SU1523115A2 - Device for controlling temperature of air in hothouse - Google Patents

Abstract

The invention relates to agriculture, greenhouse vegetable growing and floriculture. The purpose of the invention is to optimize the process of adjusting air temperature by improving the dynamic characteristics of this process. A device for controlling the air temperature in the greenhouse contains sensors for weather conditions and technological parameters of the greenhouse. The computing unit 8 is connected to the outputs of the weather sensors and corrects the operation of the lower main circuit 13 of the heating system, equipped with a three-way mixing valve 12 with the actuator 11. The upper circuit 23 of the heating system is similar to the lower one and is connected with it via the scheme OR 17. DEVICE ADDITIONAL EQUIPPED WITH THE AIR CONDITION 26 OF THE HEATING SYSTEM, WHICH INCLUDES THE CALORIFIER 30 WITH A VALVE 29 HAVING AN ELECTROMAGNETIC ACTUATOR 28, THE FAN 25 AND THE AIR MIXING VALVE 35 WITH ISOLED MECHANISM 34. CHANNEL CONTROL CIRCUIT AIR HEATING SYSTEM INCLUDING ELECTRONIC KEY MODE SELECT 27, the electronic key 31 and 32 and the sensor supply air temperature. AVAILABILITY OF AIR HEATING CIRCUIT ALLOWS TO REDUCE THE INERTIALITY OF THE DEVICE DURING A COMPENSATION OF THE EFFECT OF VARIABLE PERTYING IMPACTS. THE UPPER CIRCUIT 23 OF THE HEATING SYSTEM IS INCLUDED IN THE WORK ON THE SIGNAL SIGNAL 4 SANDING CLEARANCE AND IN THE PROCESS OF FUNCTIONING PREVENTS THE REDD. 1 IL.

Description

The invention relates to agriculture, in particular to the greenhouse, mainly to greenhouses with combined (water and air) heating, and is an improvement of the known device according to the author. St. No. 1113041.

The aim of the invention is to optimize the process of adjusting air temperature by improving the dynamic characteristics of this process.

The drawing shows a functional diagram of the device for adjusting the air temperature in the greenhouse.

The device contains weather sensors: sensor 1 for outdoor air temperature T, sensor 2 for solar radiation level E, sensor 3 for wind speed V, sensor 4 for precipitation Do, sensor 5 for air humidity in the greenhouse ((i, sensor 6 for soil temperature T ,,, the setting unit 7 of the required air temperature TBJ, which together with the sensors 3 are connected to the input of the computing unit 8, the output of the setting unit 7 of the required air temperature is connected to one of the inputs of the regulator 9 of the main control channel, to the second input of which the sensor 10 is connected t air temperature TB, and the output is connected to the operating mechanism 11 connected to the three-way mixing valve 12 of the lower Koirrypa 13 greenhouse heating system. The output of the computational unit 8 is connected to one of the inputs of the regulator 14 of the THpyioniei o channel , to the second input of which is connected the sensor 15 of the current temperature of the heat carrier T in the lower circuit of the heating system, and its output is connected to one of the inputs of the electronic switch 16. whose second input is connected to the output of the regulator 9 of the main control channel and the output is connected to the control input of the actuator 11 of the three-way mixing valve 12 of the lower circuit 13 of the heating system. The output of the regulator 9 is simultaneously through the upper contact. South of the actuator 11 of the valve 12 is connected to the OR circuit 17, the second input of which is connected to the output of the precipitation sensor 4, and the output of the circuit OR 17 is connected to the first outputs of the electronic switches 18 and 19. Moreover, the second input of the electronic switch 18 is connected to The sensor 20 of the temperature of the coolant of the upper circuit of the heating system of electronic switches 18 and 19, the outputs are connected to the control input of the actuator 2 of the three-way mixing valve 22 of the upper circuit 23 of the greenhouse heating system. In this case, the second input of the electronic switch 19 is connected to the power supply 24. At the same time, the output of the regulator 9 of the main channel is connected to the fan 25 of the air circuit 26 of the power supply system and with the electronic key 27 for selecting the mode, the first output of which is connected to the electromagnet 5

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the valve actuator 28 of the valve 29 of the heater 30, and its second output - with the first inputs of the fourth and fifth electronic switches 31 and 32. Moreover, the second input of the electronic switch 31 is connected to the sensor 33 of the temperature of the incoming air of the heating circuit air 26, and the second input of the electronic switch 32 is connected to a power source 24, and their outlets are connected to the control input of the actuator 34 of the air mixing valve 35 of the air circuit 26 of the heating system.

