KR100904981B1 - Earth heat cooling and heating system connected to stable ventilation and control method - Google Patents

Abstract

The present invention relates to a geothermal heating and cooling system associated with livestock ventilation, and more particularly, by reducing the heating and cooling costs by using an alternative source of groundwater as an alternative energy, and maintaining the temperature inside the livestock house at an appropriate temperature to increase the productivity of livestock. Rather, it relates to geothermal heating and cooling systems associated with livestock ventilation that reduces the cost of livestock feed and can be installed in existing livestock farms, thereby improving the applicability of livestock farms.

Accordingly, the present invention provides a heat source of groundwater to the refrigerant through a heat pump device to supply cooling and heating air due to evaporation and condensation of the refrigerant to the inside of the house, and in conjunction with this, to drive fans at one side of the house, thereby using optimal energy. It provides a geothermal heating and cooling system linked to the ventilation of the house to create the environment of the house.

Groundwater, Geothermal, Air Conditioning, Ventilation, Barn, Refrigerant, Heat Pump, Livestock

Description

Earth heat cooling and heating system connected to stable ventilation and control method

The present invention relates to a geothermal heating and cooling system associated with livestock ventilation, and more particularly, by reducing the heating and cooling costs by using an alternative source of groundwater as an alternative energy, and maintaining the temperature inside the livestock house at an appropriate temperature to increase the productivity of livestock. Rather, it relates to geothermal heating and cooling systems associated with livestock ventilation that reduces the cost of livestock feed and can be installed in existing livestock farms, thereby improving the applicability of livestock farms.

In general, cooling and heating facilities are required in places where the four seasons are distinct, such as in Korea, and the hot and cold regions of summer and winter are distinct.

Especially, in case of livestock, the breeding temperature by breeding and breeding stage is about 15 ~ 34 degrees Celsius, and in case of young livestock, it needs to be heated in winter because it requires more careful temperature and ventilation management. Cooling must be provided to prevent stress and loss of productivity.

Accordingly, a hot air heater is mainly used for heating the barn in winter, and the hot air heater is a hot air fan using petroleum, which is fossil fuel, and the fuel is burned by the hot air fan to supply combustion gas directly to the inside of the barn with hot heat. Will be

However, the use of such a hot air heater has a problem that the carbon dioxide concentration in the livestock house is increased, the oxygen consumption in the livestock house is large, and the oxygen shortage occurs in the livestock house, so that the productivity for livestock raising in winter is very low.

In addition, the fuel cost for heating is excessively consumed in a high oil price era such as these days, causing a burden of expense on livestock farms.

In addition, there is a problem in that the inside environment of the barn becomes very poor by enclosing the inside of the barn as much as possible and minimizing the ventilation amount in order to suppress the fuel cost increase through the heat insulation during the operation of the hot air fan in winter.

For example, Korea's licensed livestock farms are about 63,000, and among them, pig and chicken farming farms No. 4,131 use hot air all the time, and fossils to prevent environmental pollution and reduce global greenhouse gas, which are emerging internationally recently. As the price of fossil fuels is expected to continue to increase due to the use of fuels, the use of petroleum-based hot air fans will be a huge burden on livestock farmers.

As described above, in order to reduce heating costs in winter, there have been various methods such as solar heat collecting method and thermal insulation in addition to the hot air heating unit, but there is a problem that the efficiency is lowered because it is not sufficient to secure heat for the barn heating.

On the other hand, during the summer heat, the barn cooling is not possible to execute itself due to excessive cooling facilities and operating costs. Accordingly, there is a problem in that the productivity of the livestock is lowered due to heat stress and various problems, and the young livestock dies.

Thus, in a more advanced and new way, the Japanese Livestock Grass Research Institute produced biogas using livestock meal and then used it for livestock heating. The University of Illinois, USA, built a corrugated pipe underground to utilize cold wind after geothermal exchange for air conditioning. In the US, Kentucky expectation is not the heating and cooling of the barn, but air conditioning and heating methods have been proposed, such as the use of heat from the waste coal mine for house cultivation by installing ducts in the abandoned coal mine shaft and greenhouse.

