Tran-Cor, “Grain oriented electrical steels.” Available: https ://ww w.aks teel. eu/fi les/d ownlo ads/T RAN-C OR_H_ %20Gr ain_O rient ed_El ectri cal_ S teel. pdf.
20. F. P. Incropera, and D. P. DeWitt, Fundamentals of Heat and Mass Transfer, 4th ed. Hoboken: Wiley, 1996.
21. Flow Solver Reference Manual. Siemens, 2017 Available: https://docs. plm.automation.siemens.com/data_services/resources/nx/12/nx_ help/common/en_US/graphics/fileLibrary/nx/tdoc_advanced_simulation/ flowrefman.pdf .

APA	Şeker A, celik b, yildirim d, SAKACI E, Deniz A (2023). Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. , 107 - 120. 10.5152/electrica.2022.22029
Chicago	Şeker Ahmet Efe,celik bayram,yildirim deniz,SAKACI EGEMEN ASLAN,Deniz Arif Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. (2023): 107 - 120. 10.5152/electrica.2022.22029
MLA	Şeker Ahmet Efe,celik bayram,yildirim deniz,SAKACI EGEMEN ASLAN,Deniz Arif Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. , 2023, ss.107 - 120. 10.5152/electrica.2022.22029
AMA	Şeker A,celik b,yildirim d,SAKACI E,Deniz A Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. . 2023; 107 - 120. 10.5152/electrica.2022.22029
Vancouver	Şeker A,celik b,yildirim d,SAKACI E,Deniz A Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. . 2023; 107 - 120. 10.5152/electrica.2022.22029
IEEE	Şeker A,celik b,yildirim d,SAKACI E,Deniz A "Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear." , ss.107 - 120, 2023. 10.5152/electrica.2022.22029
ISNAD	Şeker, Ahmet Efe vd. "Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear". (2023), 107-120. https://doi.org/10.5152/electrica.2022.22029

APA	Şeker A, celik b, yildirim d, SAKACI E, Deniz A (2023). Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. Electrica, 23(1), 107 - 120. 10.5152/electrica.2022.22029
Chicago	Şeker Ahmet Efe,celik bayram,yildirim deniz,SAKACI EGEMEN ASLAN,Deniz Arif Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. Electrica 23, no.1 (2023): 107 - 120. 10.5152/electrica.2022.22029
MLA	Şeker Ahmet Efe,celik bayram,yildirim deniz,SAKACI EGEMEN ASLAN,Deniz Arif Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. Electrica, vol.23, no.1, 2023, ss.107 - 120. 10.5152/electrica.2022.22029
AMA	Şeker A,celik b,yildirim d,SAKACI E,Deniz A Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. Electrica. 2023; 23(1): 107 - 120. 10.5152/electrica.2022.22029
Vancouver	Şeker A,celik b,yildirim d,SAKACI E,Deniz A Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear. Electrica. 2023; 23(1): 107 - 120. 10.5152/electrica.2022.22029
IEEE	Şeker A,celik b,yildirim d,SAKACI E,Deniz A "Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear." Electrica, 23, ss.107 - 120, 2023. 10.5152/electrica.2022.22029
ISNAD	Şeker, Ahmet Efe vd. "Temperature Field and Power Loss Calculation With Coupled Simulations for a Medium-Voltage Simplified Switchgear". Electrica 23/1 (2023), 107-120. https://doi.org/10.5152/electrica.2022.22029