KR100774241B1 - A floor cooling system - Google Patents

Abstract

The present invention relates to a cooling system capable of cooling the floor by using the coolness of the water supplied from the outside. Such a cooling system includes a floor pipe 10 installed on a floor F or a wall of a building inhabited by a person; A use pipe 20 connected to the outlet 10b of the bottom pipe 10 and connected to the kitchen or the toilet; A supply pipe 30 connected to the inlet 10a of the bottom pipe 10 to supply water from the outside; A boiler pipe 40 connected to the inlet 10a and the outlet 10b of the bottom pipe 10 and connected to the boiler B to provide heating water; And a flow path conversion valve 50 for selectively connecting the inlet 10a of the bottom pipe 10 to any one of the supply pipe 30 and the boiler pipe 40.

Description

Air Conditioning System {A FLOOR COOLING SYSTEM}

The present invention relates to a cooling system capable of cooling the floor by using the coolness of the water supplied from the outside.

When the temperature rises in midsummer, the air conditioner is usually operated to cool. The air conditioner enables cooling by forcibly circulating the cooled air inside the residential space after cooling the air.

However, as described above, in the case of a cooling method using an air conditioner, a lot of energy is consumed for cooling, which causes a lot of economic burden. In addition, since the circulating cooling air becomes very dry, the use of air conditioning for a long time caused cooling diseases such as nasal mucosa, allergic rhinitis, cold, and various bronchitis. In addition, if the air-cooling heat exchanger is not cleaned frequently, various bacteria or molds parasitic in the heat exchanger are circulated with the cooled air, thereby causing serious health hazards to the inhabitants.

Ondol, on the other hand, is a Korean indigenous method, closely related to the lifestyle of Korean people, and used in all private houses. Ondol's chananan principle uses heat conduction. When fire is introduced into a wide stone underneath the floor, the temperature of the stone increases, and the heat emitted from the heated stone heats the floor. The air in contact with the floor is heated, resulting in heating.

By the way, the method of heating the floor by the above-mentioned ondol has been adopted in many homes, but the method of cooling the floor by cooling the floor has not been known until now.

The present invention was created in order to achieve the above object, while providing a cooling system that can cool the floor without using energy by using cold water supplied from the outside while using the bottom pipe embedded in the existing floor as it is. It aims to do it.

Another object of the present invention is to provide a cooling system using geothermal heat, which can fundamentally prevent cooling diseases and bacterial diseases by preventing air from drying and preventing the occurrence of various bacteria and molds in the cooling process. do.

In order to achieve the above object, the cooling system according to the present invention,

Floor piping 10 is laid on the floor (F) of the building inhabited; Use pipe 20 connected to the outlet (10b) of the bottom pipe 10 to the kitchen or toilet; A supply pipe 30 connected to the inlet 10a of the bottom pipe 10 to supply water from the outside; A boiler pipe 40 connected to the inlet 10a and the outlet 10b of the bottom pipe 10 and connected to the boiler B to provide heating water; And a flow path conversion valve (50) for selectively variablely connecting the inlet (10a) of the bottom pipe (10) with any one of the supply pipe (30) or the boiler pipe (40).

In the present invention, the flow path conversion valve 50 is a three-way valve of the solenoid type operated by electricity; And an external air temperature sensor 60 for sensing an ambient temperature, and a controller 70 for operating the flow path conversion valve 50 in association with a signal generated by the external air temperature sensor 60.

In the present invention, the outside temperature sensor 60 and the control unit 70 may be replaced by a temperature sensor and a controller built in the boiler.

In the present invention, as the inlet (10a) and the outlet (10b) of the bottom pipe 10 is connected, respectively, the storage tank 90 is stored and the water passing through the bottom pipe 10, and the storage tank 90 And a circulation pump 100 installed between the bottom pipe 10 and circulating the water stored in the reservoir 90, a refrigeration air conditioner 110 for cooling the water stored in the reservoir 90, and It further includes a reservoir temperature sensor 120 for measuring the temperature of the water stored in the reservoir 90 to generate a signal for operating the refrigeration air conditioner (110).

