KR20120008805A - Vortex Tube - Google Patents

Abstract

PURPOSE: A vortex tube is provided to maximize the torque of compressed air provided to a swirl chamber. CONSTITUTION: A vortex tube comprises a vortex housing(1), a cold air discharge trap(2), and a hot air discharge trap(3). The vortex housing is equipped with a compressive air inlet(11), a cool air outlet(12), a hot air outlet, and a cooling part. The cooling part is formed in the outer circumference of a swirl chamber and meets a heat radiation fin(14) at right angle. The cold air discharge trap is equipped with a rotation groove(21) and a cold air exhaust passage. The cold air exhaust passage communicates with the outside in the inner circumference of the swirl chamber.

Description

Vortex Tube

The present invention relates to a vortex tube that rotates compressed air at a high speed to separate cold and hot air by vortex phenomena, and to obtain only cold air separately in the separation process so as to be used as a refrigerant.

In general, Vortex Tube is a cooling device with low cost, high reliability, and no need for maintenance that can obtain cold air only by compressed air of compressor used in industrial field without any mechanical driving part. Is -46 ℃ to + 127 ℃, cold air flow control range from 28 SLPM to 4248 SLPM, and maximum cooling capacity reaches 2571 Kcal / hr.

Therefore, it is effectively used to create a pleasant environment by supplying cold air locally to the harsh environment that may be generated by heat such as casting, glass, steel, ceramics, or electrical equipment, equipment, and facilities.

Recently proposed vortex tube was a "Vortex tube" of the patent registration No. 0797653 to the patent registration No. 0880276, and compares the pre-registered invention with the present invention as follows.

First, in the case where the structure of injecting the compressed air to rotate into the vortex chamber is the same as the former, the compressed air supplied into the vortex chamber is formed by rotating the injected air by forming an injection hole up and down in the rotation direction of the rotating chamber. Due to the weak rotational force, it was difficult to completely separate the cold and hot air due to vortex phenomena, and in the latter case, it was rotated by the radial groove formed in the disc, but the compressed air reaches the circulating space. Was weak and pressure and supply in the manner that is consumed.

 In addition, when the cold and the heat are separated by the rotary air flow inside the vortex chamber, the former and the latter are equally hit by the entire wall of the end of the vortex chamber, so that only the backflow efficiency and the cold air cannot be obtained effectively.

In the process of acquiring only cold air and discharging heat, in the case of the former, the entire wall at the end of the vortex chamber is discharged to the cold air including heat, and in the latter case, without the discharge of heat. Because the vortex chamber is air cooled, there was a closed end that eroded the cold air while remaining in the vortex chamber.

In addition, if the cooling method of the outer circumferential surface of the vortex chamber is the former, the heat discharged to the rear of the vortex chamber is transferred to the cooling fin, and the rear side becomes hot. In the latter case, the cooling plate is air-cooled by using a part of the compressed air injected. The tip is cooled by the supply of compressed air, but the rear end is low in its effect, as well as hot, as a part of the compressed air introduced for cooling passes through a narrow passage, causing severe noise.

KR 10-0797653 "Vortex Tube" KR 10-0880276 "Vortex Tube"

The present invention was developed to solve the problems of the conventional vortex tube at once, and in particular, the structure is simple, but the rotational force of the compressed air supplied to the vortex chamber is maximized, and the rotary airflow hits the wall at the end of the vortex chamber. When the reverse flow and cold air is effectively obtained, the heat is discharged directly and directly, but the discharge process is performed independently without interfering with the cooling method of the vortex chamber, and the cooling of the vortex chamber is sufficient air cooling by its own structure. The purpose is to enable the heat of the vortex chamber outer circumferential surface to be efficiently dissipated to the outside.

In another aspect, the present invention is to facilitate the fastening of the air hose, and to adjust the amount of the compressed air to be injected to facilitate the handling in actual use.

The configuration of the present invention according to the above object is provided with a cold air discharge port on one side of the compressed air inlet, the other side is provided with a hot air outlet through the vortex chamber, the vortex chamber outer circumferential surface of the vortex housing having a cooling portion formed at regular intervals to orthogonally radiate fins and;

A cold air discharge trap coupled to the cold air discharge port of the vortex housing, the rotary groove communicating with the injection port and the vortex chamber, and a cold air discharge path communicating with the outside from the inner circumferential surface of the vortex chamber and having a rearward tapered shape;

A return piece coupled to the hot exhaust outlet of the vortex housing and narrowly protruding from the wall while forming a wall at the end of the vortex chamber, and a radial hot exhaust hole and a hot exhaust path formed on the outer circumferential surface of the wall and directly connected to the outside from the vortex chamber. And, it consists of a heat exhaust trap consisting of a silencer provided at the end of the heat exhaust path.

