KR101477995B1 - Radiant floor heating and cooling, and ventilation system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floor heating and air conditioning and air conditioning system having a fluid circulation path through which a fluid can circulate and a gas circulation path through which gas can circulate and heat exchange is performed between the gas and the fluid, A heat source unit connected to the fluid circulation path and selectively supplying hot water or cold water to the fluid circulation path, a gas circulation path connected to the gas circulation path, And an air conditioning unit connected to the heat exchanging unit for introducing the gas heat exchanged with the fluid into the internal space of the facility. Thus, by performing cooling and heating using natural energy such as solar heat and ground water instead of fossil fuel or electric energy, Pollution can be prevented, and natural energy such as solar heat and groundwater can be used It is possible to implement a shut copy air conditioning system and air-conditioning systems at the same time can increase the efficiency of heating and cooling.

Description

Radiant floor heating and cooling, and ventilation system

The present invention relates to a floor radiation cooling and heating system and an air conditioning system applicable to a greenhouse and other facilities in which a multi-layered type cultivation apparatus is installed.

Domestic plant factories depend on electric cooling system and kerosene heating system to maintain the thermal environment during the summer high temperature and low temperature during winter.

However, the electric cooling system is disadvantageous in that it is hardly used due to low efficiency in the structure of the cultivation facility in the summer, so that the greenhouse is opened in the summer to natural ventilation. Also, in case of natural ventilation in summer, the quality of crops is lowered compared to spring and autumn due to high temperature, and the yield and yield of crops become unstable. Therefore, in summer, .

On the other hand, heating facilities for kerosene and other fossil fuels pollute the environment due to various carbon emissions occurring in the combustion process of fossil fuels, and fossil fuels have a disadvantage that their reserves are limited. Therefore, in recent years, alternative energy that can replace fossil fuels has been actively developed. Among these alternative energies, research on natural energy such as wind power, solar heat, and geothermal energy has been carried out for a long time, and natural energy heating and cooling devices are being developed. However, natural energy has the advantage of obtaining infinite energy with little impact on environmental pollution and climate change, but it has a disadvantage that the energy density is very low.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art and it is an object of the present invention to provide a floor heating and air conditioning and air conditioning system in which the structure is improved so as to perform cold- The purpose of the system is to provide.

Further, it is an object of the present invention to provide a floor radiation cooling and heating and air conditioning system improved in structure to increase energy density of natural energy.

The floor radiating air conditioning and air-conditioning system according to a preferred embodiment of the present invention includes a fluid circulation path through which fluid can circulate and a gas circulation path through which the gas can circulate, heat exchange is performed between the gas and the fluid, And a heat source unit connected to the fluid circulation path and selectively supplying hot water or cold water to the fluid circulation path, the heat source unit being installed in at least one of the fluid circulation path and the wall surface, And an air conditioning unit connected to the gas circulation path and for introducing the gas heat exchanged with the fluid in the heat exchange unit into the internal space of the facility.

Preferably, the heat source unit includes a solar heat collecting plate installed on at least one of the outside and the inside of the facility, the solar heat collecting plate capable of collecting solar heat, and the hot water supplying tube capable of receiving hot water collected from the solar heat collecting plate, A groundwater cooler having a groundwater supply pipe capable of collecting groundwater in a subterranean space of the facility, and a connection unit selectively connected to the hot water supply pipe or the ground water supply pipe to selectively supply hot water or ground water to the fluid circulation path. do.

Preferably, the solar heat source further comprises an auxiliary boiler for reheating the hot water of the hot water supply pipe, and a bypass pipe for bypassing the hot water of the hot water supply pipe to the auxiliary boiler and then introducing the reheated hot water back into the hot water supply pipe .

Preferably, the solar heat source further comprises a hot water temperature sensor capable of measuring the temperature of the hot water of the hot water supply pipe, and when the hot water temperature of the hot water supply pipe is lower than a predetermined temperature, By-pass.

Preferably, the groundwater cool source further comprises a groundwater pump capable of pumping groundwater into the groundwater supply pipe.

Preferably, the connecting portion is provided with a discharge valve capable of discharging hot water or ground water to the outside.

Preferably, the heat exchanging unit is composed of a double tube in which the inner space is partitioned into a gas circulation path and a fluid circulation path by partition walls provided therein, and the gas and the fluid are heat-exchanged through the partition.

