• Title/Summary/Keyword: summer indoor temperature

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Preferred Indoor Temperature of College Students in Summer by Body Composition (체성분 구성에 따른 대학생의 여름철 실내 쾌적온도)

  • Shim, Huen-Sup;Jeong, Woon-Seon
    • The Korean Journal of Community Living Science
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    • v.22 no.1
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    • pp.155-161
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    • 2011
  • This study was designed to present the preferred indoor temperature of college students in summer based on their body composition. A total of 19 subjects, 10 females and 9 males, participated in this study. They sat in a climatic chamber controlled at $27^{\circ}C$ wearing a short sleeved shirt and short trousers. The air temperature decreased by $0.5^{\circ}C$ every 10 minutes until it reached $24^{\circ}C$. Oxygen uptake, rectal temperature, and skin temperature, subjective sensation were measured and recorded. Females increased the rectal temperature and decreased mean skin temperature in an air conditioned environment, showing better physiological responses. But they felt more thermal discomfort than males. The preferred indoor temperature of college students in summer was $25.3^{\circ}C$, $25.7^{\circ}C$ for females and $24.97^{\circ}C$ for males.

Development of Methods for Evaluation of Indoor Thermal Environment of Apartment Housing (공동주택의 실내 열환경에 대한 평가방법개발)

  • 윤정숙
    • Journal of the Korean Home Economics Association
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    • v.35 no.6
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    • pp.101-110
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    • 1997
  • The intent of this study is to propose a method for appraisal of the indoor thermal environment of apartment housing by measuring physical factors and residents' response to questionnaire survey. The experiments were performed on eight houses each in summer (August 18 through 31,1995) and winer (february 16 through 20,1996). It included measurements of indoor air temperature, globe temperature, relative humidity, and CO2 concentration. The questionnaire surveys were performed each in summer (July 16 through 20, 1996) and winer (February 13 through 16, 1996). And 248 cases in summer and 297 cases in winter were used in analysis. These questionnaire surveys asked residents' response about thermal sensation, humidity sensation, sense of air freshness regarding the indoor thermal environment. data acquired through the experiments and questionnaire surveys were then transferred to scales that allowed relative comparison, and measured to an appraisal standard chart. Appraisal tools included appraisal charts and radar charts. Indoor thermal environment was judged to be positive according to experiments, but residents appraised the thermal environment to be average. This difference between the two can be found in the strict standards by which residents judge the thermal environment of their apartments.

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A Study on the Indoor Climate Characteristics and Thermal Sensation Vote of the Earthen House in Summer Season (흙집의 하절기 실내 물리적 환경 특성과 온열감에 관한 연구)

  • Chan, Kook;Jeon, Ji-Hyeon;Shin, Yong-Gyu
    • Journal of the Korean housing association
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    • v.17 no.5
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    • pp.9-16
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    • 2006
  • The researches on the environmental friendly buildings have carried out on the materials, environmental property, technical elements and etc., and various buildings with these green materials have built and under construction nowadays and became a new trend of the green building. And recently, new building technique which builds the wall with the soil and wood and very easy to construct (called M Earthen House) was introduced as the green building and rapidly propagated. But the research on the indoor climatic characteristics, the ability to control the environmental comfort and the influence to the human beings of these buildings are not sufficiently identified yet. In this paper, the indoor environmental characteristics and the temperature controlling ability of these buildings in summer season were measured and analysed by the Portable Indoor Air Quality Monitor(BABUC/A, LSI) measuring equipments, ana the subjective test on the thermal environment of the subjects were carried out to evaluate the thermal comfort. The results can be summarized as follows; 1) Compared to the outdoor dry bulb temp.($15.4{\sim}28.7^{\circ}C$), the indoor temp. was $19.5{\sim}26.8^{\circ}C$. It showed the temperature controlling ability of the M earthen house was outstanding. And the indoor relative humidity, compared to the outdoor($45.4{\sim}100%$), was $58.1{\sim}76.4%$, it showed the humidity controlling ability of the M earthen house was also outstanding. 2) The thermal environment was evaluated as 'comfort'(neutral-slightly warm) and the humidity was also evaluated as 'comfort'(neutral-slightly humid). So, the results of the physical and subjective evaluation on the indoor thermal comfort in summer season were 'neutral' and 'comfort' coincidently, it was confirmed that the controlling ability of the indoor temperature and humidity of the M earthen house was very excellent.

