CAJ | 학술논문

土壤连作灾害、生产资源严重浪费和环境污染已成为日光温室生产中制约其发展的瓶颈问题，为了解决这些问题，实现节水、节肥、保护环境的目的并提高温室生产的管理水平和自动化水平，该文设计了一种日光温室封闭式栽培系统。与传统栽培管理方式不同，该系统使用基质栽培代替土栽方式，采用基质袋装或塑料薄膜完全包裹的模式，实现了与外界环境的有效隔离；使用水肥一体化营养液滴灌代替水肥分离灌溉方式，回收多余营养液并循环利用；采用无线传感器网络模式，实现了温室环境信息的自动采集和发送。试验结果表明，采用封闭式栽培比传统土栽方式番茄产量提高了11.7%，水、肥用量均节省了2%（基质不同，节省水、肥量不同），同种基质情况下，采用封闭式栽培方式，由于营养液实现了循环利用，水、肥节省率可以达到17.2%。
토양련작재해、생산자원엄중낭비화배경오염이성위일광온실생산중제약기발전적병경문제，위료해결저사문제，실현절수、절비、보호배경적목적병제고온실생산적관리수평화자동화수평，해문설계료일충일광온실봉폐식재배계통。여전통재배관리방식불동，해계통사용기질재배대체토재방식，채용기질대장혹소료박막완전포과적모식，실현료여외계배경적유효격리；사용수비일체화영양액적관대체수비분리관개방식，회수다여영양액병순배이용；채용무선전감기망락모식，실현료온실배경신식적자동채집화발송。시험결과표명，채용봉폐식재배비전통토재방식번가산량제고료11.7%，수、비용량균절성료2%（기질불동，절성수、비량불동），동충기질정황하，채용봉폐식재배방식，유우영양액실현료순배이용，수、비절성솔가이체도17.2%。
The traditional cultivation of a solar greenhouse is to use the soil, but soil-borne diseases lead to continuous cropping obstacles, and with the fertilizer going into the soil along with water, often the environment and groundwater has been polluted, so that it is impossible to achieve sustainable development. Therefore, these problems must be solved, not only as to saving water and fertilizer, but also for protecting the environment, while improving the level of automation in the solar greenhouse. So a closed cultivation system was presented. <br> The traditional cultivation methods are with soil or substrate piled in a ridge on the ground, and crops have been planted on the ridge. In this system of digging a ditch on the ground from south to north, the width of the ditch was 35cm, the depth of the ditch was 25 cm, and the fall of ditch from south to north was about 5~10 cm. Substrate was bagged up or completely wrapped by plastic film, and then it was placed in the ditch, so the substrate was isolated from the outside world, the incidence of soil-borne diseases was avoided, and the same heat energy saved by the soil can also be used. The system designed was a wireless sensor network using the 433MHz frequency, and it developed the environment monitoring node, the microcontroller of node was PIC16F876A, and it connected sensors of SHT15, ISL29010, FDS100, and MF52. <br> Traditional irrigation in the solar greenhouse was conducted in the following method:water irrigation first, then fertilizers were added for a period of time, and finally irrigation with water was again carried out. An integrated water and fertilizer irrigation mode was applied in this system, with the function of irrigation by controller implementation, the core of the irrigation controller was a ARM7 processor, the operating voltage was provided by the power supply module, the processor was connected with an EC measuring module, a pH measurement module, and a relay control module through the I2C bus module. The EC measurement module and pH module were respectively connected to the EC and pH measuring instrument, with measurement of the solution in a mixing fertilizer tank. The values of EC and pH detected by the electrode, were transmitted to the processor through the I2C bus. The switch of the solenoid valve was controlled by a processor based on the PID control method, and the nutrient solution was automatically mixed and adjusted according to the set value of the program. An already adjusted nutrient solution was supplied to the water lines by a pump, and every irrigation line for a greenhouse, with the irrigation lines starting and stopping regulated by a solenoid valve. The solenoid valves were controlled by a relay control module worked through the program. Any excess nutrient solution was recycled. When the water level of the recycle tank reached a certain height, the nutrient solution in the recycle tank would be pumped into the mixing tank, and then recycling was implemented. <br> Experimental results showed that the yield of a closed culture system increased by 11.7%more than the traditional soil planting, along with saving 2% of the water and fertilizers. If the same kind of substrate case was used to achieve recycling of the nutrient solution, then 17.2%of the water and fertilizers of the closed culture system were saved. It was able to effectively enhance the degree of automation in greenhouse production, conserve resources, protect the environment, and promote sustainable development of the greenhouse industry.