SU1554822A1 - Device for temperature control of air and water in hothouse - Google Patents

Abstract

The invention relates to agriculture, crop production in green buildings. The purpose of the invention is to optimize the control process by preventing overheating of plants and the use of solar energy to heat irrigation water. The device contains a source 1 of a hot coolant, which is supplied by the transporting pump 2 to the greenhouse. The heating system 3 is connected via the first circulation pump 4 to the inlet of the first three-way mixing valve 5. The valve 5 is controlled by a regulator 6, the first input of which is connected to the sensor 7 of the coolant temperature, the second and third are respectively connected to the sensor 8.9 solar radiation and air temperature in the greenhouse. In the period of high solar radiation, after the supply of hot coolant stops, in order to prevent the temperature of the air in the greenhouse above the optimum, the second three-way mixing valve, controlled by the second regulator outlet, is activated. The inlet of the second three-way mixing valve 10 is connected to the conveying pump 2, and the first outlet is connected to the first inlet of the heat exchanger 11. The first outlet of the heat exchanger 11 is connected to the inlet of the heating system 3. The storage tank 12 is connected via the second circulation pump 13 to the second inlet of the heat exchanger 11. The second output of the heat exchanger 11 through the third three-way mixing valve 14, controlled by a signal from the third output of the regulator 6, is connected to the system 15 for watering the plants and the storage tank 12. Sensor 16 tons The temperature of the water after the heat exchanger 11 is connected to the fourth inlet of the regulator 6, which helps prevent overheating of the plants and use the sun's energy to preheat the irrigation water during the period of high solar radiation, as well as reduce moisture loss with ventilation. 2 Il.

Description

The invention relates to agriculture, in particular, to crop production under greenhouse conditions.

The purpose of the invention is to optimize the control process by preventing overheating of plants and the use of solar energy to heat irrigation water.

Figure 1 shows the functional diagram of the device; FIG. 2 is a block diagram of the regulator.

The device for regulating the temperature of the air and irrigation water in the greenhouse includes a source of hot heat carrier 1, which is supplied to the greenhouse by a transporting pump 2, a heating system 3 connected via the first circulation pump 4 to the inlet of the first three-way mixing valve 5 controlled by the first regulator outlet torus 6, the first inlet of the latter is connected to the sensor 7 of the temperature of the coolant, the first outlet of the first three-way mixing valve 5 is connected to the inlet of the source 1 of hot heat The second outlet is connected with the output of the transporting pump 2, sensors 8 and 9 are connected to the second and third regulator inputs, respectively, of solar radiation and greenhouse air temperature, the second three-way mixing valve 10 inlet, controlled by the second output of regulator 6 connected to the transporting pump 2, and the first output

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Nozzle with the first inlet of the heat exchanger 11, the first outlet of which is connected to the second outlet of the second three-way mixing valve 10 and the inlet of the heating system 3, storage tank 12 connected through the second circulation pump 13 to the second inlet of the heat exchanger 11, the second outlet of which the third three-way mixing valve 14, controlled by the third output of the regulator 6, is connected to the plant watering system 15 and the storage tank 12, and the water temperature sensor 16 after the heat exchanger 11 is connected to the fourth Controller input.

The regulator 6 (FIG. 2) consists of two-element regulator blocks 17-19 and proportional-integral regulator blocks 20 and 21. The regulator blocks are built on the basis of standard functional elements: ES - sound signaling, 3 - setting unit, ES is an element of comparison, Y is an amplifier, P is a regulator, T is a trigger. The remaining elements of the blocks are indicated functionally.

The block regulator 17 of the regulator 6 serves to control the temperature of the irrigation water. If the temperature deviates from the setpoint, a signal is supplied from the third output of the regulator 6 to the third three-way mixing valve 14, and irrigation water is supplied to the storage tank until it reaches the setpoint. The temperature of the polyp pod is set and controlled by the regulator unit 20, the sensor 16 of the irrigation water temperature after the heat exchanger is connected to the fourth input of the regulator 6, and the second output of the regulator 6 controls the first three-way mixing valve 10, the position of which depends on the amount of heating water supplied in the heat exchanger 11.

The regulator 18 of the regulator 6 serves to signal the decrease or excess of the temperature.

the inlet of the first three-way mixing valve 10) or from the control unit 19 connected to the solar radiation sensor 8.

The device works as follows.

In the cold period of the year, the regulation of the air temperature in the greenhouse is made by changing the amount of hot coolant supplied to the heating system 3 from the source of hot coolant by means of a transport pump 2 through the second three

water from the permissible value. Block-j; the flow mixing valve 10, the chopper regulator 21 controls the air temperature in the greenhouse by changing the position of the second three-way mixing valve 5, while changing the amount of heating water 0 mixed from the return pipe (second outlet of the second three-way mixing valve 5) in the forward ( the inlet of the first three-way mixing valve 25 10), the sensor 9 of the air temperature in the greenhouse is connected to the third input of the regulator 6, and the first output of the regulator 21 of the regulator 6 to the executive the three-way mixing valve 5. The controller 19, acting on the setpoint controller 20, changes the task to maintain the temperature in the greenhouse depending on the level of solar radiation (the second input of the controller 6 from 5 sensor 8 solar radiation).

As a heat exchanger 11, any typical water heater is used with an appropriate heating area and water consumption. Irrigation water, having entered through the second entrance to the heat exchanger 11, the passage through a multitude of thin tubes, is heated and the outlet 40

cut the heat exchanger 11 at the time of heating the irrigation water (the first input is the first output of the heat exchanger 11), or past it at the rest of the time (the second output of the second three-way mixing valve 10 is the input of the 3 nd ash system) and then the first circulation pump A - on the inlet of the first three-way mixing valve 5, controlled by the first outlet of the regulator 6, which during this period receives signals from the sensor 7 of the heat carrier temperature and the sensor 9 of the air temperature in the greenhouse.

