KR100868518B1 - Geothermal heat pump system and control method thereof - Google Patents

Abstract

A geothermal heat pump system and control method thereof is provided to prevent the ground temperature from rising by decreasing the heat of the heat medium. A geothermal heat pump system comprises as the follows. A geothermic heat exchanger(110) is laid under the equipment house outside underground. An air heat source heat exchanger(120) is installed on ground. A circulation fan(130) operates with a fan motor(M) connected to the air heat source heat exchanger. A ground temperature control device includes a key input unit, a first temperature sensor, a second temperature sensor, a first current portion, a second current portion, a third temperature sensor, and a ground temperature control micro computer.

Description

Regenerative geothermal heat pump system and control method thereof

The present invention relates to a heat storage geothermal heat pump system for maintaining a temperature in a facility house at a temperature at which crops can be grown under optimal conditions in summer or winter.

Conventional heat storage geothermal heat pump system (Patent: Republic of Korea Patent Registration No. 10-0557460) controls the refrigerant flow of the refrigerant circuit including the compressor, the condenser and the evaporator in the heating mode and the cooling mode by operating the four-way valve.
In the heating mode, the refrigerant gas in the refrigerant circuit is compressed by the compressor and then passed through the condenser to form a low-temperature, low-pressure liquefied refrigerant. When the liquefied refrigerant passing through the condenser passes through the evaporator, a high-temperature and high-pressure refrigerant gas is generated. After the cycle is repeated, the process of compression by the compressor is repeated. At this time, the evaporator absorbs the geothermal heat from the fluid circulated through the second fluid pipe disposed in the ground to vaporize the liquefied refrigerant, and the condenser vaporizes the fluid in the fluid tank. Forced circulation produces hot fluid, and the hot fluid stored in the fluid tank is forcedly circulated through the first fluid pipe installed in the thermal tunnel in the greenhouse to maintain the temperature in the greenhouse at a temperature at which crops can grow.
When controlled in the cooling mode, the operation of the four-way valve reverses the refrigerant flow in the refrigerant circuit to reverse the roles of the evaporator and the condenser, so that high temperature heat is transferred through the second fluid pipe connected to the evaporator in a heat exchangeable manner. It is radiated to the ground, and the condenser generates the fluid in the fluid tank as a low temperature fluid, and the low temperature fluid stored in the fluid tank is forced to circulate through the first fluid pipe in the heat tunnel, so that the crops in the heat tunnel are kept at a temperature at which growth is possible. Let's do it.
The conventional regenerative geothermal heat pump system (document: Korean Patent Registration No. 10-0557460) that operates as described above is a second fluid disposed in the ground to heat the heat of the high-temperature heat medium oil (eg, water) generated during the daytime cooling operation during summer. As the ground is discharged through the pipe, the ground temperature of the ground where the second fluid pipe is disposed is raised. Therefore, the heat of the high-temperature heat medium oil due to the heat dissipation of the evaporator during the cooling operation was not sufficiently released, resulting in a case in which the high pressure of the geothermal heat pump is not increased or the continuous operation is not performed. There has been a problem that this consumption or cooling efficiency is also lowered.

The present invention was developed to solve this problem, and an object of the present invention is to provide a regenerative geothermal heat pump system and a method of controlling the same, which lowers the temperature of a high temperature heat medium oil and prevents a rise in temperature.

The heat storage geothermal heat pump system of the present invention according to the above object

A heat pump unit configured with a compressor, a condenser, and an evaporator installed in the facility house, a heat storage tank storing heat medium oil exchanged with the condenser of the heat pump unit, and a circulation pump for circulating the heat medium oil in the heat storage unit to the condenser and the facility house of the heat pump unit. In the heat storage geothermal heat pump system comprising a fluid pipe having an intermittent valve for regulating the thermal fluid flow circulating in the circulation pump,

Geothermal heat exchanger embedded in the ground outside the facility house, air heat source heat exchanger installed on the ground outside the facility house, circulation fan interlocked with the fan motor connected to the air heat source heat exchanger, evaporator of the heat pump unit, geothermal heat exchanger, air heat source heat exchanger It is characterized in that it further comprises a fluid pipe, a temperature control device having a circulation pump on one side connected to the heat exchange with each other.

