본 연구는 고온과 연속광 조건 하의 복합 스트레스 환경에서 실내 관엽식물이 어떤 엽록소 형광 반응을 나타내는지에 대해 조사 및 분석했다. 대부분의 실내 관엽식물은 이와 같은 스트레스 조건에서 광도가 높아질수록 Fo, Fj 단계에서 형광 밀도가 증가하고 Fi, Fm 단계에서 형광 밀도가 감소한 것으로 나타나 광계II의 반응중심에 있는 전자수용체 퀴논의 상당량이 환원상태에 놓여있음을 암시했다. 뿐만 아니라 최대 양자효율과 최대 양자수율을 나타내는 Fv/Fm와 ΦPo는 광도가 높아질수록 낮게 나타났고 반대로 에너지 소산을 나타내는 DIo/RC 값은 광도가 높아지는 것에 비례하여 높게 나타났다. 이를 미루어보아 고광도 수준에서는 대부분의 광자가 제대로 활용되지 못했음을 알 수 있었다. 특히나 아이비와 테이블야자 는 고온 및 연속광 조건에서 현저한 스트레스를 받는 것으로 분석되었는데 이와 같은 스트레스 조건의 실내에서 재배할 경우 60 μmol m-2 s-1의 저광도 수준에서 재배하는 것이 바람직한 것으로 보인다. 반대로 무늬스킨답서스와 관음죽은 스트레스를 비교적 적게 받는 것으로 나타나 고온과 연속광 조건하에서도 광도의 세기와는 무관하게 양호한 생육이 가능할 것으로 판단된다.

본 연구는 가정용 냉장고를 대상으로 냉동실과 냉장실의 설정온도를 각기 달리할 경우 냉동실과 냉장실 고내의 온도를 실측하여 냉장고 식품 보관 온도분포를 추정하고자 한다. 또한, 각 실의 설정온도를 중심으로 상하로 온도차가 얼마나 큰가를 파악하고, 설정온도로 회복하는데 소요되는 시간을 파악하고자 한다. 그리고 설정된 온도로 회복하기 위해 소비하는 전력량을 측정함으로서 가정용 냉장고의 최적 설정조건을 제시하고자 한다. 그 결과, 냉동실 온도가 –18℃를 실현한 조건은 Case 3, Case 6, Case 8, Case 9로 냉동실 조건보다는 냉장실의 설정온도를 저온으로 할 경우에만 냉동실의 온도가 적정온도를 나타냈다. 이 조건에서 냉장실의 온도는 최저 –1.1℃, Case 6은 –1.5℃, Case 8은 –1.1℃, Case 9는 –0.8℃로 영하의 온도를 보였다. 또한 각 케이스의 운전시작 10시간 동안 누적소비전력량은 Case 4를 제외하고는 냉동실 및 냉장실의 설정온도가 낮을수록 컸으며, Case 4는 운전시작이 13:30분에 시작되었기에 09시경에 운전을 시작한 다른 조건보다는 낮시간의 환경온도가 높은 이유로 전력소비가 크다는 것을 확인하였다.

The torque shear high strength bolt is clamped normally at the break of pin-tail specified. However, the clamping forces on slip critical connections do not often meet the required tension, as it considerably fluctuates due to torque coefficient dependent on lubricant affected temperature. In this study, the clamping tests of torque shear bolts were conducted independently at indoor conditions and at construction site conditions. During last six years, temperature of candidated site conditions was recorded from -11℃ to 34℃. The indoor temperature condition was ranged from -1 0℃ to 50℃ at each 10℃ interval. As for site conditions, the clamping force was reached in the range from 159 to 210 kN and the torque value was from 405 to 556 Nㆍm. The range of torque coefficient at indoor conditions was analyzed from 0.126 to 0.158 while tensions were indicated from 179 to 192 kN. The torque coefficient at site conditions was ranged from 0.118 to 0.152. Based on this test, the variable trends of torque coefficient, tension subjected temperature can be taken by statistic regressive analysis. The variable of torque coefficient under the indoor conditions is 0.13%/℃ while it reaches 2.73%/℃ at actual site conditions. When the indoor trends and site conditions is combined, the modified variable of torque coefficient can be expected as 0.2% /℃. and the modified variable of tension can be determined as 0.18%/℃.

Residential thermal conditions are important because people spend the majority of their time in the home environment. Indoor temperature and relative humidity(RH) were measured continuously over 1 year in 14 residences in Seoul, Korea. The relationship between residential indoor and outdoor conditions were determined by four meteorological parameters-temperature, apparent temperature(AT), RH, and absolute humidity(AH). Outdoor and indoor temperature, AT and AH were closely correlated, but RH was not. While indoor temperatures, AT, and AH were significantly higher than the corresponding outdoor levels, indoor RH was significantly lower than outdoor RH. Regression models between indoor and outdoor temperature detected a heating threshold at 15.0oC of outdoor temperature. The indoor thermal conditions were significantly different by the two residence types. Indoor temperatures in apartments were lower in summer and higher in winter than those in detached houses. However, indoor RHs in apartments were lower than in detached houses. During tropical nights, the daily temperature range was higher in residences with air-conditioning than in naturally ventilated residences.

