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2017 | 26 | 6 |

Tytuł artykułu

Analysis of influencing factors of ground-source heat pump applications in China using partial least squares regression

Autorzy

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
Energy crisis and environmental pollution have become major challenges in China’s economic development, which has triggered the demand for alternative energy sources and promoted the popularization of ground source heat pump technology. A ground source heat pump (GSHP) is a central heating and/or cooling system that transfers heat to or from the ground. It uses the earth as a heat source (in the winter) or a heat sink (in the summer). This design takes advantage of the moderate temperatures in the ground to boost efficiency and reduce the operational costs of heating and cooling systems. This paper adopted the STIRPAT model and the influencing factors were analyzed. The major influencing factors were population (P), urbanization level (U), GDP per capita (A), energy consumption per capita (E), industrial structure (IS), R&D (T), central heating area (HA), and policy investment (PI). However, these factors themselves had strong collinearity, which might produce some uncertain impacts on the final results. To avoid the impact of collinearity, the method of partial least squares (PLS) was used. The results showed that P, U, A, E, T, HA, and PI had positive effects on GSHP, while IS had a slight effect on GSHP. This paper found that A is the most dominant factor and the effect of the IS could almost be ignored. Some policy recommendations were given on how to promote the application of GSHP systems and mitigate the growth of CO₂ emissions.

Słowa kluczowe

Wydawca

-

Rocznik

Tom

26

Numer

6

Opis fizyczny

p.2575-2583,fig.,ref.

Twórcy

autor
  • School of Humanities and Economic Management, China University of Geosciences, Beijing, 10083, China
  • Key Laboratory of Carrying Capacity Assessment for Resources and the Environment, Ministry of Land and Resources, Beijing, 100083, China
autor
  • School of Humanities and Economic Management, China University of Geosciences, Beijing, 10083, China
  • Key Laboratory of Carrying Capacity Assessment for Resources and the Environment, Ministry of Land and Resources, Beijing, 100083, China

