KR20200075573A - Vortex cooler for cutter - Google Patents

Abstract

An objective of the present invention is to provide a vortex cooler for a cutter, which has improved cooling efficiency. According to one embodiment of the present invention, the vortex cooler for a cutter comprises: a main body into which compressed air is injected; a vortex generator installed in an inner space of the main body to generate a vortex; a heat radiation body connected to the main body and discharging heat; a rotary shaft connected to the vortex generator to rotate, and extending along the main body and the heat radiation body; and a first auxiliary blade connected to one end portion of the rotary shaft to rotate, and discharging chilly air to one side of the main body.

Description

VORTEX COOLER FOR CUTTER for cutting machine

The present invention relates to a bore-tex cooler for a cutting machine.

The large cutting machine or cutting tool is large and the size of the workpiece is large, making it difficult to cool the fluid using a cutting oil. The cutting oil retaining component may oxidize or corrode the surface of the workpiece. In addition, when the cutting process is performed using cutting oil, dust may be generated to contaminate the surroundings. In addition, various attachments must be installed to prevent contamination of the cutting oil, and separate devices for recovering and supplying the cutting oil must be installed. In addition, a separate chemical process must be added to remove coolant after processing the workpiece.

Therefore, in general, large-sized cutting machines are dry-processed. However, due to this, the life of the cutting machine may be drastically reduced. Dry processing generally uses a Vortex Cooler. However, the Bore-Tex cooler has low cooling efficiency, and the cutting machine may be excessively worn or damaged.

In the present invention, to provide a bore-tex cooler for a cutting machine with improved cooling efficiency.

Bore-tex cooler for a cutting machine according to an embodiment of the present invention is a main body to which compressed air is injected; A vortex generator installed in the interior space of the main body to generate a vortex; A heat dissipating body connected to the main body to emit heat; A rotating shaft connected to the vortex generator and rotating and extending along the main body and the radiating body; And it is connected to one end of the rotating shaft and includes a first auxiliary blade that rotates and discharges cold air to one side of the main body.

The vortex generator may include a rotating vortex body, and a vortex blade connected to the vortex body and rotating to form a vortex.

The rotating shaft may be located in the inner space of the main body and the inner space of the heat radiating body.

It may further include a second auxiliary blade connected to the other end of the rotating shaft to rotate and discharge the heat to one side of the heat dissipation body.

A first support part located at one end of the main body and fixing the rotation center of the rotation shaft may be further included.

The first support part may include a first bearing surrounding the rotation shaft, and a plurality of first connection frames connecting the first bearing and one end of the main body to each other.

A cold air opening through which the cold air passes may be formed between the adjacent first connection frames.

The first support part may be located between the first auxiliary blade and the vortex generator.

A second support part positioned at one end of the heat dissipating body and fixing the rotation center of the rotation shaft may be further included.

The second support part may include a second bearing surrounding the rotation shaft, and a plurality of second connection frames connecting the second bearing and one end of the heat dissipation body to each other.

A hot air opening through which the hot air passes may be formed between the adjacent second connection frames.

The second support part may be located between the second auxiliary blade and the vortex generator.

The main body further includes a compressed air injection unit into which the compressed air is injected, and the vortex generator may be installed at a position corresponding to the compressed air injection unit.

The length of the heat dissipation body may be longer than the length of the main body.

A control valve is installed inside the heat dissipation body, and the control valve can control the amount of heat released.

The vortex cooler for a cutting machine according to an embodiment of the present invention can generate more cold and hot air, thereby improving cooling efficiency.

Therefore, the life of the cutting machine can be improved by applying the vortex cooler for the cutting machine to the dry machining of the cutting machine according to an embodiment of the present invention.

1 is a schematic cross-sectional view of a vortex cooler for a cutting machine according to an embodiment of the present invention.
2 is a view for explaining the operation of the vortex cooler for a cutting machine according to an embodiment of the present invention.
3 is an enlarged plan view of the first support of FIG. 1.
4 is an enlarged plan view of the second support part of FIG. 1.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein.

1 is a schematic cross-sectional view of a vortex cooler for a cutting machine according to an embodiment of the present invention, and FIG. 2 is a view illustrating an operation of the vortex cooler for a cutting machine according to an embodiment of the present invention.

1 and 2, the bore-tex cooler for a cutting machine according to an embodiment of the present invention is a main body 10, a vortex generator 20, a heat dissipating body 25, a rotating shaft 30, a first It includes an auxiliary blade 41, a second auxiliary blade 42, a first support portion 51, and a second support portion 52.