The temperature of the heating medium entering the heating system 3 (and, accordingly, the temperature in the greenhouse) depends on the temperature of the heating medium coming from source 1 and the amount of heat transfer medium mixed in from the return pipeline (from the second outlet of the first three-way mixing valve 5) to the direct pipeline to the output of the transporting pump 2, and the amount of coolant mixed in from the return pipeline depends on the position of the three-way mixing valve 5, controlled by the regulator 6, depending on the and on the air temperature in the greenhouse.

Pit through the second outlet, and the heat-treating water, entering the heat exchanger 11 through the first inlet, passes through the annular space, heats the irrigation water without mixing with it, and exits through the first outlet.

In the period of high solar radiation, the source 1 of the hot coolant can be switched off by the operator in manual operation mode and, in automatic mode, from the signal of limit switches of the second three-way mixing valve 5 (when all heating water from the suction inlet goes to the first one and then

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cut the heat exchanger 11 at the time of heating the irrigation water (the first input is the first output of the heat exchanger 11), or past it at the rest of the time (the second output of the second three-way mixing valve 10 is the input of the heating system 3) and then the first circulation pump A to the input of the first a three-way mixing valve 5 controlled by the first output of the regulator 6, which during this period receives signals from the sensor 7 of the heat carrier temperature and the sensor 9 of the air temperature in the greenhouse.

The temperature of the heating medium entering the heating system 3 (and, accordingly, the temperature in the greenhouse) depends on the temperature of the heating medium coming from source 1 and the amount of heat transfer medium mixed in from the return pipeline (from the second outlet of the first three-way mixing valve 5) to the direct pipeline to the output of the transporting pump 2, and the amount of heat carrier mixed from the return pipeline depends on the position of the three-way mixing valve 5, controlled by the regulator 6, depending on awn from air temperature in the greenhouse.

In the period of high solar radiation, even when the supply of hot coolant in the greenhouse is stopped, overheating of the plants and disturbance of the water balance of the plants are observed, the plants lose up to 25% of the crop from this. Overheating of plants can occur in summer months with full opening of the transoms, and in early spring transom can not be opened because of them. icing and high temperature difference between the outside and inside air. According to the data obtained during the experimental work at the greenhouse complex, the first overheating of the plants was recorded already at the end of February, and the number of hours with a leaf temperature greater than or equal to 28 ° C in the greenhouse from January to June is 519 h.

In the period of high solar radiation, the device operates as follows

The supply of hot heat carrier by the transporting pump 2 stops and the heat carrier circulates along the heating system 3, the first circulation pump 4, the first three-way mixing valve 5 (input - second output), the second three-way mixing valve 10 (input - first output ) and heat exchanger 11 (the first input is the first output), in which heat is taken from the greenhouse and given to irrigation water circulating through the second circuit: storage tank 12, second circulation pump 13, heat exchanger 11 (second input - second output ) And the third three-way mixing valve 14, koto- ing. controlled by the regulator 6, depending on the signal of the sensor 16, the water temperature after the heat exchanger 11 can direct heated water either to the irrigation system 15 or to the storage tank 12.

In the period of high solar radiation, the source 1 of the hot coolant is shut off, the coolant (network water), the circular pipe and the heating system 3 are heated, and the air of the greenhouse is cooled (on average, 1 m of the area of the winter greenhouses comes to and in the heat exchanger 11 (which operates according to the principle of a pipe in a pipe, in order not to mix chemically purified network and not chemically purified irrigation water) it gives off its heat to cold water circulating through the second circuit and intended for irrigation. Rumble torus 6 can be implemented on the basis of serial regulators PT-2 P25.

The application proposed by the device

Vacuuming the temperature of the air and irrigation water in the greenhouse helps prevent overheating of the plants and use the sun’s energy to heat the irrigation water, besides, water losses that occur during intensive ventilation during cooling of the greenhouse by known methods are eliminated.

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Claims (1)

Apparatus of the Invention A device for adjusting the temperature of air and irrigation water in a greenhouse, comprising a source of hot heat transfer fluid, communicated through a conveying pump to the inlet of the first three-way mixing valve, the first outlet of which is connected to the heating system through a supply pipe, the first circulating pump regulating a torus, the first input of which is connected to the temperature sensor, and the second input - to the solar radiation sensor of the air in the greenhouse, and the third input - to the temperature sensor coolant tours, while the first regulator output is connected to the control input of the actuator of the first three-way mixing valve, characterized in that, in order to optimize the control process by preventing overheating of plants and using solar energy to heat irrigation water, it is equipped with a water temperature sensor after the heat exchanger connected to the fourth inlet of the regulator, the second and third three-way mixing valves, the control inputs of the actuators, which They are connected respectively with the second and third outputs of the regulator, the heat exchanger, the second and third circulation pumps, the storage tank and the plant irrigation system, which is connected via a pipeline to the first outlet of the third three-way mixing valve, the second outlet of which is connected to the storage tank, and the input the pipe is connected to the second outlet of the heat exchanger, while the second inlet of the latter is connected through the second circulation pump to the storage tank, and the second The outlet of the first three-way mixing valve is connected to the first inlet of the heat exchanger, the first outlet of which is connected through the heating system to the suction inlet of the first circulation pump, and the discharge of the latter is connected to the inlet of the second three-way mixing valve, the outlet of which heat carrier and discharge pipe of the transporting pump. S CM 1 ZUG1ga CN o