Browse > Article
http://dx.doi.org/10.7744/kjoas.20170067

Performance evaluation of a 400 W precise window motor for glass houses  

Hong, Soon-Joong (Rural Human Resource Development Center, Rural Development Administration)
Park, Soo-Bok (Chung-Oh Engineering Co., Ltd)
Kang, Na-Rae (Department of Biosystems Machinery Engineering, Chungnam National University)
Kim, Yong-Joo (Department of Biosystems Machinery Engineering, Chungnam National University)
Chung, Sun-Ok (Department of Biosystems Machinery Engineering, Chungnam National University)
Publication Information
Korean Journal of Agricultural Science / v.44, no.4, 2017 , pp. 595-603 More about this Journal
Abstract
Crop growth and production cost are greatly influenced by management of environmental factors such as ambient temperature, humidity, and $CO_2$, especially in protected horticulture. Opening and closing of greenhouses is the most important operation for control of these ambient environmental factors, and precise and stable operation requires high performance window motors. In this study, a 400 W precise window motor was constructed, and its performance was evaluated for plastic and glass greenhouses. First, the motor was designed and fabricated by benchmarking of an advanced foreign product. Then, the performance was evaluated through vibration, PCB (Process Control Block), and load tests. Vibration tests resulted in averaged vibration displacement and velocity of the developed motor of 0.002 mm and 0.2267m/s, which were statistically significantly different from those of the target motor. Average vibration acceleration ($0.26m/s^2$) of the developed motor was also significantly different from that ($0.51m/s^2$) of the target motor. PCB tests showed 2 - 4 mm deviation from the target values, and confirmed the operating status and precision of the control. Load tests with a 300 kg load also showed acceptable operating status and durability. Current values were $1.31{\pm}0.06A$ and RPMs were in the range of 2.9 - 3.0. Considering the above results, the developed window motor would be competitive to the target foreign product.
Keywords
protected horticulture; glasshouse; window motor; precision control; performance;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
연도 인용수 순위
1 Kim BR, Chae SH. 2016. Policy Directions for Controlled Horticulture Industry. pp. 26. Publishing KREI (Korea Rural Economic Institute). Republic of Korea. [in Korean]
2 Lee PU, Chung SO, Chou CH, Park YJ, Kim YJ. 2016. Analysis of the effects of operating point of tractor engine on fatigue life of PTO gear using simulation. Korean Journal of Agricultural Science 43:441-449.   DOI
3 Miguel AF, Silva AM. 2000. Porous materials to control climate behaviour of enclosures: an application to the study of screened greenhouses. Energy and Buildings 31:195-209.   DOI
4 Munoz P, Montero JI, Anton A, Guiffrida F. 1999. Effect of insect-proof screens and roof openings on greenhouse ventilation. Journal of Agricultural Engineering Research 73:171-178.   DOI
5 Nandi S, Toliyat HA, Li X, Nigro L. 2005. Condition monitoring and fault diagnosis of electrical motors-A Review. Transactions on Energy Conversion 20:719-729.   DOI
6 Park NG, Kim TJ, Hwang SM. 2000. Analysis of vibration for permanent magnet motors considering mechanical and magnetic coupling effects. Transactions on Magnetics 36:1346-1350.   DOI
7 Seo DS, Kang CY. 2015. Development Strategies for Material Industries of Greenhouses in Korea. pp. 2-3. Publishing Korea Rural Economic Institute. Republic of Korea.
8 Suh WM, Bae YH, Heo HJ, Kwak CS, Lee SG, L JW, Yoon YC. 2009. Analyses of heating and cooling load in greenhouse of protected horticulture complex in Taean. Journal of the Korean Society of Agricultural Engineers 51:45-52. [in Korean]
9 Teitel M. 2007. The effect of screened openings on greenhouse microclimate. Agricultural and Forest Meteorology 143:159-175.   DOI
10 Teitel M, Ziskind G, Liran O, Dubovsky V, Letan R. 2008. Effect of wind direction on greenhouse ventilation rate, airflow patterns and temperature distributions. Biosystems Engineering 101:351-369.   DOI
11 Xu M, Marangoni RD. 1994. Vibration analysis of a motor-flexible coupling-rotor system subject to misalignment and unbalance, part I: theoretical model and analysis. Journal of Sound and Vibration 176:663-679.   DOI
12 Jang JH, Chung SO, Choi CH, Park YJ, Chun WK, Kim SI, Kwon OW, Kim CW, Hong SJ, Kim YJ. 2016. Effects of PTO gear face width on safety factors. Korean Journal of Agricultural Science 43:650-655.
13 Yun SW, Choi MK, Shin YS, Yu C, Yoon YC. 2013. Estimation of design load for analyzing behavior of greenhouse foundation in Korea. Proceedings of the KSAM & KSBEC 2013 Spring Conference 18:263-364. [in Korean]
14 Lee KC. 2004. Forecasting Future Technology, Drawing Road Maps, and Developing Effective Investment Techniques in Agriculture. pp. 58. Publishing MAFRA (Ministry of Agriculture, Food and Rural Affairs). Republic of Korea. [in Korean]
15 Ahonen T, Virrankoski R, Elmusrati M. 2008. Greenhouse monitoring with wireless sensor network. In Proceeding of the 4th International Conference on Mechatronic and Embedded Systems and Applications (MESA) pp. 403-408.
16 Candido A, Cicirelli F, Furfaro A, Nigro L. 2007. Embedded real-time system for climate control in a complex greenhouse. International Agrophysics 21:17-27.
17 Chinmaya K, Mohanty AR. 2006. Multistage gearbox condition monitoring using motor current signature analysis and Kolmogorov-Smirnov test. Journal of Sound and Vibration 290:337-368.   DOI