KR102094996B1 - Hot water supplying system for controlled horticulture using heat pump, and controll method therof - Google Patents

Abstract

The present invention relates to a hot water supply system for facility horticulture using a heat pump and its control methods, wherein the hot water supply system for facility horticulture using a heat pump is a high temperature hot water unit for storing high temperature hot water for supply to a facility, the facility A hot water tank for storing the low temperature hot water recovered after use in the hot water tank, and a hot water tank having a partition wall partitioning the internal space into the low temperature hot water unit and the high temperature hot water unit; A low temperature hot water unit pump that supplies the low temperature hot water to the heat pump from the low temperature hot water unit; A heat pump that heats the hot water using the heat discharged from the condenser and discharges it to the hot water portion when the hot water supplied from the cold water portion passes through the condenser; And a high temperature hot water unit pump supplying the high temperature hot water from the high temperature hot water unit to the facility.
Accordingly, energy efficiency is improved, and the number of operating heat pumps can be automatically controlled according to seasonal temperature changes and the like, and the temperature of the greenhouse can be maintained in an appropriate state for crop growth.

Description

Hot water supply system for facility horticulture using heat pump and its control method {HOT WATER SUPPLYING SYSTEM FOR CONTROLLED HORTICULTURE USING HEAT PUMP, AND CONTROLL METHOD THEROF}

The present invention relates to a hot water supply system for a facility garden using a heat pump and a control method thereof, and more particularly, to an energy-efficient hot water supply system for supplying hot water to control the indoor temperature of the facility garden, and a control method thereof.

Facility Horticulture Smart Farm is operated with a number of subsidiary facilities such as a raw water tank, a liquid manure tank, a mixing tank, and a hot water tank. These subsidiary facilities have a considerable size proportional to the size of the farm, and are very inefficient in terms of space utilization in designing and operating a facility gardening house or smart farm.

As a method of controlling the indoor temperature of the smart farm, the indoor temperature is controlled by allowing hot water from the hot water tank to flow into the room of the smart farm and heat exchange with indoor air, while the heat exchanged hot water is again the same. It is operated to be recovered as a hot water tank.

As the hot water recovered from the heat exchange and the warmed water from the heat source are stored in one hot water tank, the hot water in the hot water tank is not maintained at the highest temperature, but becomes the hot water to maintain the medium temperature. This is very inefficient in terms of energy efficiency, but considering the spatial constraints of the smart farm, it was operated without providing a special alternative.

On the other hand, when the indoor temperature of the smart farm needs to be rapidly raised, there are cases in which a plurality of heat pumps are installed and operated as a heat source in order to supply high heat in a short time. In order to optimally operate a plurality of heat pumps, it is desirable to operate to follow the required thermal load, but it has been operated in such a way that the manager sets the number of operating heat pumps directly. In Korea, where the temperature change is large in the same season and the day difference is large even in the day, the user sets the number of heat pumps to be operated by adjusting the temperature of the greenhouse appropriately for crop growth conditions in response to changes in the external environment. There is a limit. Therefore, there is a need for an optimal energy efficiency solution in a smart farm operating a large-capacity heat pump-based hot water tank.

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Korean Registered Patent No. 10-1171477 (2012. 07. 31.) Korean Patent Publication No. 10-2014-0147385 (Dec. 30, 2014)

Facility horticulture of power plant waste heat source heat pump system (Heo Tae-hyun, 2012)

The present invention has been devised to improve the above-mentioned problems of the prior art, and an object of the present invention is to provide a hot water supply system and a control method for a facility garden with high energy efficiency.