Preferably, the double tube is formed of a material of at least one of a metal and a synthetic resin.

Preferably, the air conditioning unit includes a gas recovery pipe connected to the gas circulation path and receiving gas heat-exchanged with the fluid from the gas circulation, the gas recovery pipe embedded in at least one of a bottom surface and a wall surface of the facility, And a spray hole capable of spraying the gas flowing in the gas return pipe toward the outside, wherein the facility is provided on at least one of a bottom surface and a wall surface, and the spray hole communicates with the inner space of the facility, And an inflow hole through which the introduced gas can be introduced into the internal space of the facility.

Preferably, the air conditioning unit further includes a gas supply pipe capable of supplying the inside air of the facility to the gas circulation unit, and the facility further includes a discharge hole communicating the internal space and the gas supply pipe to discharge the inside of the facility to the gas supply pipe .

Preferably, the discharge hole is formed in the ceiling of the facility.

Preferably, the air conditioning unit is further provided with a discharge fan installed in an internal space of the facility and capable of guiding the inside of the facility to the gas supply pipe.

The floor radiant air conditioning and air conditioning system according to the present invention has the following effects.

First, environmental pollution can be prevented by replacing fossil fuel or electric energy and performing cooling and heating using natural energy such as solar heat and ground water.

Secondly, by using natural energy such as solar heat, ground water, etc., it is possible to simultaneously realize the floor radiation heating / cooling system and the air conditioning / heating / heating system, thereby increasing the cooling / heating efficiency.

Third, heating or cooling can be selectively performed depending on the temperature inside and outside of the facility.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view for explaining a floor heating / cooling / air-conditioning system according to a preferred embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a floor heat exchanger,
3 is a view for explaining a circulation path of a gas and a fluid in a floor radiating cooling and heating and air conditioning system according to a preferred embodiment of the present invention.
4 is a view for explaining a solar heat source according to a preferred embodiment of the present invention.
FIG. 5 is a view for explaining a groundwater cold source according to a preferred embodiment of the present invention. FIG.
6 is a view for explaining a connecting portion of a floor heating / cooling / heating system according to a preferred embodiment of the present invention.
7 is a view for explaining an air conditioning unit of a floor heating / cooling / heating system according to a preferred embodiment of the present invention.
FIG. 8 is a view for explaining an air movement path of an internal space of a facility to which a floor radiation cooling and heating system according to a preferred embodiment of the present invention is applied; FIG.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In the drawings, the size of each element or a specific part constituting the element is exaggerated, omitted or schematically shown for convenience and clarity of description. Therefore, the size of each component does not entirely reflect the actual size. In the following description, it is to be understood that the detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The floor radiation cooling and heating and air conditioning system (1) according to the preferred embodiment of the present invention is applied to a specific facility, and performs floor cooling and air conditioning and air conditioning at the same time. The facilities to which the floor heating and air-conditioning and air-conditioning system 1 according to the preferred embodiment of the present invention can be applied are not particularly limited. For example, general residential and office buildings and target crops may be stacked in multi- A greenhouse 2 in which a multi-level stacking type cultivation apparatus can be installed, and the like. For the sake of convenience of description, the present invention will be described based on the fact that the floor heating / cooling and air-conditioning system 1 of the present invention is applied to a greenhouse 2 equipped with a multi-stage lamination type planting apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view for explaining a floor heating / cooling / air-conditioning system according to a preferred embodiment of the present invention; FIG. 2 is a view for explaining a heat exchange unit of a floor heating / cooling / air-conditioning system according to a preferred embodiment of the present invention.

1 to 2, a floor radiating cooling and heating and air conditioning system 1 according to a preferred embodiment of the present invention includes a heat exchange unit 10, a heat source unit 20, an air conditioning unit 30, a connection unit 60, . ≪ / RTI >

The heat exchanging part 10 may be embedded in the bottom surface of the greenhouse 2 and may include a gas circulation path 14 through which the gas can circulate and a fluid circulation path 12 through which the fluid can circulate.