The device works as follows.

Information from sensors 1-6 and setpoint 7 of the required air temperature Tez is fed to the computing unit 8, which produces a signal proportional to the temperature of the heat transfer medium in the lower circuit 13 required for these conditions (weather and microclimate), i.e. the computing unit 8 is compatible with the sensors 1-6 performs the role of setting the required coolant temperature for the given conditions in the lower circuit of the heating system. The main channel for controlling the temperature of the coolant in the lower circuit is the channel consisting of sensor 10 of the current air temperature Tv, unit 7 of the required Tez air temperature and regulator 9.

If the air temperature in the greenhouse corresponds to the given agro demands 1 76, the signal V from the output of the regulator 9 of the main channel is absent (). As the temperature Ti decreases, with respect to a given TB, (), the output V of regulator 9 causes a signal V corresponding to α. 1, which enters the actuator mechanism 11 and simultaneously locks the electronic key 16. The actuator 11, turning the three-way mixing valve 12 in the direction of increasing the opening angle of the valve, changes the ratio between the forward (hot) and reverse (cold) water, increasing the temperature in the lower circuit 13 of the greenhouse heating system. At the same time, the signal from the regulator 9 of the main channel enters the fan 25 of the air circuit 26 and the electronic switch 27 for selecting the mode and, depending on polarity, at. It is supplied to the electromagnetic actuator 28 of the valve 29 of the heater 30, which is part of the heating circuit 26 of the heating system. Due to the presence of the air circuit, the inertia of the device is reduced, which leads to an improvement in its dynamic characteristics and an increase in the quality of regulation. When the current air temperature reaches a predetermined level, the signal from the regulator 9 disappears, the heater and the fan return to their original position. The second circuit (corrective) consists of a sensor 15 of the current temperature of the heat carrier T, a setpoint for the temperature of the heat carrier TU required in these weather conditions in the lower circuit 13 of the heating system, consisting of sensor 1 - b, computing unit 8, controller 14 and electronic key 16. If the temperature of the heat carrier Tt at a given time corresponds to the required one (,), which is determined by the computing unit 8 in response to the information on weather conditions and microclimate parameters, the signal

 2 iia of the output of the correction channel regulator 14 is absent () and the temperature control of the heat transfer medium in the lower circuit is conducted along the main channel. If the temperature of the coolant differs from the predicted one, then the signal U.) of the corresponding polarity appears, which is fed to the electronic key 16. If the electronic key is open, i.e., the main channel regulator 9 does not work (), which indicates the current air temperature Te specified, with tmal V2 from the output of the regulator 14 of the correction channel through the electronic switch 16 enters the actuator 11, so that the temperature of the coolant in the lower circuit 13 of the heating system is set to and with a given. However, due to the absence of a signal from the regulator 9 of the main channel, air circuit 26 does not work, and if there is no signal from sensor 4 of precipitation, the upper circuit does not work either. In case the air temperature in the greenhouse is given by Tgj. and the three-way mixing valve 12 is fully open (the temperature of the heat carrier T, reaches the maximum value in the lower limit), its final extractor is triggered, the output of the regulator 9 is connected to the input of the OR circuit 17 and the signal: V | polarities corresponding through the circuit OR 17 and the electronic key 18 turns on the actuator 21, locking the key 19 and disconnecting the actuator from the power supply 24. The actuator 21, turning the three-way mixing valve 22 of the upper loop 23 of the heating system, raises the temperature of the coolant, increasing the air temperature in the greenhouse. At the same time, the signal from the regulator 9 of the main channel goes to the fan 25 of the heating air circuit 26 and the electronic switch 27 the mode of the electromagnetic actuator 28 of the valve 29 of the heater 30 of the air circuit 26. Connecting the air circuit to compensate for the deviation of air temperature from a given level reduces inertia device, thereby improving the quality of the process of adjusting the air temperature in the greenhouse. When the air temperature in the greenhouse reaches a predetermined level, the actuator 11 is triggered.

