• Journal of Biosystems Engineering
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• v.25 no.3
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• pp.213-220
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• 2000

Grafting of fruit-bearing vegetables has been widely used to increase the resistance to soil-borne diseases, to increase the tolerance to low temperature or to soil salinity, to increase the plant vigor, and to extend the duration of economic harvest time. After grafting, it is important to control the environment around grafted seedlings for the robust joining of a scion and rootstock. Usually the shading materials and plastic films are used to keep the high relative humidity and low light intensity in greenhouse or tunnel. It is quite difficult to optimally control the environment for healing and acclimation of grafted seedlings under natural light. So the farmers or growers rely on their experience for the production of grafted seedling with high quality. If artificial light is used as a lighting source for graft-taking of grafted seedlings, the light intensity and photoperiod can be easily controlled. The purpose of this study was to develop a prototype system for the graft-taking enhancement of grafted seedlings using artificial lighting and to investigate the effect of air current speed on the distribution of air temperature and relative humidity in a graft-taking enhancement system. A prototype graft-taking system was consisted by polyurethane panels, air-conditioning unit, system controller and lighting unit. Three band fluorescent lamps (FL20SEX-D/18, Kumho Electric, Inc.) were used as a lighting source. Anemometer (Climomaster 6521, KANOMAX), T-type thermocouples and humidity sensors (CHS-UPS, TDK) were used to measure the air current speed, air temperature and relative humidity in a graft-taking system. In this system, air flow acted as a driving force for the diffusion of heat and water vapor. Air current speed, air temperature and relative humidity controlled by a programmable logic controller (UP750, Yokogawa Electric Co) and an inverter (MOSCON-G3, SAMSUNG) had an even distribution. Distribution of air temperature and relative humidity in a graft-taking enhancement system was fairly affected by air current speed. Air current speed higher than 0.1m/s was required to obtain the even distribution of environmental factors in this system. At low air current speed of 0.1m/s, the evapotranspiration rate of grafted seedlings would be suppressed and thus graft-taking would be enhanced. This system could be used to investigate the effects of air temperature, relative humidity, air current speed and light intensity on the evaportranspiration rate of grafted seedlings.

• Proceedings of the Korea Water Resources Association Conference
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• 2015.05a
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• pp.568-572
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• 2015

하천횡단구조물은 하천을 횡단하는 시설물로, 크게 농업용수 취수용 보, 하도개수시 유속제어를 위한 낙차공 등을 들 수 있으며, 각각의 설치목적에 따라 그 형태와 설계제원(높이, 마루폭, 바닥보호공의 길이 등)이 다르나, 하천을 횡단하여 인공적인 구조물을 설치하는 형태는 동일하다. 따라서, 하천횡단구조물은 홍수시 배수위 영향으로 상류에 수위상승을 초래하여 하천의 치수 안전도를 저하시킬 뿐 아니라 직하류에서는 하상의 세굴에 의하여 호안 및 제방이 파괴되는 경우도 빈번하게 발생하고 있다. 또한, 하천횡단구조물은 생태계의 이동통로로서의 종적 연속성을 차단하는 것이다. 즉 하천을 따라 거슬러 올라가는 소하성 어종(anadromous species)이나 하천에서 바다로 내려가는 강하성 어종(catadromous species)과 같은 회유성 어종의 이동을 차단하기도 하며, 회유성 어종 이외에도 치어와 성어의 성장환경이 다른 어종의 경우는 상 중 하류를 옮겨가며 성장하는 어종의 이동도 차단하고 있다. 하천횡단구조물은 치 이수적 측면에서 반드시 필요한 하천구조물로서 치수, 생태 및 경관의 측면에서 여러 가지 문제점을 가지고 있으나 지금까지는 어도설치나 기능을 상실한 보의 철거 등 소극적인 수준에 머무르고 있기에 적극적인 개선대책이 필요한 실정이다. 따라서, 하천횡단구조물로 인한 문제점을 파악하기 위하여 경남의 20개 시 군 684개의 지방 하천에 설치된 7,725개의 하천횡단구조물에 대한 전수조사를 실시하고, 구조형식, 높이, 재료, 어도 설치 여부, 세굴현황 등을 분석하였다. 하천횡단구조물의 용도별 구성비는 보가 49%, 낙차공이 51%로 나타났으며, 구조형식은 콘크리트 구조가 72%, 콘크리트 석재 구조가 25%, 석재 구조가 3%인 것으로 분석되었다. 또한, 하천횡단구조물의 본체 높이별 구성비는 0.5m 이하가 14%, 0.5~1.0m가 35%, 1.0~1.5m가 34%, 1.5~2.0m가 10%, 2.0m 이상이 7%인 것으로 조사되었다. 어도 설치는 약 9%인 669개소에 설치되어 있었으나 대부분이 어류 등의 이용하는 생태통로 기능을 발휘할 수 없는 것으로 분석되었다. 따라서, 이러한 문제점을 해결하기 위해서 하폭, 하상고, 하상경사, 굴입정도, 유사량 등의 하도특성 및 용수이용 여건 등을 고려하여 유공관을 이용한 지하보, 석재 아치의 원리를 이용한 계단식 자연형 보/낙차공, 부분 램프 설치, 거석 놓기 등의 개선방안을 제안하였다. 제안된 개선방안은 하천복원 및 하천개수 사업 시행시에 반영하여 합리적인 하천복원 및 관리에 활용될 수 있을 것이다.

