Browse > Article
http://dx.doi.org/10.14480/JM.2019.17.4.197

Analysis of growth environment of Flammulina velutipes using the smart farm cultivation technology  

Lee, Kwan-Woo (Chungcheongbuk-Do Agricultural Research & Extension Services)
Jeon, Jong-Ock (Chungcheongbuk-Do Agricultural Research & Extension Services)
Lee, Kyoung-Jun (Chungcheongbuk-Do Agricultural Research & Extension Services)
Kim, Young-Ho (Chungcheongbuk-Do Agricultural Research & Extension Services)
Lee, Chan-Jung (Mushroom Research Division, National Institute of Horticultural & Herbal Science, RDA)
Jang, Myoung-Jun (Department of Plant Resource, Kongju National University)
Publication Information
Journal of Mushroom / v.17, no.4, 2019 , pp. 197-204 More about this Journal
Abstract
In this study, smart farm technology was used by farmers cultivating 'CHIKUMASSHU T-011' in order to develop an optimal growth model for the precision cultivation of bottle-grown winter mushroom and the results of the same are mentioned herein. Farmers participating in the experiment used 60 ㎡ of bed area with 4 rows and 13 columns of shelf shape, 20 horsepower refrigerator, 100T of sandwich panel for insulation, 6 ultrasonic humidifiers, 12 kW of heating, and 20,000 bottles of Flammulina velutipes mushroom spores. The temperature, humidity, and carbon dioxide concentrations, which directly affect the growth of the mushroom, were collected and analyzed from the environmental sensors installed at the winter mushroom cultivation area. The initial temperature was found to be 14.5℃, which was maintained at 14℃ to 15℃ until the 10th day. In the restriction phase, the initial temperature was 4℃ and was maintained between 2℃ and 3℃ until the 15th day, while during the growth phase, it was maintained between 7.5℃ to 9.5℃. Analysis of the humidity data revealed initial humidity to be 100%, which varied between 88% to 98% during primordia formation period. The humidity remained between 77% to 96% until the 15th day, in the restriction phase and between 75% to 83% during the growth phase. The initial carbon dioxide concentration was 3,500 ppm and varied between 3,500 ppm to 6,000 ppm during primordia formation period and was maintained at 6,000 ppm until the 15th day. During the growth phase, the carbon dioxide concentration was found to be over 6,000 ppm. Fruiting body characteristics of 'CHIKUMASSHU T-011' cultivated in the farmhouse were as follows: Pileus diameter of 7.5 mm and thickness of 4.1 mm, stipe thickness of 3.3 mm, and length of 154.2 mm. The number of valid fruiting bodies was 1,048 unit per 1,400 mL bottle, and the individual weight was 0.71 g per unit. The yield of fruiting bodies was 402.8 g per 1,400 mL bottle.
Keywords
Flammulina velutipes; Growth environment; Smart farm technology;
Citations & Related Records
Times Cited By KSCI : 6  (Citation Analysis)
연도 인용수 순위
1 Serodio C, Cunha JB, Morais R, Couto C, Monteiro J. 2001. A networked platform for agricultural management systems. Comput Electro Agri 31: 75-90.   DOI
2 Cha DY, Yu CH, Kim KP. 1998. The latest mushroom cultivation technology. 335-353.
3 Chang ST. 1993. The impact on mushroom industry and mushroom products. In S.T. Chang, J. A. Buswell & S. W. Chiu. (ed.), Mushroom Biology and Mushroom Products, The Chinese University Press. China.
4 Choi JH. 2000. Design and implementation of remote control on internet. MS thesis. Hongik University, Seoul, Korea (in Korean).
5 Im JH, Jang KY, Oh YL, Oh MJ, Lee SK, Raman J, Kong WS. 2018. Breeding of a new cultivar of Flammulina velutipes: 'Baeke'. J Mushrooms 16: 299-303 (in Korean).
6 Kim DU. 2002. Design and implementation of realtime monitoring for remote control based on clinet/server. MS thesis. Pukyong National University, Busan, Korea (in Korean).
7 Kim IY, Kwon HI, Hwang IH, Lee WH, No JH, Choi SG, Ko HK, Koo CD. 2018. Research of environmental condition using ICT-based smart cultivation system during high temperature period. J Mushrooms 16: 79-85 (in Korean).
8 Kong DG, Ryu KH, Jin JY. 2003. Development of database for environment and control information in greenhouse. J Agri Machin 28: 59-64 (in Korean).
9 Korea Agricultural Trade Information (KATI). http://www.kati.net/
10 Lee CJ, Park HS, Lee EJ, Kong WS, Yu BK. 2019. Analysis of growth environment by smart farm cultivation of oyster mushroom 'ChunChu No 2'. J Mushrooms 17: 119-125 (in Korean).
11 Chang ST, Hayes WA. 1978. The biology and cultivation of edible mushroom. Academic Press, New York.
12 Lee IB, Suh WM, Kim TK, Choi MG, Yoon YC. 2007. Survey and analysis on operation of equipments for environmental control in Pleurotus eryngii cultivation facilities. J Agric Life Sci 41: 47-53 (in Korean).
13 Lee SH, Yu BK, Kim HJ, Yun NK, Jung JC. 2015. Technology for improving the uniformity of the environment in the oyster mushroom cultivation house by using multi-layered shelves. Protected Hort Plant Fac 24: 128-133 (in Korean).   DOI
14 Ministry of Agriculture, Food and Rural Affairs. 2018. Cash Crop Production Records.
15 Suh WM, Yoon YC, Kim YW. 2002. Technical development of environment control complex of micro-climatic factors for oyster mushroom cultivated in protected environment. Proc 2002 Ann Con Kor Soc Agric Eng 121-124 (in Korean)
16 Moon SM, Kwon SY, Lim JH. 2015. Improvement of energy efficiency of plants factory by arranging air circulation fan and air flow control based on CFD. J Internet Comput Serv 16: 57-65 (in Korean).   DOI
17 Park BH. 2000. Teleoperation control for greenhouse via the world wide web. MS thesis. Yeungnam University, Gyeongsan, Korea (in Korean).
18 RDA (Rural Development of Administration). 2010. Standard farming textbook of mushroom cultivation.
19 Yoo YB, Oh MJ, Oh YL, Shin PG, Jang KY, Kong WS. 2016. Development trend of the mushroom industry. J Mushrooms 14: 142-154 (in Korean).   DOI