Bibliografia

  • 1. YANG W., ZHOU .J, XU W., ZHANG G.Q. Current status of ground-source heat pumps in China. Energy Policy, 38, 323, 2010.
  • 2. YANG X., SONG Y., WANG G., WangW. A comprehensive review on the development of sustainable energy strategy and implementation in China. IEEE Trans Sustain Energy, 1 (2), 57, 2010.
  • 3. CROMPTON P., WU Y. Energy consumption in China: past trends and future directions. Energy Economics, 27, 195, 2005.
  • 4. Li Z.S., Zhang G.Q., Li D.M., Zhou J., Li L.J., Li L.X. Application and development of solar energy in building industry and its prospects in China. Energy Policy, 35, 4121, 2007.
  • 5. LIAO P.C., ZHANG K.N., WANG T., WANG Y.Q. Intergrating bibliometrics and roadmapping: a case of strategic promotion for the ground source heap pump in China. Renewable and sustainable energy reviews, 57, 292, 2016.
  • 6. HEPBASLI A., AKDEMIR O. Energy and exergy analysis of a ground source heat pump system. Energy Convers. Manag., 45 (5), 737, 2004.
  • 7. Sarbu I, Sebarchievici C. General review of ground-source heat pump systems for heating and cooling of buildings. Energy and buildings, 70, 441, 2014.
  • 8. EPA. A short primer and environmental guidance for geothermal heat pumps. In: Environmental Protection Agency, 430-K-97-007, 1997.
  • 9. HUANG Y.X., LIAO P.C., TSAI S.H. Modeling the relationships of factors affecting dissemination of ground source heat pump (GSHP) in China. Adv Mater Res, 723, 976, 2013.
  • 10. LUO J., ROHNA J., BAYER M., PRIESS A., WILKMANN L., XIANG W. Heating and cooling performance analysis of a ground source heat pump system in Southern Germany. Geothermics, 53, 57, 2015.
  • 11. ZHANG Y., CHOUDHARY R., SOGA K. Influence of GSHP system design parameters on the geothermal application capacity and electricity consumption at city-scale for Westminster, London. Energy and Buildings, 106, 3, 2015.
  • 12. KECEBAS A. Energetic, exergetic, economic and environmental evaluations of geothermal district heating systems: An application. Energy Conversion and Management, 65, 546, 2013.
  • 13. BLUM P., CAMPILLO G., KOLBEL T. Techno-economic and spatial analysis of vertical ground source heat pump systems in Germany. Energy, 36, 3002, 2011.
  • 14. COL D.D., AZZOLIN M., BENASSI G., MANTOCAN M. Energy efficiency in a ground source heat pump with variable speed drives. Energy and Buildings, 91, 105, 2015.
  • 15. WANG Z.H., WANG F.H., MA Z.J., WANG X.K., WU X.Z. Research of heat and moisture transfer influence on the characteristics of the ground heat pump exchangers in unsaturated soil. Energy and Buildings, 130, 140, 2016.
  • 16. MEHRIZI A.A., PORKHIAL S., BEZYAN B., LOTFIZADEH H. Energy pile foundation simulation for different configurations of ground source heat exchanger. International Communications in Heat and Mass Transfer, 70, 105, 2016.
  • 17. SONI S.K., PANDEY M., BARTARIA V.N. Hybrid ground coupled heat exchanger systems for space heating/cooling applications:A review. Renewable and Sustainable Energy Reviews, 60, 724, 2016.
  • 18. NOOROLLAHI Y., BIGDELOU P., POURFAYAZ F., YOUSEFI H. Numerical modeling and economic analysis of a ground source heat pump for supplying energy for a greenhouse in Alborz province, Iran. Journal of Cleaner Production, 131, 145, 2016.
  • 19. QIAN H., WANG Y.G. Modeling the interactions between the performance of ground source heat pumps and soil temperature variations. Energy for Sustainable Development, 23, 115, 2014.
  • 20. OZGENER O., HEPBSLI A. A parametrical study on the energetic and exergetic assessment of a solar-assisted vertical ground-source heat pump system used for heating a greenhouse. Build Environ, 42, 11, 2007.
  • 21. NAGANO K., KATSURA T., TAKEDA S. Development of a design and performance prediction tool for the ground source heat pump system. Appl. Therm. Eng., 26, 1578, 2006.
  • 22. ESEN H., INALLI M., ESEN M. Technoeconomic appraisal of a ground source heat pump system for a heating season in eastern Turkey. Energy Convers. Manag., 47, 1281, 2006.
  • 23. MORRONE B., COPPOLA G., RAUCCI V. Energy and economic savings using geothermal heat pumps in different climates. Energy Conversion and Management, 88, 189, 2014.
  • 24. KECEBAS A., ALKAN M.A., ABANOVA I., YUMURTAC M. Energetic and economic evaluations of geothermal district heatin gsystems by using ANN. Energy Policy, 56, 558, 2013.
  • 25. BADESCU V. Economic aspects of using ground thermal energy for passive house heating. Renew Energy, 32, 895, 2007.
  • 26. SHEN P.Y., LUKES J.R. Impact of global warming on performance of ground source heat pumps in US climate zones. Energy Conversion and Management, 101, 632, 2015.
  • 27. GREENING B., AZAPAGIC A. Domestic heat pumps: Life cycle environmental impacts and potential implications for the UK. Energy, 39, 205, 2012.
  • 28. KORONEOS C.J., NANAKI E.A. Environmental impact assessment of a ground source heat pump system in Greece. Geothermic,s 65, 1, 2017.
  • 29. RUSSO S.L., BOFFA C., CIVITA M.V. Low-enthalpy geothermal energy: anopportunity to meet increasing energy needs and reduce CO₂ and atmospheric pollutant emissions in Piemonte, Italy. Geothermics, 38, 254, 2009.
  • 30. BLUM P., CAMPILLO G., MONCH W., KLBEL T. CO₂ savings of ground sourceheat pump systems - a regional analysis. Renew. Energy, 35, 122, 2010.
  • 31. AKELLA A.K., SAINI R.P., Sharma M.P. Social, economical and environmentalimpacts of renewable energy systems. Renew. Energy, 34, 390, 2009.
  • 32. BAYER P., SANER D., BOLAY S., RYBACH L., BlLUM P. Greenhouse gas emission savings of ground source heat pump systems in Europe: A review. Renewable and Sustainable Energy Reviews, 16, 1256, 2012.
  • 33. CARVALHO A.D., MENDRINOS D., ALMEIDA A.T.D. Ground source heat pump carbon emissions and primary energy reduction potential for heating in buildings in Europe-results of a case study in Portugal. Renewable and Sustainable Energy Reviews, 45, 755, 2015.
  • 34. SIVASAKTHIVEL T., MURUGESAN K., SAHOO P.K. Study of technical, economical and environmental viability of ground source heat pump system for Himalayan cities of India. Renewable and Sustainable Energy Reviews, 48, 452, 2015.
  • 35. KHARSEH M., ALTORKMANY L., ALKHAWAJA M., HASSANI F. Analysis of the effect of global climate change on ground source heat pump systems in different climate categories. Renewable Energy, 78, 219, 2015.
  • 36. EHRLICH P.R., HOLDREN J.P. Impact of population growth. Science, 191 (3977), 1212, 1971.
  • 37. DIETZ T., ROSA E.A. Rethinking the environmental impacts of population, affluence and technology. Hum Ecol Rev, 1, 277, 1994.
  • 38. SHI A. The impact of population pressure on global carbon dioxide emissions, 1975-1996:evidence from pooled cross-country data. Ecol Econ, 44 (1), 29, 2003.
  • 39. YORK R., ROSA E.A., DIETZ T. STIRPAT, IPAT and ImPACT: analytic tools for unpacking the driving forces of environmental impacts. Ecol Econ, 46 (3), 351, 2003.
  • 40. FAN Y., LIU L., WU G., WEI Y. Analyzing impact factors of CO₂ emissions using the STIRPAT model. Environ Impact Assess, 26 (4), 377, 2006.
  • 41. LIU Y., ZHOU Y., WU W. Assessing the impact of population, income and technology on energy consumption and industrial pollutant emissions in China. Appl Energy, 155, 904, 2015.
  • 42. WANG H. Partial Least Squares Regression: Method and Applications. National Defence Industry Press, Beijing, China. 200, 1999 [In Chinese].
  • 43. KEMP F. Applied multiple regression/correlation analysis for the behavioral sciences. Journal of the Royal Statistical Society, 52 (4), 691-691, 2003.
  • 44. WANG H. Linear and Nonlinear Methods of Partial Least Squares Regression. National Defence Industry Press, Beijing, China. 279, 2006 [In Chinese].
  • 45. JIA J.S., DENG H.B., DUAN J., ZHAO J.Z. Analysis of the major drivers of the ecological footprint using the STIRPAT model and the PLS method. Ecological Economics, 68, 2818, 2009.
  • 46. WOLD S. PLS for multivariate linear modeling. QSAR: chemometric methods in molecular design Methods and principles in medicinal chemistry. Weinheim, Germany 7 Verlag-Chemie; 1994.

Typ dokumentu

Bibliografia

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