• Journal of Bio-Environment Control
• /
• v.8 no.3
• /
• pp.164-171
• /
• 1999

Tomato yield and harvest date were analyzed to examine the productivity of Single Truss Tomato Production System(STTPS) for four regions in Korea. It was found that the solar radiation was not sufficient to get the maximum tomato yield during the low light seasons. The difference of total annual yield between Suwon and Jinju regions was about 12kg.m$^{-2}$ . These results indicate that supplemental lights are needed to increase the yield. The availability of natural light should be considered in deciding the locations of tomato greenhouses. The harvest date could be adjusted by using supplemental lighting. The development and implementation of the lighting control strategies are required for reducing electricity expense.

• Proceedings of the Korean Society for Bio-Environment Control Conference
• /
• 1999.04a
• /
• pp.92-95
• /
• 1999

재배시설내의 재배면적은 온실의 경우 벤치의 구성 방법에 따라서 차이는 있으나 바닥 면적의 47-68% 정도로 전체 면적에 비하여 생산에 사용되는 면적의 효율이 높지 못한 편이다(Langhans, 1990). 이러한 재배면적을 최대로 확보하여 단위 면적당 생산량을 높이기 위한 연구가 자동화 온실이나 식물공장을 중심으로 진행되고 있다. 이러한 연구는 많은 성과를 거두고 있으나 인공광을 이용하거나, 부가적인 기계화 장비나 자동화 설비가 필요하여 에너지 비용과 시설비용이 무시 못 할 정도이며, 고도의 제어기술이 요구되고 있어 상업용으로 보급되지 못하고 있다. (중략)

• Proceedings of the Korean Society for Bio-Environment Control Conference
• /
• 2003.04a
• /
• pp.58-63
• /
• 2003

폐쇄형 묘생산 시스템(closed system for transplants production)은 자연광이 투과되지 않도록 단열재로 구성되어 있어 시스템 내부와 외부의 공기, 물, 열 등의 교환이 기본적으로 제한된다. 또한 식물 생육에 필요한 관수량, 내부에 적절한 습도를 유지시켜 주기 위한 가습량 및 공조기구에 의한 제습량 등이 시스템 내에서 평형을 이루며 순환한다. (중략)

• Proceedings of the Korean Society for Bio-Environment Control Conference
• /
• 2002.11a
• /
• pp.326-331
• /
• 2002

최근 들어 육묘기술이 빠르게 발전하면서 플러그 묘의 보급이 확대되고 있으며 육묘와 재배의 분업화가 진행되고, 고품질 묘의 안정된 수급에 대한 관심이 늘어나면서 육묘 산업에 대한 비중이 점차 증가하고 있다. 현재 국내에 설치되어 있는 육묘시설은 대부분 개방형 묘생산 시스템(open system for transplant production)으로 자연광을 이용하는 장점은 있으나 여름철의 냉방과 겨울철의 난방에 소요되는 비용은 상당한 수준에 이르고 있다. (중략)

• Journal of Bio-Environment Control
• /
• v.21 no.3
• /
• pp.220-227
• /
• 2012

This study was conducted to analyze the seeding quality of paprika and the growth and early yield after transplanting of paprika nursed under artificial light and natural light. In this study, blue LED, red LED, and white fluorescent lamps (FL) were used as artificial lighting sources. Photoperiod, average photosynthetic photon flux, air temperature, and relative humidity in a closed transplants production system (CTPS) were maintained at 16/8 h, $204{\mu}mol{\cdot}m^{-2}{\cdot}s^{-1}$, 26/$20^{\circ}C$, and 70%, respectively. Leaf length, leaf width, leaf area, top fresh weight and dry weight of paprika seedlings, and chlorophyll content in paprika leaves nursed under LED and fluorescent lamps for 21 days after experiment were significantly affected by light treatments. As compared with the control (white FL), leaf area of paprika grown under blue LED, red LED, and natural light was decreased by 63%, 63%, and 28%, respectively. Top dry weight of paprika grown under blue LED, red LED, and natural light was 64%, 50%, and 22%, respectively, compared with the control. Number of leaves on 18 days after transplanting showed with red LED, blue LED, and natural light by 86%, 84%, and 48%, respectively, compared with the control. On 114 days after transplanting, paprika nursed under blue LED and red LED had relatively short plant height. This result might be caused that the elongation of its internodes was suppressed by the illumination of sole blue or red light. Average number of fruits per plant harvested during 4 weeks after first harvest was 3.5 with red LED, 3.3 with blue LED, 1.0 with natural light, and 2.2 with control, respectively. Early yield of paprika nursed under red LED, blue LED, natural light, and control were 453 g/plant, 403 g/plant, 101 g/plant, and 273 g/plant, respectively. Larger fruit of 136 g was harvested with red LED treatment. Even though the early yield of paprika was greatly increased with artificial lighting, but total yield was almost similar as the harvest period after transplanting in greenhouses was lengthened. From the above results, we could understand that paprika nursed under white FL, blue LED, and red LED showed good growth after transplanting and was early harvested by a week as compared to the natural light. Therefore, the white FL, blue LED, and red LED as the artificial lighting sources in CTPS could be strategically used to enhance the seedling quality, to shorten the harvest time, and to increase the yield of paprika.