One end of the cold air discharge trap is equipped with a fastener for connecting the hose, the inlet of the vortex housing is characterized in that the pressure control valve having a fastener for connecting the hose that is rotatable horizontally and longitudinally.

According to the present invention, the rotary groove communicating with the inlet port and the vortex chamber is integrally formed in the cold air discharge trap as described above, and the rotational force of the compressed air supplied to the vortex chamber is maximized while the rotary airflow hits the wall at the end of the vortex chamber. When returning, only the reverse flow and cold air can be effectively acquired by the return piece, and only the heat is effectively discharged by excluding the cold air by the hot air exhaust hole at the end of the vortex chamber, and a plurality of radiating fins are arranged at regular intervals at right intervals. As a result of its own structure, sufficient air cooling of the vortex chamber is possible, as well as the heat of the vortex chamber can be efficiently dissipated to the outside.

In addition, it is easy to install the air hose by installing a hose connection fastener and a pressure regulating valve, and it is possible to adjust the amount of compressed air to be injected.

1 is an exploded perspective view of the present invention
FIG. 2 is an exploded perspective view of FIG. 1 viewed from another direction
3 is an exploded cross-sectional view of the present invention.
4 is a cross-sectional view of the combination of the present invention
Figure 5 is another illustration of the present invention
6 is an exemplary operation diagram of the present invention.

Referring to the preferred embodiment of the present invention in detail with the accompanying drawings as follows. However, general description or well-known matters that may obscure the gist of the present invention are omitted or replaced with a simple name.

1 to 5, the present invention will be described in detail with reference to the accompanying drawings.

The vortex housing (1) is provided with a fastening portion for mounting the cold air outlet (12) and the cold air discharge trap (2) on one side of the compressed air inlet (11), the hot air outlet (13) through the vortex chamber (10) on the other side And a fastening part for mounting the hot air discharging trap 3, and a cooling part formed at regular intervals such that a plurality of heat dissipation fins 14 are orthogonal to the outer circumferential surface of the vortex chamber 10, and the inlet 11 is a pressure regulating valve. (5) It is composed of a fastening portion for mounting.

Cold air discharge trap (2) is provided with a fastening portion that can be mounted on the cold air outlet 12 of the vortex housing (1) for connecting the hose at one end, and the inlet 11 and the vortex chamber at the other end The circulation portion 200 and the rotary groove 21 communicating with the (10) is configured, and the cold air discharge passage 20 is communicated to the outside from the inner circumferential surface of the vortex chamber 10 and tapered in the rear.

Hot air discharge trap (3) is provided with a fastening portion that can be mounted at one end to the hot air outlet 13 of the vortex housing (1), the other end is provided with a fastening portion for mounting the silencer 33, and the vortex housing (1 The return piece 32 which protrudes narrowly from the wall 31 and forms the wall 31 at the end of the vortex chamber 10 when combined with the hot air outlet 13 of A radial hot air discharge hole 310 and a hot air discharge path 30 are formed in direct communication with the outside in the room 10, and the silencer 33 sintered the metal particles mounted at the end of the hot air discharge path 30. It is composed.

The fasteners 4 and 6 for hose connection and the pressure regulating valve 5 are pneumatic components, and detailed descriptions such as structure and operation are omitted. However, it is satisfied that it is installed in the vortex tube to facilitate the fastening of the hose and to adjust the amount of compressed air injected, so that it can be rotated in the lateral and longitudinal directions so as to facilitate the use of the yarn.

First of all, the principle of vortex is to supply compressed air into the tube while rotating it, and the compressed air moves to the end of the tube on the inner wall, forming a whirlwind-like vortex in the longitudinal direction.

At this time, the end of the tube is opened and the warmed air is discharged to some outside, and the remaining air is reversed again to form a small vortex along the center of the tube. The second internally formed vortex loses heat and is cooled and discharged back to the opposite end of the tube.

The reason why the internal vortex loses heat is that the air flowing through the inner wall of the tube whirls up to one side of the tube in a high temperature state, and a part is discharged, and the other side whirls in the same direction inside the hot whirlpool. As it cools and cools down and out of the tube, the two vortices rotate in the same direction and at the same speed. However, according to the law of conservation of angular momentum (rotation momentum) of the laws of mechanics, the gas that rotated the outer circle with large rotation radius flows into the narrow rotation radius inside and circulates and the rotation speed should be increased. The rotational angular velocity of is not the same as when rotating around the outside because the air inside has lost angular momentum. The air inside the lost angular cloud soon loses energy, resulting in a drop in temperature. The energy lost by the air inside is transferred to the air rotating outside, and the air rotating outside becomes hot.

Therefore, the compressed air is separated by the swirling vortex phenomenon and the inner air flow is cold and the outer air flow is hot air, and cold air or hot air can be obtained by acquiring the air flow on the inner or outer circumferential surface of the vortex chamber.

