KR102252193B1 - Air condition system for cooling and heating for cattle shed - Google Patents

Abstract

The present invention relates to a heating and cooling air conditioning system for a livestock shed, the system comprising a heat pump and a brine circulation device for transferring heat or cold air generated by the heat pump to the inside of the livestock shed by heat exchange. A heat exchanger applied to the heat pump comprises: two headpipes installed at regular intervals; a plurality of flat tubes installed to be vertically spaced apart at regular intervals between the two headpipes; one or more diaphragms for dividing the inner space of the headpipes into at least two independent spaces; an upper refrigerant pipe installed in communication with an upper section of the headpipes partitioned by the diaphragms; and a lower refrigerant pipe installed in communication with the lower section of the headpipes partitioned by the diaphragms. The heat exchanger further comprises an oil return pipe for recovering liquid oil remaining at the lower end of the headpipes through the upper refrigerant pipe.

Description

Air conditioning system for livestock use {AIR CONDITION SYSTEM FOR COOLING AND HEATING FOR CATTLE SHED}

The present invention relates to a cooling/heating and air conditioning system, and more particularly, by using a brine circulation device including a heat pump and a plurality of brine cooling and heating units, it is possible to equally supply cold and heat to a large-area indoor space such as a livestock shed and a gymnasium. It relates to a heating and cooling air conditioning system for livestock that can minimize the loss.

Due to the generalization of high-density and dense breeding in raising livestock including pigs and chickens, the pattern of disease outbreak is complicated, and the mortality rate increases due to high temperature stress in the summer, increasing difficulties in managing the breeding environment. Accordingly, there is a need for a heating and cooling air conditioning system for livestock to keep the indoor temperature of the livestock in an appropriate state during hot and cold seasons while responding to the climate environment that changes rapidly depending on the season and day and night.

The cooling/heating air conditioning system maintains the indoor temperature at an appropriate temperature, and representative examples include a cooling system and a heating system. The cooling system includes a compressor that compresses the refrigerant at high temperature and high pressure, a condenser for condensing the compressed refrigerant by exchanging heat with outdoor air, an expansion valve for decompressing the refrigerant from the condenser, and heat exchange of the reduced refrigerant with indoor air. It consists of an evaporator to evaporate. In addition, the heating system converts cold air in the room into hot air by burning fossil fuels or blowing heat generated by using electricity into the room.

11 is a view showing an example of a livestock cooling and heating air conditioner (No. 10-1892219) according to the prior art, the conventional livestock cooling and heating air conditioner 10, the housing 100; A heat exchange unit (200) installed in the receiving space of the housing to cool or heat the air to a set temperature while exchanging heat with the refrigerant or heat medium from the air introduced through the inlet; A blowing unit (300) for discharging the air heat-exchanged by the heat exchange unit to the outlet while forcibly blowing the air; A cooling unit 400 for circulating a low-temperature refrigerant to the heat exchange unit; A heating unit 500 for circulating the high-temperature fruit through the heat exchange unit; And a filter unit 600 provided in the heat exchange unit to filter foreign substances contained in air.

According to such a conventional cooling/heating air conditioner for livestock, because external air is introduced and cooled or heated while heat-exchanging with a heat exchange unit, air at a set temperature can be maintained inside the livestock house, and air is filtered by the filtering unit. It has an antibacterial effect. However, in the prior art, since the heat exchange unit 200 and the heating unit 500 are configured separately, the structure is complicated, and the cooling and heat generated by the heat exchange unit 200 and the heating unit 500 are transmitted through the blowing unit 300. Because it is a structure that blows air into the house by using it, there was a limit in distributing the cold and heat evenly into the inside of the house with a large area.

In consideration of this point, recently, a heating/cooling air conditioning system for livestock has been developed using a heat pump. The heat pump can selectively perform cooling and heating by adding a four-way valve to the configuration of the existing cooling system and performing reverse cycle operation by switching the moving direction of the refrigerant if necessary.

For example, a conventional livestock house cooling and heating and hot and cold drinking water supply parallel system (No. 10-1790015) includes: an air-to-water heat pump 100 for producing hot and cold water for cooling and heating and hot and cold drinking water for supplying to the livestock house; A heat exchanger 200 connected to the air-to-water heat pump 100 to make hot and cold drinking water through heat transfer from the cold and hot water produced by the air-to-water heat pump 100; A drinking water tank 300 connected to the heat exchanger 200 and storing the cold and hot drinking water; A cold and hot drinking water supply pipe 400 connected to the drinking water tank 300 and supplying cold and hot drinking water to the inside of the house; A heat storage tank 500 connected to the air-to-water heat pump 100 and storing cold and hot water produced by the air-to-water heat pump 100; And a cold and hot air duct 600 disposed in the housing and supplying hot and cold air to the inside of the housing using cold and hot water stored in the heat storage tank 500.

That is, a method of supplying and distributing the hot and cold air generated by one heat pump to the interior of the house using the hot and cold air duct 600 is used. However, since the duct is to pressurize hot and cold air along a pipe structure having a relatively large diameter, not only a lot of energy is consumed for air pressure, but the larger the indoor area, the more complicated the structure of the duct, so there is a problem that the installation cost increases. .

Meanwhile, the heat pump according to the prior art supplies the refrigerant discharged from the refrigerant compressor to the condenser and the evaporator according to the selection of the switching valve. In particular, when supplying the high-pressure refrigerant to the evaporator, the oil contained in the refrigerant is rapidly liquefied and Since it cannot move to the top and remains on the floor, the oil level inside the refrigerant compressor is lowered, resulting in damage due to poor lubrication when the compressor is operated, or there is a problem in that energy efficiency and stability are deteriorated.

