Experimental investigation of a small-scale reversible high-temperature heat pump − organic Rankine cycle system for industrial waste heat recovery
Rahul Velanparambil Ravindran, Donal Cotter, Chris Wilson, Ming Jun Huang, Neil Hewitt
Abstract
• Experimental study of a reversible HTHP–ORC system for industrial waste heat recovery. • Performance analysis of a single scroll unit in both compressor and expander roles. • Performance analysis of low GWP refrigerant, R1233zd(E) in both HTHP and ORC modes. • System achieved a COP mech = 4.8 for a temperature lift (ΔT lift,rside ) of 41 K in HTHP mode. • Maximum overall cycle efficiency of 3.01% and net power output of 512.4 W in ORC mode. Innovative technologies are required to mitigate the challenges of climate change. A reversible high-temperature heat pump (HTHP) − organic Rankine cycle (ORC) system can be used for effective utilisation of industrial waste heat in the lower temperature band <100 °C. The system can provide useful process heat for industrial processes by operating in HTHP mode or generating power in ORC mode. This paper presents the experimental investigation of the reversible system in both HTHP and ORC modes. A single scroll unit was selected for the compressor (HTHP) and expander (ORC) roles, keeping the system compact. A HCFO refrigerant, R1233zd(E), with a low GWP value, was chosen as the working fluid for both operating modes. When operated in HTHP mode, a maximum compressor overall isentropic efficiency of 73.4 % and a COP mech of 4.8 (ΔT lift,rside = 41 K, T sf,ev,in = 60 °C) was obtained. In ORC mode, the maximum net power output was 512.4 W (T sf,ev,in = 90 °C, r p = 2.3), overall cycle efficiency was 3.01 %, and overall isentropic efficiency of the expander was 54.6 %. The technical limitations encountered, and solutions put in place during the experimental testing campaign are discussed in detail.