Temperature Changes of Indoor and Outdoor by Grass Planting Block in Planting of Roof Area (잔디(Zoysia japonica Steud)식재블럭에 의한 옥상녹화지에서의 실내외 온도변화)

  • Lee, Sang Tae;Kim, Jin Seon
    • Journal of the Korean Society of Environmental Restoration Technology
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    • v.7 no.6
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    • pp.54-60
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    • 2004
  • The purpose of this study is to analyzes the effects on planting of roof with planting block and grass in a school building where users actually spend daily life to measure indoor and outdoor temperature changes with existing roof. In case of planting of roof with a summer season, the highest temperature was shown lower about $1620^{\circ}C$ in the outdoor compared to the case of not performing it. On the other hand the lowest temperature was shown higher about $0.7^{\circ}C$ and the highest temperature lower about $1.1^{\circ}C$ in the indoor. In case of planting of roof with a winter season, the lowest temperature was shown higher about $1.712.8^{\circ}C$ compared to the case of not performing it. On the other hand, it was shown higher about $3^{\circ}C$ in the indoor. The results of this study, effects of temperature control was confirmed in the indoor where planting of roof was performed higher about $3^{\circ}C$ for winter season and lower about $1^{\circ}C$ for summer season compared to the case of indoor with existing roof.

A Study on Thermal Comfort of Korea Men감s Wear in Summer - Based on Indoor Environment conditions - (하계 남성복의 온열쾌적감에 관한 연구 - 실내 환경조건을 중심으로 -)

  • 정상열;고경태
    • Proceedings of the Korean Fiber Society Conference
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    • 1997.10a
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    • pp.364-368
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    • 1997
  • The purpose of this Study was to determine thermal sensation and physiological responses for men in summer indoor environment, under various air temperature and relative humidity, with male university students. Subjective Evaluation, Heart Rate Variability(HRV), Electroencephalogram(EEG) were examined. We found that comfort of people was achieved at 50% R.H., 24C, and the difference of skin temperature was found at the calf area as air temperature changes. At low air temperature and low humidity, heart rate was decreased, but there was no change at brain wave, keeping a-wave.

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Estimation of Standard Clothing Weight for Rural Residents in Their Indoor Living (농촌지역주민의 실내환경온도에 따른 표준착의량의 추정)

  • Jeong, Young Ok;Choi, Jeong Wha
    • Journal of the Korean Society of Clothing and Textiles
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    • v.17 no.4
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    • pp.518-528
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    • 1993
  • The purposes of this study are to know the environmental conditions of rural houses, thermal sensation and clothing weight of rural residents and to estimate the standard clothing weight according to their indoor living temperature. In this study, the 631 rural residents of both sexes and all generations were selected from 5 rural districts of Kyunggi, Kangwon, Chungnam, Chonnam and Kyungbuk province and the surveys which include clothes, environmental conditions and thermal sensation carried out 4 times-once in each season-from July 1989 to April 1990. The results of this study are· as follows. 1. The ranges of outdoor temperature are $21{\sim}31^{\circ}C$ in summer, $7{\sim}20^{\circ}C$ in spring/autumn, $-15{\sim}5^{\circ}C$ in winter and those of indoor temperature are $24{\sim}31^{\circ}C$ in summer, $15{\sim}23^{\circ}C$ in spring/autumn, $11{\sim}17^{\circ}C$ in winter. The ranges of indoor temperature is within comfortable range in spring, summer and autumn but in winter it is below the range. 2. There is a negative relationship between indoor temperature and clothing weight(r = -0.927) and the simple regression equation is as follows. Y = -61.97X + 2048.44(Y : total clothing weight $g/m^2$, X : indoor temperature $^{\circ}C$). 3. There is no significant difference of clothing weight among the thermal sensation, so clothing insulation can not affect the thermal sensation. 4. Clothing weight of light-clothing-weight group is 70~75% of middle-clothing-weight group and clothing weight of heavy-clothing-weight group is 130% of middle-clothing-weight group. So the standard clothing weight for rural residents in their indoor living is estimated as Fig. 6.