In addition, the cooling and heating system for livestock according to the prior art relies on ventilation and fog cooling to alleviate high-temperature damage in summer, supplying groundwater to lower the temperature of drinking water, or some farms directly putting ice into the drinking water tank, but the effect Is known to be limited. Accordingly, in order to improve the productivity and management of livestock farms, there is a demand for a heating and cooling air conditioning system for livestock in consideration of economic performance such as energy cost and specifications characteristics of livestock species.

Republic of Korea Patent Registration No. 10-1892219 (Registration date: 2018.08.21.) Korean patent registration number 10-1790015 (Registration date: 2017.10.19)

The present invention is to solve the problems related to the prior art, and the main object of the present invention is to evenly supply cold and heat generated by a heat pump to a large-area indoor space by using a brine circulation device and minimize energy loss. It is to provide a heating and cooling air conditioning system for livestock that can be used.

In addition, the present invention is provided with a recovery means for recovering the liquid oil remaining in the heat exchanger, the oil level inside the refrigerant compressor is lowered, and thereby the refrigerant compressor is damaged or the energy efficiency and stability are prevented from falling. It is to provide air conditioning and heating air conditioning systems.

In addition, the present invention can be provided by appropriately controlling the temperature of drinking water provided to livestock according to the temperature, and when cooling and heating is not required, the productivity of livestock farms is controlled by controlling the indoor temperature using geothermal heat or spraying water on the roof. It is to provide a cooling, heating and air conditioning system for livestock that can improve performance and improve management.

And the technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned are clearly to those of ordinary skill in the technical field to which the present invention belongs from the following description. It will be understandable.

As a means for solving the problems of the prior art, the cooling/heating air conditioning system for livestock according to the present invention provides heat exchange between a heat pump that is installed outside the livestock and generates cool air and heat, and cool air or heat generated by the heat pump. In the cooling, heating and air conditioning system for livestock comprising a brine circulation device that is transmitted to the inside of the livestock house,

The heat pump includes a refrigerant compressor for compressing a refrigerant, an air-cooled refrigerant heat exchanger for performing heat exchange between the refrigerant and air, a brine refrigerant heat exchanger for performing heat exchange between the refrigerant and brine, and a refrigerant compressed by the refrigerant compressor. A switching valve for selecting to flow to the air-cooled refrigerant heat exchanger or the brine refrigerant heat exchanger, and an expansion valve for decompressing the refrigerant flowing to the brine refrigerant heat exchanger or the air-cooled refrigerant heat exchanger;

The brine circulation device includes a plurality of air-cooled brine heat exchangers installed at regular intervals in the housing and performing heat exchange between air and brine, and a blower fan for blowing air that has passed through the air-cooled brine heat exchanger into the housing. A brine cooling and heating unit of, a brine pipe connected between the plurality of air-cooled brine heat exchangers and the brine refrigerant heat exchanger provided in the heat pump to circulate brine, and a circulation pump installed on the brine pipe to circulate brine. Includes;

The brine refrigerant heat exchanger includes two head pipes installed at a predetermined interval, a plurality of flat tubes installed vertically at a predetermined interval between the two head pipes, and at least two independent spaces of the head pipe. At least one partition plate divided into space, an upper refrigerant pipe installed in communication with the upper region of the head pipe partitioned by the partition plate, and a lower side installed in communication with the lower region of the head pipe partitioned by the partition plate Including a refrigerant pipe, characterized in that it further comprises an oil return pipe for recovering the liquid oil remaining at the lower end of the head pipe through the upper refrigerant pipe.

In the present invention, an intercooler fin is installed inside the flat tube to form a plurality of passages in the longitudinal direction of the flat tube, and between the flat tubes adjacent up and down, in a direction orthogonal to the longitudinal direction of the flat tube. Outer cooler fins forming a number of passages are installed.

The oil return pipe is installed inside the head pipe, its lower end is close to the bottom of the head pipe, its upper end penetrates the head pipe and protrudes to the outside, and the upper end thereof is inside the upper refrigerant pipe. It communicates with.

The upper refrigerant pipe is further provided with a venturi pipe through which the upper end of the oil return pipe passes.

In the air-cooled brine heat exchanger of the brine cooling and heating unit, the plurality of flat tubes are installed inclined at a predetermined angle.

A drinking water refrigerant heat exchanger in which heat exchange is performed between the drinking water supplied from the drinking water tank and the refrigerant is further provided inside the heat pump.

A geothermal brine heat exchanger is connected to the brine pipe, which is buried underground and performs heat exchange between the geothermal heat and the brine.

A drinking water distribution line for supplying drinking water to livestock is connected to the drinking water tank, and a sprinkling water supply line connected to the roof of the barn is connected to a direct water supply line connected to the drinking water tank.

The housing of the heat pump is divided into an upper section and a lower section centered on a horizontal plate in the middle, and the two air-cooled refrigerant heat exchangers are installed inclined at a predetermined angle in the upper section.

The diaphragms installed inside the two headpipes are installed vertically and offset by a predetermined distance so that the refrigerant flows smoothly between the two headpipes.

According to the present invention, since the cold and heat generated by the heat pump is supplied and distributed to a large-area house using a brine circulation device that circulates brine, which is a liquid heat transfer material, energy loss can be minimized and installation costs can be reduced. In addition, it has the effect of evenly supplying cold and heat.

In addition, the present invention can supply cold and heat equally by arranging the brine cooling and heating units having a simple structure and excellent durability at regular intervals inside the house, and maintaining a pleasant livestock environment with the cooling and dehumidification functions of the brine cooling and heating units. It works.