However, such a barn heating and cooling method requires a separate treatment facility or has a problem in that it is not effective for the universal application of the technology in consideration of regional characteristics.

The present invention has been made in order to solve the above problems, by heating and cooling using a geothermal heat pump device that uses geothermal heat as a heat source, to maintain the proper temperature in the barn, as well as ventilation when the temperature rises above the breeding temperature It provides optimal breeding conditions for livestock farms, and can be connected to existing livestock farms, providing excellent applicability to livestock farms. The purpose is to provide a geothermal heating and cooling system.

The present invention for achieving the above object

An underground crystal well installed in an airtight structure around the barn; A pump pump mounted on the groundwater well to draw groundwater; A pumping pipe serving as a passage of groundwater supplied by the pumping pump; A geothermal heat exchanger installed at one side of the pump pipe to exchange heat between the ground water flowing through the pump pipe and the refrigerant in the refrigerant line; A reduction pipe connected integrally with the pumping pipe to reduce groundwater, which has undergone heat exchange, to an underground well; A heat pump connected to the geothermal heat exchanger by a refrigerant line and controlling a state of the refrigerant including a compressor and an expansion valve; A heat exchanger for cooling and heating connected to the heat pump and a refrigerant line to receive a heat source by evaporation or condensation of the refrigerant; A fan coil unit connected to a circulation pipe receiving a heat source from the heat exchanger for cooling and heating to supply cooling and heating air to the livestock house by driving a fan; An air supply duct connecting the fan coil unit and the livestock to become a passage of cooling and heating air supplied from the fan coil unit;

Characterized in that comprises a.

In addition, a large ventilation fan is installed on one side of the house, characterized in that for discharging the air inside the house to the outside.

In addition, the one side of the air supply duct is provided with a plurality of branch ducts are connected long in the barn direction so that the heating and cooling air passing through the air supply duct is uniformly supplied to the inside of the barn.

In addition, the branch duct is characterized in that a plurality of air discharge port is formed in a horizontal line with the barn bottom.

In addition, the ventilation duct is installed in the direction of the inner wall of the penetrating duct penetrating through the pen, it is characterized in that the passage of the air flowing into the pen from outside the pen.

In addition, an auxiliary ventilation fan is installed at one end of the ventilation duct, characterized in that to introduce the outside air to the livestock house.

In addition, an auxiliary damper is installed between the ventilation duct and the branch duct so that the outside air is introduced into the house only when the auxiliary ventilation fan is operated.

In addition, a suction duct is connected between the barn and the fan coil unit, and an outer duct is installed at one side of the suction duct to circulate air in the barn and the fan coil unit.

In addition, a suction damper is installed between the suction duct and the external duct to selectively control the inflow of livestock outside air into the fan coil unit.

In addition, the mutual ventilation unit is installed on one side of the house, the mutual ventilation unit and the chamber having a predetermined space; A discharge fan installed inside the chamber to discharge internal air of the livestock house to the outside; A supply fan installed at one lower side of the discharge fan to supply the outside air to the livestock house; A heat exchange pipe installed adjacent to a space between the discharge fan and the supply fan to allow heat exchange between the discharge fan and the supply fan; A heat exchange pump installed on the heat exchange pipe to circulate heat medium oil in the heat exchange pipe;

Characterized in that comprises a.

In addition, a double pipe ventilation unit is installed at one side of the house, and the double pipe ventilation unit is installed while penetrating the house, an inlet duct for introducing air outside the house into the house by the operation of the inlet fan; An exhaust duct installed through the inlet duct to exchange heat with the inlet duct, and discharging air inside the house to the outside by an operation of a driving fan;

Characterized in that comprises a.

In addition, the insulating material is applied to the outer surface of the inlet duct, it characterized in that the heat exchange with the inside of the livestock.

