• 대한기계학회논문집
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• 제17권1호
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• pp.172-181
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• 1993

본 연구에서는 이 사이클 주위에 열전달이 추가된 열기관에 대하여 최대출력 조건 등을 구하고, 내부의 사이클이 각각 타노 사이클 및 브레이튼 사이클인 경우의 결과와 비교하여, 내적가역 최대출력 사이클들의 특성을 밝히고자 한다.

• 동력기계공학회지
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• 제20권1호
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• pp.11-17
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• 2016

In this study, the simulation for performance comparison between basic single stage organic rankine cycle, multi stage reheater cycle and multi stage reheater & recuperator cycle was carried out. The multi stage reheater cycle and multi stage reheater & recuperator cycle was designed to improve the efficiency for organic rankine cycle using heat source from industrial waste heat and heat sink from deep ocean water. R245fa was selected as a refrigerant for the cycle and system efficiencies were simulated by the variation of the heat sink temperature and the cycle classification. Performance characteristics were simulated by using the Aspen HYSYS. It was confirmed that the system efficiency was decreased by the increase of heat sink temperature. These results can be considered to be applied as geo-ocean thermal energy conversion in where plenty of geothermal or ocean thermal resource exist.

• 대한기계학회논문집
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• 제15권1호
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• pp.349-354
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• 1991

본 연구에서는 이에 대한 열역학적 기초연구로서, 그러한 시스템을 단순화하 여 주어진 온도의 두 무한열원 사이에 두개의 카르노 사이클이 존재하는 이중돌력 사 이클에 대하여, 최대출력조건에서의 사이클의 온도와 각 열교환기의 용량 등을 구하였 다. 또한 사이클이 가역이 아닌 경우 사이클의 가역도에 따른 최대 출력 조건의 변 화 등도 검토하였다.

• 한국태양에너지학회 논문집
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• 제35권6호
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• pp.25-33
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• 2015

In this study, heating performance of the air-cooled heat pump with vapor-injection (VI) cycles, re-heater and solar heat storage tank was investigated experimentally. Devices used in the experiment were comprised of a VI compressor, re-heater, economizer, variable evaporator, flat-plate solar collector for hot water, thermal storage tank, etc. As working fluid, refrigerant R410A for heat pump and propylene glycol (PG) for solar collector were used. In this experiment, heating performance was compared by three cycles, A, B and C. In case of Cycle B, heat exchange was conducted between VI suction refrigerant and inlet refrigerant of condenser by re-heater (Re-heater in Fig. 3, No. 3) (Cycle B), and Cycle A was not use re-heater on the same operating conditions. In case of Cycle C, outlet refrigerant from evaporator go to thermal storage tank for getting a thermal energy from solar thermal storage tank while re-heater also used. As a result, Cycle C reached the target temperature of water in a shorter time than Cycle B and Cycle A. In addition, it was founded that, as for the coefficient of heating performance($COP_h$), the performance in Cycle C was improved by 13.6% higher than the performance of Cycle B shown the average $COP_h$ of 3.0 and by 18.9% higher than the performance of Cycle A shown the average $COP_h$ of 2.86. From this results, It was confirmed that the performance of heat pump system with refrigerant re-heater and VI cycle can be improved by applying solar thermal energy as an auxiliary heat source.

• 대한기계학회논문집
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• 제9권6호
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• pp.795-800
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• 1985

본 연구에서는 위의 내용을 한 단계 더 발전시켜 유한열용량 유동 사이에서 작동하는 브레이튼 사이클의 운전조건에 따른 출력변화와 취대출력 조건을 규명하였으 며, 이것은 단순히 이론적용 대상의 확장이라는 의미와 함께, 앞에서의 카노 사이클의 이상적인 사이클인 반면 브레이튼 사이클이라는 점에서 공학적 의의가 있으며, 특히 원자력 등을 열원으로 하는, 열교환기가 있는 가스 터어빈 사이클의 설계나 운전조건 의 결정 등에는 직접 적용될 수도 있을 것이다.

• 대한설비공학회:학술대회논문집
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• 대한설비공학회 2008년도 동계학술발표대회 논문집
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• pp.636-641
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• 2008

Heat pump drying has a great potential for energy saving due to its high energy efficiency in comparison to conventional air drying. The heat pump dryer is usually operated at the temperature less than $50^{\circ}C$ and the drying temperature is limited to the operating temperature of the heat pump system. In order to increase the drying temperature, the special box-type heat pump dryer has been developed. The dryer uses the two-cycle heat pump system which has the two heat pump cycles for high and low temperature heating. The high temperature cycle uses the refrigerant 124 to get the temperature greater than $80^{\circ}C$ and the low temperature cycle uses the refrigerant 134a. The drying experiment has been carried out to figure out the performance of the dryer with the selected drying material.