The shape of the heat exchanging portion 10 is not particularly limited and the inner space may be partitioned into the gas circulation passage 14 and the fluid circulation passage 12 by the partition walls 16 provided therein, It can be done as a double pipe. The material of the heat exchanging part 10 is not particularly limited, and may be made of at least one of, for example, a metal having high heat transfer coefficient or a synthetic resin material.

Thus, heat exchange can be achieved between the gas circulating path 14 and the circulating gas and the fluid circulating the fluid circulating path 12. The gas circulating the fluid circulation path 12 and the heat transferred from the gas circulating through the fluid circulation path 12 are stored in the bottom surface of the greenhouse 2 made of concrete, The radiant heat accumulated in the greenhouse 2 can be radiated to the inner space of the greenhouse 2 to perform cooling and heating. That is, the heat exchange unit 10 is embedded in the bottom surface of the greenhouse 2 to radiate the radiant heat accumulated by the gas of the gas circulation path 14 and the fluid of the fluid circulation path 12 into the inner space of the greenhouse 2, It is possible to perform cooling and heating for the inner space of the greenhouse 2.

The heat exchange unit 10 may be installed on the wall surface of the greenhouse 2 in addition to the bottom surface of the greenhouse 2. For convenience of explanation, The present invention will be described on the basis of being installed in a state where it is embedded in the housing.

The heat source unit 20 is connected to the fluid circulation path 12 and can selectively supply hot water or cold water to the fluid circulation path 12. The heat source unit 20 may include a solar heat source 40 and a ground water heat source and a connection unit 60 to selectively supply hot water or cold water to the fluid circulation path 12, do.

The air conditioning unit 30 is connected to the gas circulation path 14 and allows the heat exchange unit 10 to introduce the fluid that is heat-exchanged with the hot water or cold water into the inner space of the greenhouse 2. The air conditioning unit 30 may include a gas recovery pipe 31, an injection hole 32, a gas supply plate, a discharge fan 34, and the like in order to perform air conditioning for the internal space of the greenhouse 2, Details of this will be described later.

FIG. 3 is a view for explaining a circulation path of a gas and a fluid in a floor radiation cooling and heating and air-conditioning system according to a preferred embodiment of the present invention, FIG. 4 is a view for explaining a solar heat source according to a preferred embodiment of the present invention, FIG. 5 is a view for explaining a groundwater cold source according to a preferred embodiment of the present invention.

6 is a view for explaining a connecting portion of a floor heating / air conditioning and air conditioning system according to a preferred embodiment of the present invention, and FIG. 7 is a view for explaining an air conditioning portion of a floor heating / cooling / air conditioning system according to a preferred embodiment of the present invention And FIG. 8 is a view for explaining an air movement path of an internal space of a facility to which a floor heating / cooling / air-conditioning system according to a preferred embodiment of the present invention is applied.

3 to 6, the heat source unit 20 includes a solar heat source 40 that generates hot water using solar heat, a ground water cool source 50 that collects ground water to obtain cold water, 12 for selectively supplying the electric power to the first and second power sources.

The solar heat source 40 supplies hot water, which generates hot water using solar heat, to the fluid circulation path 12, and a solar heat collecting plate 41 for collecting solar heat, a hot water supply pipe 42 for generating hot water, A bypass pipe 43 for bypassing the hot water to the auxiliary boiler 44 and the auxiliary boiler 44, a hot water return pipe 48, and the like.

The solar heat collecting plate 41 is installed on at least one of the outside and the inside of the greenhouse 2 to collect solar heat. For example, the solar collector plate 41 may be installed on the roof of the greenhouse 2 and on the top of the vegetation growing stand installed inside the greenhouse 2, as shown in Fig. Since the solar heat collecting plate 41 of the present invention generally has the same configuration as the solar heat collecting plate 41 used for collecting solar heat, a detailed description thereof will be omitted.

The hot water supply pipe 42 receives solar heat collected from the solar heat collecting plate 41 to generate hot water. 4, the hot water supply pipe 42 may be coupled to the back surface of the solar heat collecting plate 41 to receive the collected solar heat, The heated water may be heated to generate hot water.

As shown in FIG. 3, a hot water temperature sensor 45 capable of measuring the temperature of the hot water, a hot water pump 45 capable of pumping hot water of the hot water supply pipe 42, (46) may be installed. The hot water supply pipe 42 is connected to the inlet of the fluid circulation path 12 through the connection part 60 so that the hot water can be selectively supplied to the fluid circulation path 12.