본 연구는 유가상승에 따른 온실의 경영비 절감과 적설지역의 적설재해를 경감시키기 위하여 온수배관을 이용한 난방효과 및 온실곡부의 온도 상승효과를 구명하고자 수행되었다. 전체적으로 실험구의 온도가 대비구 보다 약 2.0~6.0℃정도 높게 나타났다. 천창부직포를 개방한 경우, 최저온도가 약 3.0~12.0℃범위로 나타나 적극적인 난방을 하게 되면 적설피해도 어느 정도 예방할 수 있을 것으로 판단되었다. 온실 내부의 높이별 온도 차이는 미미한 것으로 나타났다. 재배작물에 따른 온실의 최대난방부하는 각각 약 37,000 kcal·h-1 및 41,700 kcal·h-1정도이었다. 실험기간동안 최저 외기온 -11.9~4.0℃ 범위에서 설정온도별 발열량은 95,000~322,000 kcal 정도로서 시간당 6,050~20,900 kcal·h-1정도의 범위에 있었고, 최대난방부하와 비교하면 약 15~56%정도의 난방에너지를 공급할 수 있을 것으로 나타났다. 그리고 실험기간동안 전체 발열량과 소비전력량은 각각 2,629,025 kcal 및 677.3 kWh이었다. 화석연료인 경유로 난방 할 경우, 실험기간동안 소요되는 소비량은 291L 정도이었고, 비용은 331,700 won인 것으로 나타났다. 전력사용에 대한 총비용은 24,400 won정도로서 경유 소비 비용의 7.5%정도로 나타났다. 또한 전체 소비전력량을 에너지로 환산하면 약 582,200 kcal이고, 이 에너지는 전체 발열량의 약 22%에 불과하였다.

A system has been developed to reduce fluctuation of the indoor temperature in a radiant floor heating system. The system we developed and implemented is called BoilerMan. With the BoilerMan system the hot water circulation pump is controlled by computer software which implements a unique strategy. To minimize the system development time a user-friendly development environment was used. This development environment was useful in the implementation and testing of the efficiency of our strategy. The environment also serves as an easy means for system maintenance. The BoilerMan went through a few test runs against a real apartment house and the result showed significant reductions in the initial temperature overshoots against the target values. It also reduced the operatingtime of the hot water circulation pump. Such positive results were possible due to our unique strategy that exploits heating efficiency information collected from the past run of the very same system. Since the strategy was implemented with embedded software, it makes the BoilerMan flexible, too.

In this study, the heat insulating performance increase the indoor temperature of the building is applied to the concrete was compared with plain concrete. As a result, the indoor surface at the outside temperature of 4.69∼7.32 ℃ temperature conditions showed a difference of up to 1.10 ℃, the lowest 0.54 ℃, indoor temperature is up to 0.95 ℃, 0.63 ℃ lower results showed a minimum.

In this study, the heat insulating performance increase the indoor temperature of the building is applied to the concrete was compared with plain concrete. As a result, the indoor surface at the outside temperature of 10.4 ~ 22.4 ℃ temperature conditions showed a difference of up to 0.6 ℃, the lowest 0.6 ℃, indoor temperature is up to 0.2 ℃, 0.2 ℃ lower results showed a minimum.

Thermal neutrality is not enough to achieve thermal comfort. The temperature level can be the optimal, and still people may complain. This situation is often explained by the problem of local discomfort. Local discomfort can be caused by radiant asymmetry, local air velocities, too warm and too cold floor temperature and vertical temperature difference. This temperature difference may generate thermal discomfort due to different thermal sensation in different body parts. Therefore, thermal comfort can not be correctly evaluated without considering these differences. This study investigates thermal discomfort sensations of different body parts and its effect on overall thermal sensation and comfort in air-heating room. Experimental results of evaluating thermal discomfort at different body parts in an air-heating room showed that thermal sensation on the shoulder was significantly related to the overall thermal sensation and discomfort. Although it is known that cool-head, warm-foot condition is good for comfort living, cool temperature around the head generated discomfort

Draft is defined as an unwanted local cooling of the human body caused by air movement. It is a serious problem in many ventilated or air conditioned buildings. Often draft complaints occur although measured velocities in the occupied zone maybe lower than prescribed in existing standards. Purpose of this study is to clarify the evaluation of thermal comfort based on temperature and air velocity in winter. Experiments were performed in an environmental chamber in winter. Indoor temperature and air velocity was artificially controlled. The experiments were performed to evaluate temperature conditions and air velocity conditions by physiological and psychological responses of human. According to physiological responses and psychological responses, it was clear that the optimum air velocity is about 0.15 m/s and 0.30 m/s.