SU1351537A1 - System for controlling carbon dioxide content in phytochamber - Google Patents

Abstract

The invention relates to the field of agriculture, in particular, to gas control systems in greenhouses, greenhouses and phytocameras. The purpose of the invention is to increase the stability of the carbon dioxide content. The system comprises a phyto-chamber 1, a source of carbon dioxide 2, an adjustable valve 3, a receiver 4, a restriction device 5, a CO sensor 6, a regulator 7, an additional regulator 8, a storage tank 9, a pressure sensor 10 and an additional valve 11. If the signal at the output of the regulator 7 is greater than the signal of the pressure sensor 10, the equilibrium signal of the bridge circuit of the additional regulator 8 is broken and the valve 3 opens, which connects source 2 to receiver 4, i.e. carbon dioxide enters phytocamera 1. When it is necessary to reduce the supply of CO2, the signal from sensor 10 will be greater than the signal from regulator 7, then regulator 8 will open kalapan 11 and excess CO from receiver 4 will go to storage tank 9. 1 sludge . (LH co-effected SP oz Szag

Description

one

The invention relates to agriculture, in particular, to a technique for growing plants under artificially controlled conditions, specifically to systems for regulating the gas regime in greenhouses, the greenhouse, and also growing climatic installations (cabinets, chambers,

phytotrones).

The purpose of the invention is to increase the stability of the carbon dioxide content.

The drawing shows a functional carbon dioxide control system.

The device contains a phyto chamber 1, a source of carbon dioxide 2, an adjustable valve 3, a receiver 4, a restriction device 5, a carbon dioxide containing sensor 6, a regulator 7, an additional regulator 8, a carbon dioxide storage tank 9, a pressure sensor 10 and an additional adjustable valve And, PID controller can be used as controller 7. Narrowing device 5 can be made in the form of a capillary.

The carbon dioxide source 2 is connected by line to the phytocamera 1 through a series-connected adjustable valve 3, a receiver 4 and a restriction device 5. The storage tank 9 is connected via an additional adjustable valve 11 to the receiver 4, which is connected to one input of an additional regulator via a pressure sensor 10 8, the other input of which is connected to the output of the regulator 7. One output of the additional regulator 8 is connected to the adjustable valve 3, and the other to the additional adjustable valve 11. The additional regulator 8 ozhet be made, e.g., of a bridge circuit assembled on the HI and H2 loads between which included polarized relay R.

The system works as follows.

The adjustable parameter, which is the content of COA in phytocamera 1, is measured by sensor 6. In the event that the intensity of photosynthesis changes within the phytocamera 1 or the driving signal C | zzd is changed, the signal Uf changes at the output of regulator 7. As a result, the equality between the signal at the output of the regulator 7 (HI load) and the signal at the output of the pressure sensor 10 (load H2) is violated.

Depending on the sign of the mismatch using a polarized relay R open

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valve 3 or valve 11. So, if the signal at the output of regulator 7 is greater than the signal from pressure sensor 10, which means an increase in the supply of CO2 to the phytocamera. 1, then

the valve 3 opens and connects the source 2 to the receiver 4.

When it is necessary to reduce the CO2 supply, valve 11 will open and an excess amount of CO2 from receiver 4 will transfer to storage tank 9 (in a particular case it is dumped into the atmosphere).

Due to the restriction device 5 installed in the supply line, the pressure in the receiver is in a certain way transformed into the flow rate of CO2. In this case, so that the relationship between the pressure drop across the restriction device 5 and the flow rate of CO2 in the supply line is linear, it is advisable to use a capillary as the restriction device.

Thus, an increase is achieved.

20 stability of carbon dioxide content in the phytochamber.

Claims (1)

Invention Formula The system for regulating the content of carbonic acid gas in a phytocamera, including a phytocamera, a source of carbon dioxide, an adjustable valve, a sensor for carbon dioxide content, a regulator whose inlet is connected to a sensor m of carbon dioxide content and the output of which is connected to controllable valve, different from the meter that, in order to increase the stability of the carbon dioxide content, it is equipped with an additional regulator, pressure sensor, receiver, additional regulating valve, storage tank and restricting device, the carbon dioxide source being connected to the phytocamera through an adjustable regulating valve, receiver and narrowing device and reservoir through AQ an additional adjustable valve is connected to a receiver, which is connected via a pressure sensor to one input of an additional controller, the other input of which is connected to the controller output, and one of the outputs of the additional controller 45 is connected to an adjustable valve, and the other output is connected to an additional adjustable valve, while the constriction device is made in the form of a capillary.