In one preferred embodiment,

(a) driving a large ventilation fan and an auxiliary ventilation fan by transmitting a signal from the main controller to the ventilation controller when the temperature outside the house is less than or equal to the maximum set value Th and greater than or equal to the minimum set value Tl;

(b) comparing the temperature inside the house to the highest and lowest set points when the temperature outside the house is above the maximum or below the minimum set point;

(c) the heat pump is operated in a cooling mode when the temperature inside the house is greater than or equal to the maximum set value so that the fan coil unit supplies cold air into the house;

(d) when the temperature inside the house is less than the minimum set point, the heat pump operates in a heating mode, and the fan coil unit supplies warm air into the house;

Characterized in that comprises a.

In addition, in the step (c), when the inside temperature of the barn is greater than or equal to the maximum set value, the ventilation controller operates a large ventilation fan to discharge the air inside the barn to the outside, thereby lowering the haptic temperature of the livestock raised in the barn.

In addition, in the step (d), if the temperature inside the house is more than the minimum set value, the ventilation controller operates the auxiliary ventilation fan to supply air outside the house to the inside, thereby reducing the temperature inside the house.

In addition, the highest set value Th is 27 ° C., and the minimum set value Tl is set to 20 ° C.

As described above, the geothermal heating and cooling system and control method associated with the barn ventilation according to the present invention provide the following effects.

First of all, by heating and cooling the barn using the heat source of groundwater, which is an alternative energy source, it eliminates the use of fossil fuels that have been used in the past, reducing the cost of heating and cooling, preventing environmental pollution,

The barn heating is also carried out during the changing seasons to keep the temperature inside the barn constant, thereby preventing respiratory diseases of livestock in the barn,

By keeping the temperature inside the barn at an appropriate temperature in winter, not only increases the productivity of the livestock, but also reduces the cost of livestock feed.

By purifying the air inside the barn according to the livestock breeding environment through air-conditioning and ventilation fan ventilation through groundwater, it can contribute to animal welfare by creating the optimal livestock environment.

It is possible to install the geothermal heating and cooling system in the existing barn without building a separate barn, thereby improving the applicability of livestock farms.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. A singular expression includes a plural expression unless the context clearly indicates otherwise. In this application, the terms “comprises” or “having” are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described in the specification, and one or more other It is to be understood that the present invention does not exclude the possibility of the presence or the addition of features, numbers, steps, operations, components, parts, or a combination thereof.

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

1 and 2 are views of the geothermal heating and cooling system associated with the barn ventilation according to the present invention, FIG. 3 is an enlarged view of the area “A” of FIG. 2, and FIG. 4 is a heat pump apparatus according to the present invention. 5 is an exploded view of one embodiment according to the present invention, FIG. 6 is an enlarged view of a region “B” of FIG. 5, and FIGS. 7 and 8 disclose another embodiment according to the present invention. It is also.

1 and 2, the groundwater is pumped up using the pump 110 from the groundwater well 100 installed in the basement around the barn 300, and the groundwater is pumped through the pumping pipe 120. It is supplied to the geothermal heat exchanger 140 to transfer the heat source to the refrigerant of the refrigerant line 160, the refrigerant received the heat source is supplied to the air-conditioning heat exchanger 170 through the heat pump 150 to cool the circulation pipe 180 Or a heating, and the fan coil unit 190 to which the circulation pipe 180 is connected supplies cooling and heating air to the house 300, thereby cooling and heating the inside of the house by geothermal heat, and a large ventilation fan installed at one side of the house under constant conditions. It provides a geothermal air-conditioning and heating system associated with the ventilation of the barn to drive the 240 and the auxiliary ventilation fan 231 to ventilate the air inside the barn (300).

The groundwater crystal 100 is installed in a suitable point underground around the barn, but is installed in the core 200 ~ 500 meters deep underground to supply abundant ground water.

In addition, a pumping pump 110 is installed inside the groundwater crystal 100 to draw groundwater to the geothermal heat exchanger 140 through a pumping pipe 120 connected to the ground from the pumping pump 110.