The above object is, in the hot water supply system for facility horticulture using a heat pump according to an aspect of the present invention, a high temperature hot water unit for storing high temperature hot water for supplying to a facility, and storing low temperature hot water recovered after use in the facility A hot water tank having a low temperature hot water unit and a partition wall partitioning the interior space into the low temperature hot water unit and the high temperature hot water unit; A low temperature hot water unit pump supplying the low temperature hot water from the low temperature hot water unit to a first heat pump; A first heat pump that heats the hot water using the heat discharged from the condenser and discharges the hot water from the low temperature hot water unit to the high temperature hot water unit when the hot water supplied from the low temperature hot water unit passes through the condenser; And it can be achieved by a hot water supply system for horticultural facilities, characterized in that it comprises a hot water pump to supply the hot water from the hot water portion to the facility.
The partition wall may be formed in an upward direction from a lower surface of the interior space, wherein the partition wall is formed with a flow path of a predetermined height or more to allow water to flow between the hot and cold hot water units. You can.
The plurality of first heat pumps, and when the temperature difference between the entrance and exit of the condenser of the first heat pump exceeds a predetermined range, supplies hot water to control the number of the first heat pumps operated in response to the temperature difference. It may be said to further include a condenser flow control valve.
The facility horticulture hot water supply system, when the temperature of the facility horticulture nutrient solution room outside air is below a predetermined temperature, a hot water boiler that heats the hot water supplied from the high temperature hot water unit to the greenhouse corresponding to the temperature of the outside of the greenhouse ; And when the temperature of the outside of the greenhouse is below a predetermined temperature, it may further include a boiler induction valve to supply the hot water from the hot water to the hot water boiler.
The boiler induction valve may be configured to control the flow rate of hot water supplied to the hot water boiler from the high temperature hot water unit in response to the temperature of the outside of the greenhouse.
The facility horticultural hot water supply system further includes a second heat pump and a heat source tank connected to the first heat pump, wherein the heat source tank stores high temperature hot water for supplying the second heat pump. The second heat pump may include a low heat source hot water unit for storing the low temperature hot water recovered after use in the second heat pump, and a heat source partition wall partitioning the internal space into the low heat source hot water unit and the high heat source hot water unit.
The connected second heat pump may be configured to absorb heat from heated hot hot water and supply it to the first heat pump by using heat supplied from a water heat source including power plant hot water.
In the control method of a hot water supply system using a heat pump according to another aspect of the present invention, the low temperature hot water supplied from the low temperature hot water portion of the hot water tank is supplied to the first heat pump; When the low-temperature hot water passes through the condenser of the first heat pump, the hot water is heated using heat discharged from the condenser; Discharging the heated hot water to the hot water portion of the hot water tank; And supplying the hot water discharged from the high temperature hot water unit to a facility.
The control method of the hot water supply system includes: when the temperature of the outside of the greenhouse is below a predetermined temperature, the hot water is supplied to the hot water boiler from the hot water unit; And when the temperature of the outside of the greenhouse is equal to or less than a predetermined temperature, heating the hot water supplied from the high temperature hot water unit in response to the temperature of the outside of the greenhouse.
The control method of the hot water supply system includes: heating the hot water using heat supplied from a water heat source including hot water from a power plant; Supplying the heated hot water to a second heat pump; Heat absorbed from the hot water when the supplied hot water passes through the evaporator of the second heat pump; And supplying heat absorbed from the hot water to the first heat pump.

According to the hot water supply system for facility horticulture using the heat pump according to the present invention and its control method, high-temperature hot water warmed from the heat pump and low-temperature hot water recovered from the smart farm can be separated to increase energy efficiency, and separate storage space When it exceeds the capacity, it is designed with a structure in which hot water is mixed to prevent accidents due to excess storage capacity for each hot water. In addition, the number of heat pumps can be automatically controlled according to seasonal temperature changes, etc., and the hot water boiler is operated according to the temperature of the outside of the greenhouse to heat the hot water supplied to the facility, so that the temperature of the greenhouse can be maintained in the proper state of crop growth. have.

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1 is a schematic block diagram of a hot water supply system for facility gardening using a heat pump according to a first embodiment of the present invention.
2 is a schematic block diagram of a hot water supply system for facility gardening using a heat pump according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram of a hot water supply system for facility gardening using a heat pump according to a first embodiment of the present invention.

Referring to FIG. 1, the hot water supply system for facility horticulture using the heat pump according to the first embodiment of the present invention 1 includes a hot water tank 10, a low temperature hot water portion pump 20, a heat pump 30, and a high temperature. It includes a hot water pump 40, a hot water boiler 50, and a control unit (not shown).

The hot water tank 10 is a tank for storing hot water for supplying to facilities such as a greenhouse, a building, or hot water after being used in the facility, and the inner space by the partition wall 13 has a high temperature hot water unit 11 and a low temperature hot water unit ( 12).