• Proceedings of the Korean Society for Bio-Environment Control Conference
• /
• 1996.10a
• /
• pp.76-80
• /
• 1996

공정육묘는 기후의 영향을 쉽게 받는 자연광하에서 대부분의 생산이 이루어지기 때문에 계획적인 묘생산이 어렵게 된다. 향후 식물공장(Plant factory) 또는 폐쇄생태계생명유지시스템(Controlled ecological life support system, CELSS)과 같이 폐쇄도가 높은 식물생산 시스템에서는 식물종묘 생산의 대부분이 인공광을 이용한 조건에서 이루어질 것으로 예상된다. (중략)

• Korean Institute of Interior Design Journal
• /
• v.22 no.1
• /
• pp.265-273
• /
• 2013

The purpose of this study is to analyze the state-of-the-art daylighting design among LEED(Leadership in Energy and Environmental Design) multi-family housing cases and to explore the feasibilities for their applications in domestic housing design. Occupants in multi-family houses are reported to consume more electricity power than those in single houses. That may imply the problems of daylighting design in domestic housing design for multi-family houses have better insulation system and less windows and outside walls than single houses. Therefore two systems, daylight delivery system and daylight control system, are scrutinized for daylighting design with LEED cases. The findings show when windows as a daylight delivery system are combined with overhangs, fins, louvers, fenestration materials, speciality fenestration, or interior controls as a daylight control system, the outcome goes with more energy savings and better facade design. Beside those, lightshelves as a daylight delivery system seem to have potentials in domestic multi-family houses with deep plans and less outside walls. Daylighting designs in domestic multi-family houses need to pursue available options more to achieve the integration of energy and aesthetics values.

• Journal of Bio-Environment Control
• /
• v.2 no.1
• /
• pp.69-76
• /
• 1993

최근 작물의 공장적 재배는 $\boxDr$식물공장$\boxUl$이라는 단어로 대표되는, 새로운 재배방식의 하나로서 세계적으로 주목받고 있다. 식물공장(plant factory or factory- style plant production system)이라는 단어의 의미와 같이 $\boxDr$시설내의 작물을 공장제품의 생산과 동일하게 재배하는 시스템$\boxUl$이다. 즉 자연환경에 의존하지 않고 인공환경하에서 식물을 공장적으로 재배하는 방식을 의미한다. 이를 위해서는 지하부의 양액, 지상부의 온습도, 탄산가스, 광 등에 대한 고도의 환경제어 및 작업의 자동화가 필요하다.(중략)

• Korean Chemical Engineering Research
• /
• v.49 no.5
• /
• pp.505-509
• /
• 2011

Visible light-activated photocatalysts (based on doped titania) are the subject of intensive current research due to the promise they offer in relation to solar powered systems for photocatalysis, hybrid systems for $CO_2$ conversion and hydrogen production from water. Current synthetic methodologies suffer from one or more serious shortcomings, which seriously hinder practical application. These include high cost, irreproducibility, difficulty in controlling the dopant level and unsuitability for scale up. In this review new reproducible and controllable methods (developed by Lambert group, Cambridge University) allowing the synthesis of practical quantities of efficient, visible light active anion (e.g. N, C and B) doped $TiO_2$ photocatalysts are summarized.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
• /
• 2013.10a
• /
• pp.188-191
• /
• 2013

In this paper, in order to economize energy inside the vertical-type water treatment plant, a chamber-illumination-LED control board, which operates via nature light or human's touches, is proposed. Moreover, this illumination control process is contrived to be wirelessly monitored in real-rime. In addition, Zigbee communication code is programmed to implement the control board's function of wireless data transmission and automatic LED brightness control. The presented control method contrives brightness to be adjusted in real-time by dimming control, which means nature light changes control, so that the interior energy can realize the maximum energy conservation.