In addition, the groundwater supplied to the geothermal heat exchanger 140 provides a heat source to the refrigerant line 160 installed on one side of the geothermal heat exchanger 140, and the groundwater crystallization through the reduction pipe 130 connected integrally with the pump pipe 120. Flows back to (100).

At this time, the reduction pipe 130 is buried deeper underground than the pump pipe 120 so that the ground water re-introduced into the underground well (100) can be filled from the bottom of the underground well (100).

The geothermal heat exchanger 140 is connected to the pump pipe 120 and the reducing pipe 130 in the form of a coil, and the refrigerant line 160 penetrates through one side of the coil-shaped connection portion 121 to be installed therein, thereby providing a heat source of groundwater. It provides a role of condensing the refrigerant supplied through the refrigerant line 160 from the heat pump 150 in the cooling mode and evaporating in the heating mode.

In addition, the heat pump 150 installed on one side of the geothermal heat exchanger 140 has a refrigerant line 160 through which the refrigerant flows, and includes a conventional compressor 151 and an expansion valve 152, according to a cooling and heating mode. Compresses and expands.

One side of the heat pump 150 is provided with a heating and cooling heat exchanger 170 to provide a heat source to the circulation pipe 180 by evaporating and condensing the refrigerant according to the cooling and heating mode.

Specifically, the refrigerant line 160 is formed through the coil line 160 in the form of a coil and the circulation pipe 180 corresponding to the coil line of the refrigerant line 160 is installed in the cooling / heating heat exchanger 170, thereby providing the refrigerant line 160. Refrigerant flowing) will transfer the heat source to the circulation pipe 180.

However, as shown in FIG. 4, in another embodiment, the cooling and heating heat exchanger 170 is omitted, and the refrigerant line 160 penetrating the heat pump 150 is directly connected to the inside of the fan coil unit 190. It is also possible to reduce costs.

The inside of the circulation pipe 180 is filled with a transfer liquid and circulated by the operation of the circulation pump 181 while receiving a heat source of the refrigerant flowing through the refrigerant line 160 in the cooling and heating heat exchanger 170, fan coil unit The heat source is supplied to 190.

In addition, the fan coil unit 190 supplied with the heat source introduces cold or warm air into the barn 300 through the air supply duct 210 according to the cooling and heating mode.

Here, the circulation pipe 180 is penetrated inside the fan coil unit 190 in the form of a coil, and a coil fan 191 is mounted at one side of the circulation pipe 180 to provide a heat source provided by the circulation pipe 180. In accordance with the supply of cooling and heating air.

The air supply duct 210 connects the fan coil unit 190 and the barn to provide a route of cooling and heating air supplied from the fan coil unit 190 to the barn.

Hereinafter, the operation process of the heat pump device 200 (geothermal heat exchanger 140, heat pump 150, air-conditioning heat exchanger 170, fan coil unit 190, air supply duct 210) according to the cooling and heating mode Let's look at it.

In the summer cooling mode, the compressor 151 of the heat pump 150 forms the low temperature low pressure refrigerant at high temperature and high pressure, and the high temperature high pressure refrigerant is supplied to the geothermal heat exchanger 140 along the refrigerant line 160 to pump the pump 110. Condensation by releasing heat into the groundwater supplied by

After the heat is released, the refrigerant is expanded to the low temperature and low pressure by the expansion valve 152 of the heat pump 150, and then moved to the air conditioning heat exchanger 170, and the low temperature low pressure refrigerant heats the heat from the air conditioning heat exchanger 170. As absorbed and evaporated, the internal temperature of the cooling and heat exchanger 170 is reduced.

Here, the geothermal heat exchanger 140 serves as a condenser, the cooling and heating heat exchanger 170 serves as an evaporator.

Thereafter, the circulation pipe 180 penetrating the inside of the cooling and heat exchanger 170 is cooled, and the fan coil unit is cooled together with the transfer liquid flowing in the circulation pipe 180 by the operation of the circulation pump 181. By being delivered to 190, the cold air inside the fan coil unit 190 is supplied into the house through the air supply duct 210 by the operation of the coil fan 191.