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the circuit and the limit switch of the valve 12 disconnects the regulator 9 from the OR circuit 17, the signal from its output disappears, the electronic switch 19 opens, connecting the actuator 21 to the power supply 24, and returns the valve of the upper circuit 23 to its initial state. When the air temperature reaches a predetermined value, the signal from the regulator 9 of the main control loop disappears and the fan 25 is disconnected and through the electromagnetic actuator 28 of the valve 29 the heater 30 of the air circuit 26. The upper circuit 23 automatically turns on when the roof is icing by the signal from the precipitation sensor 4 coming through the scheme OR 17 and the electronic switch 18 to the actuator 21, which, as in the case of the occurrence of a signal from the controller 9, increases the temperature of the coolant in the upper circuit. In this case, air circuit 26 is not included, since, due to the absence of a radiant component in air heating, the efficiency of its use for removing ice from the roof is small. As soon as the signal from the precipitation sensor 4 disappears, the valve 22 returns to its original state.

If the air temperature in the greenhouse Bbiuje of a given level (), at the output of the regulator 9 of the main channel, a signal Ui of opposite polarity appears, which is fed to the actuator of the engine 11 and simultaneously locks the electronic key 16. The actuator II, turning the three-way mixing valve 12 in the direction of decreasing the valve opening angle, changes the ratio between direct and return water, reducing the temperature of the heat carrier in the lower circuit 13 of the greenhouse heating system. At the same time, the signal from the regulator 9 of the main control channel is fed to the fan 25 of the air circuit 26 and the electronic key 27 for selecting the mode in this case (when,.) Through the key 31 turns on the actuator 34 of the air mixing valve 35 of the air circuit 26j and the signal V | locks key 32 and disconnects actuator 34 from an additional power source. The actuator 34, turning the damper of the air mixing valve 35 in the appropriate direction, mixes the external and recirculated air in a proportion determined by the required supply air temperature T-Ave. When the temperature is up; m in the greenhouse will reach a predetermined level, the signal Vi from the regulator 9 of the main channel disappears, the fan 25 turns off, the electronic switch 31 opens, connecting the actuator 21 to the power source 24 returns the valve

35 of the air circuit 26 to the initial state.

In the spring, when during the daytime the outdoor air temperatures are low from the point of view of agrotechnology and the operation of transoms therefore prohibits, and due to the increased level of solar radiation in the greenhouse, overheating is observed, the temperature of the coolant in the lower circuit reaches a minimum value and works the three-way mixing valve's limit switch 12. In this case, the signal Vi turns on the fan 25, and through it, the mode selection key 27 and the key electronic 31 actuate the actuator 34, with this m signal Vi closes switch 32 and disconnects actuator 34 from an additional source 24. The actuator 34, rotating the valve of the mixing valve 35 in the appropriate direction, performs mixing of outdoor air and recycle -As proportions determined by the desired temperature of the supply air Tcal. When the air temperature in the greenhouse reaches a predetermined level, the Vi signal from the regulator 9 of the main control channel disappears, the fan 25 turns off, the electronic switch 32 opens, connecting the actuator 34 to the power supply 24 and returning the valve 35 of the air circuit 26 to its initial state.

Thus, the introduction into the device of an additional air circuit with a control channel associated with the control channels of the lower and upper circuits of the heating system allows compensation of the effects of variable disturbing influences by simultaneously operating the lower (or upper) and air circuits, thereby reducing the inertia of the device, thereby improving the dynamic characteristics of controlling the air temperature in the greenhouse and increasing the quality of this process. Besides

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In addition, the introduction of an air circuit from the control channel 1 enhances the functionality of the device by using it to remove overheating in greenhouses during spring, which is characterized by an increased level of solar radiation causing overheating in the greenhouse and low outdoor temperatures with agrotechnics which prohibition is imposed on the operation of transoms, and the possibilities of the heating system for regulating the air temperature in the greenhouse in the direction of lowering it are completely exhausted.

Claims (1)

Invention Formula A device for adjusting the air temperature in the greenhouse by author. St. No. 1113041, characterized in that, in order to optimize the control process by improving the dynamic characteristics of this process, it is equipped with an air heating circuit containing a heater with a valve having an electromagnetic drive, a fan and an air mixing valve with an actuator, and an air heating circuit equipped with an adjustment channel, including an electronic mode selection key, a fourth and fifth electronic keys, and a supply air temperature sensor, the latter being connected to the first the fourth electronic key, the second input of which is combined with the first input of the fifth electronic key and is connected to the first output of the electronic mode selection key, the second output of the electronic mode selection key is connected to the control input of the electromagnetic valve of the radiator valve, and the input of the electronic mode selection key is connected to the power source, wherein the outputs of the fourth and fifth electronic switches are connected to the control input of the actuator of the AIR mixing valve.