The auxiliary boiler 44 can reheat the hot water of the hot water supply pipe 42 and the bypass pipe 43 bypasses the hot water of the hot water supply pipe 42 to the auxiliary boiler 44, Can be introduced into the supply pipe (42).

A three-way valve 47 having one inlet 47a and two outlets 47b and 47c may be installed on the path of the hot water supply pipe 42 as shown in FIG. The inlet 47a of the three-way valve 47 is connected to the hot water supply pipe 42 and the one outlet 47b of the three-way valve 47 is connected to the hot water supply pipe 42 and the remaining one outlet 47c And is connected to the bypass pipe 43.

When the temperature of the hot water in the hot water supply pipe 42 is lower than a predetermined temperature, the three-way valve 47 closes the outlet 47b connected to the hot water supply pipe 42 and the outlet 47c connected to the bypass pipe 43 So that the hot water can be bypassed to the bypass pipe 43. The hot water bypassed by the pipe can be reheated in the auxiliary boiler (44) and then introduced into the hot water supply pipe (42).

The hot water recovery pipe 48 is connected to the discharge port of the fluid circulation path 12 through the connection portion 60. The hot water discharged from the fluid circulation path 12 flows back to the hot water supply pipe 42 through the hot water recovery pipe 48 .

The groundwater cool source 50 collects the ground water and supplies it to the fluid circulation path 12. The groundwater supply source pipe 51 for collecting the ground water in the underground space, the groundwater pump 52 for pumping the ground water, .

The groundwater supply pipe 51 can collect the groundwater in the underground space of the greenhouse 2 and the groundwater pump 52 can pump the groundwater into the index supply pipe. Generally, the groundwater in the underground space of 10 m or less is hardly affected by the change in the temperature of the ground, and thus it is possible to maintain a low temperature between 15 ° C and 20 ° C even in the summer when the outdoor temperature is high. Therefore, ground water can be used as the cold water to be supplied to the fluid circulation path (12).

3, the open inlet of the groundwater supply pipe 51 is inserted into an underground water well or a water storage tank in which groundwater is stored, a groundwater pump 52 is installed at an end of the groundwater supply pipe 51, The groundwater supply pipe 51 can collect groundwater. The groundwater supply pipe 51 is connected to the connection unit 60 so that the groundwater can be selectively supplied to the fluid circulation path 12 through the connection unit 60.

The groundwater recovery pipe 53 is connected to the discharge port of the fluid circulation path 12 through the connection portion 60. The hot water discharged from the fluid circulation path 12 flows into the groundwater well or the water storage tank through the groundwater recovery pipe 53 .

The connection unit 60 is selectively connected to the hot water supply pipe 42 or the ground water supply pipe 51 to selectively supply the hot water or ground water to the fluid circulation path 12 and the three way valves 61 and 64, 62, a fluid return pipe 63, and the like.

The three-way valve 61 selectively connects the hot water supply pipe 42 or the groundwater supply pipe 51 to the fluid circulation path 12 and can have two inlets 61a and 61b and one outlet 61c. 3, one inlet 61a of the three-way valve is connected to the hot water supply pipe 42, the other one inlet 61b is connected to the groundwater supply pipe 51, and one outlet 61c Is connected to the fluid distribution pipe (62).

The three-way valve 61 closes the inlet 61b on the side of the groundwater supply pipe 51 and opens the inlet 61a on the side of the hot water supply pipe 42 when the temperature of the greenhouse 2 is low, The fluid distribution pipe 62 can be communicated. When the temperature of the greenhouse 2 is high, the three-way valve 61 closes the inlet 61a on the side of the hot water supply pipe 42 and opens the inlet 61b on the side of the underground supply pipe, The distribution pipe 62 can be communicated with each other.

That is, the three-way valve 61 can supply the hot water to the fluid circulation path 12 by communicating the hot water supply pipe 42 and the fluid distribution pipe 62 during the winter season when the temperature of the greenhouse 2 is low, The groundwater can be supplied to the fluid circulation path 12 by communicating the groundwater supply pipe 51 in the summer when the temperature is high. In order to measure the temperature of the greenhouse 2, a greenhouse 2 temperature sensor capable of measuring the temperature of the greenhouse 2 may be installed in the greenhouse 2 as shown in FIG.

