To read this content please select one of the options below:

The heat recovery technologies of mine waste heat sources

Lingling Bao (College of Urban Engineering, Hebei University of Engineering, Handan, China)
Jiaying Wang (College of Urban Engineering, Hebei University of Engineering, Handan, China)
Jinggang Wang (College of Urban Engineering, Hebei University of Engineering, Handan, China)
Zheng Yu (College of Urban Engineering, Hebei University of Engineering, Handan, China)

World Journal of Engineering

ISSN: 1708-5284

Article publication date: 13 February 2017

332

Abstract

Purpose

Currently, China is the largest coal producer and consumer in the world. Underground mining is the main practice. In the process of deep mining, large amounts of low-temperature waste heat are available such as in the mine return air (MRA), mine water (MW), bathing waste water (BWW), etc. Without recycling, the low-temperature waste heat is discharged directly into the atmosphere or into the drainage system. The temperature range of the MRA is about 15-25°C, the relative humidity (RH) of the MRA is above 90 per cent, the temperature range of MW is about 18-20°C and the temperature of the BWW is about 30°C. All of the above parameters are relatively stable throughout the year, and thus MRA, MW and BWW are proper low-temperature heat sources for water source heat pump (WSHP) systems. The study aims to introduce the schemes for recycling the different waste heat sources and the relevant key equipment and technology of each waste heat recycle system; analyze the heat recovery performances of the MRA heat recovery technology; and compare the economies between the MRA heat recovery system and the traditional system.

Design/methodology/approach

Based on the WSHP system, heat and mass transfer efficiencies were calculated and analyzed, the outlet air velocity diffusion of the heat and mass transfer units and the parameters including air flow rate, the MRA’s dry bulb temperatures and wet bulb temperatures at inlet and outlet of MRA heat exchanger were tested. Then, it was assessed whether this system can be applied to an actual construction. An actual reconstructive project of MRA heat recovery system is taken as an example, where the cost-saving effects of heat recovery of mine waste heat sources system are analyzed.

Findings

Analysis of field test reveals that when heat transfer is stable, heat transfer capacity can be achieved: 957.6 kW in summer, 681 kW in winter and a large amount of heat was recycled. In an economic analysis, by comparing initial investment and 10 years’ operation cost with the traditional boiler and central air conditioning system, the results show that although the MRA system’s initial investment is high, this system can save CNY 6.26m in 10 years.

Originality/value

MRA has a large amount of air volume and temperature that is constant throughout the year, and hence is a good low-temperature heat source for the WSHP system. It can replace boiler heating in winter and central air conditioning refrigeration in summer. The study reveals that this technology is feasible, and has good prospects for development.

Keywords

Acknowledgements

The present work has been supported by the National Science Foundation of China (Grant No. 51408182), Hebei Province Natural Science Foundation of China (Grant No. E2015 402139), Hebei Province Department of Education (Grant No. QN2014064) and the Collaborative Innovation Center of the Comprehensive Development and Utilization of Coal Resources, Hebei Province.

Citation

Bao, L., Wang, J., Wang, J. and Yu, Z. (2017), "The heat recovery technologies of mine waste heat sources", World Journal of Engineering, Vol. 14 No. 1, pp. 19-26. https://doi.org/10.1108/WJE-11-2016-0125

Publisher

:

Emerald Publishing Limited

Copyright © 2017, Emerald Publishing Limited

Related articles