KR101214350B1 - Cooling apparatus for room - Google Patents

Abstract

PURPOSE: A cooling device for an indoor space is provided to reduce manufacturing costs and power consumption by simplifying the structure of the device compared with an air conditioner. CONSTITUTION: A cooling device for an indoor space comprises a coolant tank(100), a cooling unit(400), a supply pipe(200), and a discharge pipe(300). The cooling unit generates cold air. The supply pipe supplies coolants from the coolant tank to the cooling unit. The discharge pipe discharges coolants from the cooling unit to the coolant tank. The cooling unit comprises an upper coolant container(420), a through hole, multiple coolant pipes(440), and a lower coolant container(450). The upper coolant container is connected to the supply pipe. The through hole penetrates through the bottom plate of the upper coolant container. The coolant pipes are connected to the bottom surface of the upper coolant container and extended downward. The lower coolant container is connected to the bottom ends of the coolant pipes and receives coolants therein.

Description

Indoor Cooling Unit {COOLING APPARATUS FOR ROOM}

The present invention relates to an indoor cooling device, and more particularly, to an indoor cooling device having a simpler structure than a general air conditioner and consuming less power.

9 is a circuit diagram illustrating a conventional air conditioner. The conventional air conditioner 1 will be described as follows.

A compressor (10) for compressing a refrigerant, which is a gas, into a high temperature liquid, a condenser (20) connected to the compressor (10) by piping, and dissipating the liquid refrigerant compressed by outside air, and the condenser (20). It is configured to include an evaporator 30 is connected to the pipe to the refrigerant to convert the refrigerant into a gas to absorb the surrounding heat. The evaporator 30 is connected to the compressor 10 by a pipe and is configured to transfer the expanded gas to the compressor 10. The refrigerant is composed of freon gas. The evaporator 30 is configured with a fan 33 for supplying cold air, and the condenser 20 is configured with a fan 23 to enable efficient heat dissipation.

Looking at the operation example of the air conditioner (1) as follows.

First, the compressor 10 compresses a refrigerant that is a gas so as to become a liquid phase. The liquid is still a hot liquid. The hot liquid is sent to the condenser 20 by the pressure of the compressor 10 to radiate heat from the condenser 20 to the outside. And it is sent to the evaporator 30 to absorb the surrounding heat while the phase change to gas, and then transferred to the compressor 10 to repeat the cycle.

That is, after absorbing heat from the evaporator 30, it functions as a heat pump for dissipating heat from the condenser 20, the evaporator 30 is placed indoors and the condenser 20 to the outside Because of the arrangement, the indoor heat is discharged to the outside.

At this time, the cold air is supplied from the evaporator 30 to the room by the respective fans 23, and the heat of the condenser 20 is radiated to the outside by the fan 33.

According to the background art, there are the following problems.

First, there is a problem in that a power consumption is burdened because a compressor is required and each fan is configured in an evaporator and a condenser. For example, it is unreasonable to use air conditioners like fans in the following season.

Second, there is a problem that the production cost is expensive because the structure of the compressor, the condenser, and the evaporator arranged outdoors.

Third, when the refrigerant is lost due to leakage, etc., there is a problem in that it is difficult for the general public to easily maintain the refrigerant.

An indoor cooling apparatus according to the present invention includes a coolant tank in which a coolant is accommodated, a cooler configured to receive a coolant from the coolant tank, and generate cool air therethrough, and a coolant connected to the coolant in the coolant tank. It comprises a supply pipe for supplying and the discharge pipe is connected to the refrigerant tank in the cooling unit for discharging the refrigerant.

In addition, the refrigerant tank includes a pump configured therein, and the pump and the supply pipe are connected to each other.

In addition, the cooling unit is connected to the supply pipe to receive a refrigerant, a through hole penetrated through the bottom plate of the upper refrigerant cylinder, a plurality of connected to the lower surface of the upper refrigerant cylinder extending downward to transfer the refrigerant And a lower coolant tube connected to a lower end of the coolant tube to accommodate a refrigerant discharged through the coolant tube, wherein the discharge tube is connected to the lower coolant tube, and the cooling unit And a fan configured to supply wind toward the refrigerant pipe.

In addition, the opening and closing plate is configured to be in close contact with the bottom plate of the upper refrigerant cylinder and the same through-holes correspond to, and the opening and closing plate is formed smaller than the bottom plate is configured to open and close the through hole by the transport.

In addition, a cooling tank configured inside the refrigerant tank to receive the cooling water, an inlet pipe connected to the cooling tank to penetrate the refrigerant tank, and configured to introduce the cooling water into the cooling tank, and connected to the cooling tank to the refrigerant tank. It is configured to include an outlet pipe configured to pass through the cooling water is discharged.

In addition, it is configured to include a filter fixed to the cooling unit to be disposed behind the fan.

Since the indoor cooling device according to the present invention has a simpler structure than an air conditioner, it requires less manufacturing cost, and there is no component that requires a large electric power, such as a compressor. That is, in the case of a general air conditioner, a fan must be mounted in the compressor, the evaporator, and the condenser, respectively, but in the present invention, only one fan and one pump are possible. Of course, the pump may also be configured to circulate the cooling water in the cooling tank, but when the ground water is used, the pump may be omitted since it is continuously supplied by water pressure. Therefore, since it does not require a compressor that consumes a lot of electricity, there is an effect of less power consumption than a general air conditioner.

1 is a perspective view showing an indoor cooling apparatus according to the technique of the present invention seen from the rear;
Figure 2 is a perspective view of the cooling unit of the indoor cooling apparatus according to the technique of the present invention as seen from the rear except for the cover.
3 is an exploded perspective view illustrating an upper part of a cooling unit configured in an indoor cooling device according to the present invention, and showing that the opening and closing plate is separated from the upper refrigerant container.
Figure 4 is a cross-sectional view showing that the transfer unit is mounted on the opening and closing plate in the indoor cooling apparatus according to the technique of the present invention.
Fig. 5 is a perspective view of a local cutaway showing a state in which an opening and closing plate is seated inside the upper refrigerant passage by cutting the upper refrigerant passage in the cooling unit of the indoor cooling apparatus according to the technique of the present invention.
FIG. 6 is a plan view of FIG. 5 seen from above; FIG.
Figure 7 is a perspective view showing the front of the cooling unit of the indoor cooling device according to the technique of the present invention with the cover omitted.
Figure 8 is an exploded perspective view showing a state in which the blade is separated from the cooling unit of the indoor cooling device according to the technology of the present invention.
9 is a circuit diagram showing a conventional air conditioner.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the indoor cooling device according to the technology of the present invention seen from the rear, FIG. 2 is a perspective view showing the cooling unit of the indoor cooling device according to the technology of the present invention except for a cover. 3 is an exploded perspective view illustrating an upper part of a cooling unit configured in an indoor cooling device according to the technology of the present invention, and showing that the opening and closing plate is separated from the upper refrigerant container, and FIG. 4 is an indoor cooling device according to the technology of the present invention. 5 is a cross-sectional view illustrating a state in which the transfer plate is mounted on the opening and closing plate, and FIG. 5 is a cutaway view of the upper refrigerant container in the cooling unit of the indoor cooling apparatus according to the present invention, and the opening and closing plate is seated inside the upper refrigerant container. FIG. 6 is a plan view showing the view of FIG. 5 from the top, and FIG. 7 is a front view of the cooling unit of the indoor cooling apparatus according to the technique of the present invention with the cover omitted. A perspective view of the present, and FIG. 8 will be described with an exploded perspective view showing a blade is removed from the cooling section of the interior of a cooling device according to the invention described.

The present invention is characterized in that the structure is configured to efficiently cool the indoor air by circulating a refrigerant as a simple structure compared to a general air conditioner.

To this end, the present invention is configured as follows.

A coolant tank 100 configured to receive a coolant is configured, and a coolant 400 configured to receive a coolant from the coolant tank 100 and pass through the coolant is configured to generate cold air, and in the coolant tank 100 It is configured to include a supply pipe 200 is connected to the cooling unit 400 to supply a coolant, and a discharge pipe 300 connected to the coolant tank 100 in the cooling unit 400 to discharge the coolant.

The refrigerant tank 100 includes, as an example, a pump 110 configured therein, and the pump 110 and the supply pipe 200 are connected to each other. The pump 110 is preferably an underwater pump as an example.

In addition, the cooling tank 120 is configured inside the refrigerant tank 120 may be further configured to receive a cooling water for cooling the refrigerant. In addition, the inlet pipe 130 is configured to be connected to the cooling tank 120 and penetrate the refrigerant tank 100 so that the cooling water is introduced into the cooling tank 120. The inlet pipe 130 is connected to the cooling tank 120. Since it passes through the refrigerant tank 100 is configured to include an outlet pipe 140 configured to discharge the cooling water.