The fluid distribution pipe 62 is provided between the three-way valve 61 and the fluid circulation path 12 to distribute hot water or cold water that has passed through the three-way valve 61 to the fluid circulation path 12. As shown in FIG. 6, a plurality of heat exchange units 10 having a fluid circulation path 12 and a gas circulation path 14 are provided in parallel on the bottom surface of the greenhouse 2. The fluid distribution pipe (62) passes through each heat exchanging part (10) and communicates with the inlet of the fluid circulation path (12). Therefore, hot water or cold water that has passed through the three-way valve 61 is distributed by the fluid distribution pipe 62 and flows into the fluid circulation path 12 provided in each heat exchange unit 10. [

On the other hand, as shown in FIG. 3, on the path of the fluid distribution pipe 62, a discharge valve capable of discharging the hot water of the fluid distribution pipe 62 or the ground water to the outside can be provided.

The fluid return pipe (63) can recover hot water or cold water that has passed through the fluid circulation path (12). As shown in Fig. 3, the fluid return pipe 63 communicates with the discharge port of the fluid circulation path 12 provided in each of the heat exchanging units 10. As shown in Fig. Therefore, hot water or cold water that has passed through the fluid circulation path (12) provided in each heat exchange unit (10) is discharged to the fluid circulation path (12) and recovered.

The three-way valve 64 selectively connects the fluid return pipe 63 with the hot water return pipe 48 or the groundwater return pipe 53 and has one inlet 64a and two outlets 64b and 64c . 3, one inlet 64a of the three-way valve 64 is connected to the fluid return pipe 63, one outlet 64b is connected to the hot water return pipe 48, One outlet 64c is connected to the groundwater return pipe 53. [

The three-way valve 64 closes the outlet 64c on the side of the groundwater recovery pipe 53 and opens the outlet 64b on the side of the hot water recovery pipe 48 when hot water flows into the fluid circulation path 12, So that the return pipe 63 and the hot water return pipe 48 can communicate with each other. The three-way valve 64 closes the outlet 64b on the side of the hot water return pipe 48 and opens the outlet 64c on the side of the groundwater return pipe 53 when the groundwater flows into the fluid circulation path 12 So that the fluid return pipe 63 and the groundwater return pipe 53 can communicate with each other. Therefore, the hot water or ground water introduced into the fluid circulation path 12 can be guided to the hot water return pipe 48 or the groundwater return pipe 53 by the three-way valve 64 and reused.

3 and 7, the air conditioning unit 30 includes a gas return pipe 31 for receiving the gas discharged from the gas circulation path 14, a gas returning pipe 31 for guiding the gas delivered to the gas return pipe 31 to the inside of the greenhouse 2 A gas supply pipe 33 for supplying the inner space of the greenhouse 2 to the gas circulation path 14 and a discharge fan 34 for guiding the inner space of the greenhouse 2 to the gas supply pipe 33 ), And the like.

The gas recovery pipe 31 is connected to the gas circulation path 14 and receives gas heat exchanged with the fluid from the gas circulation path 14 and can be embedded in the bottom surface of the greenhouse 2.

The gas recovery pipe 31 communicating with the discharge port of the gas circulation path 14 provided in each of the heat exchanging units 10 may be embedded in the bottom surface of the greenhouse 2 as shown in FIG. More specifically, the gas recovery pipe 31 communicates with the discharge port of the gas circulation path 14 provided in each of the heat exchange units 10 to recover the gas discharged from the gas circulation path 14, And distributes the gas while extending along the longitudinal direction of the bottom surface of the rear greenhouse (2).

The injection hole 32 is formed through the gas return pipe 31 so that the gas flowing through the gas return pipe 31 can be injected toward the outside. Corresponding to this, the greenhouse 2 is provided on the bottom surface and communicates the injection hole 32 with the inner space of the greenhouse 2 to introduce the gas injected from the injection hole 32 into the inner space of the greenhouse 2 Which may include an inlet hole.

