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ENERGY AUDIT AND CONSERVATION POTENTIAL ANALYSIS OF A LARGE COMPREHENSIVE COMMERCIAL BUILDING

ABSTRACT
With the rapid development of large-scale public buildings, energy consumption has increased, of which the energy consumption of comprehensive commercial buildings can reach 10~20 times the common building energy consumption, and has great energy saving potential. In this paper, a large comprehensive commercial building in Chengdu is taken as an example to analyze the energy consumption through the actual energy consumption data, viewed from the energy-saving and emission-reduction and static investment payback period point. The results show that the energy saving rate of the building can be achieved by 32.64%, the emission reduction is 6196.52 t CO2 per year, and the investment recovery period is only about 0.90 years, which provides a reference for similar buildings.
KEYWORDS
PAPER SUBMITTED: 2017-05-24
PAPER REVISED: 2017-10-08
PAPER ACCEPTED: 2017-10-09
PUBLISHED ONLINE: 2018-02-18
DOI REFERENCE: https://doi.org/10.2298/TSCI170524041Z
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2018, VOLUME 22, ISSUE Supplement 2, PAGES [S567 - S576]
REFERENCES
  1. Jiang, Y., Concept Debate for China's Building Energy Conservation, China Architecture & Building Press, Beijing, China, 2016.
  2. Jiang, Y., et al., Classification of Building Energy Consumption in China, Construction Science and Technology, 14, (2015), pp. 22-26.
  3. Mao, Q., Recent Developments in Geometrical Configurations of Thermal Energy Storage for Concentrating Solar Power Plant, Renewable & Sustainable Energy Reviews, 59, (2016), pp. 320-327.
  4. Mao, Q., et al., Design and Calculation of A New Storage Tank for Concentrating Solar Power Plant, Energy Conversion and Management, 100, (2015), pp. 414-418.
  5. Mao, Q., et al., Effects of Material Selection on the Radiation Flux of Tube Receiver in A Dish Solar System, Heat Transfer Research, 45, (2014), PP. 339-347.
  6. Mao, Q., et al., A Novel Heat Transfer Model of A Phase Change Material Using in Solar Power Plant, Applied Thermal Engineering, 129, (2018), pp. 557-563.
  7. Zeng, D., Liu, G., Investigation and Analysis on Energy Management of Large Scale of Store Buildings, Journal of Chongqing University (Social Science Edition), 19, (2013), pp. 78-83.
  8. Zhang, Z., et al., Application of Ecological and Energy-Saving Techniques in Reconstruction Design of Existing Building, Architecture Technology, 46, (2015), pp. 110-112.
  9. Rahman, M., et al., Energy Conservation Measures in An Institutional Building in Sub-tropical Climate in Australia, Applied Energy, 87, (2010), pp. 2994-3004.
  10. Liu, Z., et al., Study on Building Energy Efficiency Target based on SIR Method, Building Science, 29, (2013), pp. 70-76.
  11. Rosenquist, G., et al., Life-Cycle Cost and Payback Period Analysis for Commercial Unitary Air Conditioners, Office of Scientific & Technical Information Technical Reports (2004).
  12. Krstić, H., Teni, M., Sensitivity Analysis of Simple Payback Period Regarding Changes of Buildings Airtightness, Sabor Hrvatskih Graditelja Eu I Hrvatsko Graditeljstvo Zbornik Radova, 2016.
  13. Peng, S.W., Frequency Conversion Transformation of Central Air Conditioner Cabinet, Electrotechnical Application, 2011, 2, pp. 46-50.
  14. Tang, Y.Y., Energy Consumption Research and Energy-Saving Retrofit Simulation and Analysis on Existing Llarge Scale Public Buildings in HeFei, Doctoral dissertation, HeFei University of Technology, China, 2012.

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence