This study analyzed indoor and outdoor thermal performance among different types of green roofs and green walls in order to provide information for building greening. When temperature reduction effects of green roofs and green walls were compared to the control, the effects was highest at the green roof and wall treatment, followed by green wall, green roof, and the control, which means there was temperature reduction effects by building greening. Also these temperature reduction effects was influenced by outdoor weather condition such as being typically high in sunny days but not notable in rainy days. In addition temperature reduction was effective as the air temperature was up but was not influenced by wind velocity. As for directions, the west side showed the highest temperature followed by the south and east in the order. Heat flow was found greater in control than in green roof and green wall. In addition, heat flow reversal was found as time went on.

Numerical models of composite floor systems with various thickness of phase change material and sizes of circular spacers were developed based on finite element analysis. In order to perform a heat transfer analysis, thermal properties of steels were determined and those of phase change material were estimated from experiment results. In addition, the thermal insulation performance of composite floor systems with respect to different thickness of phase change material and sizes of circular spacers was predicted. To verify the validity of analysis, analysis results were compared with vertical furnace fire test results of equivalent conditions. As a result, available thicknesses of phase change material and sizes of circular spacers were proposed to satisfy the thermal insulation criteria of Korean Standards.

Changes in land use and increase in urban energy consumption influence urban life. This study analyzed the characteristics and patterns of urban heat and presents management schemes to generate a comfortable and sustainable urban environment. The study aimed to demonstrate the positive effects of artificial ground greening on improving the microclimate through evapotranspiration using perennial herbs. We have designed a chamber that could control constant temperature and humidity, measure temperature reductions in each plant and changes in sensible heat and latent heat. This study identified Sedum kamtschaticum as the most effective plant in controlling temperature. At 22℃, 3.2℃ temperature reduction was observed, whereas four other plants showed a 1.5℃ reduction. At 25℃, 2.0℃ temperature reduction was observed. On the other hand, the use of Sedum sarmentosum resulted in the lowest effect. Zoysia japonica is the most commonly used ground covering plant, although the temperature reduction of Lysimachia nummularia was more effective at high temperature conditions. Sensible heat and latent heat were calculated to evaluate the thermal performance of energy. At a temperature >30℃, L. nummularia and S. sarmentosum emitted high latent heat. In this study, we analyzed the thermal performance of green roof perennial plants; in particular, we analyzed the evapotranspiration and temperature reduction of each plant. Since the substrate depth and types, plant species, and seasonal change may influence temperature reduction and latent heat of green roofs, further studies are necessary.

The heat generated by the internal electro-mechanical device is not transferred to the outside, to degrade the performance of the electronic device, or the cause of failure. Heat sinks are used to control the heat. Thermal performance of the heat sink of the pine type and pin type was analyzed using ANSYS software. The numerical results were compared with the thermal performance of the pine type and pin-type heat sink. The results of the numerical simulation showed that Pine type heat sink showed an approximately 58 percent better heat transfer rate with forced convection than Pin type heat sink.

The effects of coating thickness on the delamination and fracture behavior of thermal barrier coating (TBC) systems were investigated with cyclic flame thermal fatigue (FTF) and thermal shock (TS) tests. The top and bond coats of the TBCs were prepared by electron beam-physical vapor deposition and low pressure plasma spray methods, respectively, with a thickness ratio of 2:1 in the top and bond coats. The thicknesses of the top coat were 200 and 500 μm, and those of the bond coat were 100 and 250 μm. FTF tests were performed until 1140 cycles at a surface temperature of 1100 oC for a dwell time of 5 min. TS tests were also done until more than 50 % delamination or 1140 cycles with a dwell time of 60 min. After the FTF for 1140 cycles, the interface microstructures of each TBC exhibited a sound condition without cracking or delamination. In the TS, the TBCs of 200 and 500 μm were fully delaminated (> 50 %) within 171 and 440 cycles, respectively. These results enabled us to control the thickness of TBC systems and to propose an efficient coating in protecting the substrate in cyclic thermal exposure environments.

The study on ice thermal storage system is to improve total system performance in actual air-conditioning facilities. To obtain the high charging and discharging efficiency in ice thermal storage system, the improvement of thermal stratification is essential, therefore the process flow must be piston flow in the cylindrical type. In the charging process, in case of inlet flow rate the thermal stratification has a tendency to be improved with the lower flow rate and smaller temperature gradient. The experimental results are as follows. (1) In case of Thermal storage, the stable stratification is formed with 2LPM and 4LPM after τ=0.5 and the temperature of inlet brine rises. therefore because of the heat conduction effect of Ice Ball and delay of inflowing water mixing, the heat flow keeps stably till τ＝1.5. (2) In case that the flow directions inside the thermal storage tank are the upward flow in charging and the downward in discharging, thermal stratification is improved because the thermocline thickness is maintained thin and the degree of stratification increases respectively.

본 연구에서는 PMV 온열환경이 변화함에 따라 LED광원의 조도가 시작업 성능에 미치는 영향을 분석하기 위해 오류검색수정작업 평가지를 개발하였고, 오류검색수정작업의 정확도 및 소요시간을 분석하였다. 또한 작업을 진행하면서 느끼는 시각피로도에 대한 설문을 실시하여 주관적인 평가도 병행하였다. 본 실험의 PMV 온열환경 은 온도 17±1∼29±1 ℃, 습도 50±5∼60±5 % 의 범위에서 PMV 값에 따라 4가지 형태를 구성하였으며, LED광원 의 조도는 400lx, 700lx, 1000lx의 3가지 형태로 구성하여 실험을 진행하였다. 오류검색수정작업의 정확도(LED p 값=0.058, PMV*LED p값=0.083) 및 소요시간(LED p값=0.004, PMV p값=0.000)은 PMV 온열환경과 LED광원의 조 도 변화에 모두 유의하였으나, 피로도는 PMV 온열환경(p값=0.003)과 유의한 차이를 보였다.

본 연구에서는 졸-겔, 용매치환, 표면개질, 상압건조 공정과 계면활성제에 의한 템플레이팅(templating) 공법 및 소결 공정을 이용하여 실리카 에어로겔 모노리스와 메조포러스 실리카 모노리스를 각각 합성하였다. 제조된 두 종류의 실리카 모노리스는 균열이 없이 비교적 투명하였으며, 매우 높은 기공율(92-94%) 및 비표면적(800 - 840 m²/g)과 수 십 nm 수준의 기공 크기를 갖는 것으로 확인되었다. 표면개질을 적용한 실리카 에어로겔 샘플이 스피링백 효과로 인하여 메조포러스 실리카 모노리스에 비해 더욱 미세하고 균질한 나노 기공 구조를 보였을 뿐만 아니라, 그 단열 성능도 더욱 우수한 것으로 나타났다. 본 연구를 통해 합성된 두 종류의 실리카 모노리스를 중간층으로 적용한 복층 창유리의 단열성능을 측정된 모노리스의 열전도도와 이론식을 근거로 조사한 결과, 기존의 상업적으로 응용되는 공기층 삽입 복층 창유리에 비해 우수한 단열 성능을 보이는 것으로 나타났다.

The paper describes the results of performance tests and enthalpy drop tests for a large scale turbine of power plant. The objectives of performance test is to exactly evaluate the degradation of the steam turbine generator in order to provide plant information to help performance engineers identify problems, improve performance, and make economic decisions about scheduling maintenance and optimizing operation. To see the performance changes, thermal performance calculation modelling has developed. We can obtain the detailed performance calculation methods for turbine cycle, based on the reference of ASME PTC. And also the enthalpy drop test has been carried out. The technical and economical assessment for each turbine section is analyzed based on the result of turbine enthalpy drop test By comparing the performance changes throughout the operation period, we confirmed the performance reliabilities of the turbine and its conditions.

Structure Insulated Panel (SIP) is an wooden structure material with which structure and insulation functions are satisfied. Hence, it would be a cost-effective model to implement low energy house which has higher insulation and structure performance and which the wall thickness is able to be reduced. In this study, performance of thermal insulation and fire resistance were evaluated in order to verify applicability to low energy house. Fire resistance test is performed on vertical load bearing members for partitions, and the test results satisfy one hour of fire resistance condition according to KS F 2257. The members include two layers of fireproof gypsum board with thicknesses of 12.5mm attached to SIP. Thermal insulation performance is satisfied with the 2012 standard (0.225W/㎡·K). As the performance of resistance and thermal insulation are satisfied, SIP is expected to be applied to low energy building materials. In the future, the structural safety will be confirmed by structural performance and seismic performance test and the guidelines for distribution will be drawn up.

To maintain thermal performance of the Ondol system, elements of the system must be optimally designed so that the thermal performance and hot water flow can be efficiently transmitted from the Ondol system in apartment units. The purpose of this study is to propose the optimal design data and applicable design process of the Ondol system. The design process should incorporate the energy-efficient system as well as a comfortable indoor thermal environment in the early design stage.

As the Inter-floor Thermal Insulation Regulation of apartment house applies, in this study, indoor thermal performance and downward heat loss between the cases when insulation exists and doesn t exist change in the thickness of the structure slab under the inter-floor noise isolation standard, and thermal characteristic of typical floor structure will be compared and analyzed through simulation. And the resultant information will be provided as the basic data for designing Ondol heating design suitable for the property of apartment houses in Korea. As the Inter-floor Thermal Insulation Regulation applies since 2001, upward thermal performance was found to increase by 2~3% but downward heat loss decrease by approx. 30% or more representing that remarkable portion of downward heat loss is reduced. As result of comparing five prototype floor structures, upward thermal performance of the standard floor structure was found to be 70~71 W/㎡ while downward heat loss was, in the case of prototype floor structure, 10~11 W/㎡. As result of simulating the change in thermal performance as per the height of hot water supply pipes, it was found that upward thermal performance increases as the height of pipe gets higher. On the other hand, the difference of temperature between the place right above the pipe and the in-between place gets larger, which implies that thermal performance and difference of hot water temperature should be taken into account in the design of Ondol structure. The difference of upward thermal performances according to the height of pipe and downward heat losses were found to be approx. 10.8% and 5.81% respectively. The thermal performance information in prototype floor structure suggested in this study will be used for the basic data for the design of Ondol heating design.

본 실험에서는 Ardisia속 자생식물의 온도 및 습도 변화에 따른 온열환경을 조사함으로써 자생식물의 이 용에 가능한 기초 자료를 제공하고자 실시하였다. 가로 2m, 세로 1.3m, 높이 1.8m, 총 부피가 4.68m3의 밀 폐된 유리 챔버 내에 온도 조건 변화에 따른 실내공 간의 온도 및 습도변화를 측정한 결과, Ardisia속 식 물에 의한 실내온도의 변화는 24oC 이상의 고온에서 는 식물이 없는 상태에 비해 감온 효과가 있었으며 3 종의 식물 간 큰 차이는 보이지 않았다. Ardisia속 식물 중에서 백량금이 온도 변화에 따른 습도 변화가 가장 민감하게 일어나 13%의 습도 변화를 보였고 57.3±3.1%로 비교적 높은 습도를 보였는데, 이에 비해 자금우는 8%, 산호수는 9%의 습도 변화를 보였고 자 금우와 산호수 모두 대부분의 낮 시간 동안 50~55% 의 실내 적정습도 범위를 유지했다. 식물체의 실내 발 열체로서의 열성능 평가 결과, 실내 온도를 28oC에서 26oC로 감온 시에는 식재에 의한 냉방 효과가 비식재 공간에 비해 7.5~13.6배 높았고, 적정온도 이상의 고 온에서는 자금우에 의한 냉방 효과가 백량금과 산호수 에 비해 더 좋았으며 적정온도를 유지하는데 효과적이 었다. 실내 저온 조건에서는 비식재 공간이 식물을 배 치한 경우보다 높은 열량을 나타내 식물이 저온 조건 에서 냉방효율을 낮추므로 적정온도를 유지하는데 효 과적이었다. 이로서 Ardisia속 식물은 고온의 실내에서 주위의 온도를 저하시키고 적정온도를 유지시키는데 효 과적임을 알 수 있었다.

To maintain optimal performance in a floor heating system, the elements of system must be consisted of the adequate structure in order that the heat flow is efficiently transmitted from the floor structure to indoor space. The aims of this study is to propose the optimal structure type and present applicable design data of a floor heating system. The design data suggested in this study can be applied to cooperate energy efficiency design as well as comfortable indoor thermal environment in the early design stage.

In this study, copper vapor chambers with built-in cooling fins, which eliminated the soldered or brazed joints in the conventional vapor chamber, were fabricated using the metal injection molding process. The results show that with optimized molding parameters, fins with an aspect ratio up to 18 could be produced. After sintering, the densities of the fin and chamber reached 96%. With only 32 cooling fins and a small fan installed, the thermal resistance of the heat sink was 1.156 ℃/W, and the power dissipation was 40W when the junction temperature was 70℃. When copper powder was sintered onto the chamber to make a vapor chamber, the thermal resistance decreased to 1.046℃/W.