As shown in FIG. 7, a plurality of injection holes 32 are formed in the flow path of the gas recovery pipe 31 along the longitudinal direction. 8, in the bottom surface of the greenhouse 2, there are provided a plurality of holes 32 at positions corresponding to the respective injection holes 32 so that the respective injection holes 32 and the inner spaces of the greenhouse 2 can communicate with each other, An inlet hole is formed. Therefore, the gas of the gas recovery pipe 31 flows into the indoor space of the greenhouse 2 after passing through the injection hole 32 of the gas recovery pipe 31 and the inlet hole of the greenhouse 2, have.

The gas supply pipe 33 can supply the inner space of the inner space of the greenhouse 2 to the gas circulation path 14. Corresponding to this, the greenhouse 2 may further include a discharge hole for communicating the inner space with the gas supply pipe 33 so as to discharge the inner space of the greenhouse 2 to the gas supply pipe 33.

7, a gas supply pipe 33 is provided on the ceiling of the greenhouse 2 to supply the inner space of the greenhouse 2 to the gas circulation path 14. [ A plurality of guide holes 35 are formed in the gas supply pipe 33 to guide the inner space of the greenhouse 2 to the gas supply pipe 33 along the longitudinal direction. 8, a plurality of discharge holes may be formed in the ceiling of the greenhouse 2 so as to allow the guide holes 35 and the inner space of the greenhouse 2 to communicate with each other. A gas distribution pipe 36 may be provided at an end of the gas supply pipe 33 so as to branch off the gas supply pipe 33 and connect the respective heat exchange units 10.

Therefore, the inner space of the inner space of the greenhouse 2 can be supplied to the gas circulation path 14 through the gas supply pipe 33. That is, by providing the gas supply pipe 33, an air conditioning cycle is performed to supply the inside air of the greenhouse 2 to the gas circulation path 14, to heat-exchange the air, and then to flow into the inside space of the greenhouse 2 to perform air conditioning can do.

The gas supply pipe 33 and the discharge hole of the greenhouse 2 are provided on the ceiling of the greenhouse 2 but are not limited thereto and may be formed on other structures of the wall of the greenhouse 2.

The discharge fan 34 is installed in the inner space of the greenhouse 2 and can guide the inner space of the greenhouse 2 to the gas supply pipe 33.

As shown in Fig. 8, a plurality of discharge fans 34 are installed in the ceiling of the greenhouse 2 adjacent to each discharge hole. Accordingly, as the discharge fan 34 is operated, the inner space of the inner space of the greenhouse 2 passes through the discharge hole of the greenhouse 2 and the guide hole 35 of the gas supply pipe 33 and then flows into the gas supply pipe 33 . That is, a flow of the indoor air from the floor surface toward the ceiling may occur in the inner space of the greenhouse 2 by the discharge fan 34.

Hereinafter, referring to FIG. 3, the heating of the interior space of the greenhouse 2 using the preferred floor radiation and air conditioning system 1 of the present invention will be described.

When the temperature of the inner space of the greenhouse 2 is lower than a predetermined temperature, the inlet 61b of the three-way valve 61 on the side of the groundwater supply pipe 51 is closed and the inlet 61a on the side of the hot water supply pipe 42 is opened The hot water supply pipe 42 and the fluid distribution pipe 62 of the connection portion 60 are communicated with each other. Therefore, the hot water of the hot water supply pipe 42 generated by the solar heat transferred from the solar heat collection plate 41 can be introduced into the fluid circulation path 12 of the heat exchange unit 10. When the temperature of the hot water in the hot water supply pipe 42 is lower than a predetermined temperature, hot water can be introduced into the auxiliary boiler 44 through the bypass pipe 43, reheated, and then introduced into the fluid circulation path 12.

Next, the discharge fan 34 installed in the inner space of the greenhouse 2 is operated to guide the inner space of the greenhouse 2 to the gas supply pipe 33 and to flow into the gas circulation path 14.

Heat exchange occurs between the inner space of the greenhouse 2 passing through the gas circulation path 14 through the partition 16 provided inside the heat exchange section 10 and the hot water passing through the fluid circulation path 12. That is, the heat of the hot water is transmitted to the inside of the greenhouse 2, the temperature of the hot water decreases, and the temperature of the inside of the greenhouse 2 rises.

