• Title/Summary/Keyword: greenhouse dehumidification

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The Comparative Analysis of Drying-Conditions, -Rates, -Defects and Yield, and Heat-Efficiency in Solar-Dehumidification-Drying of Oaks With Those in Conventional Air-, Semi-Greenhouse Type solar-, and Kiln- Drying (참나무류(類)의 제습태양열건조(除濕太陽熱乾燥)의 조건(條件), 속도(速度), 결함(缺陷), 수율(收率) 및 열효율(熱效率)과 관행(慣行) 천연(天然), 반온실형(半溫室型) 태양열(太陽熱) 및 열기건조(熱氣乾燥)와의 비교(比較)·분석(分析))

  • Lee, Hyoung-Woo;Jung, Hee-Suk
    • Journal of the Korean Wood Science and Technology
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    • v.17 no.1
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    • pp.22-54
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    • 1989
  • Seasonal semi-greenhouse type solar-drying of 2.5cm-and 5.0cm-thick lumber of Quercus aliena Blume and Quercus variailis Blume was carried out to investigate the possibility of solar-drying of wood and to decide the active solar-drying period in Korea. In the active solar-drying period obtained solar-dehumidification, semi-greenhouse type solar-, air- and kiln-drying of 2.5cm -thick lumber of oaks were carried out to analyze drying-rates. -defects, and -yield in each drying-method and to calculate daily total absorbed solar-radiation the solar dryers. The energy balance equations were set up, considering all the energy requirements, to analyze the heat efficiencies of semi-greenhouse type solar and solar-dehumidification-dryer. In a seasonal drying the drying rate of semi-greenhouse type solar-dryer was highest in summer, and greater in fall, spring, and winter in order. Solar-drying time was 45% in summer to 50% in winter of the air-drying rime, and more serious drying-defects occurred in air-drying than in solar-drying. In the active solar-drying period. April, May, and June, the average drying rate in solar-dehumidification-drying was 1.0%/day and greater than 0.8%/day in semi-greenhouse type solar-drying. In solar-dehumidification-drying the time required to dry lumber to 10% moisture content was less than 60 days, and solar-dehumidification-drying showed the highest drying-yield, 65.01%, than the other drying methods. The daily total absorbed solar radiations were 8.51MJ on the roof collector and 6.22 MJ on the south wall collector. In the energy blance 69.48% of total energy input was lost by heat conduction through walls, roof. and floor 11.68% by heat leakage, 0.33% by heating the internal structures of the solar-dryer and 5.38% by air-venting. Therefore the heat efficiency of semi-greenhouse type solar-dryer 13.13%, was lower than that of solar-dehumidification-dryer, 14.04%. Solar-drying of lumber in Korea showed the possibility to reduce the air-drying-time in every season and the efficiency of solar-dehumidification drying was higher than that of semi-greenhouse type solar-drying.

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Improvement of Cooling Efficiency in Greenhouse Fog System Using the Dehumidifier (제습기를 이용한 온실 포그냉방시스템의 효율향상)

  • Nam Sang Woon;Kim Kee Sung;Giacomelli Gene A.
    • Journal of Bio-Environment Control
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    • v.14 no.1
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    • pp.29-37
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    • 2005
  • In order to provide fundamental data on utilization of dehumidifier in greenhouses, a condensing type dehumidifier using ground water as a coolant was developed and tested dehumidification performance. The developed dehumidifier was applied to greenhouse with fog cooling system and effect of dehumidification on improvement of evaporative cooling efficiency was analyzed. Results of the dehumidifier performance test showed that dehumidification using ground water as a coolant was sufficiently possible in fog cooling greenhouse. When the set point temperature of greenhouse cooling was $32^{\circ}C$ and as temperatures of ground water rose from $15^{\circ}C\;to\;18^{\circ}C,\;21^{\circ}C\;and\;24^{\circ}C$, dehumidification rates decreased by $17.7\%,\;35.4\%\;and\;52.8\%$, respectively. As flow rates of ground water reduced to $75\%\;and\;50\%$, dehumidification rates decreased by $12.1\%\;and\;30.5\%$, respectively. Cooling efficiency of greenhouse equipped with fog system was distinctly improved by artificial dehumidification. When the ventilation rate was 0.7 air exchanges per minute, dehumidification rates of the fog cooling greenhouse caused by natural ventilation were 53.9%-74.4% and they rose up to 75.4%-95.9% by operating the dehumidifier. In case of using the ground water of $18^{\circ}C$ and flow rate of design condition, it was analyzed that whole fog spraying water can be dehumidified even if the ventilation rate is 0.36 exchanges per minute. As a utilization of dehumidifier, it is possible to improve cooling efficiency of fog system in naturally ventilated greenhouses.