현재 국내에서 발생하는 유기성폐기물은 에너지화 정책에 따라 육상처리의 일환으로 혐기소화를 통한 바이오가스화 시설에서 처리 및 에너지원으로 전환되고 있다. 이러한 유기성폐기물 중 음식물쓰레기는 처리 단가가 높고, 바이오가스 회수 잠재력 또한 높아 바이오가스화 시설의 경제성을 높여줄 유용한 폐자원으로 여겨지고 있다. 하지만 국내에서 발생하는 음식물쓰레기의 평균 고형물함량(TS)은 18~20% 수준으로 혐기소화를 통한 바이오가스화를 위해서는 전처리가 필수적이다. 또한, 음식물쓰레기는 구성성분이 다양할 뿐만아니라 섬유질도 다량 포함하고 있어 혐기소화를 통해 바이오가스로 전환하기 위해서는 보통 30일 전후의 소화기간을 필요로 하고 있고, 특히 파쇄/선별의 단순 물리적 전처리만 거친 음식물쓰레기의 경우에는 30일 이상의 혐기소화 기간이 필요한 것으로 알려져 있다. 이에 본 연구에서는 사전 연구를 통해 도출된 음식물쓰레기 열가수분해 운전조건을 적용해 습식 혐기소화 반응조에 적합하도록 U원 구내 식당에서 발생한 음식물쓰레기를 전처리하였고, 이렇게 얻어진 음식물쓰레기 가용화물을 실험실 규모의 중온 단상 혐기소화 반응조에 투입해 일반적인 중온 이상습식 혐기소화 체류시간(35일)의 절반 수준인 18일의 체류시간으로 운전하는 조건에서 바이오가스 수율 및 반응조 안정성 등을 평가하고자 하였다.

구명 조끼는 익수자의 부력을 유지시키는 기능을 가지며, 낮은 해수 온도에서 저체온증에 빠지는 시간을 단축 시킬 수 있는 역 할을 할 수 있다. 본 논문은 서멀 마네킹 실험과 수치적 방법을 적용하여 단열성능을 향상 시키기 위해서 개발된 팽창형 구명 조끼와 폼형 구명 조끼의 단열성능 및 저체온증 방지 효과를 평가하였다. 단열성능 평가를 위해서 서멀마네킨을 이용하여 열유속 및 열저항을 계측하였으 며, 본 연구에서 제시된 구명 조끼의 단열성능을 기존의 제품과 비교하여 검토하였다. 또한 저체온증에 빠지는 정도를 상대적으로 파악하기 위해서 유한요소해석을 이용하여 구명 조끼의 종류에 따른 체온 저감 시간을 예측하고 이를 비교 평가하였다. 저체온증 예측모델은 Pennes의 신체 열전달 해석 모델을 기반으로 작성되었으며, 실험으로부터 계측한 열저항 값을 이용하여 대류 열전달 조건을 환산하여 계산되었다. 그 결과 본 연구에서 단열성능을 향상시키기 위해서 제시된 하는 구명 조끼가 기존 제품에 비해 단열성능이 우수하게 평가됨을 확인하였다.

This study measured temperatures and albedos of urban surfaces for different colors and materials during summer, and calculated the energy budget over different urban surfaces to find out the thermal performance affecting the heat built-up. The study selected six surface colors and 13 materials common in urban landscape. Their surface temperatures (Ts) and albedos were measured at a given time interval in the daytime from June to August. Average Ts over summer season for asphalt-colored brick was 4.0℃ higher than that for light red-colored one and 9.7℃ higher than that for white-colored one. The Ts for artificial surface materials of asphalt paving, brown brick wall, and green concrete wall was 6.0℃ higher than that for natural and semi-natural ones of grass, grassy block, and planted concrete wall. There was the greatest difference of 16.3℃ at midafternoon in the Ts between asphalt paving and planted concrete wall. Average albedo over summer season of surface materials ranged from 0.08 for asphalt paving to 0.67 for white concrete wall. This difference in the albedo was associated with a maximum of 15.7℃ difference at midafternoon in the Ts. Increasing the albedo by 0.1 (from 0.22 to 0.32) reduced the Ts by about 1.3℃. Average storage heat at midday by natural and semi-natural surfaces of grass and grassy block was about 10% lower than that by artificial ones of asphalt, light-red brick, and concrete. Reflected radiation, which ultimately contributes to heating the urban atmosphere, was 3.7 times greater for light-red brick and concrete surfaces than for asphalt surface. Thus, surfaces with in-between tone and color are more effective than dark- or white-colored ones, and natural or semi-natural surfaces are much greater than artificial ones in improving the urban thermal environment. This study provides new information on correlation between Ts and air temperature, relationship between albedo and Ts, and the energy budget.