KR101319080B1 - Geothermal energy- heating and cooling system of hybrid type using extra heating source of available surplus heat - Google Patents

Abstract

The present invention provides a hybrid geothermal heating and cooling system having excess heat as an auxiliary heat source,
An auxiliary heat source device (50) consisting of a circulation pipe (55) having an inlet and an outlet for movement of the heat medium for recovering excess heat and an aero-fin (56) surrounding the pipe surface;
An installation square flange 57 attached to at least one side is provided together with the greenhouse structural columns in place of the existing greenhouse structural truss 23, and the excess heat recovery apparatus 60 which recovers the excess heat of the greenhouse while being a greenhouse structure. );
A heat storage tank 51 installed below the ground in the greenhouse and a circulation pump 52 for circulating hot water and cold water for recovering excess heat;
Three-way valves 53 and 59 connected to and controlled by the heat pump device 30 and the heat storage and heat exchanger device 20 in the greenhouse of the existing geothermal heating and cooling system;
Surplus heat recovery device 60 is a flow fan 28 for the internal air flow in the greenhouse;
A condensation receiving trough 61 for collecting and eliminating condensation water generated by a medium having different temperatures due to the operation of a flow fan;
The hybrid type geothermal heating and cooling system comprising a hybrid type geothermal heating and cooling system having an excess heat used in the greenhouse as an auxiliary heat source, and recovers excess heat in the greenhouse to the existing geothermal or It was invented to increase the performance of the existing geothermal heating and cooling system by using this directly to compensate for the insufficient heat source in the geothermal heating and cooling system using a geothermal source. To this end, the purpose is to implement a hybrid geothermal heating and cooling system that collects heat collected at the upper part of the greenhouse during the day and stores the heat to complement the main heat source when cooling and heating are required in the morning and night.

Description

Geothermal energy-heating and cooling system of hybrid type using extra heating source of available surplus heat}

The present invention relates to a hybrid type geothermal heating and cooling system having surplus heat used in a greenhouse as an auxiliary heat source, and complements a heating and cooling heat source lacking in a heat pump system using a geothermal or ground water source. Invented to complement the performance of the system. To this end, the purpose is to implement a hybrid geothermal heating and cooling system using a secondary heat source to recover the heat collected in the upper part of the greenhouse during the day.

In general, a heat pump is composed of an evaporator, a compressor, a condenser, and an expansion valve, and the circulation medium repeats liquefaction and vaporization to perform heating and cooling through other peripherals connected thereto.

Geothermal heat-cooled heat pump system receives geothermal heat from underground heat exchanger when heating and uses it as heat source of heat pump evaporator, and produces hot heat through condenser to supply hot water or warm air, and during cooling, reverse cycle operation of heat pump The generated arrangements are to be discharged through the underground heat exchanger.

In general, in the case of facility horticulture greenhouses, heating is not required during the cold winter season when the sunlight is sufficient, but rather the excess of the growth management temperature of the crop due to excessive solar energy, which opens the skylight of the facility horticulture greenhouse and lowers the temperature. have.

As shown in the figure, there is a slight difference depending on the crop, but in general, the excess energy emitted by ventilation from the facility horticulture greenhouse is estimated to be about 20% of the heating energy required for the facility horticulture greenhouse from 11 am to 3 pm. It can be regenerated using a recovery device without releasing it and used when heating is required.

<Temperature Management of Common Facility Horticulture Greenhouses>

Ventilation of these horticultural greenhouses results in the loss of carbon dioxide injected for photosynthesis of crops and the energy supplied at night and in the morning for greenhouse warming, and at the cost of releasing the injected carbon dioxide. Causing loss,

In addition, the geothermal heat pump heating system, which the government has been supporting to horticultural farms since 2008, supports 70% of the maximum load. Actual farms often operate beyond the installed capacity load to reduce operating costs. In this case, the operation is continued with a lack of a heat source such as a geothermal source, resulting in exceeding a predetermined operating capacity as time passes.