The cooling unit 400 is connected to the supply pipe 200 is configured to the upper refrigerant cylinder 420 for receiving the refrigerant, the through penetrating so that the refrigerant flows into the bottom plate 425 of the upper refrigerant cylinder 420 A sphere 423 is formed. In addition, a plurality of refrigerant pipes 440 are connected to the lower surface of the upper refrigerant container 420 to communicate with the through hole 423 and extend downward to transfer the refrigerant. The coolant pipe 440 is, for example, a plate shape formed to extend in the front and rear, and is arranged to face a wide surface on the left and right sides. Therefore, it is comprised so that the area which contacts the wind supplied from the fan 500 mentioned later may be as wide as possible. In addition, the lower refrigerant pipe 450 is connected to the lower end of the refrigerant pipe 440, the refrigerant discharged through the refrigerant pipe 440 is accommodated. Of course, a through hole (not shown) is formed in the upper plate 453 of the lower coolant cylinder 450 to communicate with the coolant pipe 440. In addition, the discharge pipe 300 is connected to the lower refrigerant container 450 is configured.

In addition, the cooling unit 400 is configured to include a fan 500 configured to feed the wind toward the refrigerant pipe 440, for example, the fan 500 is a wind between the refrigerant pipe 440. It is arranged to the rear of the cooling unit 400 so that it can be fed. For example, the fan 500 may be fixed to the bar 503 fixed to the upper refrigerant container 420 and the lower refrigerant container 450. In addition, a filter 600 fixed to the upper refrigerant cylinder 420 and the lower refrigerant cylinder 450 may be configured to be located at the rear of the fan 500. Thus, the wind sucked through the fan 500 is configured to be filtered by the filter 600.

In addition, the upper refrigerant container 420 is configured with an air pipe 430 so that the refrigerant contained therein can be easily flowed downward through the refrigerant pipe 440.

In addition, the opening and closing plate 700 which is in close contact with the bottom plate 425 of the upper refrigerant container 420 and formed with the same through hole 710 as the through hole 423 is configured. And, since the opening and closing plate 700 is formed smaller than the bottom plate 425 is configured to open and close the through hole 423 by the transfer.

A transfer part 800 is further configured to transfer the opening / closing plate 700, and the transfer part 800 has a hole penetrated to the side of the upper coolant cylinder 420 and an upper coolant cylinder 420 to match the hole. A nut 810 attached to the outer side of the is configured. In addition, a nut 830 fixed to an upper surface of the opening and closing plate 700 is configured such that the nut 810 and the center line are the same. In addition, bolts 820 fastened to the respective nuts 810 and 830 are configured. A snap ring 840 fitted to the bolt 820 is formed at the front and rear of the nut 830 so that the opening and closing plate 700 can be moved back and forth by the forward and backward movement of the bolt 820.

In addition, a block 427 attached to the side surface of the upper refrigerant container 420 may be further configured so that the opening and closing plate 700 may be in close contact with the bottom plate 425. The block 427 is attached to the same side as the conveying direction of the opening and closing plate 700 is configured. Therefore, the opening and closing plate 700 is lifted up so that the phenomenon that the refrigerant flows more than necessary is configured to be prevented.

In addition, the front of the refrigerant pipe 440, that is, the opposite side of the fan 500, a plurality of blades 900 for adjusting the wind direction of the wind passing through the refrigerant pipe 440, the lower surface of the upper refrigerant cylinder 420 and the lower refrigerant cylinder It is mounted so that it may rotate to the upper surface of 450.

The blade 900 has a bar 920 connected in a horizontal state to each of the blades 900 at the rear to automatically rotate, and the disc 950 and the disc (pin) to the bar 920 950 is configured to include a step motor 940 fixed to the rotating shaft. The blade 900 and the rack 920 are each formed by a ring (910, 930) are connected to each other. Therefore, when the step motor 940 is rotated in the forward and reverse directions, the rotation angle of the blade 900 can be simultaneously adjusted by reciprocating the bar 920.

In addition, a box-shaped case 410 is formed to accommodate and cover the upper coolant cylinder 420, the coolant pipe 440, and the lower coolant cylinder 450. The case 410 is configured such that the air hole 421 penetrates a surface corresponding to the filter 600 so that air can be easily sucked. The case 410 is configured to expose the blade 900 to the front is configured to allow the wind of the fan 500 to be discharged forward.

Hereinafter, the operation of the present invention will be described.

First, the coolant tank 100 is preferably to be low temperature by being arranged in the basement or the ground. In addition, the cooling unit 400 is installed above the refrigerant tank 100 so that the refrigerant can be efficiently discharged by gravity to the building.