On the contrary, in the winter heating mode, the heat pump 150 supplies the low temperature low pressure refrigerant to the geothermal heat exchanger 140 through the refrigerant line 160, and the low temperature low pressure refrigerant heats from the groundwater supplied by the pump 110. Will absorb.

After the refrigerant absorbed heat is compressed to high temperature and high pressure by the compressor 151, the refrigerant is moved to the air conditioning heat exchanger 170. The refrigerant having high temperature and high pressure condenses by releasing heat from the air conditioning heat exchanger 170. The internal temperature of the heat exchanger 170 is increased.

At this time, unlike the cooling mode, the geothermal heat exchanger 140 serves as an evaporator, and the cooling and heating heat exchanger 170 serves as a condenser.

Next, the circulation pipe 180 penetrating the inside of the heating and cooling heat exchanger 170 is heated to be delivered to the fan coil unit 190 while the transfer liquid inside the circulation pipe 180 is heated together, thereby providing a coil fan 191. The warm air is supplied into the barn through the air supply duct 210 by the operation of.

Usually, in the summer, after raising the ground water of 25 ~ 30 ℃ to make cold air of 10 ~ 15 ℃ by using the ground water and heat pump device 200, supply the cold air through the fan coil unit 190 The interior is adjusted to around 27 ℃.

In addition, in the case of winter, after raising the ground water of 10 ~ 15 ℃ to create a warm air of 45 ~ 50 ℃ using the ground water and heat pump device 200, supply the warm air through the fan coil unit 190 The inside is adjusted to around 20 ℃.

On the other hand, the cooling and heating air supplied to the inside of the barn by the fan coil unit 190 is supplied through the air supply duct 210, wherein the air supply duct 210 is installed to penetrate through the barn, evenly cool air inside the barn It is connected to the plurality of branch ducts 220 for distribution.

In particular, the plurality of branch ducts 220 are formed with a plurality of air outlets 221 formed in a line with the bottom of the barn horizontally to further improve the uniformity of the supply of cold air.

In a preferred embodiment, as shown in Figure 2, one side of the house is provided with a plurality of large ventilation fans 240, the temperature is constant by the temperature sensor 250 inside the house in the cooling mode. In the case of detecting abnormality or the necessity of ventilation by the gas sensor 260 inside the barn even when the heat pump apparatus 200 is not in operation, the large ventilation fan 240 is operated by the ventilation controller 270.

Here, the large ventilation fan 240 discharges the air inside the barn to lower the haptic temperature of the livestock raised in the summer barn, and to ventilate the air inside the barn.

In addition, as shown in Figure 2, one side of the branch duct 220, the ventilation duct 230 is connected through the barn and the auxiliary ventilation fan 231 is installed at one end of the ventilation duct 230, winter In the heating mode, when the detected temperature of the temperature sensor 250 is greater than or equal to a predetermined value, fresh air from outside the livestock is introduced into the inside.

At this time, an auxiliary damper 232 is installed between the ventilation duct 230 and the branch duct 220 so that the outside air is introduced into the house only when the auxiliary ventilation fan 231 is operated.

And, as shown in Figure 3, the auxiliary damper 232 is hinged to the inside of the ventilation duct 230 to rotate by the operation of a drive motor (not shown), the ventilation duct 230 when rotated by 90 degrees The stopper 233 is installed on the opposite side of the stop.

In another preferred embodiment, as shown in Figure 5, one side of the fan coil unit 190, the suction duct 280 is connected to circulate the air inside the livestock house fan coil unit 190.

In addition, a suction damper 281 is installed at an inlet at which the protruding duct 290 communicating vertically with the suction duct 280 meets the suction duct 280 so that air outside the barn is selectively introduced into the fan coil unit 190. To be possible.

