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IMPLEMENTATION OF A SMALL SCALE ORGANIC RANKINE CYCLE TEST BED SYSTEM USING STEAM AS HEAT SOURCE


Go-down asme-orc2015 Tracking Number 164

Presentation:
Session: Poster session
Plenary session
Session start: 13:30 Tue 13 Oct 2015

Muhammad Usman   usman7@kier.re.kr
Affifliation: Korea Institute of Energy Research & Korea University of Science and Technology

Muhammad Imran   imran@kier.re.kr
Affifliation: Korea Institute of Energy Research & Korea University of Science and Technology

Dong Hyun Lee   dhlee@kier.re.kr
Affifliation: Korea Institute of Energy Research

Byung-Sik Park   bspark@kier.re.kr
Affifliation: Korea Institute of Energy Research & Korea University of Science and Technology


Topics: - Prototypes (Topics), - I prefer Oral Presentation (Presentation Preference)

Abstract:

Organic Rankine cycle based power systems are well known for waste heat recovery application due to their adaptability to follow heat source variations. Industrial exhaust steam has an appreciable potential for the installation of waste heat recovery units. Korea Institute of Energy Research has developed waste heat recovery units which can generate power in the range of hundreds of kilowatts. In order to, rigorously test new cycle configurations and control strategies with least cost for heat source, a small-scale organic Rankine cycle test bed was implemented which a has steam condensing heat exchanger for using steam as a heat source in similar configurations as of larger units. The test bed was equipped with data logging and standalone control system and was configured for the electrical output around 1kW using R245fa as a working fluid. The system is composed of plate type heat exchangers, scroll type expansion machine, screw type working fluid pump and control valves with actuators. This work will present the difficulties, solutions and operational results in terms of design, equipment selection, fabrication and operational experience of system for small-scale power generation with efficiency over 5.2 % for a temperature difference of 120oC. Complexities involved in superheat control of working fluid for the system powered by steam will also be discussed