This excessive operation causes the heat source such as the geothermal source to be depleted and the temperature of the geothermal source continuously decreases, making it difficult to supply a stable heat source, degrading the efficiency of the system, damaging the heat exchanger due to freezing, and failure of the compressor. And

Especially in the case of geothermal, in a horticulture greenhouse where there is a big difference in cooling and heating loads throughout the year, continuous heating operation causes a decrease in the geothermal source temperature, and in case of continuous cooling, a decrease in the efficiency of the heating and cooling system Inoperable condition is caused.

When operating the heat pump system as described above, the inlet temperature of the heat pump low temperature part (evaporation part) is appropriate at about 5 degrees Celsius. In some cases, the system may not function properly or may be damaged due to pipe rupture or compressor damage.

In view of this point, according to Korean Patent No. 10-2012-0061797, it accumulates day-to-day solar heat from the sun to the water reservoir, but it is operated in conjunction with the heat pump system, so the efficiency of the system is high. There is a disadvantage.

In addition, according to Korean Patent No. 10-2006-0008387, the excess heat in the weekly greenhouse is recovered and supplied to the hermetically sealed underground heat exchanger, thereby constructing a temperature compensation circuit of the underground heat exchanger whose temperature is lowered. Since the volatile refrigerant should be injected, there is a problem that the use of volatile refrigerant is difficult when connecting the internal circulation circuit, the heat storage tank and the underground heat exchanger.

The present invention has been made to solve these problems, to propose a new geothermal heating and cooling system having a surplus heat of the greenhouse as an auxiliary heat source in order to increase the efficiency of the existing heat pump system using the geothermal.

In order to solve the above problems, in the embodiment of the present invention, the excess heat of the upper part of the greenhouse exceeding the management temperature is collected and stored in the heat storage device at a time when no greenhouse heating is required due to full sunlight in the greenhouse. It is a hybrid type geothermal heating and cooling system that uses a circulation circuit to be used as an auxiliary heat source. The excess heat recovery device in a greenhouse is integrated with the greenhouse structure even if it acts as a greenhouse structure. An aero-fin was attached to act as a heat recovery device to minimize the cost of installing geothermal facilities.

In addition, the present invention is composed of a system independent of the geothermal heating and cooling system and the surplus heat recovery system not only to inject the refrigerant in the underground heat exchanger, but also to use only the circulating pump power to reduce the power consumption heat pump Compared with a system using a circulating pump, the power consumption is relatively small.

In addition, by attaching additional equipment such as fan-coil units in the greenhouse, it blocks the sunlight for photosynthesis of greenhouse plants, thus minimizing bad effects on crop growth by preventing the sunlight from being blocked. The invention is to provide a hybrid geothermal heating and cooling system for the purpose of effective geothermal use by providing an auxiliary heat source circuit to supplement the insufficient heat source by supplying the regenerated energy directly to the load side inside the greenhouse by inventing a heat recovery device. .

The present invention installs an auxiliary heat source device consisting of a heat storage reservoir by recovering excess heat from the geothermal heating and cooling system using geothermal heat as a heat source and allowing the heat sources to interact with each other to reduce the cooling and heating load of the geothermal heating and cooling system, and to ensure stable and efficient geothermal heat. It has the effect of greatly improving heating and cooling performance and economic efficiency and increasing the durability of the heat pump system.

1 is a conceptual diagram of a conventional geothermal heating and cooling system of the greenhouse.
2 is a schematic diagram of a conventional greenhouse geothermal heating and cooling system.
Figure 3 is a schematic diagram of a geothermal heating and cooling system according to the existing patent 10-2006-0008387.
4 is a configuration diagram of a heat pump that is commonly implemented.
5 is a system and configuration diagram of a geothermal heating and cooling system having an excess of greenhouse heat applied as an embodiment according to the present invention as an auxiliary heat source.
6 is a system and configuration diagram of the auxiliary heat source device using the greenhouse surplus heat applied to an embodiment according to the present invention.
7 is a cross-sectional view and a plan view of an apparatus for recovering excess heat of FIG. 5 to which an embodiment of the present invention is applied.
Figure 8 is a perspective view of the excess heat recovery pipe of Figure 5 applied one embodiment according to the present invention