In the heat storage geothermal heat pump system of the present invention according to the above object, the geothermal control device is a key input unit for receiving a cold, heating key signal, a first temperature sensor for outputting a signal corresponding to the outside air temperature outside the facility house, A second temperature sensor for outputting a signal corresponding to the ground temperature of the geothermal heat exchanger buried outside the facility house, a first conducting unit connected to a fan motor of an air heat source heat exchanger installed on the ground outside the facility house, the geothermal heat exchanger, air A second conduction part connected to a circulating pump for circulating heat medium oil in a fluid pipe connected to the heat source heat exchanger and the evaporator of the heat pump unit in the facility house, and the heat source unit is introduced into the air heat source heat exchanger from the evaporator of the heat pump unit A third temperature sensor for outputting a signal corresponding to the temperature of the heat medium oil, the output of the key input unit and the first, second, third temperature sensor It characterized in that it comprises a microcomputer with a control unit for controlling the on, off operation of the first and second energizing unit according to the signal.

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The microcomputer turns on the first and second energization parts when the outside air temperature of the ground outside the facility house is lower than the temperature of the ground where the geothermal heat exchanger is embedded outside the facility house. It is characterized by a built-in algorithm configured to turn off all.

The microcomputer turns on the first and second energizing parts when the outside air temperature of the ground outside the facility house is higher than the ground temperature of the ground heat exchanger embedded outside the facility house while the heating key signal is input to the controller. And an algorithm configured to turn off the first and second energization parts in a low case.

The microcomputer, when the heating key signal is input to the controller, when the outside air temperature of the ground outside the facility house is higher than the temperature of the heat medium oil flowing out of the evaporator of the heat pump unit to the air heat source heat exchanger, the first, It is characterized in that the built-in algorithm configured to turn on the second conducting unit, the low when the first, second conducting unit.

Control method of a heat storage geothermal heat pump system according to the present invention according to the above object is the step of checking the air temperature of the ground, the outside air temperature of the ground, the ground heat exchanger, the ground outside the facility house, the check result, the outside of the facility house If the outside air temperature of the ground is lower than the temperature of the ground where the geothermal heat exchanger is buried outside the facility house, the heat exchanger is heat exchanged with the evaporator of the heat source heat exchanger installed in the ground outside the facility house and the heat pump unit in the facility house. And a circulating pump for circulating the heat medium oil in the connected fluid pipe, and a fan motor connected to the air heat source heat exchanger to be driven, and stopping each drive if high.

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As a result of the checking, when the outside air temperature of the ground outside the facility house is higher than the temperature of the ground in which the geothermal heat exchanger is buried outside the facility house, the circulation pump and the fan motor are driven. Characterized in that further comprises the step of making.

Confirming the temperature of the heat medium oil in the fluid pipe; and, if the outside air temperature of the ground outside the facility house is higher than the temperature of the heat medium oil flowing out of the evaporator of the heat pump unit into the air heat source heat exchanger, the circulation The pump and the fan motor to be driven, if low, characterized in that further comprises the step of stopping each drive.

Due to the improved cooling and heating performance according to the present invention, the temperature in the facility house is maintained at an appropriate temperature in the summer and winter, thereby obtaining a high quality crop.

Hereinafter, with reference to the accompanying drawings will be described the present invention.

The heat pump system of the present invention of FIG. 1 includes an evaporator 101, a condenser 102, a compressor 103, and operates a four-way valve 104 for controlling the temperature of the refrigerant. Heat pump unit 100, geothermal heat exchanger 110, air heat source heat exchanger 120, fan motor (M), circulation fan 130, circulation pump (P1), fluid piping (W1) to control the cooling mode This configuration, and further comprises the geothermal control device of FIG.

In addition, the heat storage tank 140, the second circulation pump (P2), the second circulation pump (P3), a plurality of intermittent valve (V1 ~ V8), the second fluid pipe (W2) is configured.

