A rural household heating method that combines a regenerative electric boiler with PV power generation

• Autorzy: Zhang C. , Gao G.
• Języki publikacji: EN

Abstrakty

EN

The heating mode of a regenerative electric boiler in China’s rural area includes many problems such as the increase of heating cost, the high expense of government subsidies and tr investment cost, etc. Consequently, this paper proposes a new heating method that combines a regenerative electric boiler with distributed photo-voltaic power generation. The photovoltaic software PVsyst was used to simulate generating capacity, and a system-wide economic efficiency calculation model was established. Taking a family in Gaobeidian City as an example, a comparative analysis of the method before and after optimization was conducted. The results showed that the new heating method has good economics, environmental benefits and promotional value. This new rural household heating method is of great significance for realizing the rural household energy cleanness in the Beijing-Tianjin-Hebei metropolitan region, promoting the green and low-carbon development of rural energy, and realizing beautiful rural construction.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2019
• Tom: 28
• Numer: 5
• Opis fizyczny: p.4001-4007,ref.

Twórcy

autor

Zhang C.

• School of Economic and Management, North China Electric Power University, Baoding, China

autor

Gao G.

• School of Economic and Management, North China Electric Power University, Baoding, China

Bibliografia

• 1. XIONG WEI, FU ZONGPING, WANG PENG Discussion on the promotion of the reform of rural energy supply side under the construction of ecological environment, Rural Economy, 12, 94, 2017.
• 2. MA XIAOQIAN, LIU ZHENG, ZHAO XUYANG, TIAN LIHUI, WANG TONG The Spatial and Temporal Variation of Haze and Its Relativity in the Beijing-Tianjin-Hebei Region. Areal Research and Development, 35 (2), 134, 2016.
• 3. LE HUI, LI HAOYUE, JIANG YI The Air Source Heat Pump replace The Heating Stove for Rural Residential Heating and adjust Power Peak Load at the same time. Energy of China, 38 (11), 9, 2016.
• 4. LV YINLING ”Coal to Electricity” promoted by the State Grid significant effect. China Energy News, 021, 2017.
• 5. ZHANG ZHENYU, YANG GUOHUA, CHE CHAO, ZHAO WENQUN Study of economic and environmental benefits analysis of roof photovoltaic system. Electric Power Environmental Protection, 32 (4), 53, 2016.
• 6. LI RUI Comprehensive Benefit Evaluation Method of Distributed Generation Micro grid Projects Based on Different Business Models. Power System Technology, 41 (06), 1748, 2017.
• 7. HEI CHENYANG, GUAN YUANPENG, XIE YUNXIANG, ZHU XIMENG Simulation analysis of distribution network with distributed photovoltaic generation system based on Thevenin-Norton equivalence. Electric Power Automation Equipment, 37 (10), 71, 2017.
• 8. CHENG LIN, ZHANG JING, HUANG RENLE, WANG CUNPING, TIAN HAO Case analysis of multi-scenario planning based on multi-energy complementation for integrated energy system. Electric Power Automation Equipment, 37 (06), 282, 2017.
• 9. ZENG BO, LI YINGZI, LIU ZONGQI, FENG JIAHUAN, ZHANG JIANHUA Comprehensive Evaluation Method for Environmental Benefits of Smart Distribution Network Based on TO-PCA. Power System Technology, 40 (02), 396, 2016.
• 10. GONG XIAOXU, JIN QIANG, WANG JI, SHI ZINAN, MA WEIJING Effects of Distributed PV Connected to Grid on Distribution Network Constructions in Typical Functional Zones. Electric Power, 49 (03), 166, 2016.
• 11. SARDI J., MITHULANANTHAN N., HUNG D.Q. Strategic allocation of community energy storage in a residential system with rooftop PV units. Applied Energy, 206, 159, 2017.
• 12. BABACAN O., RATNAM E.L., DISFANI V.R., KLEISSL J. Distributed energy storage system scheduling considering tariff structure, energy arbitrage and solar PV penetration. Appl. Energy, 205, 1384, 2017.
• 13. FISCHER D., BERNHARDT J., MADANI H., WITTWER C., YAN J. Comparison of control approaches for variable speed air source heat pumps considering time variable electricity prices and PV. Appl. Energy, 204, 93, 2017.
• 14. WHEELER K.A., ELSAMAHY M., FARIED S.O. A Novel Reclosing Scheme for Mitigation of Distributed Generation Effects on Overcurrent Protection. IEEE Trans. Power Delivery, 99, 1, 2017.
• 15. FIEDUCIK J., GODLEWSKI J. Storing Thermal Energy from Solar Collectors for the Needs of a Detached House. Polish J. Environ. Studies, 23 (4), 1373, 2014.
• 16. ABD-UR-REHMAN H.M., AL-SULAIMAN F.A., MEHMOOD A., SHAKIR S., UMER M. The potential of energy savings and the prospects of cleaner energy production by solar energy integration in the residential buildings of Saudi Arabia. J. Clean. Pro. 183, 2018.
• 17. REDLARSKI G., PIECHOCKI J., DABKOWSKI M. Reducing air pollutant emissions from the residential sector by switching to alternative energy sources in single-family homes. Polish J. Environ. Studies, 22 (1), 197, 2013.
• 18. LI YINGZI, LI ZHI Comparison and Selection of Solar Radiation Data for Photovoltaic Power Generation Projects. Building Electr. 35 (04), 35, 2016.
• 19. ROBAA S.M. A study of ultraviolet solar radiation at Cairo urban area, Egypt. Solar Energy, 77 (2), 251, 2004.
• 20. JIANG FUPING The Study of Comprehensive benefit evaluation in PV generationproject. Hubei Univer. of Technol. 2016.
• 21. ZHU QUNZHI, LEI SISI, JIANG TINGYAN Economical and environmental analysis of building photovoltaic systems with different installation styles. Acta Energy Solar Sinica, 33 (01), 24, 2012.

Identyfikatory

DOI

10.15244/pjoes/95182