The operation according to the configuration of the present invention will be described in detail with reference to FIG. 6 as follows.

The compressed air supplied through the inlet 11 is injected into the vortex chamber 10 while the compressed air is rotated at a high speed along the rotary groove 21 through the circulation part 200. The compressed air injected here is moved to the end of the vortex chamber 10 while causing the vortex phenomenon, and part of the heat of the outer circumferential surface separated by the rotary airflow during the movement is discharged to the outside through the hot air discharge hole 310 and the rest of the wall ( 31) and countercurrent. At this time, the return piece 32 projecting narrowly from the wall is efficiently generated in the reverse flow and cold air, and the cold air generated in the reverse flow flows to the opposite side again and exits through the cold air discharge path 20.

The circulation part 200 is generated by the combination of the vortex housing 1 and the cold air discharge trap 2, and has a space on the outer circumferential surface so that compressed air can flow in the entire rotary groove 21 when the compressed air is injected. Is formed.

The rotary groove 21 is positioned at the inlet of the vortex chamber 10 to form a plurality of grooves in a radial spiral to supply the compressed air injected into the vortex chamber 10 at high speed.

The hot air discharge hole 310 has a plurality of holes radially formed on the outer wall of the end wall 31 of the vortex chamber 10 so as to discharge the heat of the vortex chamber 10 to the outside.

The return piece 32 is configured to project narrowly from the end wall 31 of the vortex chamber 10 so that backflow and cool air are efficiently generated.

The cold air discharge passage 20 communicates with the inner circumferential surface of the vortex chamber 10 and is tapered so that the rear of the inlet is widened from the advancing direction so that the cold air can be efficiently obtained.

The hot air discharge path 30 is connected to the outer circumferential surface and the outside of the vortex chamber 10 in direct communication with the silencer 33 at the end to block the noise during the discharge of heat as much as possible.

The cooling unit is formed on the outer circumferential surface of the vortex chamber 10 with a plurality of heat dissipation fins 14 orthogonally spaced at a predetermined interval to structurally enable air cooling of the vortex chamber 10 as well as to efficiently heat the vortex chamber 10. At the end of the heat dissipation fins 14, the temperature is lowered to prevent the risk of burns and the like.

The cold air discharge trap 2 has the rotary groove 21 and the cold air discharge path 20 at the same time by injection molding to have a structural simplicity and ease of fabrication and assembly.

The hot air discharging trap 3 also has the structural simplicity and ease of fabrication and assembly by injection molding by forming the wall 31, the return piece 32, and the hot air discharging groove 310 which block the end of the vortex chamber 10 at once. .

The cold air discharge trap (2) and the hot air discharge trap (3) it is preferable to improve the strength of the fastening portion by embedding a screw tube made of a metal material in each fastening portion during injection molding with synthetic resin.

Although the embodiments of the present invention have been described above, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope described in the embodiments of the present invention.

1: Vortex Housing 10: Vortex Chamber
11: inlet 12: cold air outlet
13: hot air outlet 14: heat dissipation fin
2: chilled air trap 20: chilled air
21: rotating groove 200: circulation
3: hot air trap 30: hot air discharge furnace
31: wall 32: return flight
33: silencer 310: hot air exhauster
4, 6: Hose connection fastener 5: Pressure regulating valve

Claims (2)

The cold air outlet 12 is provided at one side of the compressed air inlet 11, and the hot air outlet 13 is provided at the other side via the vortex chamber 10, so that the heat dissipation fin 14 is perpendicular to the circumferential surface of the vortex chamber 10. A vortex housing 1 having a cooling unit formed at a predetermined interval;
The rotary groove 21 is coupled to the cold air outlet 12 of the vortex housing 1 and communicates with the injection port 11 and the vortex chamber 10, and communicates with the outside at the inner circumferential surface of the vortex chamber 10. A cold air discharge trap (2) having a cold air discharge path (20) having a rearward tapered shape;
A return piece 32 coupled to the hot air outlet 13 of the vortex housing 1 and protruding narrowly from the wall 31 while forming a wall 31 at the end of the vortex chamber 10, and of the wall 31. Hot air discharge is formed on the outer circumferential surface of the hot air discharge hole 310 and the hot air discharge path (30) which is directly connected to the outside in the vortex chamber (10) and the silencer (33) provided at the end of the hot air discharge path (30) Vortex tube, characterized in that configured trap (3).
The method of claim 1,
One end of the cold air discharge trap (2) is equipped with a hose connection fastener (4), the inlet port 11 of the vortex housing (1) pressure with a hose connection fastener (6) rotatable horizontally and longitudinally Vortex tube, characterized in that the control valve (5) is mounted.

Images