Thus, each operation of the summer, winter season is configured as follows.

① summer season

During the cooling mode, as mentioned in the prior art, the evaporator 101 of the heat pump unit 100 emits heat to the ground where the geothermal heat exchanger 110 is embedded.
Therefore, when the outside air temperature of the ground outside the facility house (H) is lower than the temperature of the ground where the geothermal heat exchanger 110 is embedded outside the facility house (H), the circulation pump (P1) and the fan motor (M) For example, when the outside air temperature of the ground outside the facility house (H) is 5 ℃ lower than the underground temperature where the geothermal heat exchanger 110 is embedded, the circulation pump (P1) and the fan motor (M) to be driven do.

Thus, the heat medium oil (eg, water) circulated along the fluid pipe W1 by the driven circulation pump P1 is discharged into the air introduced by the circulation fan 130 and then the geothermal heat exchanger ( 110 is introduced into the buried ground, the geothermal heat exchanger 110 to lower the temperature of the buried underground.

Thus, during the summer daytime cooling operation, the heat of the high temperature heat medium oil generated as the evaporator 101 of the heat pump unit 100 operates in the cooling mode is lowered by the circulation fan 130 and then the geothermal heat exchanger ( Since the 110 is discharged into the buried ground, the geothermal heat exchanger 110 can suppress the rise of the ground temperature of the buried ground and lower it to a certain temperature or less, and as a result, reduce the cooling performance of the heat pump unit 100. Done.

② Winter season

During the heating mode, as mentioned in the prior art, the evaporator 101 of the heat pump unit 100 absorbs heat in the ground where the geothermal heat exchanger 110 is embedded.
Therefore, when the outside air temperature of the ground outside the facility house is higher than the temperature of the ground where the geothermal heat exchanger 110 is embedded outside the facility house, the circulation pump P1 and the fan motor M are driven, for example, When the outside air temperature of the ground outside the facility house (H) is 5 ℃ higher than the underground temperature where the geothermal heat exchanger 110 is embedded, the circulation pump (P1) and the fan motor (M) is driven.

Alternatively, when the outside air temperature of the ground outside the facility house is higher than the temperature of the heat medium oil flowing out of the evaporator 10 of the heat pump unit 100 into the air heat source heat exchanger 120, the circulation pump (P1) and the fan The motor (M) is driven, for example, the outside air temperature outside the facility house (H) of the heat medium oil in the fluid pipe (W1) flowing out of the heat pump unit 100 to the air heat source heat exchanger 120 When the temperature is 5 ° C higher than the temperature, the circulation pump P1 and the fan motor M are driven.

The thermal medium oil circulated along the fluid pipe W1 by the driven circulation pump P1 absorbs heat in the air introduced by the circulation fan 130 and then the ground heat exchanger 110 is buried. Inflow to the ground, the geothermal heat exchanger 110 is to increase the temperature of the underground.

Therefore, during the winter night heating operation, even if the heat of the heat medium oil absorbed geothermal heat is lowered by being absorbed by the refrigerant introduced into the evaporator 101 of the heat pump unit 100 is increased by the circulation fan 130 Since the geothermal heat exchanger 110 is discharged into the buried ground, the geothermal heat exchanger 110 can be lowered to a certain temperature by suppressing the lowering of the ground temperature of the buried ground, as a result of the heat pump unit 100 Prevents deterioration of heating performance

The geothermal control device of the present invention shown in FIG. 2 includes a key input unit 200, first, second and third temperature sensors 201, 202, and 203, first and second energizing units 204 and 205, and a microcomputer 206. )

The key input unit 200 is provided with cooling and heating keys, and selectively receives a cooling or heating key signal according to a user's operation.

The first temperature sensor 201 is the outside air temperature of the ground outside the facility house (H), the second temperature sensor 202 is the underground temperature at which the geothermal heat exchanger 120 outside the facility house (H), the third temperature sensor 203 detects the temperature of the heat medium oil (eg, water) flowing through the fluid pipe W1 between the heat pump unit 100 and the air heat source heat exchanger 120, respectively.