Specifically, as shown in FIG. 6, when the suction damper 281 rises in the counterclockwise direction, air outside the barn flows into the fan coil unit 190, and at this time, the operation of the suction damper 281 is performed. It is controlled by the drive motor (not shown) and the stopper 282 in the same manner as the auxiliary damper 232.

In another preferred embodiment, as shown in Fig. 7, the mutual ventilation unit 310 is installed on one side of the house to circulate the air inside and outside the house, wherein the mutual ventilation unit 310 has a predetermined space Installed in the chamber 311 is composed of a discharge fan 312 for discharging the internal air of the livestock house to the outside and a supply fan 313 for supplying external air into the livestock house.

In addition, a heat exchange pipe 314 is adjacently installed in the space between the discharge fan 312 and the supply fan 313, and a heat exchange pump 315 is mounted on the heat exchange pipe 314 so that the heat medium oil forms the heat exchange pipe 314. By being circulated through, the mutual heat exchange is made between the discharge fan 312 and the supply fan 313.

As shown in FIG. 8, the double pipe ventilation part 320 is installed at one side of the barn, and the double pipe ventilation part 320 is a driving fan 324. By the operation of the discharge duct 322 for discharging the air inside the house to the outside and the inlet duct 321 for introducing the air outside the house by the operation of the inlet fan 323.

At this time, the discharge duct 322 is installed while penetrating the inside of the inlet duct 321, the heat exchange between the discharge duct 322 and the inlet duct 321 is made, the heat insulating material on the outer surface of the inlet duct 321 Is applied to prevent heat exchange with the inside of the livestock house, thereby increasing the thermal efficiency between the discharge duct 322 and the inlet duct 321.

Hereinafter, the present invention will be distinguished from the comparative example through a test using an example and a comparative example according to the present invention.

<Test Example 1>

When using the geothermal air-conditioning system associated with the ventilation of the barn according to the present invention, when the housing of the sow 48 heads, pigs area 330㎡ in the autumn heating test, when the external average temperature is 9.3 ℃, as shown in Table 1 below, In the embodiment of the present invention, the heating load was 24.101 kcal / h, and the inside temperature of the barn was maintained at a high temperature of 24.9 ° C, while the comparative example without heating maintained the barn internal temperature of 18.7 ° C.

In addition, the ammonia gas concentration was 12.2 ppm, which was significantly lower than that of the comparative example of 19.3 ppm, and the hydrogen sulfide concentration was found to be non-detection and the comparative example was 0.25 ppm, and the example was 992.3 ppm at the carbon dioxide concentration. It appears that 1,100ppm, by the embodiment of the present invention it can be seen that the fresh warm air is supplied to the barn breeding environment is improved.

In particular, pigs that did not heat during the season were able to maintain a constant temperature during geothermal heating, whereas respiratory diseases occur because of severe fluctuations in temperature in pigs.

division Example Comparative example Heating method Geothermal heating according to the present invention Blame Heating load (kcal / h) 24.101 - Average temperature in pigs (℃) 24.9 18.7 Average humidity in pigs (%) 48.3 56.6 CO2 concentration (ppm) 992.3 1,100 Ammonia Gas Concentration (ppm) 12.2 19.3 Hydrogen sulfide concentration (ppm) Not detected 0.25 Dust concentration (PM-10) (㎍ / ㎥) 203.7 303.5

<Test Example 2>

As shown in Table 2, the comparative example was tested by conventional warm air heating.

When using a geothermal air-conditioning system associated with the ventilation of the barn according to the present invention, when the housing of the sow 48 heads, pigs area 330㎡ in winter heating test, when the average temperature of the outside one day is 3.0 ℃, as shown in Table 2 below In Comparative Example, the average temperature was kept at 19.9 ℃ and the average humidity was 49.6%, while the Example maintained an average temperature of 21.0 ℃ and an average humidity of 51.6% inside the barn. It can be seen that formed.

In addition, the ammonia gas concentration was 10.6 ppm, which was significantly lower than that of the comparative example of 23.3 ppm, the hydrogen sulfide concentration was 0.045 ppm, the comparative example was 0.067 ppm, and the carbon dioxide concentration was 1,470 ppm. For example, it was shown that 2,025ppm, it can be seen that the embodiment according to the geothermal heating to improve the breeding environment by supplying the fresh warm air to the barn compared to the warm air heating.

