ELECTROMAGNETIC COMPATIBILITY TESTING OF ELECTRIC VEHICLES: METROLOGICAL METHODS AND CASE STUDY FROM UZBEKISTAN

Tulegenova Sabina

Ushbu tadqiqotda Leapmotor C16 modeliga e’tibor qaratib, elektr transport vositalarining (EV) elektromagnit moslashuvchanligini (EMC) baholash uchun metrologik asosni ishlab chiqish va qo‘llash taqdim etilgan. Ishda BMT YEIKning 10-sonli Reglamenti, CISPR 25 va IEC 61000 kabi xalqaro standartlarga muvofiq O‘zbekistonda EMC sinovlarining uyg‘unlashtirilgan tartib-qoidalariga o‘sib borayotgan ehtiyoj ko‘rib chiqilgan. Ochiq maydondagi sinov maydonchasida dala o‘lchovlarini, o‘tkazilgan va nurlangan chiqindilarni tahlil qilishni va noaniqlikni baholashni o‘z ichiga olgan keng qamrovli sinov metodologiyasi joriy etildi.

Name of journalIlmiy sinov va sifat nazorati
Number of edition2025 (4) 2
View count 73

Web Address

DOI

Date of creation in the UzSCI system 19-08-2025

Read count 73

Date of publication 20-07-2025

Main LanguageO'zbek

Pages56-69

Tags

metrologik ta’minot

elektromagnit moslashuvchanlik (EMC)

elektr transport vositasi (EV)

EMC sinovlari

o‘lchash noaniqligi

yuqori voltli tizim

Ўзбек

Ushbu tadqiqotda Leapmotor C16 modeliga e’tibor qaratib, elektr transport vositalarining (EV) elektromagnit moslashuvchanligini (EMC) baholash uchun metrologik asosni ishlab chiqish va qo‘llash taqdim etilgan. Ishda BMT YEIKning 10-sonli Reglamenti, CISPR 25 va IEC 61000 kabi xalqaro standartlarga muvofiq O‘zbekistonda EMC sinovlarining uyg‘unlashtirilgan tartib-qoidalariga o‘sib borayotgan ehtiyoj ko‘rib chiqilgan. Ochiq maydondagi sinov maydonchasida dala o‘lchovlarini, o‘tkazilgan va nurlangan chiqindilarni tahlil qilishni va noaniqlikni baholashni o‘z ichiga olgan keng qamrovli sinov metodologiyasi joriy etildi.

Tags

metrologik ta’minot

elektromagnit moslashuvchanlik (EMC)

elektr transport vositasi (EV)

EMC sinovlari

o‘lchash noaniqligi

yuqori voltli tizim

Русский

В данном исследовании представлена разработка и применение метрологической основы для оценки электромагнитной совместимости (EMC) электромобилей (EV) с акцентом на модель Leapmotor C16. В работе рассматривается растущая потребность в гармонизированных процедурах испытаний EMC в Узбекистане в соответствии с международными стандартами, такими как Регламент ЕЭК ООН No 10, CISPR 25 и IEC 61000. На испытательной площадке на открытом воздухе была внедрена комплексная методология испытаний, включающая полевые измерения анализ проведенных и облученных отходов и оценку неопределенности.

Tags

метрологическое обеспечение

электромагнитная совместимость (EMC)

электромобиль (EV)

испытания EMC

неточность измерений

высоковольтная система

English

This study presents the development and application of a metrological framework for assessing the electromagnetic compatibility (EMC) of electric vehicles (EVs), focusing on the Leapmotor C16 model. The work addresses the growing need for harmonized EMC testing procedures in Uzbekistan, in alignment with international standards such as UNECE Regulation No. 10, CISPR 25, and IEC 61000. A comprehensive test methodology was implemented, including field measurements in an open area test site, analysis of conducted and radiated emissions, and uncertainty evaluation.

Tags

metrological support

measurement uncertainty

electromagnetic compatibility (EMC)

electric vehicle (EV)

EMC testing

high-voltage system

№ Author name position Name of organisation

1 Tulegenova S.. magistr Belarus-O‘zbekiston tarmoqlararo amaliy texnik kvalifikatsiyalar instituti

№ Name of reference

1 UNECE. (2019). Regulation No. 10: Uniform provisions concerning the approval of vehicles with regard to electromagnetic compatibility (Rev.6). United Nations Economic Commission for Europe. https://unece.org

2 .O‘z DSt 35.10:2011. (2011). Electromagnetic compatibility – General technical requirements for automotive vehicles. Tashkent: Uzstandart Agency.

3 UzTR.389-010:2016. (2016). Metrological support for EMC testing of electric vehicles. Tashkent: Uzstandart Agency.

4 ILAC. (2019). Guidelines on Decision Rules and Statements of Conformity (ILAC- G8:09/2019). International Laboratory Accreditation Cooperation. https://ilac.org/publications-and-resource

5 IEC. (2017). IEC 61000 Series: Electromagnetic Compatibility (EMC). International Electrotechnical Commission.

6 .CISPR. (2020). CISPR 25: Vehicles, boats and internal combustion engines – Radio disturbance characteristics – Limits and methods of measurement. CISPR.

7 Abbasov, A., & Mamirov, U. (2023). Improvement of the road infrastructure in Namangan city. In Proceedings of the 3rd International Student Scientific-Practical Conference “Development of Logistics and Supply Chain Management” (pp. 332–337). Minsk: Belarusian National Technical University.

8 Bernacky, V. V., & Mayorov, A. F. (2014). Test bench equipment for brake system testing and its modernization for ABS component assessment. Journal of Automotive Engineers, (2)85, 36–39. (In Russian)

9 Bykov, V. V., & Voloshin, V. E. (2019). Changes in the regulations of vehicle technical inspection. Bulletin of Automotive and Road Institute, 1(28), 18–25. (In Russian)

10 European Automobile Manufacturers Association. (2023). The automotive industry calls on EU leaders to reduce competitiveness risks. https://www.acea.auto/

11 Glazyev, S. (2018). Jump into the Future: Russia in the New Technological and World Economic Ways. Moscow: Knizhny Mir. (In Russian), 52–63.

12 Govor, G. A., Evtushenko, A. V., Titov, A. V., & Belyaev, V. M. (2023). Properties of a composite magnetically soft material based on coated iron powders. E3S Web of Conf erences, 365, 05001. https://doi.org/10.1051/e3sconf/202336505001

13 International Energy Agency (IEA). (2023). Net zero emissions. https://www.iea.org/

14 Normirzaev, A. R., Nuriddinov, A. D., & Valieva, G. F. (2017). Influence of automotive transport on the environment. Exact Science, (10), 6–9.

15 Normirzaev, A. R., et al. (2022). Research focused on the development of electric transport. In Proceedings of the Conf erence “The Role of Alternative Energy Sources in the Development of the Energy Sector” (Vol. 2, pp. 354–358). Namangan Institute of Engineering and Technology.

16 President of the Republic of Uzbekistan. (2023). Proposals for the development of the electric car industry were considered. https://president.uz/ru/lists/view/5732

17 Strategy for the Development of New Uzbekistan for 2022–2026. (2021). https://president.uz/ru/pages/view/strategy?menu_id=144

18 Tricky, D. (2021). Electric vehicles: Global trends, problems, and prospects. Energy Policy – Social and Business Journal. https://energypolicy.ru/elektromobili-mirovye-trendy-problemy-i- perspektivy/energoperehod/2021/14/27/

19 Cambridge Economics. (2013). Fueling Europe’s Future: How Auto Innovation Leads to EU Jobs. http://eurobat.org/sites/def ault/files/51cfcb6d4d573d59c7852a06e9782d1f.pdf

20 Semikashev, V. V., Kolpakov, A. Yu., Yakovlev, A. A., & Rostovskiy, Y. K. (2022). Development of the electric vehicle market in Russia as a prerequisite for benefiting from the global electrification trend. Problems of Forecasting, (3), 52–63

21 World Electric Vehicle Association. (2021). World Electric Vehicle Journal, 12. http://www.worldelectricvehicleassociation.info/journal

22 Agency of Statistics under the President of the Republic of Uzbekistan. (2023). Statistical data on electric vehicle imports. https://stat.uz/ru/

23 Atamirzayev, N., & Masharipov, S. (2024). Processing of several groups of direct measurements with multiple observations. AIP Conf erence Proceedings, 3045, 040042. https://doi.org/10.1063/5.0197907

