Estimation of Temperature Recovery Distance and the Influence of Heat Pump Discharge on Fluvial Ecosystems

Temperature differences between the atmosphere and river water allow rivers to be used as a hydrothermal energy source. River-water heat pump systems are a relatively non-invasive renewable energy source; however, effluent discharged from the heat pump can cause downstream temperature changes which may impact sensitive fluvial ecosystems. The temperature change associated with heat pump discharge in a river reach was examined using the heat transfer equation in a previous study, but not using models. There were also no studies on the impact of temperature change due to heat pump discharge on river ecosystem elements such as endangered fishes. Therefore, in this study, the water temperature recovery distance of effluent was estimated for a river section in the Han River Basin, Korea, using the heat transfer equation and the Environmental Fluid Dynamic Code (EFDC) model. The water temperature recovery distance was estimated to be 9.7 km using the heat transfer equation and 5 km using the EFDC model in summer. It was also estimated to be 4.5 km using the heat transfer equation and 6.7 km using the EFDC model in winter. Results showed that the water temperature recovery distance results estimated by the heat transfer equation had greater variation than the EFDC model. The water temperature recovery distance could also be used as an objective indicator to decide the reuse of downstream river water. Furthermore, as the river system was found to support an endangered fish species that is sensitive to water environment changes, care should be taken to exclude the habitats of protected species affected by water temperatures within water temperature recovery distance.

[1]  H. Kim,et al.  Feasibility Study on the Use of River Water Hydrothermal Energy in Korea : (2) Impact Assesssment of the Change in Water Temperature of Return Flow on the River Environment , 2019, New & Renewable Energy.

[2]  Jungwook Kim,et al.  Feasibility Study on the Use of River Water Hydrothermal Energy in Korea : (1) Estimation of the Permitted Standard Discharge and Determination of the Potential Water Intake Area , 2018, New & Renewable Energy.

[3]  Zhang Yong,et al.  Experimental Research of a Water-Source Heat Pump Water Heater System , 2018 .

[4]  Young-Teck Hur,et al.  A Investigation and Analysis of Water Temperature by Juam Regulation Dam Outflow in Downstream and Suncheon Bay , 2015 .

[5]  H. Kim,et al.  Impact of Climate Change on Habitat of the Rhynchocypris Kumgangensis in Pyungchang River , 2013 .

[6]  Ji Yeon Son,et al.  Simulation of Water Temperature in the Downstream According to Withdrawal Types of Dam using EFDC Model , 2012 .

[7]  J. Armengol,et al.  Water temperature modeling in the Lower Ebro River (Spain): Heat fluxes, equilibrium temperature, and magnitude of alteration caused by reservoirs and thermal effluent , 2012 .

[8]  Zhaoqing Yang,et al.  Modeling Hydrothermal Response of a Reservoir to Modifications at a High-Head Dam , 2005 .

[9]  N. Lamouroux,et al.  Long‐term changes within the invertebrate and fish communities of the Upper Rhône River: effects of climatic factors , 2004 .

[10]  Joanna L. Lessard,et al.  Effects of elevated water temperature on fish and macroinvertebrate communities below small dams , 2003 .

[11]  장기창,et al.  온도차에너지를 열원으로 하는 미활용에너지의 부존량과 이용가능성에 관한 조사연구 , 2002 .

[12]  S. Chapra Surface Water-Quality Modeling , 1996 .

[13]  Heinz G. Stefan,et al.  Stream temperature dynamics: Measurements and modeling , 1993 .

[14]  H. Stefan,et al.  Deterministic Modeling of Stream Water Temperatures: Development and Applications to Climate Change Effects on Fish Habitat , 1992 .

[15]  D. Bowles,et al.  Coupled Dynamic Streamflow-Temperature Models , 1977 .

[16]  J. Geyer,et al.  Heat exchange and transport in the environment. Report No. 14 , 1974 .

[17]  J. C. Geyer,et al.  The Response of Water Temperatures to Meteorological Conditions , 1968 .

[18]  한국에너지기술연구원 이산화탄소 저감 및 처리 기술개발 사업(Development program of the carbon dioxide reduction & sequestration R&D) 미활용에너지 네트워크 실증사업 최적화 연구(The optimization of a demonstration network plant using unutilized energy resources) , 2005 .

[19]  T. Cole,et al.  CE-QUAL-W2: A Two-dimensional, Laterally Averaged, Hydrodynamic and Water Quality Model, Version 3.1 , 2003 .

[20]  R. Thomann,et al.  Principles of surface water quality modeling and control , 1987 .