The main body 10 has an inner space 10a in which the vortex generator 20 is installed. A compressed air injection unit 12 into which compressed air 1 is injected may be installed at the top of the main body 10.

The vortex generator 20 may include a rotating vortex body 21 and a vortex blade 22 connected to the vortex body 21 to rotate and form a vortex. The vortex generator 20 may be installed at a position corresponding to the compressed air injection unit 12. The vortex generator 20 rotates the vortex blade 22 using compressed air 1 to generate vortex in the inner space 10a of the main body 10.

The heat dissipation body 25 is connected to the main body 10 and has an internal space 25a. The length D2 of the heat dissipation body 25 may be longer than the length D1 of the main body 10. The heat dissipation body 25 may discharge the heat 3 generated by the vortex to the outside. The heat dissipation body 25 may be formed of an aluminum material having high thermal conductivity.

The control valve 60 may be installed inside the heat dissipation body 25. The control valve 60 may control the amount of external discharge of the hot air 3. That is, the gap d between the control valve 60 and the heat radiating body 25 may be adjusted using the control valve 60. Therefore, it is possible to control the amount of heat 3 emitted to the outside through the gap d between the control valve 60 and the heat dissipation body 25.

Since the vortex generator 20 rotates at a high speed by the compressed air 1, the rotating shaft 30 connected to the vortex generator 20 also rotates at a high speed.

As shown in FIG. 2, when the compressed air 1 is introduced into the inner space 10a of the main body 10, a vortex such as a whirlwind is generated by the vortex generator 20. And, the vortex proceeds along the inner space (25a) of the heat dissipating body (25) to convert the rotational kinetic energy into thermal energy to generate the heat (3). The generated heat 3 is discharged to the outside of the heat dissipation body 25, and the heat not discharged to the outside of the heat dissipation body 25 changes direction again to form a vortex toward the main body 10 and flows back. Therefore, the vortex that has lost heat becomes cold air 2 and is discharged to one end of the main body 10.

The reason the inside vortex loses heat is as follows. The air flowing while swirling the inner walls of the main body 10 and the heat dissipating body 25 flows to either side of the main body 10 and the heat dissipating body 25 in a high temperature state, and a part is discharged, and the rest are the same inside the high temperature vortex Swirling in the direction, it becomes a low temperature state and flows to the opposite sides of the main body 10 and the heat dissipating body 25 and is discharged. However, according to the law of conservation of angular momentum among the laws of mechanics, if the gas that rotates around the outer periphery with a large radius of rotation flows into the interior with a narrow radius of rotation, the rotational speed must be increased. The angular velocity does not increase, but it is the same as when turning around, because the air inside has lost angular momentum. The air inside the angular momentum loses energy, and as a result, the temperature drops. The energy lost inside the air is transmitted to the air rotating outside, and the air rotating outside becomes hot.

The rotating shaft 30 may be located in the inner space 10a of the main body 10 and the inner space 25a of the heat dissipation body 25. The rotating shaft 30 is connected to the vortex generator 20 and rotates, and may extend along the main body 10 and the heat dissipation body 25.

The first auxiliary blade 41 is connected to one end 31 of the rotating shaft 30 and rotates, so that the cold air 2 can be more smoothly discharged to one side of the main body 10. Therefore, since the cold air 2 can be quickly discharged, the cooling efficiency of the vortex cooler for a cutting machine can be increased. Therefore, the life of the cutting machine can be improved by applying the vortex cooler for the cutting machine to the dry machining of the cutting machine according to an embodiment of the present invention.

The second auxiliary blade 42 is connected to the other end 32 of the rotating shaft 30 and rotates, so that the heat 3 can be discharged more smoothly to one side of the heat dissipation body 25.

The first support part 51 is located at one end 11 of the main body 10 and can support the rotating shaft 30. That is, the position of one end portion 31 of the rotating shaft 30 can be fixed to the rotation center. The first support part 51 may be located between the first auxiliary blade 41 and the vortex generator 20.

3 is an enlarged plan view of the first support of FIG. 1.

1 to 3, the first support portion 51 includes a first bearing 51a surrounding one end portion 31 of the rotating shaft 30, and a first bearing 51a and a main body 10 ) May include a plurality of first connection frames 51b connecting one end 11 of each other. The first bearing 51a may minimize friction between the rotating shaft 30 and the first connection frame 51b. At this time, since the plurality of first connection frames 51b are spaced apart from each other, a cold air opening 53 through which the cold air 2 passes may be formed between adjacent first connection frames 51b.

