KR20010002345U - Cooling Device Using Air - Google Patents

Abstract

The present invention relates to a cooling apparatus using air, the air supply means for supplying air in the atmosphere at a predetermined pressure;

The air supplied from the air supply means 10 is introduced through the inlet pipe 21, and the introduced air is vortexed along the inner wall and reflected at the end to be taken out into the inlet pipe 21 again. 22) a tubular heat exchange base body 20 through which;

Vortex means positioned within the inlet pipe 21 of the heat exchange body 20 to vortex the air supplied from the air supply means 10 to vortex in the working chamber 22 of the heat exchange body 20. 30;

In the configuration of the cooling tube 40 to allow the air reflected from the working chamber 22 of the heat exchange base body 20 to be cooled by heat exchange with the outside vortex air;

The vortex means 30 is a plurality of vortex passages 31 in the radial direction of the vortex member 33 installed in the tangential position of the inlet pipe 21 into the heat exchange body 20 is dug to induce compressed air to vortex In addition, the cooling pipe 40 is partially extended toward the inside of the heat exchange main body 20 by penetrating the center of the vortex member 33, thereby compressing air in the air and forcibly vortexing the heat exchange chamber. By passing through, the vortex air and the reflected air can obtain cooling air by centrifugation and heat exchange.

Therefore, since no harmful refrigerant is used, there is no concern about environmental pollution, and there is no need for a device for recycling the refrigerant, thereby facilitating installation and operation.

In addition, as a result of inducing forced vortex evenly in several places by the vortex member 33, the overall cooling performance according to the increase of the vortex efficiency is improved.

In addition, a portion of the cooling tube 40 penetrates the vortex member 33 and is partially extended to the inside of the heat exchange main body 20 to smoothly induce the discharge of the cooling air and reduce the discharge resistance of the cooling air. It is a very useful design, such as to increase the overall efficiency with a smooth flow.

Description

Cooling Device Using Air

The present invention relates to a cooling apparatus using air, and more particularly, it is designed to obtain a more efficient cooler using air without using a harmful refrigerant that destroys ozone.

In general, air conditioners of various industrial, domestic, and automobiles are provided with a cooling device for indoor cooling.

Conventionally, the cooling device is configured to have a cooling function by cooling a cooling coil or the like by using vaporization heat that takes away heat from the surroundings when the refrigerant is vaporized, and passing the cooling coil through the cooling water or by blowing it into a fan.

Conventionally, the refrigerant having such a cooling function mainly uses ammonia and carbon fluorochloride, or so-called Freon gas, which is a cause of environmental pollution such as destroying the ozone layer, which is regulated by the Montreal Convention. .

In addition, the conventional refrigerant has a problem that the device is complicated and consumes a lot of energy since a compression means such as a compressor is required as a function for forming a recycle again.

On the other hand, in order to solve this problem, as shown in Korean Patent Application Publication No. 93-2768, when blowing with compressed air without vortex, the pressure in the pipe wall is high due to the centrifugal force and the pressure in the center is low, so that the energy enthalpy and The so-called vortex tube has been proposed to induce low temperature air by the relationship of speed.

The performance of this vortex tube is determined by the pressure and vortex velocity of the compressed air.

However, according to the conventional Korean Patent Publication No. 93-2768, the problem is that the vortex efficiency and the overall efficiency are deteriorated by constituting the compressed air to vortex by installing the nozzles tangentially to the pipe wall under conditions for vortexing the compressed air. This was there.

An object of the present invention is to provide a cooling device using air without any concern about environmental pollution.

Another object of the present invention is to provide a cooling device using air which is simple and has excellent overall cooling efficiency due to the increase in vortex efficiency of compressed air.

Another object of the present invention is to provide a cooling device using air that is excellent in economic efficiency because there are few parts, there is no fear of failure, easy maintenance and easy installation.

Figure 1 is a longitudinal sectional view showing the configuration of the main part of the present invention

Figure 2 is a cross-sectional view of Figure 1 showing the configuration of the vortex means of the present invention

Figure 3 is an apparatus of an embodiment showing a state of cooling the coolant by the cooling device of the present invention

Figure 4 is an apparatus of an embodiment showing a state used as the indoor unit of the air conditioner by the cooling device of the present invention

5 is a perspective view showing the configuration of the vortex means of the present invention

Explanation of symbols for main parts in drawings

10-Air supply means 20-Heat exchanger base

21-Inlet 22-Operating Room

30-Vortex Flow 31-Vortex Passage

33-Vortex member 40-Cooling tube

50-regulating valve

The object of the present invention, the air supply means for supplying air in the atmosphere at a predetermined pressure;

