• 대한기계학회논문집 C: 기술과 교육
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• 제4권1호
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• pp.43-47
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• 2016

지열 히트펌프 시스템은 환경 친화적이고 에너지 절감 시스템으로 알려져 있다. 특히 지중 열교환기는 초기투자비와 시스템 성능을 결정하는 매우 중요한 요소다. 수직형 지열 시스템 설계를 위해서는 현장 열응답 테스트를 통해 지중 유효 열저항을 고려해야 한다. 본 연구에서는 지열이용검토서를 통해 접수된 전국의 지중 열전도도를 지역별로 분석하였다. 전국 평균 지중 열전도도는 2.56 W/mK로 분석되었다. 지중 열전도도가 가장 높은 지역은 서울로 평균 2.68 W/mK이고, 가장 낮은 지역은 부산으로 2.28 W/mK다. 또한 해안을 접하고 있는 지역의 열전도도는 전국 평균에 비해 약 30% 낮다.

• 대한기계학회:학술대회논문집
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• 대한기계학회 2008년도 추계학술대회B
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• pp.2381-2384
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• 2008

The heat exchange between the Borehole Heat Exchanger(BHE) and the surrounding ground depends directly on ground thermal conductivity k at the certain site. The k is thus a key parameter in designing BHE and coupled geothermal heat pump systems. Currently, although a thermal hydraulic Response Test(TRT) is mostly used in practice, the thermal hydraulic TRT needs additional power and is generally time-consuming. A new, simple wireless probe for hi-speed k determination was introduced in this paper. This technique using a wireless probe is less time-consuming and requires no external source of energy for measurement and predicts local thermal properties by measuring soil temperatures along the depth. Measured temperature data along the depth was analyzed. As a result, the electronic wireless probe can replace the conventional hydraulic TRT method after carrying out the additional research on a lot of local heat flow, etc.

• 지질공학
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• 제23권4호
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• pp.389-398
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• 2013

국내에서 열물성에 관한 연구는 지역별, 암종별 열물성 파악을 위주로 진행되었으나, 지열냉난방시스템 설계 시에 실시하는 TRT (thermal response test)의 열전도도와 차이가 크게 나타남에 따라 본 연구에서는 지하수 부존량이 풍부한 지역에서 시료를 통한 열전도도와 TRT를 통한 열전도도를 비교하였다. 토양 시료의 열전도도는 1.32 W/m-K, 암석 시료의 열전도도는 2.88 W/m-K로 나타났으며, TRT로 측정된 열전도도는 3.13 W/m-K로 나타나 암석 시료보다 약 10% 정도 높게 나타났다. 연구지역은 지하수가 풍부하고 0.01의 수리경사를 가지고 있어 이 차이는 지하수 흐름에 의한 영향이라고 판단된다. 라인소스(line source) 이론에 따르면 TRT는 지반의 순수한 열전도도를 산정하는 것이 목적이므로, 국내 SCW (standing column well)형의 TRT는 라인소스 이론에 적합하지 않으며 지열냉난방시스템 설계 시에는 시료를 통한 열전도도값을 사용하는 것이 타당하다고 판단된다.

• 설비공학논문집
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• 제27권11호
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• pp.581-586
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• 2015

In this study, an analysis was performed on the performance of the solar water heating system with geo-thermal heat pump for a detached house. This system has a flat plate solar collector ($8\;m^2$) and a 3 RT heat pump. The heat pump acts as an auxiliary heater of the solar water heating system. These systems were installed at four individual houses with the same area of $100\;m^2$. The monitoring results for one year are as follows. (1) The average daily operating time of the solar system appeared to be 313 minutes in spring (intermediate season), and 135 minutes and 76 minutes in winter and summer respectively. The reason for the short operating time in summer is the high storage temperature due to low water heating load. The high storage temperature is caused by a decrease in collecting efficiency as well as by overheating. (2) The geothermal heat pump as an auxiliary heater mainly operates on days of poor insolation during the winter season. (3) Despite controlling for total house area, hot water consumption varies greatly according to the number of people in the family, hot water usage habits, etc. (4) The yearly solar fraction was 69.8 to 91.5 percent, which exceeds the maximum value of 80% as recommended by ASHRAE. So the solar collector area of $8\;m^2$ appeared to be somewhat greater for the house with an area of $100\;m^2$. (5) The observed annual efficiency of solar systems was relatively low at 13.5 to 23.6%, which was analyzed to be due to the decrease in thermal efficiency and the overheating caused by a high solar fraction.

• 설비공학논문집
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• 제28권10호
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• pp.402-407
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• 2016

Ground-coupled heat pump systems have been widely used, as they are regarded as a renewable energy source and ensure a high annual efficiency. Among the system components, borehole heat exchangers (BHE) play an important role in decreasing the entering water temperature (EWT) to heat pumps in the cooling season, and consequently improve the COP. The optimal sizing of the BHEs is crucial for a successful project. Other than the existing sizing methods, a simulation-based design tool is more applicable for modern complex geothermal systems, and it may also be useful since design and engineering works operate on the same platform. A simulation-based sizing method is proposed in this study using the well-known Duct STorage (DST) model in Trnsys. TRNOPT, the Trnsys optimization tool, is used to search for an optimal value of the length of BHEs under given ground loads and ground properties. The result shows that a maximum EWT of BHEs during a design period (10 years) successfully approaches the design EWT while providing an optimal BHE length. Compared to the existing design tool, very similar lengths are calculated by both methods with a small error of 1.07%.