In addition, in the present invention, an oil return pipe for recovering liquid oil is installed inside the head pipe of the heat exchanger, so that the oil remaining at the lower end of the heat exchanger is automatically recovered to the refrigerant compressor, so that the oil inside the refrigerant compressor is damaged or damaged. There is an effect that can prevent the loss of energy efficiency and stability.

In addition, the present invention can be provided by appropriately controlling the temperature of drinking water provided to livestock according to the temperature, and when cooling and heating is not required, the productivity of livestock farms is controlled by controlling the indoor temperature using geothermal heat or spraying water on the roof. There is an effect that can improve management and improve management.

1 is a block diagram showing an example of a cooling, heating and air conditioning system for livestock according to the present invention,
2 is a side view showing an example of a heat pump according to the present invention,
3 is a perspective view showing an example of a brine cooling and heating unit according to the present invention,
4 is a perspective view showing an example of a heat exchanger according to the present invention,
5 is an exploded view showing the structure of a head pipe according to the present invention,
6 is an exploded perspective view showing the structure of a flat tube according to the present invention,
7 and 8 are schematic cross-sectional views showing the operation of the heat exchanger according to the present invention,
9 is a block diagram showing another example of a cooling, heating and air conditioning system for livestock according to the present invention,
10 is a block diagram showing another example of a cooling, heating and air conditioning system for livestock according to the present invention,
11 is a cross-sectional view showing a heating and cooling air conditioning system for livestock according to the prior art.

Hereinafter, the advantages and features of the present invention, and a method of achieving the same will be described through embodiments to be described in detail later with reference to the accompanying drawings. However, if it is determined that a detailed description of a known technology or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, the terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators, so the definitions are defined throughout the present specification for describing the air conditioning system for livestock use according to the present invention. It will have to be made based on the contents of

First, FIG. 1 is a block diagram showing an example of a cooling/heating air conditioning system 1 for livestock according to the present invention. As shown, the cooling and heating air conditioning system 1 for livestock according to the present invention is for controlling the temperature inside the large-area confinement house 2 such as a pig house or cage by selectively performing cooling and heating according to the temperature. And a heat pump 100 for generating cold air or hot air, and a brine circulation device 200 for evenly transferring the cold air or hot air generated by the heat pump 100 to the inside of the confinement house 2.

The heat pump 100, which is installed outside the confinement house 2, is largely a housing 110 and a refrigerant compressor 120, an air-cooled refrigerant heat exchanger (130:130a, 130b), an expansion valve (140), It includes a brine refrigerant heat exchanger 150 and a switching valve 160.

In addition, the brine circulation device 200 connects between the heat pump 100 and a plurality of air-cooled brine heat exchangers 220 installed inside the confinement house 2 to provide cold air generated by the heat pump 100 or A plurality of brine cooling and heating units 210 installed in the housing 2 at regular intervals are used to transfer heat to the inside of the housing 2 after heat exchange using brine.

The brine cooling and heating unit 210 includes a plurality of air-cooled brine heat exchangers 220 connected to the brine refrigerant heat exchanger 150 provided in the heat pump 100, and a front side of the air-cooled brine heat exchanger 220 It is installed in the air-cooled brine heat exchanger 220 and includes a plurality of blowing fans 230 for blowing air into the interior of the confinement house (2).

In addition, the brine circulation device 200 further includes a brine pipe 240. The brine pipe 240 is installed between a plurality of air-cooled brine heat exchangers 220 and the brine refrigerant heat exchanger 150 to circulate brine, and a circulation pump 260 and a storage tank on the brine pipe 240 250 is further installed. The circulation pump 260 provides power to circulate brine along the brine pipe 240, and the storage tank 250 supplements insufficient brine. In addition, a plurality of control valves for controlling the flow of brine are provided on the brine pipe 240. In this case, the plurality of control valves may be automatically opened and closed by control of a controller (not shown).

As described above, the cooling/heating air conditioning system 1 for livestock according to the present invention includes a heat pump 100 capable of cooling and heating all installed on the outside of the house 2, and an air-cooled brine heat exchanger in the inside of the house 2 A plurality of brine cooling and heating units 210 including 220 and a blowing fan 230 are installed, and the brine refrigerant heat exchanger 150 of the heat pump 100 and the air-cooled brine heat exchanger of the brine cooling and heating unit 210 ( 220) By connecting between the brine pipes 240, the cold air or heat generated from the heat pump 100 is absorbed by using brine, and then transferred to the interior of the confinement house 2, and then exchanged with the indoor air. (2) It is possible to maintain the internal temperature within an appropriate range.

Hereinafter, the structures of the heat pump 100 and the brine circulation device 200 according to the present invention will be described in more detail. 2 is a side view showing an example of a heat pump 100 according to the present invention, and FIG. 3 is a perspective view showing an example of a brine cooling and heating unit 210 according to the present invention.

As shown, the heat pump 100 of the present invention includes one housing 110. The housing 110 is a housing having a predetermined size forming the outer shape of the heat pump 100 and provides a space in which components to be described later are installed.

1 and 2, the housing 110 is divided into an upper space 110a and a lower space 110b with a center horizontal plate 113 at the center. In addition, inlets 111a and 111b through which outside air is introduced are formed on both sides of the upper space 110a, and an outlet 112 for discharging the air of the upper space 110a to the outside is formed in the middle of the top. In addition, a blowing fan 115 for discharging the air in the upper space 110a to the outside is installed at the outlet 112.

In addition, two air-cooled refrigerant heat exchangers 130a and 130b are installed adjacent to the inlets 111a and 111b in the upper space 110a. Here, the'air-cooled refrigerant heat exchanger' is used to exchange heat without mixing the refrigerant and air with a temperature difference.The refrigerant flows along the tube and the air passes through the outside of the tube, thereby heat exchange between the refrigerant and air. . In addition, the two air-cooled refrigerant heat exchangers 130a and 130b may be connected in series or in parallel.

Preferably, the two air-cooled refrigerant heat exchangers 130a and 130b may be installed in an inclined manner. For example, the two air-cooled refrigerant heat exchangers 130a and 130b may be inclined to form a'V' shape. Accordingly, the outside air introduced into the inlets 111a and 111b may be smoothly discharged through the outlet 112 through the two air-cooled refrigerant heat exchangers 130a and 130b.

In addition, a refrigerant compressor 120, an expansion valve 140, and a brine refrigerant heat exchanger 150 are installed in the lower space 110b. They form a closed circulation circuit through the refrigerant pipe 170 together with the air-cooled refrigerant heat exchangers 130a and 130b to constitute a cooling cycle. Here, the'brine refrigerant heat exchanger' is used to exchange heat without mixing the refrigerant and brine having a temperature difference, and the refrigerant and the brine flow along a tube disposed adjacent to each other to achieve heat exchange between the refrigerant and brine. . Here,'brine' is a type of heat transfer medium, and is composed of aqueous solutions such as calcium chloride, sodium chloride, and magnesium chloride. Such brine can absorb and transmit cold or heat without changing its state. In particular, since brine is always in a liquid state, its volume is small and stable, reducing facility costs and preventing energy loss.

The refrigerant compressor 120 compresses the refrigerant at high temperature and high pressure. The switching valve (four-way valve) may supply the refrigerant compressed in the refrigerant compressor 120 to the air-cooled refrigerant heat exchanger 130a, 130b or the brine refrigerant heat exchanger 150 according to a selection of a control unit (not shown). . In addition, the expansion valve 140 decompresses the refrigerant discharged from the air-cooled refrigerant heat exchanger 130 and supplies it to the refrigerant tube of the brine refrigerant heat exchanger 150. Other configurations of the heat pump 100 are well known in the art, so a detailed description thereof will be omitted.

Therefore, the heat pump 100 of the present invention, when supplying the refrigerant compressed by the refrigerant compressor 120 to the air-cooled refrigerant heat exchanger 130 according to the selection of the switching valve 160, the brine refrigerant heat exchanger ( When the refrigerant compressed by the refrigerant compressor 120 is supplied to the brine refrigerant heat exchanger 150, the brine refrigerant heat exchanger 150 generates heat. It can be operated in a heating mode.

Subsequently, the brine circulation device 200 includes a plurality of brine cooling and heating units 210 installed in the housing 2. As shown in FIG. 3, the brine cooling and heating unit 210 includes a case 211 of a certain size, an air-cooled brine heat exchanger 220 installed at the rear portion of the case 211, and the air-cooled brine heat exchanger 220 ) And includes one blowing fan 223 installed on the front side. Here, the'air-cooled brine heat exchanger' is used to exchange heat without mixing brine and air with a temperature difference.Brine flows along the tube and air passes through the outside of the tube, allowing heat exchange between brine and air. Done. In addition, the blowing fan 223 blows the air cooled or heated while passing through the air-cooled brine heat exchanger 220 to the inside of the confinement house 20.

In addition, as shown in FIG. 1, the brine circulation device 200 connects between the plurality of air-cooled brine heat exchangers 220 and the brine refrigerant heat exchanger 150 of the heat pump 100 to circulate brine. It further includes a brine pipe 240 to enable. The brine pipe 240 includes a brine supply line 240a supplying brine discharged from the brine refrigerant heat exchanger 150 to the plurality of air-cooled brine heat exchangers 220, and the plurality of air-cooled brine heat exchangers 220 ) Discharged from the brine is made of a brine conveying line (240b) conveyed to the brine refrigerant heat exchanger (150).

Therefore, the cooling/heating air conditioning system 1 for livestock of the present invention uses the brine circulation device 200 to transfer cold air or heat generated from the heat pump 100 to a plurality of brine cooling and heating units installed inside the livestock house 2 By transferring to 210, the temperature inside the confinement house 2 can be uniformly and uniformly controlled.

For example, when the cooling mode is selected, the refrigerant compressed by the refrigerant compressor 120 is supplied to the air-cooled refrigerant heat exchanger (130a) (130b) and flows through the tube from the air-cooled refrigerant heat exchanger (130). Heat exchange is made between the refrigerant of the refrigerant and external air, so that the refrigerant loses heat and condenses. The condensed refrigerant is depressurized through the expansion valve 140, and the low-temperature, low-pressure refrigerant flows along the refrigerant tube 150a of the brine refrigerant heat exchanger 150.

At this time, the high-temperature brine circulating in the brine circulation device 200 flows inside the brine tube 150b installed close to the refrigerant tube 150a. Accordingly, in the brine refrigerant heat exchanger 150, heat exchange is performed between the low-temperature refrigerant and the high-temperature brine, so that the refrigerant absorbs heat and evaporates, and the brine is cooled by absorbing cold air. In addition, the evaporated refrigerant is discharged to the refrigerant compressor 120 and compressed again, and the cooled brine is supplied to the plurality of brine cooling and heating units 210 and exchanged with indoor air to cool the interior of the house 2 .

Conversely, when the heating mode is selected, the refrigerant compressed by the refrigerant compressor 120 is directly supplied to the refrigerant tube 150a of the brine refrigerant heat exchanger 150. At this time, the brine circulating in the brine circulation device 200 is supplied to the inside of the brine tube 150b installed close to the refrigerant tube 150a.

Accordingly, in the brine refrigerant heat exchanger 150, heat exchange is performed between the high-temperature refrigerant and the relatively low-temperature brine, so that the refrigerant is deprived of heat and condensed, and the brine is heated by absorbing heat. The condensed refrigerant is depressurized through the expansion valve 140 and then supplied to the air-cooled refrigerant heat exchanger 130. In addition, the heated brine is supplied to the plurality of brine cooling and heating units 210 and heat-exchanged with indoor air to heat the inside of the house 2.

As described above, the cooling/heating air conditioning system 1 for livestock according to the present invention is capable of cooling and heating using one heat pump 100, and transfers heat to the interior of the livestock house 2 using liquid brine. Therefore, the structure of the pipe is simple, energy loss can be minimized, and installation cost can be reduced. In addition, by blowing the heat-exchanged indoor air using the blower fan 230 provided in the brine heating and cooling unit 210, the internal temperature of the confinement house 2 can be quickly and uniformly adjusted.

Hereinafter, a preferred embodiment of a heat exchange device applied to the air conditioning system 1 for livestock use according to the present invention will be described.

First, FIG. 4 is a perspective view showing a preferred embodiment of a heat exchanger according to the present invention, FIG. 5 is an exploded view showing the structure of a head pipe according to the present invention, and FIG. 6 is an exploded view showing the structure of a flat tube according to the present invention. It is a perspective view, and FIGS. 7 and 8 are schematic cross-sectional views showing the operation of the heat exchanger according to the present invention.

As shown, a heat exchanger 600 applied to an air-cooled refrigerant heat exchanger 130, a brine refrigerant heat exchanger 150, and an air-cooled brine heat exchanger 220 used in the air-cooling and heating air conditioning system 1 of the present invention. It includes two headpipes 610a and 610b, and a plurality of flat tubes 620 installed between the two headpipes 610.

The head pipe 610 is a circular or rectangular vertical pipe, and forms an inner space 613 having a certain size therein. The upper and lower ends of the head pipe 610 are sealed, the inner surface is open, and the vertical plate 617 to which the ends of the plurality of flat tubes 620 are fixed is integrally coupled to the opened inner surface.

In addition, one or more diaphragms 615a and 615b are installed inside the head pipe 610. The partition wall 615 closes the inner space of the head pipe 610 to block the movement of the refrigerant in the vertical direction. The diaphragm 615 is installed vertically and spaced at a predetermined interval, and separates the inner space of the head pipe 610 into two or more independent spaces. For example, the partition plate 615 may divide the inner space 613 of the head pipe 610 into an upper section 163a, a lower section 613b, and an intermediate section 613c.

In addition, a refrigerant pipe for injecting a refrigerant into the head pipe 610 or discharging the refrigerant inside the head pipe 610 to the outside is installed on one side of the head pipe 610, the head pipe 610 An upper refrigerant pipe 650 communicating with the upper region 613a divided by the partition plate 615 is installed at the upper end of the head pipe 610, and the lower region divided by the partition plate 615 at the lower end of the head pipe 610 A lower refrigerant pipe 660 in communication with the 613b is installed.

Next, as shown in FIG. 6, the flat tube 620 forms a flat inner space 622 therein, and a refrigerant (or brine) flows through the inner space 622. Preferably, the flat tube 620 is installed horizontally between the two head pipes 610 and spaced at a predetermined interval in the vertical direction.

In addition, cooler fins (cooling fins) are installed inside and outside the flat tube 620. That is, the intercooler fin 630 is installed inside the flat tube 620, and the outer cooler fin 640 is installed outside.

Preferably, the flat tube 620 is made by combining the upper plate (620a) and the lower plate (620b), the upper plate (620a) has a certain space formed on the lower surface, and the lower plate (620b) is concave in the upper surface. A space is formed. In addition, flange portions are formed corresponding to the left and right sides of the upper plate member 620a and the lower plate member 620b. Therefore, when the upper plate member 620a and the lower plate member 620b are stacked up and down, when blazing with the intercooler fin 630 interposed between the upper plate member 620a and the lower plate member 620b, the flat plate The intercooler fin 630 is integrally installed inside the tube 620.

The intercooler fins 630 are formed by bending a plate of a predetermined length in a predetermined shape, and form a plurality of passages in the longitudinal direction of the flat tube 620 to free the flow of refrigerant while maximizing its surface area. And'Brazing' is a bonding method in which the molten filler material is placed at the junction of the base material that needs to be bonded and heated at 450°C or higher so that the molten filler material permeates the junction of the base material and joins the junction. It has the advantage that it is possible to bond dissimilar metals with different properties, has strong bonding strength, and has excellent airtightness and corrosion resistance.

In addition, outer cooler fins 640 are installed on the flat upper and lower surfaces of the flat tube 620. For example, the outer cooler fins on the flat upper and lower surfaces of the flat tube 620 by brazing with an outer cooler pin 640 interposed between the flat tubes 620 that are installed at regular intervals apart from each other up and down ( 640) can be installed integrally. The outer cooler fin 640 is a louvered fin that is bent up and down, and forms a passage through which air passes in a direction orthogonal to the longitudinal direction of the flat tube 620. Therefore, when the refrigerant flows along the passage of the intercooler fin 640 installed in the inner space of the flat tube 620, the air passes through the passage of the outer cooler 640 and heat exchange between the refrigerant and air is made. In this way, the intercooler fins 630 and the outer cooler fins 640 maximize the contact area between the refrigerant and air to increase heat exchange efficiency.

Meanwhile, FIGS. 7 and 8 are schematic cross-sectional views showing the operation of the heat exchanger according to the present invention. As shown, when the cooling mode and the heating mode are selectively performed according to the selection of the switching valve 160, the refrigerant flows in the heat exchanger 600 are in opposite directions to each other.

That is, in the cooling mode, as shown in FIG. 7, the low-temperature, low-pressure refrigerant reduced by the expansion valve 140 passes through the upper refrigerant pipe 650 of the first head pipe 610a. ) Is supplied to the upper section 613a). And the refrigerant in the upper section 613a exchanges heat with outside air or brine while moving to the upper section 613a of the second head pipe 610b through a plurality of flat tubes 620 connected to the upper section 613a.

At this time, since the partition plate 615b installed inside the second head pipe 610b is installed below a predetermined length than the partition plate 615a installed inside the first head pipe 610a, the second head pipe 610b The refrigerant in the upper section 613a of the upper section 613a exchanges heat with outside air or brine while moving to the middle section 613c of the first headpipe 610a through a plurality of flat tubes 620 connected to the lower end of the upper section 613a. do.

In addition, the refrigerant in the middle region 613c of the first headpipe 610a is provided with a lower diaphragm 615c installed inside the first headpipe 610a. Since it is installed below a certain length than the partition plate 615b, while moving to the lower region 613b of the second headpipe 610b through a plurality of flat tubes 620 connected to the lower end of the intermediate region 613c, outside air or Heat exchange with brine.

And the refrigerant in the lower region 613b of the second headpipe 610b is one or a plurality of flat tubes connected between the lower end of the lower region 613b and the lower region 613b of the first headpipe 610a. While moving to the lower region 612b of the first head pipe 610a through 620, heat exchange with outside air or brine is performed. Finally, the refrigerant evaporated while descending to the lower end of the heat exchanger 600 is discharged to the refrigerant compressor 120 through a lower refrigerant pipe 660 connected to the lower region 612b.

In contrast, in the heating mode, as shown in FIG. 8, the high-temperature and high-pressure refrigerant compressed by the refrigerant compressor 120 passes through the lower refrigerant pipe 660 of the first head pipe 610a. It is supplied to the lower section 613b. Then, the refrigerant in the lower region 613b of the first headpipe 610a, the partition plate 615b installed inside the second headpipe 610b is the lower partition plate installed inside the first headpipe 610a. Since it is installed above a certain height than (615c), heat exchange with outside air or brine while moving to the lower section 613b of the second headpipe 610b through a plurality of flat tubes 620 connected to the lower section 613b. .

And the refrigerant in the lower region 613b of the second head pipe 610b, the upper partition plate 615a installed inside the first head pipe 610a is a partition plate installed inside the second head pipe 610b Since it is installed at a certain height above (615b), outside air or brine while moving to the middle section 613c of the first headpipe 610a through a plurality of flat tubes 620 connected to the upper end of the lower section 613b Heat exchange with

In addition, the refrigerant in the middle region 613c of the first head pipe 610a is transferred to the upper region of the second head pipe 610b through a plurality of flat tubes 620 connected to the upper end of the middle region 613c. While moving to 613a), heat exchange with outside air or brine. And the refrigerant in the upper region 613a of the second head pipe 610b, the upper partition plate 615a installed inside the first head pipe 610a is a partition plate installed inside the second head pipe 610b Since it is installed at a certain height above (615b), outside air or brine while moving to the upper region 613a of the first headpipe 610a through a plurality of flat tubes 620 connected to the upper end of the upper region 613a Heat exchange with Finally, the refrigerant condensed while rising to the top of the heat exchanger 600 is discharged to the expansion valve 140 through the upper refrigerant pipe 650 connected to the upper region 613a of the first head pipe 610a. At this time, since a constant pressure acts inside the heat exchanger 600, the refrigerant discharged to the upper refrigerant pipe 650 may be discharged at a high flow rate.

However, in the heating mode, since the high-temperature refrigerant introduced through the lower refrigerant pipe 660 is heat-exchanged with low-temperature air or brine and rapidly condenses, there is a problem in that the oil contained in the refrigerant changes to a liquid state. The oil changed to a liquid state as described above does not rise to the upper end of the heat exchanger 600 even under the pressure inside the heat exchanger 600 and remains at the lower end of the header pipe 610. In this way, if the oil contained in the refrigerant moves to the upper portion of the heat exchanger 600 and fails to circulate, the oil level inside the refrigerant compressor 120 decreases, and there is a problem that damage due to poor lubrication occurs when the refrigerant compressor is operated. . Accordingly, an oil recovery device 700 for recovering and circulating oil remaining in the heat exchanger 600 is required.

The oil recovery device 700 according to the present invention includes an oil recovery pipe 710 having a predetermined length that is vertically installed inside the head pipe 610 and extends from the lower end of the head pipe 610 to the upper end. . The oil return pipe 710 is a pipe having a small diameter, and the lower end is installed close to the bottom of the head pipe 610, and the upper end passes through the outer wall of the head pipe 610 to the upper refrigerant pipe 650. Communicates with.

That is, the oil return pipe 710 is bent outward from the upper end and extends outward through the through hole 612 formed in the outer wall of the head pipe 610, and is formed to be inclined at a certain angle to the upper refrigerant pipe. It penetrates through the bottom surface of 650 and is connected to the inside of the upper refrigerant pipe 650. Preferably, a venturi pipe 720 having a diameter smaller than the diameter of the upper refrigerant pipe 650 is installed at the upper end of the oil return pipe 710, and the venturi pipe 720 is the upper refrigerant pipe 650 Is connected to Here, the'venturi tube' increases the flow velocity by narrowing the diameter of the flow path in a certain section. In addition, a check valve 730 for preventing the refrigerant from flowing backward may be further provided in the oil return pipe 710.