Analysis of Solar Radiation and Heat-Efficiency in Semi-Greenhouse Type Solar-Dehumidification Lumber Dryer (반온실형(半溫室型) 제습(除濕).태양열(太陽熱) 목재(木材)드라이어의 일사량(日射量)과 열효율분석(熱效率分析)에 관(關)한 연구(硏究))

  • Lee, Hyoung-Woo
    • Solar Energy
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    • v.9 no.3
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    • pp.3-12
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    • 1989
  • Semi-greenhouse type solar-dehumidification drying of oak was carried out to investigate the possibility to dry wood using solar energy in Korea. The energy balance equation was set up, considering all the energy requirements, and the solar radiation was calculated to analyze the efficiencies of solar dryer with and without the dehumidifier. The average temperature inside dryer and collector rose up to $52^{\circ}C$ and $70^{\circ}C$, respectively. The average daily total beam, diffuse, and ground-reflected radiations were 7.27MJ, 8.70MJ, and 0.33MJ on the roof and 2.08MJ, 4.84MJ, and 5.37MJ on the south wall collector, respectively. Heat efficiency of solar dryer was 14.04% with dehumidifier and 13.13% without dehumidifier. The energy required to remove 1g of water from wood was 0.0289MJ/g in solar-dehumidification drying and 0.0310 MJ/g in semi-greenhouse type solar drying.

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Development of a Refrigeratory-Based Dehumidifier for Humidity Environment Control in Greenhouse (시설원예 습도환경 제어를 위한 냉각식 제습기 개발)

  • Kang, G.C.;Yon, K.S.;Ryou, Y.S.;Kim, Y.J.;Kang, Y.K.;Paek, Y.
    • Journal of Biosystems Engineering
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    • v.32 no.4
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    • pp.247-255
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    • 2007
  • During the winter season in Korea, the relative humidity of greenhouse at night often exceeds 90% because air temperature inside the greenhouse is usually controlled using a heater with all of windows closed to minimize heat loss, thereby requiring the use of a dehumidifier that can maintain optimum humidity levels of $70{\sim}80%$ to provide a good growth condition of crops. Also, such a high humid condition can cause the development of a pest, such as insects, fungi or diseases. However, the use of most conventional dehumidifiers for low temperature dehumidification is limited because their performance is degraded due to frost accumulation on the evaporator coil. This study was carried out to develop a refrigeratory-based dehumidifier suitable for low temperature dehumidification in greenhouse cultivation. The developed dehumidifier consists of a condenser and an evaporator installed separately so that relative and absolute humidity levels can be reduced when air passed through the condenser and evaporator, respectively. The prototype dehumidifier showed a dehumidification capacity of $5{\sim}7kg/h$ when air with a temperature of $15{\sim}25^{\circ}C$ and a relative humidity of $70{\sim}95%$ came into the dehumidifier. Under the condition that either temperature or relative humidity was fixed, the amount of condensed water was proportional to the levels of both temperature and relative humidity.

Development of Dehumidifier for Protected Horticulture (시설원예용 제습기 개발)

  • Yon K.S.;Kang G.C.;Kang Y.K.;Ryou Y.S.;Kim Y.J.;Paek Y.
    • Journal of Biosystems Engineering
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    • v.30 no.2 s.109
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    • pp.110-113
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    • 2005
  • Relative humidity of air In the greenhouse has to be maintained at 70 to 80 percents to provide a better growth condition of crops. To control relative humidity of air in the greenhouse, a dehumidifier functioning by refrigeration cycle was designed and manufactured in this study. And, results of its performance test in the greenhouse site were reported. The developed dehumidifier has separated condenser and evaporator in the heat exchanger part in order to increase dehumidifying capacity at a low temperature condition. When the conditions of incoming air into the dehumidifier were temperature of $15\~25^{\circ}C$ and relative humidity of $0\~95\%$, quantity of condensed water per hour, ie, dehumidification rate was $4.7\~7.0\;kg/hr$. Relative humidity difference was not greater than 5 percents at various locations in the greenhouse due to proper distributing of dehumidified air through vinyl duct. Thermal energy output from the developed dehumidifier was about 8,5000 kcal/hr that was 7 percents of maximum greenhouse heating load of 10 a.