The air supplied from the air supply means 10 is introduced through the inlet pipe 21, and the introduced air is vortexed along the inner wall and reflected at the end to be taken out into the inlet pipe 21 again. 22) a tubular heat exchange base body 20 through which;

Vortex means positioned within the inlet pipe 21 of the heat exchange body 20 to vortex the air supplied from the air supply means 10 to vortex in the working chamber 22 of the heat exchange body 20. 30;

In the configuration of the cooling tube 40 to allow the air reflected from the working chamber 22 of the heat exchange base body 20 to be cooled by heat exchange with the outside vortex air;

The vortex means 30 is a plurality of vortex passages 31 in the radial direction of the vortex member 33 installed in the tangential position of the inlet pipe 21 into the heat exchange body 20 is dug to induce compressed air to vortex Then, the cooling pipe 40 is partially extended toward the inside of the heat exchanging body 20 through the center of the vortex member 33.

Therefore, when the fast air is vortexed and reflected, the outside vortex air and the reflected air passing through the inside exchange heat with each other, and cool air is generated to blow the cooling pipe 40 that guides the cold air to the indoor fan or to be immersed in the coolant. By using it as the cooling water of the air conditioner or various devices.

According to this apparatus, since no harmful refrigerant is used, there is no concern about environmental pollution, and there is no need for a device for recycling the refrigerant, so the equipment and operation are easy and economical.

In addition, as a result of inducing forced vortex evenly in several places by the vortex member 33, the overall cooling performance according to the increase of the vortex efficiency is improved.

In addition, a portion of the cooling pipe 40 penetrates the vortex member 33 and is partially extended to the inner side of the heat exchanging body 20 to smoothly induce the discharge of cooling air and reduce the discharge resistance of the cooling air. Smooth flow can increase overall efficiency.

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

1 is a cross-sectional view showing the configuration of the present invention, the compressed air drawn by the air supply means 10 into the heat exchange main body 20 is rotated (vortexed) by the vortex means 30 at a high speed to the working chamber It can be seen that the reflected air is reflected at the end of (22) and reflected air crosses each other to the center of the vortex air.

At this time, the rotational direction of the vortex air and the reflected air is the same, but only the direction of travel is reversed and another rotational air is generated, and since the rotational direction is the same, the rotational speed of the vortex air and the reflected air is combined to a faster speed Proceeds to the inlet of the cooling tube (40).

2 shows a cross-sectional view of the structure of the vortex means 30.

3 is a device diagram showing a state in which the cooling tube 40 is locked to cool the cooling water by the device of the present invention, Figure 4 is a cooling fan (40) is a blower fan for the indoor unit (1) function of the air conditioner ( The state arranged in front of 2) is shown in the apparatus diagram.

5 is a perspective view showing the shape of the vortex member 33, and a hole is drilled in the center to penetrate the cooling tube 40, and shows a structure in which several vortex passages 31 are radially excavated.

As shown in this figure, the device of the present invention induces the cooled air by mutual heat exchange and centrifugation between the vortex air vortexing outside the working chamber 22 of the heat exchange base 20 and the reflected air reflected at the end. It is to be used in an air conditioning device such as cooling water or air conditioning.

The air supply means 10 for injecting air into the heat exchange body 20 is heat exchanged by a guide of a hose or pipe by a forced air supply such as a blower 11 or an air compressor that blows atmospheric air at a predetermined pressure. It is injected into the base 20.

As shown in FIG. 1, the heat exchange main body 20 has a diameter at which the air supplied from the air supply means 10 is introduced through the inlet pipe 21 at the inlet, and in the center, the vortex air and the reflected air can cross each other. The working chamber 22 having a circular hole shape with a smooth surface is drilled.

The end of the working chamber 22 is blocked so that when the incoming air is strongly vortexed by the vortex means 30, it is hit at its end and the reflected air reflected from the center can be sent back to the entrance side through the center of the vortex air. .

The reflected air is moved by the central vortex passage mainly because of the strong power output to move forward, and the incoming air is moved through the outer space of the reflected air by the vortex induction.

In this way, the incoming air is moved at a relatively slow speed along the pipe wall of the working chamber 22 and the blowing speed of the reflected air passing through the center of the working chamber 22 is rapidly acted, so that the pressure is high in the pipe wall of the working chamber 22.

And at the center, as the speed increases, the pressure decreases.

Therefore, cold air can be obtained by the difference between enthalpy and speed.

At this time, in order to control the heat efficiency and the like reflected in the working chamber 22, the end of the working chamber 22 is preferably screwed to the control valve 50 to the heat exchange base 20.

