KR102676760B1 - Mist Sprayer - Google Patents

Abstract

The present invention relates to a spraying device that sprays machining mist, that is, cutting oil mist, when cutting a workpiece. To be described in more detail, during cutting processing, cooled compressed air and cutting oil are mixed in the mixing section using a vortex tube, and then the tool is sprayed. and technology related to a machining mist spray device that prevents deterioration of the oil by spraying it on the material, ensures that the viscosity of the oil is sufficiently maintained, and reduces the heat generated during cutting to enable cutting to proceed smoothly. The field opens.

Description

Processing mist sprayer {Mist Sprayer}

The present invention relates to a spraying device that sprays machining mist, that is, cutting oil mist, when cutting a workpiece. To be described in more detail, during cutting processing, cooled compressed air and cutting oil are mixed in the mixing section using a vortex tube, and then the tool is sprayed. and a machining mist spray device that prevents deterioration of the oil by spraying it on the material, ensures that the viscosity of the oil is sufficiently maintained, and reduces the heat generated during cutting to enable cutting to proceed smoothly. .

In general, when cutting using machine tools such as lathes and milling machines, lubrication and cooling of the machined area of the workpiece, reduction of friction coefficient, chip removal, processing of the machined surface, etc. are facilitated, and the workpiece is cut smoothly. We supply various oils to increase the durability of tools.

At this time, in the past, when the cutting tool was rotated in a liquid state, oil was injected to sufficiently wet the workpiece and the cutting tool. When the cutting tool was rotated at high speed, the oil was sprayed to the outside and a large amount of oil was leaked to the outside, deteriorating the working environment. It caused many problems such as contamination and waste of expensive oil.

Accordingly, the oil is pulverized into ultra-fine particles and the oil mist, which is in a fog-like state, is sprayed on the area where cutting work is performed, thereby maximizing the effect while using the minimum amount of oil and reducing startup costs to ensure economic feasibility. Methods to reduce pollution have been developed and their use is gradually expanding.

However, the existing method of pulverizing oil is difficult to pulverize into even particles, and it is supplied through the flow path in a mixed state of relatively large and small particles. During this process, large particles adhere to the inner wall and merge with other particles, forming a liquid state. There was a problem with oil flowing.

In addition, if the supplied oil mist is supplied in a hot state, the nature of the oil does not have the desired viscosity, which reduces cutting and lubricating effects, does not provide sufficient cooling effect during the cutting process, and causes deterioration of the oil, but requires a separate cooling device. This requires power and has the disadvantage of complicating the device.

As an example of the prior art, Korea Registered Utility Model No. 20-0469578 prevents the oil mist sprayed during cutting, i.e. vaporized oil molecules, from turning into coarse particles and flowing in the oil mist transfer pipe during the supply process, and generates particles of uniform size. An oil mist manufacturing device for cutting processing equipped with a cooling device was developed to cool the inside of the oil tank to prevent deterioration of the oil and increase cooling efficiency during the cutting process.

In other words, the Republic of Korea Registered Utility Model No. 20-0469578 uses a vortex tube to cool the inside of the oil tank, thereby preventing deterioration of the oil and increasing cooling efficiency during the cutting process. However, some of the air supplied from the compressor is not cooled and There is a problem that the cooling effect is minimal because it is supplied.

As another example of the prior art, in Korea Registered Utility Model No. 20-0491998, an auxiliary block is integrally combined with a mist spray unit to provide a structure in which air flows into the mist spray unit through the auxiliary block, thereby providing a structure in which machine tools are driven. Depending on the situation, coolant mist injection by the mist spray unit and air injection by the air injection pipe nozzle directly connected to the auxiliary block can be selectively performed, improving operator convenience, and the magnetic body is attached to the assembly of the mist spray unit and auxiliary block. Introducing a cutting oil mist supply device for machine tools that is additionally combined to ensure that the mist spray unit and auxiliary block are firmly fixed without movement at a fixed position selected according to the field conditions where the machine tool is driven, thereby improving work stability. I'm doing it.

The above-mentioned Korean Utility Model No. 20-0491998 allows mist to be sprayed by selectively controlling the flow rates of cutting oil and air through an oil adjustment needle and an air adjustment needle. However, as uncooled air is sprayed, the oil deteriorates or There is a problem in that the lubricating effect is reduced because the oil does not have sufficient viscosity.

Republic of Korea Registered Utility Model No. 20-0469578 (October 15, 2013) Republic of Korea Registered Utility Model No. 20-0491998 (2020.07.08.)

The present invention is a technology developed to solve the problems caused by the prior art described above. In the conventional oil mist device, the oil may not have sufficient viscosity due to the high temperature of the supplied air, and as a result, the oil may deteriorate. , if a separate cooling device is operated to solve this problem, the configuration becomes complicated.

Using a vortex tube, the compressed air supplied from the compressor is cooled and supplied to the mixing section, and at the same time, oil is supplied to the mixing section so that the cooled compressed air and oil are mixed, and the air control member and the oil control member are The main purpose is to provide a machining mist injection device that allows cutting to proceed smoothly by adjusting the flow rate of compressed air and oil to selectively spray machining mist according to the field conditions where the machine tool is driven. there is.

In order to achieve the above-mentioned objective, the present invention includes a body 100 that is detachable from the machine tool 10; and a vortex pipe ( A vortex tube 200 that is installed so that 210 passes through it, and that an air inlet 220 passes through one side or the other side of the body 100, and a moving pipe 230 is formed in the downward direction; and the body 100 ) and an oil supply pipe 300 installed to penetrate one side or the other side of the body 100, and the moving pipe 230 of the vortex tube 200 and the oil supply pipe 300 are connected to the upper portion. a mixing unit 400; and a flexible pipe 500 installed penetrating through the lower part of the body 100, the upper part of which is connected to the lower part of the mixing unit 400; and a nozzle 600 installed at the lower part of the flexible pipe 500. A processing mist spraying device is provided.

In addition, the body 100 of the present invention is characterized by being configured to include a magnet portion 110 installed on either the front or the rear.

In addition, the mixing part 400 of the present invention is formed inside an air passage 410, the upper part of which is formed to communicate with the moving pipe 230; An oil passage 420 formed to communicate; and a mixing passage 430 internally connected to the lower portions of the air passage 410 and the oil passage 420.

In addition, the mixing part 400 of the present invention is formed at the front or rear, and has an air control hole 440 formed to communicate with the air passage 410; and air screwed into the air control hole 440. It is characterized in that it includes an adjustment member 450.

In addition, the mixing part 400 of the present invention is formed at the front or rear, and has an oil control hole 460 formed to communicate with the oil passage 420; and an oil screwed into the oil control hole 460. It is characterized in that it includes an adjustment member 470.

In addition, the air control member 450 and the oil control member 470 of the present invention are installed to penetrate the front or rear of the body 100.

In addition, the air control member 450 and the oil control member 470 of the present invention are screwed to the air control hole 440 or the oil control hole 460, and the ends are connected to the air control hole 440 or the oil control hole. Includes an adjustment screw 472 inserted into the inside of the hole 460; and a fixing nut 474 screwed to the outer periphery of the adjustment screw 472 and close to the front or rear of the mixing section 400. It is characterized by being composed of.

The processing mist injection device according to the present invention presented as described above not only prevents deterioration of the oil mixed in the mixing section by cooling the compressed air supplied from the compressor using a vortex tube and then supplying it to the mixing section. In addition, it is possible to obtain the effect of ensuring that the oil has sufficient viscosity so that cutting can be performed smoothly.

In addition, the present invention adjusts the flow rate of compressed air and oil mixed in the mixing section through the air control member and the oil control member to selectively spray processing mist according to the field conditions where the machine tool is driven. , the effect of allowing cutting processing to proceed smoothly can be achieved.

