SU1443858A2 - Apparatus for regulating temperature of air in hothouse - Google Patents

Abstract

The invention relates to agriculture, in particular to devices for regulating the microclimate in greenhouses. The purpose of the invention is to increase the uniformity of the temperature field of the greenhouse. Computing unit 7 with sensors 1-5 serves as a setpoint for the temperature of the heat transfer medium in the lower circuit 15 of the heating system. The temperature in circuit 15 of the heating system, required for these conditions, is set by setpoint 6 and is controlled by controller 8 taking into account information from sensors 10–12 tempo with (L 4 4; from 00 SP 00 1H

Description

air from the controller 9, which is fed to the input of the regulator 8. If the electronic key 18 is open, then the regulator 8 of the main channel does not work, which corresponds to the set temperature, and CHrHajj from the output of the regulator 16 of the corrected channel through the electronic key 18 an actuator 13 that sets the temperature of the heat transfer medium in the lower circuit 15 and both branches 29 and 30 of the side circuit of the heating system. The air temperature at the fences on the left and right sides is maintained using temperature sensors 11 and 12, an adder 31, and a unit 28 for redistributing the flow of the heat transfer fluid. 1 hp f-ly, 2 ill.

one

The invention relates to agriculture, in particular, to greenhouse vegetable growing, mainly to black-hot water heating.

The purpose of the invention is to increase the uniformity of the greenhouse temperature floor.

FIG. 1 shows a functional diagram of the proposed device in FIG. 2 is a functional diagram of the unit for redistributing the coolant flow.

Device O contains sensor 1 for outdoor air temperature Tj5, sensor 2 for the level of solar radio E,

sensor 3 wind speed V, sensor 4 I humidity of air S in the greenhouse, sensor 5 soil temperature T, setpoint 6 of the required temperature Tgj, air, which are connected to the inputs of the computing unit 7. The output of the sensor 6 is connected to one of the controller inputs 8 of the main control channel, to the second input of which the output of the averaging unit 9 is connected

current temperature Tg. three sensors, namely sensor 10, located in the center of the greenhouse, and sensors 11, 12, located respectively to the left and right near the side frame for the greenhouse, and the output of the regulator 8 is connected to the actuator 13 of the three-way mixing valve 14 of the lower contour 15 of the greenhouse heating system. The output of the computing unit 7 is connected to one of the inputs of the regulator 16, to the second input of which the sensor 17 of the current temperature T of the lower circuit coolant is connected, and

0

five

0

five

30 35

the output is connected to the first input of the electronic switch 18, the second input of which is connected to the output of the regulator 8, and the output is connected to the actuator 13 of the three-way mixing valve 14 of the lower circuit 15 of the greenhouse heating system. The output of the controller 8 is connected to the OR 19 circuit, the second input of which is connected to the output of the precipitation sensor 20 DO, and the output of the OR 19 circuit is connected to the first inputs of the second 21 and third 22 electron keys. Moreover, the second input of the electronic switch 21 is connected to the heat carrier temperature sensor T of the upper circuit of the heating system, the second input of the electronic switch 22 to the power source 24, and their outputs are connected to the actuator 25 of the three-way mixing valve 26 of the upper circuit of the greenhouse heating system.

Parallel to the lower circuit 18 of the heating system via direct and reverse heat transfer fluids, the I and II inputs of the flow distribution block 28 of the heat transfer fluid are connected respectively to the left (output VI) and right (output V) of branch 29 and 30 of the lateral heating circuit of the greenhouse, while the input III block 28 is connected to the output of the adder 31, the inputs connected respectively to the outputs of the sensors 11, 12 air temperature at the left and right fences of the greenhouse.

The unit 28 for redistributing the coolant flow contains a vortex chamber 32, exits IV and V connected respectively to the left 29 and right 30 branches of the side heating circuit, and input I connected simultaneously to the lower heating circuit 15 on the direct coolant and to the output of the pump 33, whose input It is also connected to the lower circuit 15 via a direct heat carrier. A two-way valve is connected to the outlet of the pump 33

34, connected to the lower circuit 15 through a return heat carrier (output II) equipped with an actuator

35, to the input of which an additional regulator 36 is connected, connected

with the output of the adder 31 (input III).

The device works as follows.

The signals from sensors 1-5, as well as the sensor b, the required temperature TC, air enter the input of the computing unit 7. Computing unit 7, together with sensors 1-5, plays the role of setting the temperature of the coolant in the lower circuit 15 of the heating system data conditions. The main channel for controlling the heat transfer medium in the lower circuit 1 is the channel consisting of the sensor 10-12 of the averaging unit 1, the setting unit 6 and the controller 8.

If the air temperature in the greenhouses corresponds to a given agro-demand (Tdcr-Tg,), the signal and output from the regulator B of the main channel is absent (and, 0). If the current temperature T deviates from the one set at the controller output

Corresponding polarity, which goes to the actuating mechanism 13, turning the shutter of the three-way mixing valve 14 and the ratio between direct (hot) and reverse (cold) water changes, which means that the temperature of the coolant in the lower circuit

15i through the vortex chamber 32 in the left and right branches 29 and 30 of the booster heating circuit. The second (contracting) circuit consists of a sensor 17 of the current temperature T of the flow medium set by the required temperature T, - for these conditions, the heat transfer medium in the lower circuit 15 of the heating system, consisting of sensors 1-5 of the computing unit 7, of the controller

16 and an electronic key 18. If the temperature of the heat carrier T at the given moment answers the required Tu. (

 TT-), which is determined by computation (t, t, t ,,)

8 a signal appears and.

