SU1189391A1 - Apparatus for regulating microclimate variables in hothouses - Google Patents

Abstract

1. A DEVICE FOR REGULATING PARAMETERS / V IKPOKLIMATA IN GREENHOUSES, containing an air-cooled system having electric motorized ventilation ducts, which is connected to the output of the temperature control channel, the sensor and the temperature setting device are connected to the first and second inputs, respectively, , in order to increase the accuracy of maintaining the specified microclimate parameters in the greenhouse during the transitional periods of the year and in the summer, the device contains an air humidification system having a pipeline with a damping valve, equipped with an electric drive, which is connected with the outlet of the humidity control channel, to the first and second inputs of which are connected respectively a sensor and a setting unit for relative humidity, as well as a water cooling system having a cold water source with supply and return pipes and a pressure pump in the supply direct and reverse cold water pipelines, a circulation pump in the cold water return pipe, a three-way electric motorized mixing valve, This is connected to the output of the water cooling control channel, the first and second inputs of which are connected respectively to the temperature sensors of the air cooling system and the relative humidity sensor of the air humidification system, and the third input is connected to the output of the temperature control channel comparison unit through dead zone, while the circulation pump on the return pipe of cold water is connected to the first inlet of the three-way mixing valve, the second inlet of which n with the inlet conduit cold water source, and an output - with a direct cold water conduit, wherein the return line is connected to the cold water conduit system and a return air duct humidification source of cold water. 2. The device according to claim 1, characterized by The fact that each of the control channels (L of temperature and humidity contains a comparison unit, a pulse controller and a matching unit, wherein the inputs of the comparison unit are connected to the sensor and temperature or humidity setter, and the output through the pulse regulator and matching unit is connected to an electric drive 3. The device in paragraphs 1 and 2, characterized in that the water cooling control channel contains a switching unit with a dead zone, a unit switching polarity, the first and second blocks of mass coefficients, an adder, a pulse controller and a matching unit, while the first and second inputs of the block of switching polarity are connected to a temperature sensor and a relative humidity sensor, and the outputs through the first and second blocks of mass coefficients are the inputs of the adder, the output of which through the pulse controller and the matching unit is connected with the electric drive of the three-way valve of the water cooling system.

Description

The invention relates to devices that regulate the parameters of the microclimate inside structures, largely subject to environmental influences, such as greenhouses. The purpose of the invention is to improve the accuracy of maintaining the specified parameters of the microclimate in the greenhouse during the transitional periods of the year and in the summer. FIG. a general scheme of the device is presented; in fig. 2 is a diagram of matching blocks; in fig. 3 is a diagram of a switching unit with a dead zone; in fig. 4 is a diagram of a polarity switching unit. The device for adjusting the microclimate parameters contains a greenhouse 1, equipped with transoms 2, the opening angle of which is changed by the electric drive 3. The greenhouse 1 also has a temperature sensor, a relative humidity sensor 5, pipelines 6 of the water cooling system and humidification system 7. The device includes channels for adjusting the air temperature, regulating the humidity and regulating the water cooling system. The temperature control channel contains a sensor 4 and a setting device 8, which are connected respectively to the inputs of the first comparison unit 9 connected to the output via the pulse controller 10 and the matching unit 11 and the electric drive 3 of the ventilation grids 2. The humidity control channel 7 includes the system 7 humidification with a control valve 12, a sensor 5 and a humidity control unit 13 connected to the second comparison unit 14, connected to the output via the second pulse controller 15 and the second matching unit 16 to the actuator 12 Adjusts the valve system 7 humidification. The water cooling system contains cold water piping 6 with a circulating pump 17 on a return pipe connected to the first inlet of a three-way mixing valve 18, the second inlet of which is connected to the supply pipe of the cold water supply source 19 through the pressure pump 20, and the outlet connected to the direct piping 6 water cooling system 6. The return pipe 6 of the water cooling system is also connected to the pipeline of the air humidification system 7 through the control valve 12 and the return pipe line 19 source of cold water. The control channel of the water cooling system contains a switch unit, 21 switches with the dead zone, a two-channel switch unit 22 for polarity, two blocks 23 and 24 of the mass coefficients of each of the channels connected respectively to the inputs of the adder 25, the output of which is through the third pulse controller 26 and the block 27 matching is connected to the actuator 28 of the three-way mixing valve 18. The input of the block 21 is connected to the output of the first block 9 of the comparison of the temperature control channel, and its output is simultaneously connected the two inputs of the gate dual-channel switching unit 22, to signal inputs of which are 5 relative humidity sensor 4 and temperature sensor are connected, respectively. The matching blocks 11, 16 and 27 (Fig. 2) are arranged in the same way and contain input thyristor switches 29 and 30 connected to sources of constant voltage, positive 31 and negative 32 polarities, to which coils 33 and 34 of the reversing magnetic starter are connected, in turn, connected to the electric drive through a filter 35. During operation, positive polarity pulses c. the outputs of the regulator 10 include a switch 29, which with each pulse connects to the source 31 of a positive polarity voltage a coil 33 of the magnetic actuator. The negative polarity pulses include a switch 30, which with each pulse connects to the source 32 of a negative polarity a coil 34 of a magnetic starter. Such switching ensures that the electric drive is turned on in specified directions. The circuit of the switch unit 21 with the dead zone (Fig. 3) contains a trigger 38, switching from the position "O to" 1 with a positive voltage. The trigger threshold (deadband) of the trigger 38 is set at the input voltage divider 36 by the tuning element 37. During operation, as soon as the positive voltage from the output of the comparison unit 14 exceeds the set voltage at the divider 36, the trigger 31 switches to the position "1. If the positive voltage from the output of the comparator unit 14 is less by the voltage set on the divider 36 or negative etc., then the flip-flop 38 remains in the "O" position. The circuit of the polarity switching unit 22 (FIG. 4) contains input switches 39 and 40; To the signal inputs of which the relative humidity temperature sensors are connected, respectively. The control inputs of both keys 39 and 40 are connected to the output of the block, 21, and inverting amplifiers 41 and 42 are connected in parallel at their outputs. The position "1 of the flip-flop 38 of the switching unit 21 with the deadband

