• Monthly Korean Chicken
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• v.14 no.11
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• pp.114-118
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• 2008

• Journal of Energy Engineering
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• v.14 no.4 s.44
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• pp.248-258
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• 2005

In the present study, in order to estimate possibility as a waste heat recovery system, three different heat exchangers are developed. The developed heat exchangers are tile system to supply the hot water using fermentation of waste biomass. For the experiments, various biomass materials were examined to obtain the best heat recovery. Waste heat recovery system was studied numerically and experimentally. Heat exchanger system was designed specially to obtain the optimum heat exchanging performance. The biomass heat exchanger was operated for 20 minutes, after 1 hour from start-up, the temperature of the biomass dump has been raised to the possible operation temperature. From the three time operations per day, the system would be able to supply the amount of energy, about 62,400 kcal/day.

• Journal of the KSME
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• v.35 no.9
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• pp.805-815
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• 1995

히트파이프에 관한 연구는 구미, 일본 등 선진 각국뿐만 아니라, 중국, 독립국가연합 및 동구권 에서도 다년간 활발하게 진행되어 왔다. 석유파동 이후 에너지 절약을 위한 노력의 결과로 폐 열회수 장치가 많이 개발되면서 히트파이프를 전열소자로 사용한 폐열회수 장치가 상당히 늘어나 이에 소요되는 히트파이프의 생산량도 급격한 신장세를 나타내고 있다. 이는 히트파이프 자체가 응답성이 좋고, 구조가 간단하며, 전열성이 뛰어난 장점으로 인하여 많은 연구가 이루어졌기 때 문이라 하겠다.그 응용분야는 인공위성으로부터 폐열회수용 열교환기, 전기장치 전자소자의 냉각, 음향기기의 냉각, 태양열과 지열의 유효이용, 플라스틱 금형의 냉각, 공작기계의 주축냉각, 포장 기계, 주방기기, 전력케이블의 냉각, 엔진 및 브레이크의 냉각 등 응용분야가 광범위하여 급격 하게 발전하고 있다. 그러나 국내에서는 히트파이프와 관련된 학술적인 연구결과가 발표되고 있을 뿐, 체계적이며 지속적인 연구가 수행되지 못하고 있다. 또한 산업계에서도 관련제품의 대 부분을 수입에 의존하고 있으며, 일부 제작업체에서는 제품이 나오고 있으나 축적기술결여로 그 성능면에 있어서 보증이 어려워 업계의 연구개발에 대한 노력이 절실히 요구되고 있다.

• Resources Recycling
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• v.14 no.2
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• pp.28-32
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• 2005

By using thermal decomposition method, the preliminary experiments for recovery of metallic Ga from GaAs scraps produced in the manufacturing of compound semiconductors were carried out in laboratory(200 g/batch) scales. From these results, decomposition appratus with packed tower was constructed in commercial scale(30 kg/batch). The decomposition rate of GaAs increased with raising decomposition temperature, but the yield of Ga decreased over 1000$^{\circ}C. As a result, the optimum decomposition temperature was 1000~1050$^{\circ}C when the pressure of decomposition reactor was 2~2.5${\times}10^{-2} mmHg, and the yield of Ga was about 89 wt.%. The commercial decomposition apparatus was designed with packed tower because the partial pressure of As in vapor state was not reduced even if the temperature of As vapor was decreased. The recovery yield of Ga from GaAs scraps in large scale experiment showed 99%.

• Journal of Advanced Marine Engineering and Technology
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• v.38 no.6
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• pp.639-647
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• 2014

Due to global warming and depletion of fossil fuels, technologies reducing $CO_2$ emission and increasing fuel efficiency simultaneously are required. An exhaust gas heat recovery system is a technology to satisfy both issues. This study analyses three types of heat exchanger installed on an exhaust pipe. In case of plate type heat exchanger, back pressure rapidly increased and maximum cylinder pressure reduced in high speed and maximum load, and back pressure increased over twice and specific fuel consumption also increased up to 2% which were the highest increasing rate. In case of fin tube type, the amounts of exhaust emissions and specific fuel consumption rate were less than the other two types. The effect of shell and tube was in the middle. Making a decision by only the effect on engine performance, a fin tube type is the best for exhaust heat recovery systems.

• Journal of the Korea Academia-Industrial cooperation Society
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• v.18 no.4
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• pp.21-26
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• 2017

In this study, performance tests were conducted to investigate the applicability of a double-tube heat recovery ventilation system. Paper, aluminum, polymer, were investigated as materials for the inner tube using the same exhaust-air volume. In all cases, the temperature exchange efficiency of the aluminum tube was the highest, while the paper tube showed similar results to those of the polymer tube. This probably resulted from the differences in thermal conductivity and thicknesses of the materials. The humidity exchange efficiency was the highest for the paper tubes in all cases, while the aluminum tubes and polymer tubes showed similar results. The total heat exchange efficiency, which includes the values of humidity exchange and temperature exchange, was highest in the case of the paper tube, and the aluminum tube and the polymer tube showed similar results. In the case of the paper tube, sensible heat and latent heat exchange occur at the same time, and the coefficient of energy of the aluminum tube and polymer tube are large values, when to be compared with only applicably sensible heat exchange coefficient of the aluminum tube and the polymer tube of total heat exchange efficiency value. The results of this study could be applied to the design of a ventilation system.