The cooling system according to the present invention can cool the floor without consuming energy by flowing cold water supplied from the outside to the floor pipe embedded in the floor (including walls and ceilings) of the inhabited building. In addition, by using the existing floor piping as it is possible to enable cooling at the same time can be heated in winter. In addition, since the air is in contact with the floor and the wall to naturally cool the air, the air can be prevented from drying during the cooling process, and the occurrence of bacteria and mold can be prevented, thereby threatening cooling diseases and various bacterial diseases. Protect residents from

Hereinafter, a cooling system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a cooling system according to the present invention. As shown, the cooling system according to the present invention, the floor pipe 10 is laid on the floor (F) of the building inhabited; A use pipe 20 connected to the outlet 10b of the bottom pipe 10 and connected to the kitchen or the toilet; A supply pipe 30 connected to the inlet 10a of the bottom pipe 10 to supply water from the outside; A boiler pipe 40 connected to the inlet 10a and the outlet 10b of the bottom pipe 10 and connected to the boiler B to provide heating water; It includes; the flow path conversion valve 50 for selectively variable connecting the inlet (10a) of the bottom pipe 10 and any one of the supply pipe 30 or the boiler pipe (40).

Floor pipe 10 is built in the floor (F) of the building, in the cold water supplied from the supply pipe 30 in the summer flows to cool the floor (F), in winter heating from the boiler (B) supplied Water (hot water) flows to heat the floor (F). At this time, it is preferable that a wide stone (ball field) is built in the floor (F). In the present embodiment, but the bottom pipe 10 is described as being laid on the floor (F), it means that the floor (F) here means that the wall or cloth is included.

The end of the use pipe 20 is connected to the faucet 21 of the kitchen and the toilet, the washing machine or the toilet of the toilet. The water passing through the use pipe 20 is used by the residents during daily life, for example, washing dishes, washing, showering and washing.

The supply pipe 30 is for supplying water, which is pumped from an external water purification plant or underground, to the flow path conversion valve 50. Although the water temperature of the water supplied to the supply pipe 30 is different, the water supplied from the water purification plant is 22 ㅁ 1 ° C on a summer basis of 30 ° C. In case of groundwater, 10 ㅁ 3 ℃. That is, the water temperature via the supply pipe 30 is considerably lower than the temperature of the outside air.

The boiler pipe 40 is connected to the inlet and outlet of the bottom pipe 10 to supply the heating water in the winter. In the cooling system of the present application, the bottom pipe 10 is connected to the boiler pipe 40, thereby enabling heating even in winter.

The flow path conversion valve 50 prevents cold water from flowing into the boiler pipe 40 when the cold water supplied from the outside flows into the bottom pipe 10, and is supplied when the heating water flows into the boiler pipe 40. It is a three-way valve to prevent the external cold water flowing through the pipe 30 to flow to the bottom pipe (10). That is, the flow path conversion valve 50 is a three-way valve to connect the inlet 10a of the bottom pipe 10 with the supply pipe 30 or the boiler pipe 40 by manual operation of the occupant.

At this time, the flow path conversion valve 50 may be automatically operated rather than manual. To this end, the flow path conversion valve 50 uses a three-way valve of the solenoid type electrically operated. And, the cooling system of the present application. It further includes a control unit 70 for operating the flow path conversion valve 50 in conjunction with the outside air temperature sensor 60 for sensing the ambient temperature, and the signal generated from the outside air temperature sensor 60.

The outside air temperature sensor 60 senses the temperature of the upper portion of the floor F, so that it is possible to know whether the season is required for cooling or the season for heating. The temperature of outside air is 25 degreeC or more normally in the summer which requires cooling, and is 15 degreeC or less in the winter which requires heating.

The outside air temperature sensor 60 senses this when the temperature of the outside air is 25 ° C. or more, and sends a corresponding signal to the control unit 70. In response to the signal, the control unit 70 operates the flow path conversion valve 50 to supply a pipe. 30 and the bottom pipe 10 to be connected. Accordingly, the inlet 10a of the bottom pipe 10 and the boiler pipe 40 are blocked. In this case, the occupant is using the water through the use pipe 20 during the daily life, the cold water supplied to the supply pipe 30 is the bottom pipe 10, while the heat around the bottom pipe 10 It absorbs and cools the floor F.

On the other hand, the outside temperature sensor 60 senses this when the temperature of the outside air is less than 15 ℃ sends a corresponding signal to the control unit 70, in conjunction with the signal control unit 70 operates the flow path conversion valve (50) The boiler pipe 40 and the bottom pipe 10 to be connected. Accordingly, the inlet 10a of the bottom pipe 10 and the supply pipe 30 are blocked. In this case, the heating water supplied from the boiler B may be heated by applying heat to the floor F while circulating the bottom pipe 10.

In the drawings of this embodiment, the outside air temperature sensor 60 and the control unit 70 is shown separately from the boiler (B), but this is to facilitate the description, the outside air temperature sensor 60 and Of course, the control unit 70 may be replaced by a temperature sensor and a controller built in the boiler.