• Journal of Bio-Environment Control
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• v.32 no.2
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• pp.148-156
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• 2023

This study was conducted in an indoor cultivation room and chamber where environmental control is possible to investigate the effect of temperature and irrigation interval on photosynthesis, growth and growth analysis of potted seedling cucumber. The light intensity (70 W·m^-2) and humidity (65%) were set to be the same. The experimental treatments were six combinations of three different temperatures, 15/10℃, 25/20℃, and 35/25℃, and two irrigation intervals, 100 mL per day (S) and 200 mL every 2 days (L). The treatments were named 15S, 15L, 25S, 25L, 35S, and 35L. Seedlings at 0.5 cm in height were planted in pots (volume:1 L) filled with sandy loam and treated for 21 days. Photosynthesis, transpiration rate and stomatal conductance at 14 days after treatment were highest in 25S. These were higher in S treatments with a shorter irrigation interval than L treatments. Total amount of irrigation water was supplied evenly at 2 L, but the soil moisture content was highest at 15S and lowest at 25S > 15L > 25L, 35S and 35L in that order. Humidity showed a similar trend at 15/10℃ (61.1%) and 25/20℃ (67.2%), but it was as high at 35/25℃ (80.5%). Cucumber growth (plant height, leaf length, leaf width, chlorophyll content, leaf area, fresh weight and dry weight) on day 21 was the highest in 25S. Growth parameters were higher in S with shorter irrigation intervals. Yellow symptom of leaf was occurred in 89.9% at 35S and 35L, where the temperature was high. Relative growth rate (RGR) and specific leaf weight (SLA) were high at 25/20℃ (25S, 25L), RGR tended to be high in the S treatment, and SLA in the L treatment. Water use efficiency (WUE) was high in the order of 25S, 25L > 15S > 15L, 35S, and 35L. As a result of the above, the growth and WUE were high at the temperature of 25/20℃.

• Journal of Internet Computing and Services
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• v.16 no.1
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• pp.57-65
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• 2015

As information technology fusion is accelerated, the researches to improve the quality and productivity of crops inside a plant factory actively progress. Advanced growth environment management technology that can provide thermal environment and air flow suited to the growth of crops and considering the characteristics inside a facility is necessary to maximize productivity inside a plant factory. Currently running plant factories are designed to rely on experience or personal judgment; hence, design and operation technology specific to plant factories are not established, inherently producing problems such as uneven crop production due to the deviation of temperature and air flow and additional increases in energy consumption after prolonged cultivation. The optimization process has to be set up in advance for the arrangement of air flow devices and operation technology using computational fluid dynamics (CFD) during the design stage of a facility for plant factories to resolve the problems. In this study, the optimum arrangement and air flow of air circulation fans were investigated to save energy while minimizing temperature deviation at each point inside a plant factory using CFD. The condition for simulation was categorized into a total of 12 types according to installation location, quantity, and air flow changes in air circulation fans. Also, the variables of boundary conditions for simulation were set in the same level. The analysis results for each case showed that an average temperature of 296.33K matching with a set temperature and average air flow velocity of 0.51m/s suiting plant growth were well-maintained under Case 4 condition wherein two sets of air circulation fans were installed at the upper part of plant cultivation beds. Further, control of air circulation fan set under Case D yielded the most excellent results from Case D-3 conditions wherein air velocity at the outlet was adjusted to 2.9m/s.

• Journal of Animal Science and Technology
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• v.44 no.1
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• pp.123-134
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• 2002

An experiment was conducted to establish the most suitable ventilation system for the enclosed nursery pig house in Korea, comparing four different ventilation systems ; i) air enters through perforated ceiling and exhausts through chimney (NA), ii) air enters through perforated ceiling and exhausts through side walls (NB), iii) air enters through perforated ducts and exhausts through side walls (NC) and iv) air enters through perforated ducts and exhausts through chimney(ND). The experiment was carried out during winter and summer separately. The experimental pigs were weaned at fourteen days old in winter (December-February) and at twenty one days old in summer (June-August). The main results of the experiment are as follows : A preliminary experiment showed that in the NC system during summer, air can reach all the pig rooms in the house and the air flow rates of the upper, middle (1.2 m height of the room) and low (at the height of pig stature) parts of the room were measured at 7.0-8.08, over 0.5 and over 0.2 m/s, respectively, which flow rates were much higher(p$<$0.05) than those in other system. At the minimum ventilation efficiency during winter, air flow rates of upper, middle and low parts of the room equipped with the NC system were detected at over 1, less than 0.5 and around 0.07 m/s, respectively. It is concluded that the separated ventilation system air-entering through ducts is the most suitable for the ventilation system of the enclosed nursery pig house and the exhausting system through side walls is more efficient for ventilation than the system through roof. Furthermore, to sustain proper temperature and reduce energy waste as well as heat consumption, a future research should be carried out to develop the environmental control system in relation to developing a heat regulator.