The high temperature hot water part 11 is a side of the hot water tank 10, and is a place where high temperature hot water for supplying to facilities is stored.

The low temperature hot water unit 12 is a side of the hot water tank 10, and is used to recover and store low temperature hot water that has been lowered in temperature after being used in facilities.

The partition wall 13 is for dividing the inner space of the hot water tank 10 into a hot water portion 11 and a cold water portion 12, and the upper surface from the lower surface of the hot water tank 10 It can be implemented with an open wall formed in the direction. As shown, the partition wall 13 may be formed with a constant gap so as not to contact the upper surface (ceiling), which is the height of the hot water in the high temperature hot water section 11 or the low temperature hot water section 12, the partition wall 13 In the case of overflow, it is to maintain the flow balance of hot water between the hot water heater 11 and the cold water heater 12 by allowing hot water overflowing from one hot water unit to flow to the other hot water unit. Here, the partition wall 13 may be embodied to form a different type of flow path that allows the hot water overflowing from one hot water portion to flow to the other hot water portion. As a result, the interior space of the hot water tank 10 is divided into a high temperature hot water unit 11 and a low temperature hot water unit 12 by a partition wall 13, thereby increasing energy efficiency of the entire facility gardening house.

The low temperature hot water portion pump 20 is a pump that supplies hot water from the low temperature hot water portion 12 to the heat pump 30, and may be implemented as a pressure pump to uniformly supply hot water at a constant flow rate.

The heat pump 30 is an air-conditioning device that transfers a low-temperature heat source to a high temperature or heats a high-temperature heat source to a low temperature by using heat of heat or condensation of the refrigerant, and heats the hot water supplied from the low-temperature hot water unit 12. That is, when the hot water supplied from the low temperature hot water unit 12 passes through a condenser (not shown) of the heat pump 30, the hot water is heated using the heat released while the refrigerant condenses to the high temperature hot water unit 11 Is provided.

Heat pump 30 may be implemented in a plurality in order to quickly supply a large amount of heat in a short time. When the temperature difference between the entrance and exit of the condenser of the heat pump 30 exceeds a predetermined range (eg, 5 to 7 ° C), the condenser flow control valve 31 connected to the left end of the heat pump 30 corresponds to the temperature difference. Hot water is supplied to the heat pump 30 of the large number, so that the heat pump 30 of the large number is operated. Accordingly, hot water may be heated to a higher temperature by using more heat discharged from the condenser of more heat pumps 30. As a result, it is possible to more appropriately maintain the temperature inside the greenhouse by operating a suitable number of heat pumps flexibly according to the environment outside the greenhouse or crop growth conditions.

The high temperature hot water portion pump 40 is a pump that supplies hot water from the high temperature hot water portion 11 to a facility, and can be implemented as a pressurized pump to uniformly supply hot water at a constant flow rate. same.

The hot water boiler 50 is for heating hot water supplied to the facility from the high temperature hot water unit 11, and when the temperature of the outside of the greenhouse is below a certain temperature, the hot water supplied from the high temperature hot water unit 11 is supplied to the temperature of the outside of the greenhouse. Correspondingly, hot water can be heated. For example, if the outside temperature of the greenhouse is 0 ℃, hot water is heated to 50 ℃, if the temperature of outside of the greenhouse is -5 ℃, hot water is 60 ℃, and if the temperature of outside of the greenhouse is -10 ℃, the hot water boiler 50 is heated to heat the hot water to 70 ℃. Can be implemented. Accordingly, by using the hot water boiler 50 to heat the hot water to a suitable temperature in accordance with the temperature of the outside of the greenhouse to be supplied to the greenhouse, even if a cryogenic phenomenon occurs in winter, it can contribute to maintaining the temperature inside the greenhouse properly. have.