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

Facility horticulture A circulation pump is provided for supplying a heat medium from a heat storage tank for recovering and storing heat in the upper part of the greenhouse, and the heat medium supplied from the circulation pump is supplied to a greenhouse structure (heat recovery device) designed to facilitate heat exchange in the upper part of the greenhouse. It absorbs heat through heat exchange. And the heat medium which absorbed heat is returned to a heat storage tank through a return pipe.

2 is a system diagram of a heat pump air-conditioning system using geothermal heat according to the prior art, FIG. 4 is a configuration diagram of a heat pump system, and FIG. 5 is a schematic diagram of a system to which an excess heat recovery apparatus 60 according to the present invention is applied.

The main configuration of this embodiment will be described first with reference to FIG.

A conventional geothermal heat source heat pump air-conditioning apparatus shown in FIG. 2 is installed on the compressor 33 and the greenhouse 70 side which compresses the refrigerant gas of low temperature and low pressure into high temperature and high pressure so as to cool or heat the room by the refrigerant. It is installed on the load side heat exchanger 34 and the ground heat exchanger 10 side, and is installed between the heat source side heat exchanger 32 and the load side heat exchanger 34 configured to exchange heat of the refrigerant with heat obtained in the ground. And an expansion valve 31 for throttling the refrigerant at low pressure and a four-way valve adjacent to the compressor 33 for changing the circulation path of the refrigerant.

At this time, the heat source side heat exchanger (32) is connected to the underground heat exchanger (10) buried in the ground to form a circulation path of the water refrigerant, and the heat exchange with the refrigerant by the water refrigerant circulated by the circulation pump 15 It can be. That is, the water refrigerant heat-exchanged with the refrigerant by the load-side heat exchanger 32 is transferred to the underground heat exchanger 10, heat-exchanged by the heat of the ground, and then transferred to the load-side heat exchanger 32 again. Recently, the underground heat exchanger tube 12 may be configured to exchange heat from seawater or a lake, or may be configured to directly circulate groundwater.

First, referring to the circulation path of the refrigerant during the cooling operation, the four-way valve adjacent to the compressor 33 is controlled to transfer the refrigerant gas compressed by the compressor 33 to the heat source side heat exchanger 32. Then, the compressed refrigerant gas is condensed by heat exchange with geothermal heat in the heat source side heat exchanger (32), and the condensed refrigerant is expanded (throed) by the expansion valve (31) to convert into a low temperature refrigerant and then the load side heat exchanger (34). Transfer to. Then, the load-side heat exchanger 34 is to cool the room in the evaporation process by evaporating the low-temperature refrigerant, at this time is converted into the medium-temperature refrigerant gas by the heat of the room obtained in the cooling process adjacent to the compressor 33 It is transferred to the compressor 33 via the four-way valve.

Next, since the four-way valve adjacent to the compressor 33 is controlled in the heating operation, and the four-way valve is controlled in the reverse order to the circulation path in the cooling operation, the refrigerant is the compressor 33. The load side heat exchanger 34, the expansion valve 31 and the heat source side heat exchanger 32 are circulated in this order. At this time, the load side heat exchanger 34 serves as a condenser to heat the room with heat in the condensation process, and the heat source side heat exchanger 32 serves as an evaporator to absorb heat from geothermal heat during the evaporation process. .

The heat pump air-conditioning system using the geothermal heat according to the prior art configured as described above heats the refrigerant in the outdoor heat exchanger 32 with the geothermal heat, not the queue, thus saving the power required to operate the heat pump system than using the queue. In addition, the heating as well as the cooling has the advantage that can be made as a heat pump system.

In addition, in the case of the existing greenhouse 70, as shown in FIG. 2, it is common to use the boiler 100 and the heating pipe 101 using high temperature water as auxiliary heating of the geothermal system.