In addition, the analysis of the productivity of pigs showed that the number of piglets in the piglet was 13.2 heads, the comparative example was 12.7 heads, the body weight was 6.93kg, the comparative example was 6.86kg, and the sow intake was 88.22kg, which is lower than that of the comparative example 99.56kg. .

As such, by maintaining geothermal heating in accordance with an embodiment of the present invention in winter to maintain the proper temperature inside pigs, to improve the productivity of the breeding pigs and to reduce the feed cost, and to reduce the cost of oil used in the conventional warm air heating It became.

division Example Comparative example Heating method Geothermal heating according to the present invention Warm air heating Heating load (kcal / h) - - Average temperature in pigs (℃) 21.0 19.9 Average humidity in pigs (%) 51.6 49.6 CO2 concentration (ppm) 1,470 2,025 Ammonia Gas Concentration (ppm) 10.6 23.3 Hydrogen sulfide concentration (ppm) 0.045 0.67 Dust concentration (PM-10) (㎍ / ㎥) 185.3 481.4 Childbirth pig (money) 13.2 12.7 Weaning weight (kg) 6.93 6.86 Sow intake (kg) 88.22 99.56

Hereinafter, with reference to the accompanying drawings, a control method of a geothermal air-conditioning system associated with a barn ventilation according to the present invention will be described.

9 is a flowchart illustrating a control method of a geothermal air-conditioning and heating system associated with a barn ventilation according to the present invention.

First, when the temperature outside the livestock house is less than or equal to the maximum set value (Th) or more than the minimum set value (Tl), the main controller 400 transmits a signal to the ventilation controller 270 to provide the large ventilation fan 240 and the auxiliary ventilation fan 231. By driving, the air inside the house is ventilated.

In addition, when the temperature outside the house is outside the maximum set value and the minimum set value range, the temperature sensed by the temperature sensor 250 inside the house is compared with the highest and lowest set values.

At this time, when the temperature inside the house is above the maximum set value, the heat pump device 200 operates in the cooling mode to supply the cold air to the fan coil unit 190, and when the temperature inside the house is below the minimum set value, the heat pump 150. The device operates in a heating mode to allow the fan coil unit 190 to supply warm air.

In addition, when cold air is supplied to the inside of the house in the cooling mode, when the inside temperature of the house is above the maximum setting value, the ventilation controller 270 operates the large ventilation fan 240 to rapidly discharge the air inside the house to the outside. Use to lower the sense of temperature felt by livestock.

In addition, the ventilation controller 270 operates the auxiliary ventilation fan 231 in the heating mode when the temperature inside the barn is higher than the minimum set value to supply the air outside the barn to the inside, so that the livestock breeding temperature of the livestock is always maintained. .

Specifically, the temperature inside the barn to be maintained for good breeding of livestock is suitable 20 ~ 27 ℃ bar, the highest set value (Th) is 27 ℃, the minimum set value (Tl) is preferably 20 ℃.

While the present invention has been illustrated and described with respect to particular preferred embodiments, the invention is not limited to these embodiments, and various forms of embodiments that can be practiced without departing from the spirit to which the invention pertains It includes everything.

1 and 2 are a view of the geothermal air conditioning system associated with the barn ventilation according to the present invention,

3 is an enlarged view of the area “A” in FIG. 2, FIG.

4 is another embodiment of the heat pump apparatus according to the present invention,

5 is a view of an embodiment according to the present invention;

6 is an enlarged view of the area “B” in FIG. 5, FIG.