Therefore, when the heat exchanger 600 operates in the heating mode, the high-temperature refrigerant flowing into the lower inner medium pipe 660 of the head pipe 610a is gradually condensed and moves to the upper side of the heat exchanger 600, Since the oil contained in the refrigerant rapidly condenses and changes into a liquid state, it does not move to the upper side of the heat exchanger 600 and remains at the lower end of the head pipe 610.

At this time, when the refrigerant moved to the upper side of the heat exchanger 600 is rapidly discharged through the upper refrigerant pipe 650, the upper end of the oil return pipe 710 communicated with the inside of the upper refrigerant pipe 650 and A suction force is formed inside. Accordingly, when a suction force is generated at the upper end of the oil return pipe 710, the oil remaining at the lower end of the head pipe 710 is transferred upward along the oil return pipe 710. In addition, the oil raised to the upper end of the oil return pipe 710 is injected into the upper refrigerant pipe 650 and mixed with the condensed refrigerant, and then circulated to the refrigerant compressor 120.

As described above, in the heat exchanger 600 provided with the oil recovery means 700 according to the present invention, even in the heating mode, the oil does not remain inside the heat exchanger 600 and is circulated. It is possible to prevent the refrigerant compressor 120 from being damaged. In particular, since the oil recovery means 700 according to the present invention is automatically performed without a complicated control process, it is convenient to use, and since most of the components are installed inside the head pipe 610, the structure is very simple.

9 is a block diagram showing another embodiment of a cooling, heating and air conditioning system 1 for livestock according to the present invention. As shown, the cooling/heating and air conditioning system 1 for livestock according to the present embodiment includes a heat pump 100 for generating cold air or heat, and cold air or heat generated by the heat pump 100 of the livestock house 2. It includes a brine circulation device 200 that is evenly delivered to the inside.

The heat pump 100 largely includes a housing 110, a refrigerant compressor 120, an air-cooled refrigerant heat exchanger 130, an expansion valve 140, a brine refrigerant heat exchanger 150, a switching valve 160, and the like. In addition, the brine circulation device 200 includes a plurality of brine cooling and heating units 210 installed at regular intervals in the house 2. Preferably, the brine cooling and heating unit 210 is an air-cooled brine heat exchanger 220 connected to the brine refrigerant heat exchanger 150 of the heat pump 100 and circulating brine, and the air-cooled brine heat exchanger 220 It is installed in front of the air-cooled brine heat exchanger 220 and includes a blowing fan 230 for blowing air into the interior of the confinement house (2). In addition, the brine circulation device 200 further includes a brine pipe 240 and a circulation pump 260 installed on the brine pipe 240 to circulate the brine.

On the other hand, the air conditioning system (1) for livestock use of the present invention further includes a drinking water supply device (800) for supplying drinking water to animals raised in the livestock house (2). The drinking water supply device 800 includes a drinking water tank 830 having a predetermined capacity, a drinking water refrigerant heat exchanger 190 installed inside the heat pump 100, the drinking water tank 830 and a water refrigerant heat exchanger ( 180) a drinking water circulation pipe 840 connected therebetween, and a drinking water circulation pump 850 installed on the drinking water circulation pipe 840. And a drinking water supplement tank 831 is installed at the top of the drinking water tank 830, and a filter 832 for filtering contaminants in direct water is further installed in the direct water supply line 833 connected to the drinking water supplement tank 831 do. Non-explanatory number 835 denotes direct water such as tap water or groundwater.

Therefore, when performing the cooling mode and the heating mode according to the selection of the switching valve 160 in the heat pump 100, a high or low temperature refrigerant flows along the refrigerant tube 190a of the drinking water refrigerant heat exchanger 190. Then, heat exchange is performed between the drinking water flowing along the drinking water tube 190b installed adjacent to the refrigerant tube 190a, so that the drinking water is cooled or heated. In this case, the temperature of the drinking water may be adjusted by controlling the amount of the refrigerant supplied to the refrigerant tube 190a. In addition, the drinking water cooled or heated along the drinking water tube 190b is stored in the drinking water tank 830.

On the other hand, the drinking water tank 830 is connected to a drinking water distribution line 860 for supplying drinking water to a plurality of drinking water ports 861 installed at regular intervals inside the confinement house 2. A drinking water distribution pump 862 for distributing drinking water is installed on the drinking water distribution line 860.

In addition, the direct water supply line 833 connected to the drinking water tank 930 has a sprinkling water supply line for supplying water for sprinkling to a plurality of sprinkling nozzles 871 installed at regular intervals on the roof of the barn 2 870) is connected. A sprinkling water supply pump 872 for supplying sprinkling water is installed on the sprinkling water supply line 870. Therefore, direct water can be sprayed onto the roof of the barn (2).

10 is a block diagram showing another embodiment of a cooling, heating and air conditioning system 1 for livestock according to the present invention. As shown, the heating and cooling air conditioning system 1 for livestock according to the present embodiment further includes a geothermal heat recovery device 900 for controlling the temperature inside the livestock house 2 by using geothermal heat.

The geothermal heat recovery device 900 includes a brine pipe 240 connected to a plurality of brine cooling and heating units 210 installed at regular intervals in the housing 2, and geothermal heat generated in the ground after being buried in the ground at a predetermined depth. And a geothermal brine heat exchanger 910 in which heat exchange is performed between the brine and the brine, and a geothermal recovery pipe 940 connected between the brine pipe 240 and the geothermal brine heat exchanger 910. In addition, a circulation pump 950 for circulating brine may be further installed on the geothermal heat recovery pipe 940.