The radiant heat transferred from the inner space of the greenhouse 2 passing through the gas circulation passage 14 of the heat exchange unit 10 and the hot water passing through the fluid circulation path 12 and stored on the bottom surface of the greenhouse 2 during the heat exchange, It is possible to radiate to the inner space of the greenhouse 2 to perform heating for the inner space of the greenhouse 2.

Next, hot water passing through the fluid circulation path (12) flows into the hot water supply pipe (42) again through the hot water return pipe (48) and is reused. The three-way valve 64 opens the outlet 64b on the side of the hot water return pipe 48 so that the hot water passing through the fluid circulation path 12 can flow into the hot water return pipe 48, Side outlet 64c.

The inner space of the greenhouse 2 that has passed through the gas circulation path 14 is discharged to the gas return pipe 31 and then passes through the discharge hole of the injection hole 32 and the greenhouse 2, Respectively. Therefore, heating of the inner space of the greenhouse 2 can be performed by allowing the inner space of the greenhouse 2 whose temperature has been increased by heat exchange with hot water to flow into the inner space of the greenhouse 2 again.

As described above, the floor radiation cooling and air conditioning system 1 according to the preferred embodiment of the present invention induces the hot water generated by solar heat and the inner space of the greenhouse 2 to the bottom surface of the greenhouse 2 to perform heat exchange, And heating can be performed simultaneously by the air conditioning by which the heated air and the heated air are introduced. Accordingly, compared to the case where heating is performed using fossil fuel and electricity, the heat efficiency is high, so that the heating cost can be reduced and the environmental pollution can be prevented by performing the heating using the solar heat.

Hereinafter, cooling of the inner space of the greenhouse 2 using the preferred floor radiation cooling and heating and air conditioning system 1 of the present invention will be described with reference to FIG.

When the temperature of the inner space of the greenhouse 2 is higher than the predetermined temperature, the inlet 61b of the three-way valve 61 is opened to the groundwater supply pipe 51 side and the inlet 61a of the hot water supply pipe 42 is closed And the groundwater supply light and the fluid distribution pipe 62 of the connection unit 60 are communicated with each other. Therefore, groundwater pumped by the groundwater pump 52 and groundwater collected in the groundwater supply pipe 51 from the groundwater well or the waterway can be introduced into the fluid circulation path 12.

Next, the discharge fan 34 installed in the inner space of the greenhouse 2 is operated to guide the inner space of the greenhouse 2 to the gas supply path and to flow into the gas circulation path 14.

Heat exchange occurs between the inner space of the greenhouse 2 passing through the gas circulation passage 14 and the groundwater passing through the fluid circulation passage 12 through the partition wall 16 provided inside the heat exchange section 10. That is, the heat of the inner space of the greenhouse 2 is transferred to the groundwater, the temperature of the groundwater increases, and the temperature of the inner space of the greenhouse 2 decreases.

Radiation heat transferred from groundwater passing through the gas circulation path 14 of the heat exchange unit 10 and the inner space of the greenhouse 2 through the fluid circulation path 12 and stored on the bottom surface of the greenhouse 2 during the heat exchange, It is possible to radiate to the inner space of the greenhouse 2 and perform cooling for the inner space of the greenhouse 2.

Next, the groundwater passing through the fluid circulation path (12) flows into the groundwater well or the water tank through the groundwater recovery pipe (53) and is reused. The three-way valve 64 opens the outlet 64c on the side of the groundwater return pipe 53 so that the groundwater passing through the fluid circulation path 12 can flow into the groundwater return pipe 53, And closes the outlet 64b.

The inner space of the greenhouse 2 that has passed through the gas circulation path 14 is discharged to the gas return pipe 31 and then passes through the discharge hole of the injection hole 32 and the greenhouse 2, Respectively. Therefore, cooling of the inner space of the greenhouse 2 can be performed by introducing the inner space of the greenhouse 2 whose temperature has been reduced by the heat exchange with the groundwater, into the inner space of the hot water again.