Boiler induction valve 51 is for supplying hot water to be supplied to the facility from the hot water heater 11 to supply to the hot water boiler 50, and operates when the temperature of the outside of the greenhouse is below a predetermined constant temperature (for example, 0 ° C) By doing so, hot water is supplied from the high temperature hot water unit 11 to the hot water boiler 50. Here, the boiler induction valve 51 may be implemented as a 3 way valve that is opened so that hot water is supplied from the high temperature hot water unit 11 to the hot water boiler 50 only when the temperature outside the greenhouse is below a certain temperature. As a result, the boiler induction valve 51 operates in a low-temperature environment in which the outside temperature of the greenhouse is below a predetermined temperature, so that hot water is supplied from the high-temperature hot water unit 11 to the hot water boiler 50 to be heated.

In addition, the boiler induction valve 51 may be implemented as a proportional control valve that can adjust the flow rate of hot water supplied to the hot water boiler 50 from the hot water heater 11 according to the temperature of the outside of the greenhouse. For example, when the temperature of the outside air of the greenhouse is 0 ° C., the boiler induction valve 51 is opened 50% toward the hot water boiler 50, so that the flow rate of 50% of the hot water supplied to the facility from the hot water heater 11 is reduced to When the temperature is -5 ° C, the boiler induction valve 51 is opened 60% toward the hot water boiler, so that a flow rate of 60% of the hot water supplied to the facility from the hot water heater 11 can be supplied to the hot water boiler 50. have. Accordingly, the opening rate of the boiler induction valve 51 is changed according to the outside temperature of the greenhouse, so that the flow rate of the hot water supplied to the hot water boiler 50 is optimized, so that the hot water boiler 50 can be efficiently operated.

The control unit (not shown) controls the operation of each of the above-described components so that the hot water supply system for facility gardening using a heat pump according to the first embodiment of the present invention is implemented. Hereinafter, a method of controlling each component by the control unit will be described.

First, the control unit performs necessary preparations for hot water supply.

The hot water stored in the low temperature hot water unit 12 is heated through the heat pump 30 to be stored in the high temperature hot water unit 11. The high-temperature hot water portion 11 and the low-temperature hot water portion 12 are formed separately by the partition wall 13, so that the hot water is thermally managed and not hot water, thus increasing energy efficiency.

When the hot water to be supplied to the greenhouse is prepared, the control unit monitors a predetermined first environmental condition, such as the temperature condition inside the greenhouse, and controls the high temperature hot water unit pump 40 when the conditions are met to control the high temperature hot water unit 11 Supplies hot water to the greenhouse. The supplied hot water is recovered after raising the temperature inside the greenhouse and is stored in the low temperature hot water unit 12 again.

The control unit of the heat pump 30 when a predetermined second environmental condition is satisfied as a condition in which a larger thermal load is required, for example, when a high amount of heat is required in a short time or when the temperature of the outside of the greenhouse is below a predetermined reference temperature. It is possible to further increase the temperature of the hot water to be stored in the high temperature hot water unit 11 by increasing the number of operations, and to supply hot water supplied to the greenhouse from the high temperature hot water unit 11 to a higher temperature through the hot water boiler 50. have.

As described above, the hot water supply system of the first embodiment of the present invention can increase the energy efficiency of the hot water tank and increase the operational efficiency by actively increasing the number of operation of the heat pump 30 in response to a thermal load. .

2 is a schematic block diagram of a hot water supply system for facility gardening using a heat pump according to a second embodiment of the present invention.

Referring to FIG. 2, the hot water supply system 2 for facility horticulture using a heat pump according to the second embodiment of the present invention includes a hot water tank 10, a low temperature hot water portion pump 20, a heat pump 30, and a high temperature. The hot water portion pump 40, the hot water boiler 50, the heat source tank 60, the high heat source hot water portion pump 70, the low heat source hot water portion pump 80, the heat exchanger 90, and a control unit (not shown) It includes.

The facility horticultural hot water supply system using the heat pump according to the second embodiment of the present invention uses an additional component to heat the hot water hot by utilizing the power plant hot water as a heat source of the hot water supply system according to the first embodiment described above. There is a main characteristic to the composition.

Therefore, the aforementioned hot water tank 10, the low temperature hot water portion pump 20, the high temperature hot water portion pump 40, and the hot water boiler 50 related to the facility gardening hot water supply system 1 according to the first embodiment of the present invention ) Will be omitted for clarity.
Heat pump 30 is composed of a first heat pump 30 and a second heat pump 30, the first heat pump 30 is connected to the hot water tank 10, the second heat pump 30 is It is connected to the heat source tank 60.