Figure 1 is a perspective view showing a state in which a processing mist injection device according to a preferred embodiment of the present invention is installed on a machine tool.
Figure 2 is a perspective view showing a processing mist injection device according to a preferred embodiment of the present invention.
Figure 3 is a partially exploded perspective view showing a processing mist injection device according to a preferred embodiment of the present invention.
Fig. 4 is a partial front view of Fig. 3;
Figure 5 is a projected front view showing a mixing section according to a preferred embodiment of the present invention.
Figure 6 is an enlarged view of portion "A" of Figure 3.
Figure 7 is a front cross-sectional view showing a grinding unit according to a preferred embodiment of the present invention.
Figure 8 is an exploded perspective view showing a first crushing plate and a second crushing plate according to a preferred embodiment of the present invention.

The present invention relates to a spraying device that sprays machining mist, that is, cutting oil mist, when cutting a workpiece. To be described in more detail, compressed air cooled using the vortex tube 200 is sprayed into the mixing unit 400 during cutting. supply, cutting oil, that is, oil, is supplied to the mixing section 400 so that the cooled compressed air and oil are mixed in the mixing section 400, and the air control member 450 installed in the mixing section 400 By using the oil control member 470 to control the flow rate of the compressed air and oil mixed in the mixing unit 400, processing mist can be selectively sprayed according to the field conditions where the machine tool is driven, so that the oil It relates to a machining mist spray device that prevents deterioration, ensures sufficient viscosity of oil, and reduces the heat generated during cutting to enable cutting to proceed smoothly.

The processing mist injection device of the present invention as described above includes a body 100 that is detachable from the machine tool 10; and a vortex pipe 210 installed on the upper inner side of the body 100. A vortex tube 200 is installed to penetrate, and the air inlet 220 is installed to penetrate through one side or the other side of the body 100, and a vortex tube 230 is formed in the downward direction; and the body 100 An oil supply pipe 300 installed to penetrate one side or the other side; and a mixture installed in the inner lower part of the body 100, and the moving pipe 230 of the vortex tube 200 and the oil supply pipe 300 are connected to the upper part. Part 400; and a flexible pipe 500 installed penetrating through the lower part of the body 100, the upper part of which is connected to the lower part of the mixing part 400; And a nozzle 600 installed at the lower part of the flexible pipe 500.

In addition, the body 100 of the present invention is characterized by being configured to include a magnet portion 110 installed on either the front or the rear.

In addition, the mixing part 400 of the present invention is formed inside an air passage 410, the upper part of which is formed to communicate with the moving pipe 230; An oil passage 420 formed to communicate; and a mixing passage 430 internally connected to the lower portions of the air passage 410 and the oil passage 420.

In addition, the mixing part 400 of the present invention is formed at the front or rear, and has an air control hole 440 formed to communicate with the air passage 410; and air screwed into the air control hole 440. It is characterized in that it includes an adjustment member 450.

In addition, the mixing part 400 of the present invention is formed at the front or rear, and has an oil control hole 460 formed to communicate with the oil passage 420; and an oil screwed into the oil control hole 460. It is characterized in that it includes an adjustment member 470.

In addition, the air control member 450 and the oil control member 470 of the present invention are installed to penetrate the front or rear of the body 100.

In addition, the air control member 450 and the oil control member 470 of the present invention are screwed to the air control hole 440 or the oil control hole 460, and the ends are connected to the air control hole 440 or the oil control hole. Includes an adjustment screw 472 inserted into the inside of the hole 460; and a fixing nut 474 screwed to the outer periphery of the adjustment screw 472 and close to the front or rear of the mixing section 400. It is characterized by being composed of.

Hereinafter, the present invention will be described in detail with reference to Figures 1 to 8 showing embodiments of the present invention.

The body 100, the main component of the present invention, is

It is attached and detached to the machine tool 10 by the magnet part 110, which will be described in detail later, and has a vortex tube 200, an oil supply pipe 300, which will be described later in detail, inside. A mixing unit 400 is installed.