In accordance with the information on weather conditions and microclimate parameters, the signal Uj is absent at the output of the regulator 16 of the correction channel (U 0) and the control of the temperature of the heat carrier in the lower circuit is conducted through the main channel. If the temperature T of the coolant differs from the predicted temperature, then a signal 5. of the corresponding polarity appears, which is fed to the electronic key 18. If the electronic key 18 is open,

those. the regulator 8 of the main channel does not work (U (0), which corresponds to a given temperature, the signal U from the output of the regulator 16 of the corrective channel through the electronic switch 18

enters the actuator 13. The temperature of the coolant in the lower circuit 15, and hence in both branches x 29 and 30 of the side circuit is set in accordance with the set. If there is no precipitation, the signal from the output of the precipitation sensor 20 is absent (U 0), the limit switch (not shown) of valve 14 is the signal from the output of the circuit OR 19

is absent, the electronic switch 22 is open, and the actuating mechanism of the valve 26 is connected to the power supply 24 and is in its lowest position. This corresponds to the minimum temperature of the coolant in the upper circuit 27 of the heating system, and therefore the minimum consumption of thermal energy.

In cold weather, in winter

the period when, to maintain the desired air temperature in the greenhouse, the three-way mixing valve 14 occupies the uppermost position (the temperature of the coolant in the lower

and the lateral circuits reaches the maximum value), its final switch (not shown) is activated and the output of the regulator 8 is connected to the input of the IZH circuit 19. If this is

the temperature of the air in the greenhouse cannot be increased to a predetermined level, using the signal Uj through the circuit OR 19, the electronic switch 21 turns on the actuator 25, with sig55

and locks key 22 and disconnects actuator 25 from power supply 24. The actuator 25, turning the three-way mixing valve 26 of the upper heating circuit 27, raises the temperature of the heat carrier, increasing the air temperature in the greenhouse. When the air temperature in the greenhouse reaches a predetermined value, the actuator 13 of the lower circuit 15 is activated, and the limit switch of the valve 14 turns off the regulator 8 from the OR circuit 19, the signal from its output disappears, the electronic switch 22 opens, connecting the actuator 25 to source 24 supply, and returns the valve 26 of the upper circuit 27 to its original state, thereby reducing the consumption of thermal energy. In order to eliminate the glaciation of the roof during the cold season and at the same time economically consume thermal energy, the upper circuit 27 is automatically turned on. The upper heating circuit 21 is turned off when there is a signal from precipitation sensor 20, which through the OR 19 circuit and the electronic switch 21 enters the actuator 25, which, as in the case of the signal from the regulator 9, increases the temperature of the coolant in the upper circuit 27, valve, 26 returns to its original state immediately after the signal from the sensor output 20 disappears. In order to save thermal energy, the maximum temperature in the coolant in the upper circuit 27 is limited by the setting on the sensor 23 for the coolant temperature, the output of which is connected to the second input of the electronic key 21, When the coolant temperature in the upper circuit 27. reaches the set value, the signal from the sensor 23 closes the electronic the key 21 and the signal from the output of the regulator 8 do not pass to the actuator 25. If, for example, due to strong side wind during the cold, the air temperature at the fences decreases on the left TDC or right T ,, side, at the output of the adder 31 connected to the outputs of the sensors 11 and 12, a signal of the corresponding polarity uU appears, which is fed to the input of the regulator 36 of the heat flux redistribution unit 8. Additional regulator. 36 controls the actuator 35, which, by turning the shutter of the two-way valve 34, changes the capacity of the pump 33. With a constant pump performance of 33 Q and Q Qi, the change in Q also changes the Q component that performs. the role of the regulating flow of the vortex chamber 32. The adjustable flow enters B the vortex chamber 32 in the radial direction from the periphery to the center, the regulating flow Qp enters the chamber 32 tangentially to the periphery. As a result of the mixing of two streams in the chamber, a total stream is formed which has a tangential

(swirling flow) and radial (non-swirling flow) components of the flow velocities, the values of which are determined by the ratio of the flow rates of the controlled and regulating

flows at the entrance to the chamber 32. Part of the total flow (non-swirled flow Q,) is diverted to the right side 30 of the side heating circuit, and swirling flow Q - to its left branch

29. The ratio of Qf and PD is determined by the value of the regulating flow Q, and can be d | pd; p Q Q ,, Adjusting the position of the two-way valve 34, the signal from the output of the adder 31 transfers the main part of the heat carrier flow to the branch of the side heating circuit, which is currently located at the fence with low air temperature. This allows compensating for the influence of the force and direction of the side wind with minimal heat input.

Thus, the goal is achieved

invention, namely increasing the uniformity of the temperature field of the greenhouse.

Claims (1)

1. Device for regulating the air temperature in the greenhouse according to the ed. St. № 1113041, about tl and h and y sch. E e with the fact that, in order to increase uniformity of the greenhouse temperature field, it is equipped with air temperature sensors, left and right branches of the side heating circuit, a unit for redistributing the coolant flow and an adder, the air temperature sensors being connected to the inputs of the averaging unit of the current air temperature and the adder inputs whose output is connected to input A .Makovska 6417/2 f "/. 2 Compiled by G. Sharkov Tehred M. Khodanych F Corrector Circulation 661 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 F Proofreader V. But ha