The heat source tank 60 connected to the right side of the second heat pump 30, the high heat source hot water portion pump 70, and the low heat source hot water portion pump 80 are for supplying heat from the water heat source to the heat pump 30. , Symmetrical structure with the hot water supply system (1) for facility horticulture connected to the left side of the first heat pump (30), and the structure is also the same, so the symmetrical relationship between the hot water tank (10) and the low / high temperature hot water pump (20) , 40).

When the power plant hot water used as a water source is provided to the smart farm complex through a pipe, the heat of the power plant hot water is transferred to the ultra-high temperature hot water of the heat source tank 60 through the heat exchanger 90, and again the ultra-high temperature hot water is a heat pump It is transferred to the hot water of the hot water tank 10 through (30).

For controlling the flow rate of the hot water, the control unit (not shown) controls the pumps 20, 40, 70, 80, and the control of the heat pump 30 is the same as the first embodiment of the present invention described above, and the specific control Conditions can be changed by user settings.

The embodiments of the present invention will be understood by those of ordinary skill in the art to which various modifications are possible without departing from the technical spirit of the present invention.

Therefore, the protection scope of the present invention is not limited to the embodiments of the present invention, it should be understood that it affects the invention and its equivalents described in the claims.

10: hot water tank 11: hot water section
12: low temperature hot water part 13: partition wall
20: low temperature hot water pump 30; Heat pump
31: condenser flow control valve 32: evaporator flow control valve
40: hot water pump 50: hot water boiler
51: boiler induction valve 60: heat source tank
61: high heat source hot water unit 62: low heat source hot water unit
63: heat source partition wall 70: high heat source hot water pump
80: low heat source hot water pump 90: heat exchanger

Claims (10)

In the hot water supply system for facility gardening using a heat pump,
High temperature hot water unit for storing high temperature hot water for supplying to a facility, low temperature hot water unit for storing low temperature hot water recovered after use in the facility, and hot water having a partition wall partitioning the interior space into the low temperature hot water unit and the high temperature hot water unit Tank;
A low temperature hot water unit pump supplying the low temperature hot water from the low temperature hot water unit to a first heat pump; A first heat pump that heats the hot water using the heat discharged from the condenser and discharges the hot water from the low temperature hot water unit to the high temperature hot water unit when the hot water supplied from the low temperature hot water unit passes through the condenser;
A high temperature hot water unit pump supplying the high temperature hot water from the high temperature hot water unit to the facility;
A hot water boiler that heats the hot hot water supplied to the greenhouse from the hot hot water unit in correspondence with the temperature of the outside of the greenhouse when the temperature of the outside of the greenhouse is below a predetermined temperature; And
When the temperature of the outside of the greenhouse is below a predetermined temperature, further comprising a boiler induction valve to supply the hot water to the hot water boiler from the hot water portion,
The boiler induction valve controls the flow rate of hot water supplied to the hot water boiler from the high temperature hot water unit in response to the temperature of the outside of the greenhouse,
The partition wall is formed in the upper surface direction from the lower surface of the interior space, the facility garden using a heat pump, characterized in that a flow path of a predetermined height or more is formed to allow water to flow between the hot and cold water portion Water supply system.
delete delete According to claim 1,
The first heat pump is a plurality,
When the temperature difference between the entrance and exit of the condenser of the first heat pump exceeds a predetermined range, further comprising a condenser flow rate control valve for supplying hot water so that the number of the first heat pumps operated in response to the temperature difference is adjusted Facility hot water supply system for facility gardening using a heat pump
delete delete According to claim 1,
Further comprising a second heat pump and a heat source tank connected to the first heat pump, the heat source tank is a high heat source hot water unit for storing hot water for supply to the second heat pump, the second heat pump is used It characterized in that it comprises a low-heat source hot water unit for storing the recovered low-temperature hot water, and a heat source partition wall partitioning the interior space into the low-heat source hot water unit and the high-heat source hot water unit,
The second heat pump is supplied to the first heat pump by absorbing heat from the heated hot water using the heat supplied from the water heat source including the power plant warm water supply to the first heat pump facility garden hot water supply using a heat pump system.
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