The body 100 of the present invention is formed in a curved shape, includes a plurality of corner members (not shown) with slide grooves (not shown) on both sides, and slides in the slide groove on one side or the other of one corner member. A plurality of front, left, right and left side plates (not shown) are coupled and slidingly coupled to the slide groove on the other side or one side of another corner member adjacent to one of the corner members, and are located in front or rear of the plurality of corner members and are coupled to each other. It consists of a pair of front and rear plates (not shown).

That is, the body 100 of the present invention can be easily separated through a plurality of corner members, a plurality of front and rear left and right side plates, and a pair of front and rear plates, thereby realizing the effect of easy maintenance.

In addition, an air control member 450 and an oil control member 470 of the mixing unit 400, which will be described in detail later, are protruded from one of the pair of front and rear plates so that the user can easily operate the air control member. An air hole (not shown) and an oil hole (not shown) are formed to correspond to 450 and the oil control member 470.

In addition, the body 100 of the present invention is configured to include a magnet portion 110 installed on either the front or rear side. In other words, the magnet portion 110 is installed on either the front or rear side of the front or rear plates. This achieves the effect of making it easy to attach and detach from the machine tool (10).

This magnet unit 110 has one side coupled to either the front or rear of the body 100, a support arm 112 whose length is adjustable, and a magnet 114 coupled to the other side of the support arm 112. ) and consists of.

At this time, any conventional configuration may be used for adjusting the length of the support arm 112, so detailed description and illustration in the drawings are omitted, and the length of the support arm 112 is adjusted. The installation position of the processing mist spray device of the invention can be easily changed, and this is to minimize the impact on the many connection lines or wires of the machine tool 10.

The vortex tube 200, the main component of the present invention, is

It is installed on the inner upper part of the body 100, so that the vortex pipe 210 penetrates the upper part of the body 100, and the air inlet 220 penetrates one side or the other side of the body 100. A moving pipe 230 is formed in the downward direction, separating the compressed gas into a hot flow and a cold flow, so that the cold flow, that is, cold compressed air, flows through the moving pipe 230 into the mixing section 400, which will be described in detail later. ) to prevent deterioration of the oil and maintain its viscosity. The operation of the vortex tube 200 of the present invention is generally known in the prior art, and detailed description will be omitted.

In the vortex tube 200 of the present invention, when oil mist, that is, processing mist, is sprayed, oil and compressed air are mixed and sprayed together in the mixing section 400, which will be described in detail later, so the temperature of the compressed air By lowering it, the effect of preventing deterioration of the oil and maintaining its viscosity when mixed with the oil is realized.

To explain further, compressed air mixed with oil and sprayed together when spraying processing mist is supplied through a compressed air generator such as a compressor, and the compressor increases the temperature of the compressed air when the air is compressed, so the temperature rises. When the compressed air is mixed with oil, not only there is a risk that the oil may deteriorate, but the viscosity of the oil may decrease, which may cause a problem in that the effect of the oil during cutting may be minimal. Therefore, the present invention provides a vortex tube as described above. Using (200), the temperature of the compressed air mixed with the oil is lowered without a separate device so that it is mixed with the oil.

Specifically, the vortex tube 200 of the present invention receives compressed air by connecting the air inlet 220 to a compressor, and after hot compressed air and cold compressed air are separated in the vortex tube 210, the vortex tube 210 is connected to the compressor. Hot compressed air is discharged to the end of 210, and cold compressed air is moved to the moving pipe 230.

The vortex pipe 210 causes the compressed air supplied through the air inlet 220 to vortex and move, but accelerates and rotates at a high speed, and hot compressed air rotating from the outside through a conical nozzle provided at the end. Only the remaining compressed air, that is, the cold compressed air, which is discharged to the outside and cannot escape, receives a force returning in the opposite direction from the inside of the outer vortexed compressed air, causing a vortex and moving to the moving pipe 230, and thus Cold compressed air is supplied to the mixing unit 400, which will be described in detail later, through the moving pipe 230.