Although three first connection frames 51b are illustrated in this embodiment, the present invention is not limited thereto, and various numbers of first connection frames 51b may be installed.

The second support part 52 is located at one end 26 of the heat dissipation body 25 and can support the rotating shaft 30. That is, the position of the other end 32 of the rotating shaft 30 can be fixed to the rotation center. The second support 52 may be located between the second auxiliary blade 42 and the vortex generator 20.

4 is an enlarged plan view of the second support part of FIG. 1.

1, 2 and 4, the second support 52 is a second bearing (52a) surrounding the rotating shaft 30, and a second bearing (52a) and one end of the heat dissipating body (25) A plurality of second connection frames 52b connecting the parts 26 to each other may be included. The second bearing 52a may minimize friction between the rotating shaft 30 and the second connecting frame 52b. At this time, since the plurality of second connection frames 52b are spaced apart from each other, an opening opening 54 through which the hot air 3 passes may be formed between the adjacent second connection frames 52b. Although three second connection frames 52b are illustrated in the present embodiment, the present invention is not limited thereto, and a variety of second connection frames 52b may be installed.

As described above, by installing the first support portion 51 and the second support portion 52, the first auxiliary blade 41 and the second auxiliary blade 42 are stabilized by preventing the rotation of the rotating shaft 30 rotating at high speed. It makes it possible to rotate. Therefore, the cooling air 2 can be discharged more smoothly.

Although the present disclosure has been described through preferred embodiments as described above, the present invention is not limited thereto, and various modifications and variations are possible without departing from the scope of the claims described below. Those in the field will readily understand.

10: main body 20: vortex generator
25: heat dissipation body 30: rotating shaft
41: first auxiliary blade 42: second auxiliary blade
51: first support 52: second support

Claims (15)

A main body into which compressed air is injected;
A vortex generator installed in the interior space of the main body to generate a vortex;
A heat dissipation body connected to the main body and releasing heat;
A rotating shaft connected to the vortex generator and rotating and extending along the main body and the radiating body; And
A first auxiliary blade connected to one end of the rotating shaft to rotate and discharge cold air to one side of the main body
Bore-Tex cooler for a cutting machine comprising a. According to claim 1,
The vortex generator
Rotating vortex body, and
A vortex blade connected to the vortex body to rotate to form a vortex
Bore-Tex cooler for a cutting machine comprising a. According to claim 2,
The rotating shaft is a bore-tex cooler for a cutting machine located in the inner space of the main body and the inner space of the heat dissipating body. According to claim 2,
A bore-tex cooler for a cutting machine further comprising a second auxiliary blade connected to the other end of the rotating shaft to rotate and discharge the heat to one side of the heat dissipating body. According to claim 4,
A vortex cooler for a cutting machine further comprising a first support part located at one end of the main body and fixing a rotation center of the rotation shaft. According to claim 4,
The first support part
A first bearing surrounding the rotating shaft, and
A plurality of first connection frame connecting the first bearing and one end of the main body to each other
Bore-Tex cooler for a cutting machine comprising a. The method of claim 6,
A vortex cooler for a cutting machine in which a cold air opening through which the cold air passes is formed between adjacent first connection frames. The method of claim 5,
The first support is a bore-tex cooler for a cutting machine located between the first auxiliary blade and the vortex generator. According to claim 4,
A vortex cooler for a cutting machine further comprising a second support part positioned at one end of the heat dissipating body and fixing a rotation center of the rotation shaft. The method of claim 9,
The second support part
A second bearing surrounding the rotating shaft, and
A plurality of second connection frames connecting one end of the second bearing and the heat dissipation body to each other
Bore-Tex cooler for a cutting machine comprising a. The method of claim 10,
A bore-tex cooler for a cutting machine in which a hot air opening through which the hot air passes is formed between adjacent second connection frames. The method of claim 9,
The second support is a bore-tex cooler for a cutting machine located between the second auxiliary blade and the vortex generator. According to claim 1,
The main body further includes a compressed air injection unit into which the compressed air is injected, and the vortex generator is a vortex cooler for a cutting machine installed at a position corresponding to the compressed air injection unit. According to claim 1,
The length of the heat dissipating body is longer than the length of the main body, the vortex cooler for a cutting machine. According to claim 1,
A control valve is installed inside the heat dissipation body,
The control valve is a vortex cooler for a cutting machine that controls the amount of heat released.

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