Each of the temperature sensors 201, 202, and 203 may use, for example, a negative temperature coefficient (NTC) thermistor. The temperature sensor 201, 202, and 203 may use a different voltage according to the sensed temperature to inform the sensed temperature.

The first conducting unit 204 is connected to the fan motor (M) of the air heat source heat exchanger 120 installed on the ground outside the facility house (H).

The second conducting unit 205 is connected to the circulating pump P1, that is, the geothermal heat exchanger 110, the air heat source heat exchanger 120, and the evaporator 101 of the heat pump unit 100 in the facility house H, respectively. It is connected to the circulation pump (P1) for circulating the heat medium oil in the fluid pipe (W1) connected to the heat exchange.

The microcomputer 206 performs on and off operations of the first and second energizing units 204 and 205 according to output signals from the key input unit 200 and the first, second and third temperature sensors 201, 202 and 203. The control unit is built with a control algorithm.

Operation of the geothermal control device of the present invention configured as described above is as follows.

① summer season

First, the microcomputer 206 compares the output voltage of the first temperature sensor 201 with the output voltage of the second temperature sensor 202 while the cooling key signal is input from the key input unit 200. When the output voltage of the 201 is lower than the output voltage of the second temperature sensor 202, that is, when the temperature outside the facility house is lower than the underground temperature at which the geothermal heat exchanger 110 is buried, a high pulse (eg, 5V) is applied. ) Is applied to the first and second energizing parts 204 and 205 to drive the circulation pump P1 and the fan motor M.

On the other hand, while the cooling key signal is input from the key input unit 200, the output voltage of the first temperature sensor 201 and the output voltage of the second temperature sensor 202 by comparing the output voltage of the first temperature sensor 201 When the output voltage of the second temperature sensor 202 is higher, that is, when the temperature outside the facility house is higher than the underground temperature at which the geothermal heat exchanger 110 is buried, a low pulse (for example, 0V) is applied to the first and second. It is applied to the energization unit 204, 205 to stop the driving of the circulation pump (P1) and the fan motor (M).

② Winter season

The microcomputer 206 compares the output voltage of the first temperature sensor 201 with the output voltage of the second temperature sensor 202 while the heating key signal is input from the key input unit 200. When the output voltage of) is higher than the output voltage of the second temperature sensor 202, that is, when the temperature of the ground outside the facility house is higher than the underground temperature at which the geothermal heat exchanger 110 is buried, the high pulse is applied to the first and second tubes. It is applied to all (204, 205) to drive the circulation pump (P1) and the fan motor (M).

On the other hand, while the heating key signal is input from the key input unit 200, the output voltage of the first temperature sensor 201 is compared with the output voltage of the second temperature sensor 202 by comparing the output voltage of the first temperature sensor 201. When the output voltage of the second temperature sensor 202 is lower, that is, when the temperature of the ground outside the facility house is lower than the underground temperature at which the geothermal heat exchanger 110 is buried, the low pulse is applied to the first and second conducting units 204,. 205 to stop the driving of the circulation pump (P1) and the fan motor (M).

Alternatively, the microcomputer 206 compares the output voltage of the first temperature sensor 201 with the output voltage of the third temperature sensor 203 so that the output voltage of the first temperature sensor 201 is the third temperature sensor 203. When the output voltage is higher than, that is, when the temperature of the ground outside the facility house is higher than the temperature of the heat medium oil flowing into the ground where the geothermal heat exchanger 110 is buried, a high pulse is applied to the first and second conducting units 204 and 205. By applying to the circulation pump (P1) and the fan motor (M) to be driven.

On the other hand, the microcomputer 206 compares the output voltage of the first temperature sensor 201 with the output voltage of the third temperature sensor 203 so that the output voltage of the first temperature sensor 201 is the third temperature sensor 203. When the output voltage is lower than, that is, when the temperature of the ground outside the facility house is lower than the temperature of the heat medium oil flowing into the ground where the geothermal heat exchanger 110 is buried, the first and second conducting unit (204, 205) It is applied to stop the driving of the circulation pump (P1) and the fan motor (M).