• 한국해양공학회지
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• 제25권1호
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• pp.80-84
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• 2011

The cycle performance of closed ocean thermal energy conversion (OTEC) system with 50 kW gross power was evaluated to obtain the basic data for the optimal design of OTEC using waste heat such as solar power, discharged heat from condenser of power plant. The basic thermodynamic model for OTEC is Rankine cycle, and the surface seawater and deep seawater were used for the heat source of evaporator and condenser, respectively. The cycle performance such as efficiency, heat exchanger capacity, etc. was analyzed on the variation of temperature increase by waste heat. The cycle efficiency increased and necessary capacity of evaporator and condenser decreased under 50kW gross power with respect to the temperature increase of working fluid. Also, when the temperature increase is about $13.5^{\circ}C$, the heat which can be used is generated. By generator with 0.9 effectiveness under the simulated condition, the cycle efficiency was improved approximately 3.0% comparing with the basic cycle.

• Journal of Advanced Marine Engineering and Technology
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• 제39권6호
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• pp.592-598
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• 2015

본 연구에서는 공랭식 VI(Vapour-Injection) 사이클을 적용한 R410A용 고성능 하절기 냉방 열펌프의 성능 특성을 실험적으로 규명하였다. 실험에 사용한 장치는 VI 압축기, 응축기, 유분리기, 판형열교환기, 에코노마이져(economizer), 증발기, 그리고 재냉기(re-cooler)로 구성하였다. 냉방 성능 실험 조건은 다음과 같이 3가지 사이클로 VI 사이클을 적용하고 증발기 출구 냉매와 VI사이클 흡입 냉매가 재냉기에서 서로 열교환 하지 않는 사이클(사이클 A)과 열교환을 하는 사이클(사이클 B), 그리고 VI 사이클도 적용하지 않고 증발기 출구 냉매와 VI 사이클 흡입 냉매와의 열교환도 없는 사이클(사이클 C)로 구분하였다. 분석 결과, 냉방 성능은 증발기 출구 냉매와 VI사이클 흡입 냉매가 서로 열교환하는 VI사이클(사이클 B)이 가장 높았으며 VI사이클을 적용하지 않은 사이클 C가 가장 낮음을 알 수 있었으며, 사이클B의 냉방성능계수($COP_C$)가 평균 3.5로 사이클A보다 8.6%, 사이클C보다 33% 높은 값을 나타내었다.

• 설비공학논문집
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• 제25권10호
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• pp.548-554
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• 2013

A thermodynamic analysis of the R404A refrigeration system with an internal heat exchanger using R744 as a secondary refrigerant is presented in this paper to optimize the design for operating parameters of the system. The main results are summarized as follows: The COP increases with increasing subcooling and superheating degree of R404A, internal heat exchanger and compression efficiency of the R404A cycle and evaporating temperature of the R744 cycle and decreasing temperature difference of the cascade heat exchanger and condensing temperature of the R404A cycle. The mass flow ratio decreases with increasing evaporating temperature of the R744 cycle and internal heat exchanger efficiency of the R404A cycle and decreasing subcooling and superheating degree of the R744 cycle, temperature difference of the cascade heat exchanger and condensing temperature of the R404A cycle.

• Advances in Energy Research
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• 제4권1호
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• pp.29-45
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• 2016

There has been a growing interest in the recent time for the development of solar power tower plants, which are mainly used for utility scale power generation. Combined heat and power (CHP) is an efficient and clean approach to generate electric power and useful thermal energy from a single heat source. The waste heat from the topping Brayton cycle is utilized in the bottoming HRSG cycle for driving steam turbine and also to produce process steam so that efficiency of the cycle is increased. A thermal storage system is likely to add greater reliability to such plants, providing power even during non-peak sunshine hours. This paper presents a conceptual configuration of a solar power tower combined heat and power plant with a topping air Brayton cycle. A simple downstream Rankine cycle with a heat recovery steam generator (HRSG) and a process heater have been considered for integration with the solar Brayton cycle. The conventional GT combustion chamber is replaced with a solar receiver. The combined cycle has been analyzed using energy as well as exergy methods for a range of pressure ratio across the GT block. From the thermodynamic analysis, it is found that such an integrated system would give a maximum total power (2.37 MW) at a much lower pressure ratio (5) with an overall efficiency exceeding 27%. The solar receiver and heliostats are the main components responsible for exergy destruction. However, exergetic performance of the components is found to improve at higher pressure ratio of the GT block.