Then, the exhaust pipe 23 communicating with the working chamber 22 is formed to communicate with the outside, and the outlet gap is adjusted by adjusting the screw of the regulating valve 50 so that By adjusting the amount of reflection, the overall cooling efficiency can be controlled.

That is, by adjusting the clearance of the exhaust pipe 23 with the control valve 50, the amount of air reflected by the discharge of a part of the air vortexed from the vortex means 30 back to the outside, and the working chamber ( 22) can be varied in length.

Therefore, by varying the ratio of the reflected air to the vortex air and the length of the working chamber 22, the heat exchange efficiency can be lowered to induce a change in the efficiency of the cooled air, thereby controlling the desired output cooling temperature by using this function. There is a number.

As such, the vortex air for vortexing the air injected into the outside is made by the vortex means 30.

As shown in FIG. 1, the vortex means 30 acts to induce vortices when the air introduced through the inlet pipe 21 passes through the vortex passage 31 which is radially displaced into the vortex member 33 at several places. The air is moved in a vortex state along the inner wall of the seal 22.

At this time, a space is formed in the center of the vortex air, and when the reflected air is moved to the center space after the vortex air that hits the tip of the control valve 50 is reflected at the end of the working chamber 22, the vortex is strongly outside. Heat is taken between the vortex air and the reflected air, which loses heat due to the difference in speed and enthalpy.

Cooling air cooled by the heat exchange is guided through a cooling tube 40 which is partially extended through the vortex member 33 at the inlet side, and the cooling tube 40 is coolant when cooling water is desired as shown in FIG. The cooling tube 40 cooled by the cooling air by being immersed in the inside has a function of cooling the cooling water.

It is used, for example, to form cooling water for cooling the device, such as in an automobile engine.

In addition, as shown in FIG. 4, the cooling pipe 40 is guided to the inside of the indoor unit 1, and the cold air is blown to the blower fan 2 with the cooling fin attached to increase the cooling efficiency. It can be used as a function of an air conditioner such as air conditioning.

The inlet of the cooling tube 40 allows the cooled reflected air to enter the state of entering the working chamber 22, and penetrates the center of the vortex means 30 to the desired destination, that is, the coolant and the indoor unit. Will be arranged.

At this time, the end of the cooling pipe 40 may be returned to send to the inlet of the air supply means 10, but since the cooling air is compressed air in the air, there is no need for piping equipment for recycling, and the atmosphere is kept again. It may be released in the middle.

On the other hand, the rear end of the vortex means 30 is screwed with a cap 60 to prevent the sealing of the working chamber 22 and the separation of the vortex means 30.

According to the experiment, the cooling air can achieve high efficiency cooling performance between 30 ° C. and 70 ° C., and can be applied to the cooling water and various air conditioners for indoor cooling of various equipments required for automobile engine.

According to the configuration of the present invention as described above, by passing through the heat exchange chamber that is forced to vortex by compressing the air in the atmosphere, the vortex air and the reflected air can be obtained by the centrifugal separation and heat exchange.

Therefore, since no harmful refrigerant is used, there is no concern about environmental pollution, and there is no need for a device for recycling the refrigerant, thereby facilitating installation and operation.

In addition, as a result of inducing forced vortex evenly in several places by the vortex member 33, the overall cooling performance according to the increase of the vortex efficiency is improved.

In addition, a portion of the cooling tube 40 penetrates the vortex member 33 and is partially extended to the inside of the heat exchange main body 20 to smoothly induce the discharge of the cooling air and reduce the discharge resistance of the cooling air. It is a very useful design, such as to increase the overall efficiency with a smooth flow.

Claims (1)

Air supply means (10) for supplying air in the atmosphere at a predetermined pressure; The air supplied from the air supply means 10 is introduced through the inlet pipe 21, and the introduced air is vortexed along the inner wall and reflected at the end to be taken out into the inlet pipe 21 again. 22) a tubular heat exchange base body 20 through which; Vortex means positioned within the inlet pipe 21 of the heat exchange body 20 to vortex the air supplied from the air supply means 10 to vortex in the working chamber 22 of the heat exchange body 20. 30; In the configuration of the cooling tube 40 to allow the air reflected from the working chamber 22 of the heat exchange base body 20 to be cooled by heat exchange with the outside vortex air; The vortex means 30 is a plurality of vortex passages 31 in the radial direction of the vortex member 33 installed in the tangential position of the inlet pipe 21 into the heat exchange body 20 is dug to induce compressed air to vortex The cooling device using air, characterized in that the cooling pipe (40) is partially extended toward the inside of the heat exchange main body (20) through the center of the vortex member (33).