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The Research on the Indoor Temperature and Humidity Control of Green Roof by Solid Growing Medium in Summer (고형화된 식생기반재를 활용한 여름철 옥상녹화의 실내 온·습도 조절효과 연구)

  • Lee, Hyun-Jung;Yeom, Dongwoo;Lee, Kyu-In
    • KIEAE Journal
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    • v.15 no.3
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    • pp.93-99
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    • 2015
  • Purpose: Various studies on the soil-based green roof systems have been conducted, and a lot of green roof systems were developed. A growing medium board is one of them which was developed for better application and maintenance, however the effect and performance of this material need to be verified. On this background, the purpose of this study is to prove cooling load reduction of green roof by monitoring experiment on the full-scale mock-ups. Method: To do this, Solid growing medium boards were installed on the mock-ups, and indoor temperature and humidity were monitored and analyzed. Result: As a results, the green roof with solid growing medium board were verified effective for controlling indoor temperature in summer.

24 hours' Exposed Temperature and Thermal Comfort in Summer (여름철 도시의 일상생활에서 경험하는 환경온도와 온냉감 평가)

  • 전정윤;이민정
    • Journal of the Korean housing association
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    • v.14 no.3
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    • pp.51-56
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    • 2003
  • All the outdoor and indoor spaces are connected with each other. The human being moves toward those spaces with temperature fluctuation between the natural and artificial temperature. We conducted an experiment which subjects were wearing the data logger in urban life, and measured 24 hours' exposed temperature and thermal comfort in summer. Results were as follows. 1. Subjects controls their micro climate like this. Most of them(84.6%) get weather information. Fashion(46.2%) and weather(30.8%) are the reasons to select clothes. They spend their time in indoor environment for 84.92% hours of a day and have an air-conditioner(61.5%) in their houses. 2. Temperature fluctuation which subjects were exposed for 24 hours were from 15.6$^{\circ}C$ to 33.8$^{\circ}C$ and average fluctuation was 9.02$^{\circ}C$. The median value of experienced temperature were 26-26.5$^{\circ}C$ and average temperature was 26.18$^{\circ}C$. They experienced cold shock of 3.96 times in a day.

The Adaptability of Korean Farmers to Environment by the Seasonal Fluctuation of Energy Expenditure, Cold and Heat Tolerance (에너지대사의 계절변동과 내한내열성으로 본 한국농업인의 환경적응 능력)

  • Choi Jeong-Wha;Hwang Kyoung-Sook
    • The Korean Journal of Community Living Science
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    • v.17 no.2
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    • pp.49-60
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    • 2006
  • It was measured the energy expenditure in each season, the cold tolerance in winter and the heat tolerance in summer. Farmers' adaptability to the change of environment was compared with those of city-dwellers such as indoor workers and street cleaners to determine the effect of living environment, especially living temperature, on the health of human body. It turned out that farmers had experienced wide range of temperature that was higher in summer and lower in winter than indoor workers. Farmers and street cleaners showed seasonal adaptation in energy expenditure, which was high in winter and low in summer. However, indoor workers did not show seasonal changes. Energy expenditure had an inverse correlation with the temperature in work place where subjects spend the longer time in a day except in female indoor workers in Seoul. And It was proved that farmers and street cleaners had stronger cold tolerance and heat tolerance than indoor workers.

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Environmental Analysis of a Windowless Delivery Swine Building : Temperature and Relative Humidity (무창분만돈사의 온.습도 환경 분석)

  • 이성현;조한근;장유섭
    • Journal of Animal Environmental Science
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    • v.3 no.2
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    • pp.77-85
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    • 1997
  • Recently, local swine producers are rapidly adopting the indoor production system which developed in foreign countries. However, this imported system is reported as not functioning properly because of different climate conditions. The objective of this project was to investigate the environment characteristics of a windowless delivery swine building. The parameters studied were the heating and cooling loads, the daily changes of indoor temperature and relative humidity, the horizontal and the vertical distributions of indoor temperature, and the effect of mist cooling on indoor temperature. From this study, the following are founded : 1. The maximum cooling and heating loads were - 317.0kcal/㎡$.$h and 336.5kal/㎡$.$h in summer and in winter. The large loads seems to be on account of inappropriate operations of ventilating fans. 2. The daily variations of relative humidity in indoor were smaller than those in outside. Those values both in summer and in winter as relative humidities in door was lower than optimum for growing pigs, the additional humidifier might be helpful to increase the relative humidity in indoor. 3. The horizontal distribution of the indoor temperature was found to be uniform in the variation range of 1$^{\circ}C$. 4. The vertical distribution of the indoor temperature was not found to be uniform; the temperature of upper part was higher than that of slot part. 5. Average values of indoor temperature became lower by 3$^{\circ}C$ by mist cooling. But the variation of temperature was found to be larger; The middle part of the room was cooled down, but the corner part of the room was not affected by misting due to uneven nozzle configuration.