• Journal of Energy Engineering
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• v.9 no.4
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• pp.319-327
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• 2000

산업분야의 여러공정에서 배출되는 휘발성 유기화합물은 1차적인 작업자에 대한 유해성뿐만이 아니라 대기중에 배출시의 제 2차 오염물질의 생성 때문에 최근 들어 이러한 물질의 처리에 큰 관심이 집중되고 있다. 본 연구에서는 휘발성 유기화합물로서 프로판을 사용하여 이러한 초 희박 혼합기의 제거를 위해 재생열산화법이 제안되었다. 실험장치에는 중앙에 연소실과 전기적 열량공급장치를 장착하였다. 초 희박 혼합기의 연소실에서의 산화과정과 열사화 장치의 폐열회수 특성을 연구하기 위하여 혼합기의 농도, 유속 및 연소실 최대온도와 같은 다양한 작동조건을 고려하였다. 그 결과. 재생열산화장치가 초 희박 혼합기의 산화에 적절하게 사용될 수 있음을 알았으며 최대 96%의 제거효율 얻을 수 있었다. 산화과정중에 발생하여 배출되는 CO는 운전조건을 변화시킴으로써 그 농도를 낮출 수 있었으며 열적 NOx는 배출되지 않았다. 페열회수효율은 전 운전영역에서 높게 나타났으며 그 값이 최대 98%에 이르렀다.

• The Journal of the Korea institute of electronic communication sciences
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• v.12 no.6
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• pp.1151-1158
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• 2017

The Effluent Heat Pipe integral with the heater is a device that recreates unused thermal energy from the plant in winter, and thus reuses unused energy before releasing the exhaust heat. Through the establishment of facility horticulture and glass greenhouses, we identified the problems of our agricultural heaters, and we proposed efficient agricultural efficiency and smart control systems for optimum agricultural efficiency and smart house.

• Journal of Bio-Environment Control
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• v.11 no.3
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• pp.101-107
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• 2002

This study was carried out to improve the performance of heat recovery device attached to exhaust gas flue connected to combustion chamber of greenhouse heating system. Three different units were prepared far the comparison of heat recovery performance; A-type is exactly the same with the typical one fabricated for previous study of analyzing heat recovery performance in greenhouse heating system, other two types (B-type and C-type) modified from the control unit are different in the aspects of airflow direction (U-turn airflow) and pipe arrangement. The results are summarized as follows ; 1. In the case of Type-A, when considering the initial cost and current electricity fee required for system operation, it was expected that one or two years at most would be enough to return the whole cost invested. 2. Type-B and Type-C, basically different with Type-A in the aspect of airflow pattern, are not sensitive to the change of blower capacity with higher than 25m$^3$.min$^{-1}$ . Therefore, heat recovery performance was not improved so significantly with the increment of blower capacity. This was assumed to be that air flow resistance in high air capacity reduced the heat exchange rate as well. Never the less, compared with control unit, resultant heat recovery rate of Type-B and Type-C was improved by about 5％ and 13％, respectively 3. Desirable blower capacity of these heat recovery units experimented were expected to be about 25m$^3$.min$^{-1}$ , and at the proper blower capacity, U-turn airflow units showed better heat recovery performance than control unit. But, without regard to the type of heat recovery unit, it was recommended that comprehensive consideration of system's physical factors such as pipe arrangement density, unit pipe length and pipe thickness, etc., was required for the optimization of heat recovery system in the aspects of not only energy conservation but economic system design.

• Journal of Advanced Marine Engineering and Technology
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• v.36 no.4
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• pp.445-450
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• 2012

At the limited space, the air conditioning may have difficult to control temperature or humidity for home use. Nowdays, the people reponse to temperature or humidity sensitively. This becomes the Indoor Air Quality (IAQ) is an important factor for comfortably. Heat recovery ventilator (HRV) is used for the solution of inconsistency between IAQ and power-saving. Also, the thermoelectric element is applied to HRV and compared with temperature efficiency and verifying the capacity of the system. To improve the temperature efficiency a single motor and thermoelectric element with the conductive guide vane is experimented. The results shows that it can save 23 W by using the single motor. The developed system of 250 CMH capacities with the thermoelectric element reveals the temperature efficiency improvement of 4.01% in cooling period and 2.98% in heating period compared to the conventional system.