As described above, according to the preferred embodiment of the present invention, the floor radiation cooling and air conditioning system 1 induces groundwater and the inner space of the greenhouse 2 to the bottom surface of the greenhouse 2 to perform heat exchange, And cooling by air conditioning in which air is introduced can be performed at the same time. Therefore, compared with the case where the cooling is performed by using the fossil fuel and electricity, the thermal efficiency is high, so that the cooling cost can be reduced and the environmental pollution can be prevented by performing the cooling using the ground water.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

1: Floor Radiant Heating & Cooling System 2: Greenhouse
10: Heat exchanging part 12: Fluid circulation path
14: gas circulation passage 16: partition wall
20: heat source unit 30: air conditioning unit
31: gas recovery pipe 32: injection hole
33: gas supply pipe 34: exhaust fan
35: Guide hole 36: Gas distribution pipe
40: solar heat source 41: solar heat collecting plate
42: hot water supply pipe 43: bypass pipe
44: auxiliary boiler 45: hot water temperature sensor
46: Hot water pump 47: 3-way valve
48: Hot water return pipe 50: Ground water cold source
51: ground water supply pipe 52: ground water pump
53: groundwater recovery pipe 60: connection part
61, 64: three-way valve 62: fluid distribution pipe
63: Fluid recovery pipe

Claims (12)

A fluid circulation path through which the fluid can circulate and a gas circulation path through which the gas can circulate and heat exchange is performed between the gas and the fluid and is embedded in at least one of a bottom surface and a wall surface of the facility, A heat exchanger for radiating radiant heat radiated by the fluid into the internal space of the facility;
A heat source connected to the fluid circulation path and selectively supplying hot water or cold water to the fluid circulation path; And
And an air conditioning unit connected to the gas circulation path and configured to introduce the gas heat-exchanged with the fluid in the heat exchange unit into the internal space of the facility. The method according to claim 1,
The heat source unit includes:
A solar heat source installed on at least one of the outside and the inside of the facility and having a solar heat collecting plate capable of collecting solar heat and a hot water supply pipe capable of generating hot water by receiving solar heat collected from the solar heat collecting plate;
An underground water cooler having an underground water supply pipe for collecting underground water of the facility; And
And a connection unit selectively connected to the hot water supply pipe or the groundwater supply pipe to selectively supply hot water or ground water to the fluid circulation path. 3. The method of claim 2,
The solar heat source,
And an auxiliary boiler for reheating the hot water of the hot water supply pipe and a bypass pipe for bypassing the hot water of the hot water supply pipe to the auxiliary boiler and then flowing the reheated hot water back into the hot water supply pipe. Floor-to-floor air-conditioning and air-conditioning system. The method of claim 3,
The solar heat source,
Wherein the bypass pipe is configured to bypass the hot water of the hot water supply pipe to the auxiliary boiler when the temperature of the hot water of the hot water supply pipe is lower than a predetermined temperature, And the air-conditioning and air-conditioning system. 3. The method of claim 2,
In the groundwater cool source,
Further comprising a groundwater pump capable of pumping groundwater into the groundwater supply pipe. 3. The method of claim 2,
The connecting portion
And a discharge valve capable of discharging hot water or ground water to the outside. The method according to claim 1,
The heat-
Wherein the inner space is partitioned into the gas circulation path and the fluid circulation path by partition walls provided inside the partition wall, and the gas and the fluid are heat-exchanged through the partition wall. 8. The method of claim 7,
The double-
Wherein the at least one of the first and second heat exchangers is made of at least one of metal and synthetic resin. The method according to claim 1,
The air-
A gas recovery pipe connected to the gas circulation path to receive the gas exchanged with the fluid from the gas circulation and embedded in at least one of a bottom surface and a wall surface of the facility; And
And a spray hole formed through the gas return pipe and capable of spraying the gas flowing through the gas return pipe toward the outside,
Wherein the facility is provided in at least one of the bottom surface and the wall surface and is provided with an inflow hole capable of communicating the injection hole with the internal space of the facility and allowing the gas injected from the injection hole to flow into the internal space of the facility Hole for cooling and heating the floor. The method according to claim 1,
The air-
Further comprising: a gas supply pipe capable of supplying a vapor of the facility to the gas circulation unit,
Wherein the facility further comprises a discharge hole communicating the inner space and the gas supply pipe to discharge the inner air of the facility to the gas supply pipe. 11. The method of claim 10,
Wherein the discharge hole is formed in a ceiling of the facility. 11. The method of claim 10,
The air-
Further comprising a discharge fan installed in the internal space of the facility and capable of guiding the inside of the facility to the gas supply pipe.

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