Dehumidification and Evaporative Cooling Efficiency by Water Pipes in Greenhouse (냉수파이프에 의한 온실의 제습 및 증발냉각효율)

  • 김문기;남상운;윤남규
    • Journal of Bio-Environment Control
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    • v.7 no.3
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    • pp.237-245
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    • 1998
  • Greenhouse crop production under critical summer climate In Korea has considerable difficulties because of high temperature and relative humidity. In this study, some water pipes were tested as a means of the dehumidification and increment of evaporative cooling efficiency. As a result of heat transfer characteristic analysis, overall heat transfer coefficient of copper pipe was larger than steel pipe, and estimated values were smaller than measured values. The condensed quantities of vapor were not significantly different between copper pipe and steel pipe, however dehumidifying effect by the water pipes was significantly large. It was estimated based on the results that the evaporative cooling system by the water pipe will be able to increase the evaporative cooling efficiency of about 48%, and decrease the temperature of about 1.3$^{\circ}C$.

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Dehumidification and Temperature Control for Green Houses using Lithium Bromide Solution and Cooling Coil (리튬브로마이드(LiBr) 용액의 흡습성질과 냉각코일을 이용한 온실 습도 및 온도 제어)

  • Lee, Sang Yeol;Lee, Chung Geon;Euh, Seung Hee;Oh, Kwang Cheol;Oh, Jae Heun;Kim, Dea Hyun
    • Journal of Bio-Environment Control
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    • v.23 no.4
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    • pp.337-341
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    • 2014
  • Due to the nature of the ambient air temperature in summer in korea, the growth of crops in greenhouse normally requires cooling and dehumidification. Even though various cooling and dehumidification methods have been presented, there are many obstacles to figure out in practical application such as excessive energy use, cost, and performance. To overcome this problem, the lab scale experiments using lithium bromide(LiBr) solution and cooling coil for dehumidification and cooling in greenhouses were performed. In this study, preliminary experiment of dehumidification and cooling for the greenhouse was done using LiBr solution as the dehumidifying materials, and cooling coil separately and then combined system was tested as well. Hot and humid air was dehumidified from 85% to 70% by passing through a pad soaked with LiBr, and cooled from 308K to 299K through the cooling coil. computational Fluid Dynamics(CFD) analysis and analytical solution were done for the change of air temperature by heat transfer. Simulation results showed that the final air temperature was calculated 299.7K and 299.9K respectively with the deviation of 0.7K comparing the experimental value having good agreement. From this result, LiBr solution with cooling coil system could be applicable in the greenhouse.

Dehumidification and Increment of Efficiency of Evaporative Cooling in Greenhouse with Water Pipe (냉수배관에 의한 온실의 제습 및 증발냉각효율 증대효과)

  • 김문기;남상운;윤남규
    • Proceedings of the Korean Society for Bio-Environment Control Conference
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    • 1995.10a
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    • pp.103-106
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    • 1995
  • 최근 시설재배 면적이 급증하고 있는 것에 부응하여 시설을 이용한 작물의 주년안정생산에 관한 연구가 활성화되고 있다. 그러나 여름철의 고온극복과 냉방에 관한 연구는 아직까지도 많은 어려움을 겪고 있다. 우리나라와 같이 사계절이 뚜렷한 기후여건에서는 겨울철의 난방 및 보온에 못지 않게 여름철의 냉방 및 고온극복 대책이 주년안정생산에 있어서 빼놓을 수 없는 중요한 과제가 아닐 수 없다. (중략)

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Variation of Vapor Pressure Deficit and Condensation Flux of Air Heating Plastic Greenhouse Installed with Two Layers Thermal Curtain in Winter (이층커튼 온풍난방 플라스틱온실의 겨울철 포차 및 결로량 변화)

  • Lee, Hyun-Woo;Kim, Young-Shik;Sim, Sang-Youn;Lee, Jong-Won
    • Journal of Bio-Environment Control
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    • v.22 no.1
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    • pp.35-41
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    • 2013
  • This study was conducted to provide data necessary for reducing the condensation on greenhouse covering in winter season. The variation of VPD (Vapor Pressure Deficit) and condensation flux was analyzed in experimental tomato greenhouse. VPD values in experimental plastic greenhouse were greater than 0.2 kPa of disease prevention threshold, and lower than 0.5 kPa of threshold for dehumidification. The surface temperature of inside covering was slightly higher than the average temperature of outside and above curtain, and changed according to outside temperature. The humidity above curtain was nearly 100% and good condition for condensation. The humidity below curtain was 75~90% and comparatively stable condition for growing. The condensation flux value in experimental greenhouse corresponded with result of Seginer and Kantz (1986).