As an example of the first conducting unit 204 of FIG. 2A according to the present invention, the first conducting unit of FIG. 2B is composed of a relay and a TNR, and is electrically connected to the fan motor M of the air heat source heat exchanger 120. Under the control of the microcomputer 206, it is turned on and off to selectively operate an operating power supply (for example, AC 100V) to the fan motor M. Thus, the drive of the fan motor M is controlled.

The second conducting portion of FIG. 2C is an example of the second conducting portion 205 of FIG. 2A according to the present invention. A circulation pump configured to circulate heat medium oil in the fluid pipe W1 is composed of a transistor, a photodiak, and a triac. Electrically connected to P1, it is turned on and off under the control of the microcomputer 206 to selectively energize an operating power source (for example, AC 100V) to the circulation pump P1. Thus, the driving of the circulation pump P1 is controlled.

Summer temperature control method of the present invention shown in Figure 3 is as follows.

First, the cooling and heating mode of the heat pump unit 100 is checked (S300). Then, it is checked whether the outside air temperature of the ground outside the facility house is lower than the temperature of the ground in which the geothermal heat exchanger 110 is embedded outside the facility house (S301).

As a result, in the cooling mode, when the outside air temperature of the ground outside the facility house is lower than the temperature of the ground where the geothermal heat exchanger 110 is embedded outside the facility house, the heat medium oil (eg, water) in the fluid pipe W1 Fan motor (M) connected to the circulating pump (P1) and the air heat source heat exchanger 120 to circulate () is driven (S302), and if the driving is high (S303).

Winter geothermal control method of the present invention of Figure 4 is as follows (see Figure 1).

First, the cooling and heating mode of the heat pump unit 100 is checked (S400).

Next, it is checked whether the outside air temperature of the ground outside the facility house is higher than the temperature of the ground in which the geothermal heat exchanger 110 is embedded outside the facility house (S402).

As a result, when the outside air temperature of the ground outside the facility house in the heating mode is higher than the temperature of the ground where the geothermal heat exchanger 110 is buried outside the facility house, or the outside air temperature of the ground outside the facility house is the heat pump unit When the temperature is higher than the temperature of the heat medium oil flowing out of the evaporator of 100 and flowing into the air heat source heat exchanger 120, the circulating pump P1 and the fan motor M are driven (S403). (S404).

1 is a view showing a heat storage geothermal heat pump system according to the present invention

Figure 2a is a block diagram showing a geothermal control device of a heat storage geothermal heat pump system according to the present invention

FIG. 2B is a circuit diagram showing an example of the first conducting portion of FIG. 2A.

FIG. 2C is a circuit diagram of an example of the second energizing unit of FIG. 2A.

Figure 3 is a flow chart showing the summer geothermal control method according to the present invention

4 is a flow chart illustrating a winter geothermal control method according to the present invention

* Description of the symbols for the main couples in the drawings

100: heat pump unit 110: geothermal heat exchanger

120: air heat source heat exchanger 130: circulation fan

140: heat storage tank M: fan motor

W1: Fluid piping P1: Circulation pump

V1 ~ V8: Intermittent valve W2: Second fluid piping

      200: key input unit 201: first temperature sensor

202: second temperature sensor 203: third temperature sensor

204: first conducting portion 205: second conducting portion

206: Microcomputer

Claims (8)