The cooling system of the present application may further include an auxiliary cooling unit for circulating cold water in order to more effectively cool. The auxiliary cooling unit is connected to the inlet 10a and the outlet 10b of the bottom pipe 10, respectively, the storage tank 90, the storage tank 90 and the bottom through which the water passing through the bottom pipe 10 is stored. A circulation pump 100 installed between the pipes 10 to circulate the water stored in the storage tank 90, a refrigeration air conditioner 110 for cooling the water stored in the storage tank 90, and stored in the storage tank 90. The storage tank temperature sensor 120 for generating a signal for automatically operating the refrigeration air conditioner 110 by measuring the temperature of the water may be further included.

The refrigeration air conditioner 110 is located in the storage tank 90 to absorb the heat of the stored water to vaporize the refrigerant and the high temperature and low pressure installed in the storage tank 90 via the evaporation pipe 111 Compressor 112 for compressing the refrigerant gas into a high pressure gas, a radiator 113 for discharging the refrigerant heat to the outside as condensation heat while changing the refrigerant gas of high temperature and high pressure into a high-pressure liquid refrigerant, and the evaporation tube 111 The high pressure liquid refrigerant is introduced to the expansion valve 114 to lower the pressure to facilitate the evaporation, the configuration of the refrigeration air conditioner 110, so the detailed description thereof will be omitted.

By employing the refrigeration air conditioner of this structure, it is possible to lower the temperature of the water stored in the reservoir (90). In particular, when the temperature of the water becomes a set temperature, for example, the image 5 ° C or more, the storage tank temperature sensor 120 senses it and transmits a corresponding signal to the control unit 70, the control unit 70 controls the refrigeration air conditioner 110 It works. When the temperature of the stored water is 10 ° C. or less, the controller 70 stops the operation of the refrigeration air conditioner 110.

The auxiliary cooling unit is preferably operated at night when the electric charge is low to lower the temperature of the water stored in the reservoir (90).

According to the above structure, when the occupant uses the faucet 21 installed at the end of the use pipe 20 or the toilet of the toilet, the external cold water (direct water) supplied from the supply pipe 30 is the bottom pipe 10 Via). In this process, the bottom pipe 10 is cooled by cold water, and thus the bottom F is cooled.

On the other hand, the water passing through the bottom pipe 10 becomes lukewarm because it absorbs heat from the bottom F. This lukewarm water makes the occupant more comfortable when taking a shower and increases the washing efficiency when washing.

When the heating season is to be recommended, the flow path conversion valve 50 is automatically or manually operated to connect the inlet 10a of the bottom pipe 10 to the boiler pipe 40. In this case, the heating water supplied from the boiler B heats the floor F while circulating the bottom pipe 10.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a block diagram of a cooling system according to the present invention.

<Description of Symbols for Major Parts of Drawings>

10 ... floor piping 1 Oa ... entrance

10b ... outlet 20 ... used piping

21 ... faucet 30 ... supply piping

40 ... boiler piping 50 ... euro conversion valve

60 ... outside temperature sensor 70 ... control unit

90 ... reservoir 100 ... circulation pump

110 ... Refrigeration and Air Conditioner 120 ... Storage Tank Temperature Sensor

Claims (4)

Floor pipe 10 which is laid on the floor (F) or wall of the inhabited building; Use pipe 20 connected to the outlet (10b) of the bottom pipe 10 to the kitchen or toilet; A supply pipe 30 connected to the inlet 10a of the bottom pipe 10 to supply water from the outside; A boiler pipe 40 connected to the inlet 10a and the outlet 10b of the bottom pipe 10 and connected to the boiler B to provide heating water; And a flow path conversion valve (50) for selectively variablely connecting the inlet (10a) of the bottom pipe (10) with any one of a supply pipe (30) or a boiler pipe (40). The method of claim 1, The flow path conversion valve 50 is a three-way valve of the solenoid type operated by electricity; And an external air temperature sensor 60 for sensing an ambient temperature, and a control unit 70 for operating the flow path conversion valve 50 in association with a signal generated from the external air temperature sensor 60. Cooling system. The method of claim 1, Cooling system, characterized in that the outside temperature sensor 60 and the control unit 70 is replaced by a temperature sensor and a controller built in the boiler. The method of claim 1, As the inlet 10a and the outlet 10b of the bottom pipe 10 are connected, respectively, a reservoir 90 for storing water via the bottom pipe 10, the reservoir 90 and a bottom pipe ( 10 is installed between the circulation pump 100 for circulating the water stored in the reservoir 90, the refrigeration air conditioner 110 for cooling the water stored in the reservoir 90, and in the reservoir 90 Cooling system, characterized in that it further comprises a storage temperature sensor 120 for measuring the temperature of the stored water to generate a signal for operating the refrigeration air conditioner (110).

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