Therefore, when the temperature difference between the room and the outside is not large, such as in spring and autumn, the operation of the heat pump 100 is stopped, and the geothermal heat recovery device 900 is operated to use the geothermal heat. That is, when the brine discharged from the air-cooled brine heat exchanger 220 is supplied to the geothermal brine heat exchanger 910 through the brine pipe 240 and the geothermal heat recovery pipe 940, the brine flowing along the brine tube and Heat exchange is performed between the geothermal heat in the ground, so that the brine is cooled or heated. In addition, the cooled or heated brine may be heat-exchanged with indoor air in the air-cooled brine heat exchanger 220 to increase or decrease the temperature inside the confinement house 2.

As described above, the cooling/heating and air conditioning system 1 for livestock according to the present embodiment recovers geothermal heat and adjusts the temperature inside the livestock house 2, thereby reducing operating costs.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. You will understand that you can do it.

1: Air conditioning system for livestock use 2: Livestock house
100: heat pump 120: refrigerant compressor
130: air-cooled refrigerant heat exchanger 140: expansion valve
150: brine refrigerant heat exchanger 160: switching valve (four-way valve)
190: drinking water refrigerant heat exchanger 200: brine circulation device
210: brine cooling and heating unit 220; Air-cooled brine heat exchanger
230: blowing fan 240: brine piping
260: circulation pump 610: head pipe
613: inner space 615: diaphragm
620: flat tube 630: intercooler fin
640: outer cooler fin 650: upper refrigerant pipe
660: lower refrigerant pipe 700: oil recovery device
710: oil return pipe 720: venturi pipe
800: drinking water supply device 830: drinking water tank
833: direct water supply line 860: drinking water distribution line
870: water supply line for sprinkling 900: geothermal recovery device
910: geothermal brine heat exchanger

Claims (10)

A cooling/heating and air conditioning system for livestock comprising a heat pump installed outside the livestock house and generating cool air and heat, and a brine circulation device that heat-exchanges cold air or hot air generated by the heat pump and delivers it to the inside of the house,
The heat pump includes a refrigerant compressor for compressing a refrigerant, an air-cooled refrigerant heat exchanger for performing heat exchange between the refrigerant and air, a brine refrigerant heat exchanger for performing heat exchange between the refrigerant and brine, and a refrigerant compressed by the refrigerant compressor. A switching valve for selecting to flow to the air-cooled refrigerant heat exchanger or the brine refrigerant heat exchanger, and an expansion valve for decompressing the refrigerant flowing to the brine refrigerant heat exchanger or the air-cooled refrigerant heat exchanger;
The brine circulation device includes a plurality of air-cooled brine heat exchangers installed at regular intervals in the housing and performing heat exchange between air and brine, and a blower fan for blowing air that has passed through the air-cooled brine heat exchanger into the housing. A brine cooling and heating unit of, a brine pipe connected between the plurality of air-cooled brine heat exchangers and the brine refrigerant heat exchanger provided in the heat pump to circulate brine, and a circulation pump installed on the brine pipe to circulate brine. Includes;
The brine refrigerant heat exchanger includes two headpipes installed at a predetermined interval, a plurality of flat tubes installed vertically at a predetermined interval between the two headpipes, and at least two independent spaces of the headpipe. Two or more partitions partitioned into space, an upper refrigerant pipe installed in communication with the upper region of the head pipe partitioned by the partition plate, and a lower side installed in communication with the lower region of the head pipe partitioned by the partition plate A refrigerant pipe and an oil return pipe installed inside the head pipe to recover liquid oil remaining at the lower end of the head pipe to the upper refrigerant pipe;
The diaphragms installed in the two headpipes are installed vertically at a certain distance, so that the refrigerant flows through the plurality of flat tubes installed between the two headpipes and the upper and lower regions formed inside the headpipes. , The lower end of the oil return pipe is installed close to the bottom of the head pipe and extends a certain length upward along the inner space of the head pipe, and the upper end of the oil return pipe penetrates the head pipe and protrudes to the outside, and the upper refrigerant pipe And the upper end thereof is installed to communicate with the inside of the upper refrigerant pipe, and the liquid oil contained in the refrigerant flowing through the lower refrigerant pipe and remaining at the lower end of the head pipe is formed in the oil return pipe. A cooling/heating air conditioning system for livestock, characterized in that recovering to the upper refrigerant pipe using pneumatic pressure.
The method of claim 1,
In the inside of the flat tube, intercooler fins are installed to form a plurality of passages in the longitudinal direction of the flat tube, and a plurality of passages are formed in a direction orthogonal to the longitudinal direction of the flat tube between vertically adjacent flat tubes. A cooling/heating air conditioning system for livestock, characterized in that an outer cooler fin is installed.
delete The method of claim 1,
The cooling, heating and air conditioning system for livestock, characterized in that the upper refrigerant pipe is further provided with a venturi pipe through which an upper end of the oil return pipe passes.
The method according to any one of claims 1 to 2,
In the air-cooled brine heat exchanger of the brine cooling and heating unit, the plurality of flat tubes are installed inclined at a predetermined angle.
The method of claim 5,
A cooling/heating air conditioning system for livestock, characterized in that the heat pump further includes a drinking water refrigerant heat exchanger in which heat exchange is performed between the drinking water supplied from the drinking water tank and the refrigerant.
The method of claim 6,
A geothermal brine heat exchanger, which is buried underground and performs heat exchange between geothermal heat and brine, is connected to the brine pipe.
The method of claim 6,
A drinking water distribution line for supplying drinking water to livestock is connected to the drinking water tank, and a water supply line for sprinkling connected to the roof of the barn is connected to a direct water supply line connected to the drinking water tank. .
The method of claim 1,
The housing of the heat pump is divided into an upper section and a lower section around a horizontal plate in the middle, and the two air-cooled refrigerant heat exchangers are installed inclined at a predetermined angle in the upper section.
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