Waiting

№	Name of reference
1	UNECE. (2019). Regulation No. 10: Uniform provisions concerning the approval of vehicles with regard to electromagnetic compatibility (Rev.6). United Nations Economic Commission for Europe. https://unece.org
2	.O‘z DSt 35.10:2011. (2011). Electromagnetic compatibility – General technical requirements for automotive vehicles. Tashkent: Uzstandart Agency.
3	UzTR.389-010:2016. (2016). Metrological support for EMC testing of electric vehicles. Tashkent: Uzstandart Agency.
4	ILAC. (2019). Guidelines on Decision Rules and Statements of Conformity (ILAC- G8:09/2019). International Laboratory Accreditation Cooperation. https://ilac.org/publications-and-resource
5	IEC. (2017). IEC 61000 Series: Electromagnetic Compatibility (EMC). International Electrotechnical Commission.
6	.CISPR. (2020). CISPR 25: Vehicles, boats and internal combustion engines – Radio disturbance characteristics – Limits and methods of measurement. CISPR.
7	Abbasov, A., & Mamirov, U. (2023). Improvement of the road infrastructure in Namangan city. In Proceedings of the 3rd International Student Scientific-Practical Conference “Development of Logistics and Supply Chain Management” (pp. 332–337). Minsk: Belarusian National Technical University.
8	Bernacky, V. V., & Mayorov, A. F. (2014). Test bench equipment for brake system testing and its modernization for ABS component assessment. Journal of Automotive Engineers, (2)85, 36–39. (In Russian)
9	Bykov, V. V., & Voloshin, V. E. (2019). Changes in the regulations of vehicle technical inspection. Bulletin of Automotive and Road Institute, 1(28), 18–25. (In Russian)
10	European Automobile Manufacturers Association. (2023). The automotive industry calls on EU leaders to reduce competitiveness risks. https://www.acea.auto/
11	Glazyev, S. (2018). Jump into the Future: Russia in the New Technological and World Economic Ways. Moscow: Knizhny Mir. (In Russian), 52–63.
12	Govor, G. A., Evtushenko, A. V., Titov, A. V., & Belyaev, V. M. (2023). Properties of a composite magnetically soft material based on coated iron powders. E3S Web of Conf erences, 365, 05001. https://doi.org/10.1051/e3sconf/202336505001
13	International Energy Agency (IEA). (2023). Net zero emissions. https://www.iea.org/
14	Normirzaev, A. R., Nuriddinov, A. D., & Valieva, G. F. (2017). Influence of automotive transport on the environment. Exact Science, (10), 6–9.
15	Normirzaev, A. R., et al. (2022). Research focused on the development of electric transport. In Proceedings of the Conf erence “The Role of Alternative Energy Sources in the Development of the Energy Sector” (Vol. 2, pp. 354–358). Namangan Institute of Engineering and Technology.
16	President of the Republic of Uzbekistan. (2023). Proposals for the development of the electric car industry were considered. https://president.uz/ru/lists/view/5732
17	Strategy for the Development of New Uzbekistan for 2022–2026. (2021). https://president.uz/ru/pages/view/strategy?menu_id=144
18	Tricky, D. (2021). Electric vehicles: Global trends, problems, and prospects. Energy Policy – Social and Business Journal. https://energypolicy.ru/elektromobili-mirovye-trendy-problemy-i- perspektivy/energoperehod/2021/14/27/
19	Cambridge Economics. (2013). Fueling Europe’s Future: How Auto Innovation Leads to EU Jobs. http://eurobat.org/sites/def ault/files/51cfcb6d4d573d59c7852a06e9782d1f.pdf
20	Semikashev, V. V., Kolpakov, A. Yu., Yakovlev, A. A., & Rostovskiy, Y. K. (2022). Development of the electric vehicle market in Russia as a prerequisite for benefiting from the global electrification trend. Problems of Forecasting, (3), 52–63
21	World Electric Vehicle Association. (2021). World Electric Vehicle Journal, 12. http://www.worldelectricvehicleassociation.info/journal
22	Agency of Statistics under the President of the Republic of Uzbekistan. (2023). Statistical data on electric vehicle imports. https://stat.uz/ru/
23	Atamirzayev, N., & Masharipov, S. (2024). Processing of several groups of direct measurements with multiple observations. AIP Conf erence Proceedings, 3045, 040042. https://doi.org/10.1063/5.0197907