In addition, the refrigerant tank 100 is filled with a refrigerant, and the refrigerant may be ethylene glycol as an example, and mixing with water in a volume of 1: 1 is preferable because it has excellent fluidity and properties as a refrigerant. . However, of course, tap water or ground water may be used as the refrigerant.

The coolant may use general water, but the use of a coolant such as ethylene glycol may reduce the corrosion of the present invention, and has the advantage of rapidly absorbing heat and dissipating heat as compared to water.

In addition, the cooling tank 120 is configured to allow cold water to be always filled by allowing cold water such as groundwater to flow in and out, thereby efficiently cooling the refrigerant.

When power is applied to the fan 500 in this state, the air absorbed by the fan 500 is filtered through the filter 600 and is discharged between the refrigerant pipes 440.

In this case, electricity is applied to the pump 110 to supply and charge the refrigerant to the upper refrigerant container 420 through the supply pipe 200. Then, the coolant dropped downward through the through hole 710 of the opening and closing plate 700 and the through hole 423 of the upper coolant cylinder 420 is filled in the lower coolant cylinder 450. Then, the refrigerant is returned to the refrigerant tank 100 through the discharge pipe 300. This circulation is repeated continuously by the pump 110.

Therefore, the hot air in the room is filtered by the filter 600, and the heat retained while passing between the refrigerant pipes 440 is absorbed by the refrigerant to be converted into cold air, and foreign substances such as dust are filtered out. It is discharged to the outside. Thus, a comfortable environment is enabled while lowering the room temperature.

The refrigerant absorbing heat in the room is returned to the refrigerant tank 100 and then converted back to a low temperature by the cooling tank 120.

Ice may be added to the coolant tank 100 to cool the coolant more efficiently.

In addition, it is possible to adjust whether the through hole 423 overlaps the through hole 710 through the forward and backward transport of the opening and closing plate 700. Therefore, the amount of the refrigerant flowing down can be adjusted. That is, in order to quickly cool the indoor air, the through hole 423 and the through hole 710 overlap a lot, so that the heat of absorbed air can be absorbed efficiently. That is, the room temperature may be controlled by the operation of the opening and closing plate 700.

100: refrigerant tank 110: pump
200: supply pipe 300: discharge pipe
120: cooling tank 130: inlet pipe
140: outlet pipe 400: cooling unit
410: case 420: upper refrigerant container
421: air hole 423: through hole
425: bottom plate 427: block
430: air pipe 440: refrigerant pipe
450: lower refrigerant container 453: top plate
500: fan 503: bar
600: filter 700: opening and closing plate
710: through hole 800: transfer unit
810: nut 820: bolt
830: nut 840: snap ring
900: blade 910: ring
920 bar 930 ring
940: step motor 950: disc

Claims (6)

delete delete delete A refrigerant tank 100 in which a refrigerant is accommodated,
A cooling unit 400 configured to receive the coolant from the coolant tank 100 and to pass the coolant to generate cold air;
A supply pipe 200 connected to the cooling unit 400 in the refrigerant tank 100 to supply a refrigerant;
It is configured to include a discharge pipe 300 is connected to the refrigerant tank 100 in the cooling unit 400 to discharge the refrigerant,
The cooling unit 400 is connected to the supply pipe 200 and the upper refrigerant container 420 for receiving the refrigerant;
A through hole 423 penetrated through the bottom plate 425 of the upper refrigerant container 420;
A plurality of refrigerant pipes 440 connected to a lower surface of the upper refrigerant container 420 and extended downward to transfer the refrigerant;
It is connected to the lower end of the refrigerant pipe 440 is configured to include a lower refrigerant container 450 for receiving the refrigerant discharged through the refrigerant pipe 440,
The discharge pipe 300 is connected to the lower refrigerant container 450 is configured,
It comprises a fan 500 configured to feed the wind toward the refrigerant pipe 440 in the cooling unit 400,
The opening and closing plate 700 which is in close contact with the bottom plate 425 of the upper coolant cylinder 420 and is formed to correspond to the same through hole 710 as the through hole 423,
Since the opening and closing plate 700 is formed smaller than the bottom plate 425, the indoor cooling device, characterized in that configured to open and close the through-hole (423) by the transfer. 5. The method of claim 4,
The refrigerant tank 100 includes a pump 110 configured therein,
Indoor pumping device, characterized in that the pump 110 and the supply pipe 200 is configured to be connected. delete

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