At this time, the end of the moving tube 230 is connected to the mixing unit 400, which will be described in detail later.

In addition, the vortex pipe 210 protrudes through the upper surface of the body 100 so that hot air can be discharged to the outside of the processing mist injection device of the present invention, that is, the body 100. ) is formed with a through hole (not shown) on the upper surface so that the vortex tube 210 can penetrate and protrude.

The oil supply pipe 300, the main component of the present invention, is

It is installed to penetrate one side or the other side of the body 100, and one side is connected to an oil supply device (not shown) to receive oil, and the other side is connected to the mixing section 400, which will be described in detail later, to receive the oil. By supplying the oil supplied from the supply device to the mixing unit 400, cold compressed air and oil can be mixed in the mixing unit 400.

The mixing unit 400, which is a main component of the present invention,

It is installed on the inner lower part of the body 100, and the moving pipe 230 of the vortex tube 200 and the oil supply pipe 300 are connected to the upper part, and cool air is supplied through the moving pipe 230 of the vortex tube 200. Compressed air is supplied, oil is supplied through the oil supply pipe 300, the cold compressed air and oil are mixed inside, and then the workpiece is processed through the flexible pipe 500 and nozzle 600, which will be described in detail later. Allow the mist to be sprayed.

The mixing part 400 of the present invention has a first coupling part (not shown) formed on the upper surface to which the end of the moving pipe 230 is coupled, and a first coupling part (not shown) formed on the upper surface to which the distal end of the oil supply pipe 300 is coupled. A second coupling portion (not shown) is formed.

In addition, the mixing part 400 of the present invention has an air passage 410 formed inside, the upper part of which communicates with the moving pipe 230, and an air passage 410 formed inside, the upper part of which communicates with the oil supply pipe 300. It is configured to include an oil passage 420 formed so as to be formed and a mixing passage 430 connected to the lower part of the air passage 410 and the oil passage 420 therein.

In additional explanation, the air flow path 410 extends from the first coupling part and communicates with the moving pipe 230, and the oil flow path 420 extends from the second coupling part and communicates with the oil flow path ( 420), and the mixing passage 430 mixes the cold compressed air and oil supplied through the air passage 410 and the oil passage 420 to be moved to the flexible pipe 500, which will be described in detail later. make it possible

At this time, the mixing part 400 of the present invention is formed at the front or rear, and includes an air control hole 440 formed to communicate with the air passage 410, and an air control unit screwed to the air control hole 440. It is configured to include a member 450.

The air adjustment member 450 is screwed into the air adjustment hole 440 and opens or closes the air passage 410 as it is raised and lowered, and the degree of opening or closing, that is, the end is connected to the air passage 410. By adjusting the insertion length, the amount of cold compressed air flowing through the air passage 410 can be adjusted.

In addition, the mixing part 400 of the present invention is formed on the front or rear side, has an oil control hole 460 formed to communicate with the oil passage 420, and an oil control hole 460 screwed to the oil control hole 460. It is configured to include a member 470.

The oil control member 470, like the air control member 450, is screwed to the oil control hole 460 and opens or closes the oil passage 420 as it is raised and lowered, and is opened or closed. By adjusting the degree, that is, the length at which the end is inserted into the oil passage 420, the amount of oil flowing through the oil passage 420 can be adjusted.

At this time, the air control member 450 and the oil control member 470 are formed in a shape in which the diameter becomes smaller as the distal ends move towards the distal ends, which means that air flows through the air control member 450 and the oil control member 470. This is to prevent the cold compressed air and oil from moving by the air control member 450 and the oil control member 470 by preventing the flow path 410 or oil flow path 420 from being completely closed.

In addition, the air control member 450 and the oil control member 470 are installed to penetrate the front or rear of the body 100, which allows the operator to control the air control member 450 and the oil. This is to enable the member 470 to be smoothly rotated and adjusted.