The heat pump unit 100 including the evaporator 101, the condenser 102, the compressor 103 installed in the facility house and operating the four-way valve 104 to control the refrigerant flow in the heating mode and the cooling mode, the heat pump A heat storage tank 140 for storing the heat transfer oil heat exchanged with the condenser of the unit 100, a circulation pump (P2, P3) for circulating the heat transfer oil in the heat storage tank 140 to the condenser and the facility house of the heat pump unit 100, In the heat storage geothermal heat pump system comprising a fluid pipe (W2) having an intermittent valve for regulating the heat medium oil flow circulated in the circulation pump (P2, P3), Geothermal heat exchanger 110 buried in the ground outside the facility house; An air heat source heat exchanger 120 installed on the ground outside the facility house; A circulation fan 130 interlocked with the fan motor M connected to the air heat source heat exchanger 120; A fluid pipe (W1) connected to the evaporator, the geothermal heat exchanger (110) and the air heat source heat exchanger (120) of the heat pump unit (100), and having a circulation pump (P1) on one side thereof; And A key input unit 200 for receiving a cooling and heating key signal; A first temperature sensor 201 for outputting a signal corresponding to the outside air temperature of the ground outside the facility house; A second temperature sensor 202 for outputting a signal corresponding to the temperature of the ground in which the geothermal heat exchanger 110 is embedded outside the facility house; A first conducting unit 204 connected to the fan motor M of the air heat source heat exchanger 120 installed outside the facility house; The geothermal heat exchanger 110, the air heat source heat exchanger 120, the circulation pump (P1) for circulating the heat medium oil in the fluid pipe (W1) connected to each of the heat exchange unit and the evaporator of the heat pump unit 100 in the facility house A second conducting unit 205 connected to the second conducting unit; A third temperature sensor 203 for outputting a signal corresponding to the temperature of the heat medium oil flowing out of the evaporator of the heat pump unit 100 into the air heat source heat exchanger 120; The microcomputer 206 is provided with a control unit for controlling the on and off operation of the first, second power supply unit 204, 205 according to the output signal of the key input unit 200 and the first, second, third temperature sensors (201, 202, 203). Geothermal control device, including Regenerative geothermal heat pump system comprising a further. delete The method of claim 1, The microcomputer 206 is While the cooling key signal is input to the controller, when the outside air temperature of the ground outside the facility house is lower than the temperature of the ground in which the geothermal heat exchanger 110 is buried outside the facility house, the first and second conducting units 204 and 205. ) Is turned on, if the high, the first and second energization unit (204, 205) is a heat storage geothermal heat pump system with a built-in algorithm. The method of claim 1, The microcomputer 206 is While the heating key signal is input to the control unit, when the outside air temperature of the ground outside the facility house is higher than the temperature of the ground in which the geothermal heat exchanger 110 is embedded outside the facility house, the first and second conducting units 204 and 205. ), The low-power geothermal heat pump system with a built-in algorithm configured to turn off the first, second conducting portion (204, 205) when low. The method of claim 1, The microcomputer 206 is While the heating key signal is input to the controller, when the outside air temperature of the ground outside the facility house is higher than the temperature of the heat medium oil flowing out of the evaporator of the heat pump unit 100 into the air heat source heat exchanger 120, the A regenerative geothermal heat pump system with an integrated algorithm configured to turn on the first and second energized parts (204, 205) and to turn off the first and second energized parts (204, 205) if they are low. Confirming the cold, heating mode, the outside air temperature of the ground outside the facility house, and the underground temperature at which the geothermal heat exchanger 110 is embedded; As a result of the check, when the outside air temperature of the ground outside the facility house in the cooling mode is lower than the temperature of the ground where the geothermal heat exchanger 110 is buried outside the facility house, the ground heat exchanger 110 and the ground outside the facility house An air heat source circulating pump (P1) for circulating heat medium oil in a fluid pipe (W1) connected to the heat exchanger (120) and the evaporator (101) of the heat pump unit (100) in the facility house in heat exchange. And driving the fan motor (M) connected to the heat exchanger (120) and stopping each drive when the heat exchanger (120) is high. The method of claim 6, As a result of the check, when the outside air temperature of the ground outside the facility house in the heating mode is higher than the temperature of the ground where the geothermal heat exchanger 110 is embedded outside the facility house, the circulation pump (P1) and the fan motor (M) And driving each drive to be stopped when the power is low. The method of claim 6, Confirming a temperature of the heat medium oil in the fluid pipe (W1); As a result of the checking, when the outside air temperature of the ground outside the facility house in the heating mode is higher than the temperature of the heat medium oil flowing out of the evaporator of the heat pump unit 100 into the air heat source heat exchanger 120, the circulation pump (P1) And a fan motor (M) are driven, and each drive is stopped when the fan motor (M) is low.

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