When described in detail by the accompanying Figure 5 is an embodiment according to the present invention.

The present invention is a surplus consisting of a circulation pipe 55 and an aero fin 56 in the truss structure of the heat storage tank 51 and the venlo-type greenhouse as an auxiliary heat source device 50 in the heat pump air-conditioning system using geothermal heat according to the prior art. It is characterized by consisting of a heat recovery device 60, the circulation pump 52, three-way control valve (53, 59).

The excess heat recovery device 60 of the auxiliary heat source device 50 is composed of a circulating pipe 55 for recovering the excess heat of the greenhouse and an aerofin 56 surrounding the circulating pipe and a mounting bracket 57. ,

The operating system is introduced into the excess heat recovery device 60 through the low temperature water pipe 54 to the excess heat recovery device 60 to recover the excess heat located in the upper greenhouse, and circulates the excess heat recovery device 60 to recover the excess heat. The hot water recovered and heat-exchanged is stored in the heat storage tank 51 buried beneath the greenhouse surface through the hot water pipe 59.

When the heat source water accumulated in the heat storage tank 51 reaches a constant temperature, the heat source water is transferred through the circulation pump 52. At this time, the flow path is connected to the load side supply pipe 26 in the greenhouse through the control of the three-way valve 53. Supply the heat source water in the indoor heat exchanger (25), and return after cooling or heating the greenhouse through the indoor heat exchanger, wherein the three-way valve (29, 59) is controlled to return the heat medium to the heat storage tank (51). .

The auxiliary heat source device 50 is in contact with the aerofin 56 and the circulating pipe 55 of the excess heat recovery device 60 to heat exchange by the internal air flow by the flow fan 28 in the greenhouse to recover the excess heat. do.

At this time, the dew condensation water is generated by the contact of the medium having different temperatures, and condensation water treatment trough 61 as shown in FIGS. 7 and 8 at the lower end of the excess heat recovery device 60 for treating the condensation water in order to prevent damage of crops. Install it.

In addition, the excess heat recovery device 60 of the auxiliary heat source device 50 is connected to the greenhouse structural columns in place of the existing greenhouse structural truss 23 to exchange heat exchange and excess heat recovery device 60 as well as the greenhouse structural truss 23. It is an invention of a hybrid type air-conditioning system utilizing the greenhouse surplus heat as an auxiliary heat source, characterized in that it is installed to serve as a combined role.

30: heat pump
31 expansion valve 32 heat source side heat exchanger
33 compressor 34 load side heat exchanger
50: auxiliary heat source device
56: excess heat recovery device 23: truss for greenhouse structure
54: Aero-Fin 55: heat exchange pipe
51: heat storage tank

Claims (4)

In a hybrid geothermal heating and cooling system having excess heat as an auxiliary heat source, an auxiliary heat consisting of a circulation pipe 55 having an inlet and an outlet for the movement of the heat medium recovering the excess heat, and an aero-pin 56 surrounding the pipe surface. Heat source device 50;
An installation square flange 57 attached to at least one side is provided together with the greenhouse structural columns in place of the existing greenhouse structural truss 23, and the excess heat recovery apparatus 60 which recovers the excess heat of the greenhouse while being a greenhouse structure. );
A heat storage tank 51 installed below the ground in the greenhouse and a circulation pump 52 for circulating hot water and cold water for recovering excess heat;
Three-way valves 53 and 59 connected to and controlled by the heat pump device 30 and the heat storage and heat exchanger device 20 in the greenhouse of the existing geothermal heating and cooling system;
Surplus heat recovery device 60 is a flow fan 28 for the internal air flow in the greenhouse;
A condensation receiving trough 61 for collecting and eliminating condensation water generated by a medium having different temperatures due to the operation of a flow fan;
Hybrid geothermal heating and cooling system having a surplus heat as an auxiliary heat source, characterized in that comprises a. delete delete delete

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