Specifically, the air control member 450 and the oil control member 470 are screwed to the air control hole 440 or the oil control hole 460, and the ends are connected to the air control hole 440 or the oil control hole ( An adjustment screw 472 inserted into the inside of 460) is screwed to the outer periphery of the adjustment screw 472 to secure the adjustment screw 472 as it comes close to the front or rear of the mixing section 400. It is configured to include a fixing nut (474).

The fixing nut 474 fixes the adjusting screw 472 to prevent it from rotating due to vibration or external shock generated as the machine tool 10 operates, thereby providing cold compressed air and It achieves the effect of stably maintaining the controlled amount of oil.

That is, the fixing nut 474 rotates along the outer periphery of the adjustment screw 472 when the adjustment screw 472 is screwed into the air adjustment hole 440 or the oil adjustment hole 460 and the position is adjusted. This prevents rotation of the adjustment screw 472 as the lower part comes into close contact with the front or rear of the mixing unit 400.

The flexible tube 500, a main component of the present invention, is

It is installed to penetrate the lower part of the body 100, and the upper part is connected to the lower part of the mixing part 400, and the cold compressed air and oil mixed through the mixing part 400 enter the nozzle, which will be described in detail later. It can be sprayed onto the workpiece through (600).

At this time, the flexible pipe 500 of the present invention is configured to be flexibly bent like a conventional flexible pipe, thereby realizing the effect of allowing the nozzle 600 to be smoothly positioned at the location where the processing mist is to be sprayed. Do it.

The nozzle 600, the main component of the present invention, is

It is installed at the lower part of the flexible pipe 500, and allows the mixture of cold compressed air and oil moving through the flexible pipe 500 to be sprayed onto the workpiece, and the oil can be pulverized and sprayed.

At this time, any conventionally used configuration for pulverizing the oil of the nozzle 600 of the present invention may be used, so detailed description will be omitted.

In connection with the above, the oil supply pipe 300 of the present invention is installed to be located inside the body 100 and includes a grinding part 310 that grinds the oil supplied and moved, the grinding part ( 310) realizes the effect of allowing cold compressed air and oil to be mixed more smoothly in the mixing section 400.

Specifically, the pulverizing part 310 is formed in a cylindrical shape, includes a housing 312 whose diameter becomes smaller toward one side or the other, and is installed on one inner side or the other inner side of the housing 312, and is located in the center. A first crushing protrusion 314a is formed sharply on one side or the other direction, and includes a first crushing plate 314 through which a plurality of first moving holes 314b are formed.

In addition, the first crushing plate 314 allows oil flowing in from one side or the other direction to be crushed by hitting the first crushing protrusion 314a and then moved through a plurality of first moving holes 314b. .

That is, the first crushing plate 314 crushes the oil moving through the oil supply pipe 300 of the present invention before being supplied to the mixing section 400, thereby forming the mixing passage 430 of the mixing section 400. It achieves the effect of allowing it to mix smoothly with cold compressed air.

In addition, the crushing unit 310 is installed on one side or the other inside of the housing 312, and is installed on the other side or one side of the first crushing plate 314, and the first moving hole 314b A plurality of second pulverizing protrusions (316a) are formed sharply in one side or the other direction at a position corresponding to the and includes a second pulverizing plate (316) through which a plurality of second moving holes (316b) are formed. .

In addition, the second crushing plate 316 is the second crushing plate 316 when the oil primarily crushed in the first crushing plate 314 moves to the other side or one direction through the plurality of first moving holes 314b. By causing secondary pulverization by the pulverizing protrusions (316a) and then moving the oil through the plurality of second moving holes (316b), the pulverization of the oil is more effective and mixing with cold compressed air can be achieved smoothly. .

That is, the second crushing plate 316, together with the first crushing plate 314, more effectively crushes the oil moving through the oil supply pipe 300 of the present invention before it is supplied to the mixing unit 400, This achieves the effect of allowing smooth mixing with cold compressed air in the mixing passage 430 of the mixing section 400.