corresponds to the position "1 keys 39 and 40, in which the signals from sensors 4 and 5 are fed to amplifiers 41 and 42 and change their sign from positive to negative. The position "On the trigger 38 corresponds to the position" On the keys 39 and 40, at which the signals of the sensors 4 and 5, mine, the amplifiers 41 and 42, remain positive.

Comparisons 9 and 14 are made in the form of differential circuits.

The device works as follows.

With closed natural ventilation, due to the arrival of intense solar radiation during the transitional periods of the year, the temperature and relative humidity in the greenhouse 1 are increasing. These microclimate parameters are measured by sensors 4 and 5, the signals from which are fed to the inputs of blocks 9 and 14 of the comparison channels for temperature and humidity control and to the two-channel block 22 for switching the polarity of the signals for the control channel of the water cooling system.

As soon as the temperature or relative humidity in the greenhouse 1 becomes higher than the predetermined values set by the setting units 8 and 13, then at the outputs of blocks 9 or 14 of the comparison, signals of negative polarity appear, which are fed to the switching regulators 10 or 15. At the output of the regulator 0, positive polarity control pulses are formed, which, through matching unit 11, include an electric actuator 3 of the transom 2, the duration of pulses. Pa negative polarity control pulses are generated at the output of the regulator 15, Through the matching unit 16, the actuators turn on the actuator of the control valve 12 of the air humidification system 7. This opens the transoms 2 natural ventilation, through which colder outside air enters the greenhouse I and at the same time the humidification rate decreases due to a decrease in water consumption by the valve 12.

Simultaneously from the output of the temperature control channel comparison block 9, a negative signal is sent to the switch unit 21, and if it exceeds the dead band of the block 21, the block trips the key elements of the two-channel polar switch block 22 and the positive signals from sensors 4 and 5 go directly through the blocks 23 and 24 of the mass coefficients and the adder 25 to the pulse controller 26, the positive pulses of which, affecting the block 27 of the matching, are switched on by the duration

pulses the actuator 28, increasing the flow rate of cold water in the cooling piping system 6, while simultaneously reducing the flow rate of return water at the second inlet of the mixing valve 18. This increases the flow rate of the return water in the piping of the humidification system 7.

