Browse > Article

Variations of Air Temperature, Relative Humidity and Pressure in a Low Pressure Chamber for Plant Growth  

Park, Jong-Hyun (Dept. of Bioindustrial Machinery Engineering, Graduate School, Chonbuk National University)
Kim, Yong-Hyeon (Dept. of Bioindustrial Machinery Engineering, College of Agriculture & Life Sciences, Chonbuk National University(The Institute of Agricultural Science & Technology))
Publication Information
Journal of Bio-Environment Control / v.18, no.3, 2009 , pp. 200-207 More about this Journal
Abstract
This study was conducted to analyze the variations of air temperature, relative humidity and pressure in a low pressure chamber for plant growth. The low pressure chamber was composed of an acrylic cylinder, a stainless plate, a mass flow controller, an elastomer pressure controller, a read-out-box, a vacuum pump, and sensors of air temperature, relative humidity, and pressure. The pressure leakage in the low pressure chamber was greatly affected by the material and connection method of tubes. The leakage rate in the low pressure chamber with the welding of the stainless tubes and a plate decreased by $0.21kPa{\cdot}h^{-1}$, whereas the leakage in the low pressure chamber with teflon tube and rubber O-ring was given by $1.03kPa{\cdot}h^{-1}$. Pressure in the low pressure chamber was sensitively fluctuated by the air temperature inside the chamber. An elastomer pressure controller was installed to keep the pressure in the low pressure chamber at a setting value. However, inside relative humidity at dark period increased to saturation level.. Two levels (25 and 50kPa) of pressure and two levels (500 and 1,000sccm) of mass flow rate were provided to investigate the effect of low pressure and mass flow rate on relative humidity inside the chamber. It was concluded that low setting value of pressure and high mass flow rate of mixed gas were the effective methods to control the pressure and to suppress the excessive rise of relative humidity inside the chamber.
Keywords
air temperature; leakage rate; low pressure; plant growth chamber; relative humidity;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Levine, L.H." P.A. Bisbee, J.T. Richards, M.N. Birmeie, R.L. Prior, M. Perchonok, M. Dixon, N.C. Yorio, Gw. Stutte, and R.M. Wheeler. 2008. Quality characteristics of the radish grown under reduced atmospheric pressure. Advances in Space Research 41:754-762   DOI   ScienceOn
2 NASA. 1996. Requirements and design considerations. Report Nr. JSC 38571, CSTD-ADV-245, NASA Johnson Space Center, houston, Texas
3 Purswell, J.L. 2002. Engineering design of a hypobaric plant growth chamber. MS thesis. Texas A&M University.
4 Guo, S., Y. Tang, F. Gao, W. Ai, and L. Qin. 2008. Effects of low pressure and hypoxia on growth and development of wheat
5 Brown, D. and R.E. Lacey. 2002. A distributed control system for low pressure plant growth chambers. ASAE Paper No. 023078
6 ESA, 2005. http://www.esa.intiesaCP/SEMOBUV797E_index O.html
7 Hublitz, L., D.L. Henninger, B.G Drake, and P. Eckart. 2004. Engineering concepts for inflatable Mars surface greenhouses. Adv. Space Res. 34(7):1564-1551   DOI   ScienceOn
8 Kaplan, D. 1998. Environment of Mars, NASA technical memorandum 100470, NASA Johnson Space Center, Houston, Texas
9 Chuangjiu, H, F.T. Davies Jr., R.E. Lacey, M.e. Drew, and D.L. Brown. 2003. Effect of hypobaric conditions on ethylene evolution and growth of lettuce and wheat. J. Plant Physiol. 160:1341-1350   DOI   ScienceOn
10 Fowler, P.A. and R.M. Wheeler. 2000. Low pressure greenhouse concepts for Mars, NASA technical memorandum 208577, NASA Johnson Space Center, Houston, Texas
11 NASA. 2004. Mars fact sheet. http://nssdc.gsfc.nasa.gov/planetary/factsheetlmarsfact.htrnl
12 Kim, Y.H. 2005. Engineering approach to crop production in space. J. of Bio-Environment Control. 14(3):218-231 (In Korean)