As a result, the processing mist injection device of the present invention uses the vortex tube 200 to cool the compressed air whose temperature has risen in the compressor, that is, separate it into warm compressed air and cold compressed air, and mix only the cold compressed air with oil. By mixing in the unit 400, it is possible to obtain the effect of preventing deterioration of the oil and maintaining sufficient viscosity of the oil to enable cutting processing to be performed smoothly.

The above has been described with reference to preferred embodiments of the present invention, and the present invention is not limited to the above embodiments, and the gist of the present invention can be understood by those skilled in the art through the above embodiments. It can be implemented with various changes without departing from the scope.

10: machine tool 100: body
110: magnet part 112: support arm
114: Magnet 200: Vortex tube
210: vortex pipe 220: air inlet
230: moving pipe 300: oil supply pipe
310: Grinding unit 312: Housing
314: first crushing plate 314a: first crushing protrusion
314b: first moving hole 316: second crushing plate
316a: second crushing protrusion 316b: second moving hole
400: mixing section 410: air flow path
420: Oil oil path 430: Mixed oil path
440: air conditioning hole 450: air conditioning member
460: Oil adjustment hole 470: Oil adjustment member
472: Adjustment screw 474: Fixing nut
500: Flexible pipe 600: Nozzle

Claims (7)

A body 100 detachable from the machine tool 10; and
It is installed on the inner upper part of the body 100, so that the vortex pipe 210 penetrates the upper part of the body 100, and the air inlet 220 penetrates one side or the other side of the body 100. A vortex tube 200 in which a moving tube 230 is formed in the downward direction; and
An oil supply pipe 300 installed to penetrate one side or the other side of the body 100; and
A mixing section 400 installed at the inner lower part of the body 100 and connected to the moving pipe 230 of the vortex tube 200 and the oil supply pipe 300 at the upper portion;
A flexible pipe (500) installed to penetrate the lower part of the body (100), the upper part of which is connected to the lower part of the mixing unit (400); and
It is configured to include a nozzle 600 installed at the lower part of the flexible pipe 500,
The oil supply pipe 300 is
It is installed to be located inside the body 100 and is configured to include a grinding unit 310 that grinds the oil supplied and moved,
The crushing unit 310 is
A housing 312 that is formed in a cylindrical shape and whose diameter becomes smaller toward one side or the other; and
A first crusher is installed on one side or the other inside of the housing 312, has a sharp first crushing protrusion 314a formed in the center toward one side or the other, and has a plurality of first moving holes 314b formed therethrough. A processing mist spray device comprising a crushing plate (314).
According to paragraph 1,
The body 100 is
A processing mist spray device comprising a magnet unit 110 installed on either the front or the rear.
According to paragraph 1,
The mixing section 400 is
An air passage 410 formed inside, the upper part of which is in communication with the moving pipe 230;
An oil passage 420 formed inside, the upper part of which is in communication with the oil supply pipe 300; and
A processing mist injection device comprising a mixing passage 430 connected to the lower portion of the air passage 410 and the oil passage 420 therein.
According to paragraph 3,
The mixing section 400 is
An air control hole 440 formed on the front or rear side and communicated with the air passage 410;
A processing mist injection device comprising: an air control member (450) screwed to the air control hole (440).
According to paragraph 4,
The mixing section 400 is
An oil control hole 460 formed on the front or rear side and communicated with the oil passage 420;
An oil control member (470) screwed to the oil control hole (460). A processing mist injection device comprising a.
According to clause 5,
The air control member 450 and the oil control member 470 are
A processing mist spray device, characterized in that it is installed to penetrate the front or rear of the body 100.
According to clause 5,
The air control member 450 and the oil control member 470 are
An adjustment screw 472 that is screwed into the air control hole 440 or the oil control hole 460 and whose end is inserted into the air control hole 440 or the oil control hole 460;
A processing mist injection device comprising a fixing nut (474) screwed to the outer periphery of the adjustment screw (472) and close to the front or rear of the mixing unit (400).