Such changes lead to a decrease in the temperature of the water entering the cooling system 6 and to an additional cooling of the volume of the greenhouse 1 until the negative signal from the output of the temperature control channel comparison unit 9 is less than the dead zone of the switching unit 21. In this case, the block 21 is turned off, the key elements are installed in the neutral position and, thus, the additional control channel of the cooling system is turned off. Further cooling and draining

0 greenhouses are carried out only at the expense of the opening angle of the transoms 2 until the temperature and relative humidity of the air in the greenhouse become equal to the given value. If the temperature or relative 5 pa the humidity of the air in the greenhouse 1 becomes lower than the preset one, then at the outputs of blocks 9 or 14 of the comparison, positive signals appear, which are converted into pulses of the corresponding polarity at the outputs of the pulse regulators 10 or 15,

0 influences the actuators 3 of the ventilation and the valve 12 of the humidification system 7, reducing air exchange and increasing the intensity of humidification until the climate parameters in the greenhouse 1 are equal to the preset.

5 At the same time, a positive signal from the temperature control channel comparison block 9 is fed to the switching unit 2l, and if this signal exceeds the dead band of the block 21, it triggers and closes the key elements of the block 22 so that the polarity of the signals changes (position "1). In this case, the signals from sensors 4 and 5 become negative and after passing through blocks 23 and 24 mass

5 coefficients and the adder 25 a common signal is fed to the pulse controller 26, switches on the electric actuator 28 of the three-way valve 18 through the matching unit 27, which moves

Q valve spool 18 so as to reduce the water flow rate at the inlet of the water cooling piping system 6 with a simultaneous increase in the return water flow.

In addition, at the same time decreases

5 Return water flow rate in the humidification piping system 7. These changes lead to an increase in the temperature of the water entering the system 6 pipelines

water cooling, and thereby reducing the degree of cooling of the greenhouse volume, until the positive signal from the output of the temperature control channel comparison unit 9 becomes equal to the dead zone of the switching unit 21. In this case, it switches the key elements of the unit 22 to the neutral position, as in the case when the parameters exceed the set ones, thereby shutting off the channel for regulating the water cooling system.

Thus, the channel for adjusting the water cooling system allows the cooling capacity of the water cooling system 6 to be rearranged by a signal exceeding the control error over the permissible value specified by the dead band of unit 22.

The use of the device improves the accuracy of maintaining the specified microclimate parameters in the greenhouse during the transitional periods of the year and in the summer.

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Claims (3)

1. DEVICE FOR REGULATING THE MICROCLIMATE PARAMETERS IN GREENHOUSES, containing an air cooling system having ventilation transoms with an electric drive, which is connected to the output of the temperature control channel, to the first and second inputs of which are connected a temperature sensor and adjuster, characterized in that, in order to increase the accuracy of maintaining the specified microclimate parameters in the greenhouse during the transition periods of the year and in the summer, the device contains an air humidification system having a pipeline with adjustable a control valve equipped with an electric actuator, which is connected to the output of the humidity control channel, to the first and second inputs of which a relative humidity sensor and setter are connected, as well as a water cooling system having a cold water source with supply and return pipes and a discharge pump in the supply pipe, direct and return pipelines of cold water, a circulation pump in the return piping of cold water, a three-way mixing valve with an electric actuator, which is connected with the output of the water cooling control channel, the first and second inputs of which are connected respectively to the temperature sensors of the air cooling system and the relative humidity sensor of the air humidification system, and the third input is connected to the output of the temperature control channel comparison unit through the switching unit with a dead zone, while the circulation pump the cold water return pipe is connected to the first inlet of the three-way mixing valve, the second inlet of which is connected to the feed pipe gadfly cold water source, and an output - with a direct cold water conduit, wherein the return line is connected to the cold water pipe and the air humidification system return line source of cold water. 2. The device according to π. 1, characterized in that each of the temperature and humidity control channels contains a comparison unit, a pulse controller and a matching unit, the inputs of the comparison unit being connected to a sensor and a temperature or humidity setpoint, and the output through a switching controller and matching unit is connected to an electric ventilation fan transom, or control valve of the humidification system. 3. The device according to paragraphs. 1 and 2, characterized in that the water cooling control channel comprises a switching unit with a dead zone, a polarity switching unit, a first and second mass coefficient blocks, an adder, a pulse regulator and a matching unit, while the first and second inputs of the polarity switching unit are connected to the sensor temperature and relative humidity sensor, and the outputs through the first and second blocks of mass coefficients - with the inputs of the adder, the output of which is connected via an impulse regulator and a matching unit to the electric roprivodom cooling water three-way valve system. SU „„ 1189391 ί189391