7 and 8 are views of another embodiment according to the present invention,

9 is a flowchart illustrating a control method of a geothermal heating and cooling system associated with a barn ventilation according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: groundwater crystal 110: pumping pump

120: positive pipe 130: reducing pipe

140: geothermal heat exchanger 150: heat pump

160: refrigerant line 170: cooling and heating heat exchanger

180: circulation pipe 190: fan coil unit

200: heat pump device 210: air supply duct

300: barn 400: main controller

Claims (16)

An underground crystal well installed in an airtight structure around the barn; A pump pump mounted on the groundwater well to draw groundwater; A pumping pipe serving as a passage of groundwater supplied by the pumping pump; A geothermal heat exchanger installed at one side of the pump pipe to exchange heat between the ground water flowing through the pump pipe and the refrigerant in the refrigerant line; A reduction pipe connected integrally with the pumping pipe to reduce groundwater, which has undergone heat exchange, to an underground well; A heat pump connected to the geothermal heat exchanger by a refrigerant line and controlling a state of the refrigerant including a compressor and an expansion valve; A heat exchanger for cooling and heating connected to the heat pump and a refrigerant line to receive a heat source by evaporation or condensation of the refrigerant; A fan coil unit connected to a circulation pipe receiving a heat source from the heat exchanger for cooling and heating to supply cooling and heating air to the livestock house by driving a fan; An air supply duct connecting the fan coil unit and the livestock to become a passage of cooling and heating air supplied from the fan coil unit; Geothermal heating and cooling system associated with the barn ventilation, characterized in that comprising a. The geothermal air conditioning system according to claim 1, wherein a large ventilation fan is installed at one side of the house to discharge air inside the house to the outside. The geothermal heat associated with the ventilation of the livestock duct according to claim 1, wherein a plurality of branching ducts are connected to one side of the air supply duct for a long time in the barn direction so that the heating and cooling air passing through the air supply duct is uniformly supplied to the inside of the barn. Air conditioning system. The geothermal air conditioning system according to claim 3, wherein the branch duct is provided with a plurality of air outlets in a horizontal line with the bottom of the barn. The geothermal air conditioning system according to claim 3, wherein a ventilation duct is installed in the direction of the inner wall of the branch duct to penetrate the barn to be a passage of air introduced from the outside of the barn. The geothermal air conditioning system according to claim 5, wherein an auxiliary ventilation fan is installed at one end of the ventilation duct to introduce external air into the housing. The geothermal air conditioning system according to claim 6, wherein an auxiliary damper is installed between the ventilation duct and the branch duct so that outside air is introduced into the house only during operation of the auxiliary ventilation fan. The method of claim 1, wherein the intake duct is connected between the livestock duct and the fan coil unit, an external duct is installed on one side of the suction duct to circulate air inside the livestock and the fan coil unit and Linked geothermal heating and cooling system. 10. The geothermal air conditioning system according to claim 8, wherein a suction damper is installed between the suction duct and the external duct to selectively control the inlet of the outside air into the fan coil unit. The method according to claim 1, wherein the mutual ventilation unit is installed on one side of the house, the mutual ventilation unit and the chamber having a predetermined space; A discharge fan installed inside the chamber to discharge internal air of the livestock house to the outside; A supply fan installed at one lower side of the discharge fan to supply the outside air to the livestock house; A heat exchange pipe installed adjacent to a space between the discharge fan and the supply fan to allow heat exchange between the discharge fan and the supply fan; A heat exchange pump installed on the heat exchange pipe to circulate heat medium oil in the heat exchange pipe; Geothermal heating and cooling system associated with the barn ventilation, characterized in that comprising a. The inlet duct of claim 1, wherein a double pipe ventilation unit is installed at one side of the house, and the double pipe ventilation unit is installed while penetrating the house, and the inlet duct introduces air outside the house into the house by the operation of the inlet fan; An exhaust duct installed through the inlet duct to exchange heat with the inlet duct, and discharging air inside the house to the outside by an operation of a driving fan; Geothermal heating and cooling system associated with the barn ventilation, characterized in that comprising a. 12. The geothermal air conditioning system according to claim 11, wherein a heat insulating material is applied to an outer surface of the inlet duct to prevent heat exchange with the inside of the barn. delete delete delete delete

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