KR101355408B1 - Apparatus for separating cutting oil - Google Patents

Abstract

The present invention relates to a cutting oil separation apparatus removing fluid such as cutting oil attached to metal chips produced from a lathe machine process, by compression and rotation. The cutting oil separation apparatus according to the present invention comprises a main motor (100) forming rotary power; a supply pipe (200) equipped on one side of the main motor (100) and guiding the transport of chips; a supply means (210) equipped on one side of the supply pipe (200) and forcing to supply chips to one side by the rotary power of the main motor (100); a compressing and crushing pipe (220) equipped on one side of the supply pipe (200) and compressing and crushing the chips guided to one side through the supply pipe (200); an oil removal means (300) equipped on one side of the supply means (210) and removing foreign substances attached to the chips transported along the supply pipe (200) with the centrifugal force; a rotary means (400) equipped on one side of the oil removal means (300) and guiding to switch the direction of the oil removal means (300) so as to discharge the chips in the oil removal means (300) to down; and a transport means (500) equipped on one side of the supply pipe (200) and controlling to selectively combine the oil removal means (300) to one end of the supply pipe (200). According to the present invention, the waste of resources is prevented by collecting the cutting oil, and the work performance is improved.

Description

Apparatus for separating cutting oil}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cutting oil separation device, and more particularly, to a cutting oil separation device that separates and recovers a fluid, such as cutting oil, attached to a metal chip generated from lathe work by compression milling and centrifugal force (rotation).

In general, chips generated after metal processing may be recycled because they are metal materials, but since such chips are embedded with cutting oil supplied during processing, chips and cutting oil may be difficult to recycle.

Of course, there is a device for removing the coolant, such as the prior patent No. 10-0495174, but since such a device is to remove the cutting oil to the dust collection function, it is possible to quickly and continuously Removing is actually a difficult problem.

Patent number 10-0495174

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, by compressing and crushing the chip (primarily) to remove the cutting oil and at the same time reduce the chip volume, and second The present invention provides a cutting oil separation device for forcing a cutting oil (fluid) attached to a chip to be separated by a centrifugal force.

Another object of the present invention is to provide a coolant separation device having a function of separately filtering solid foreign materials such as tools and components included in a chip.

Still another object of the present invention is to provide a cutting oil separating apparatus having a structure in which chips having been removed from cutting oil can be separated and discharged downward at a time.

According to a feature of the present invention for achieving the above object, the cutting oil separating apparatus according to the present invention, the main motor 100 for forming a rotational power; A supply pipe 200 provided at one side of the main motor 100 to guide a transfer of a chip; A supply means (210) provided at one side of the supply pipe (200) and forcibly supplying a chip to one side by the rotational force of the main motor (100); A compression pulverization tube 220 provided at one side of the supply pipe 200 and configured to compress and crush a chip guided to one side through the supply pipe 200; Deoiling means 300 is provided on one side of the supply means 210, and removes the foreign matter attached to the chip (moved) along the supply pipe 200 by centrifugal force; It is provided on one side of the deoiling means 300, the rotation means 400 for guiding the chip of the deoiling means 300 is discharged to the lower side by switching the direction of the deoiling means 300; It is provided on one side of the supply pipe 200, the transfer means 500 for controlling the deoiling means 300 is selectively coupled to one end of the supply pipe 200; characterized in that it comprises a.

The supply means 210 includes a main shaft 212 that rotates by receiving the rotational force of the main motor 100, and a supply propeller 214 formed in a spiral direction on the outer surface of the main shaft 212, ; In the inner surface of the supply pipe 200, the interference protrusion 202 protruding inward is formed in a spiral direction, characterized in that configured to interfere with the chip (chip) moving along the supply pipe 200.

The compression pulverization tube 220 is provided with at least one or more at the inner or end portion of the supply pipe 200, the inclined tube 222 and the smaller diameter than the supply pipe 200 gradually decreases toward one side Has a configuration including a small tube (224); Inside the inclined tube 222 and the small tube 224, the supply propeller 214 is formed to have a size corresponding to the diameter of the inclined tube 222 and the small tube 224; In the inner surface of the inclined tube 222 and the small tube 224, the interference protrusion 202 formed on the inner surface of the supply pipe 200 is characterized in that it is formed in a spiral direction.

The deoiling means 300 includes a deoiling case 310 selectively contacting one side of the supply pipe 200 and accommodating a chip supplied through the supply pipe 200; A deoiling motor 320 provided at one side of the deoiling case 310 and providing rotational force to the deoiling case 310; A deoiling shaft 330 connected to one end of the deoiling case 310 and transmitting a rotational force of the deoiling motor 320 to the deoiling case 310; It is provided on one side of the deoiling shaft 330, the deoiling support 320 for supporting the deoiling motor 320 and the deoiling case 310; characterized in that it comprises a.

The conveying means 500 is provided on one side of the conveying support end 510 and the conveying support end 510 coupled to the deoiling means 300, and a conveying rail for guiding the movement of the conveying support end 510. 520 and a transfer cylinder 530 provided on one side of the transfer support end 510 to force the transfer support end 510 to flow along the transfer rail 520; On the upper side of the supply pipe 200, a hopper 240 for guiding the introduction of a chip (chip) to the supply pipe 200 is further provided; At the lower end of the hopper 240, the supply control means 250 to facilitate the introduction of the chip (chip) supplied to the supply pipe 200, and at the same time to filter out the solid foreign matter in the chip (chip) is characterized in that it is provided do.

Cutting oil separating apparatus according to the present invention has the following effects.

First, in the present invention, a chip is continuously supplied to one side by a propeller, and at the same time, there are a plurality of portions in which a moving path of the chip is narrowed by a compression mill. In addition, the compression pulverization tube is provided with an interference protrusion to cause chip pulverization. Therefore, as the chip passes through the compression pulverization tube, the chip is crushed and compressed, whereby a fluid such as cutting oil naturally contained in the chip is advantageously separated first.

In the present invention, the cylindrical feed pipe end is further provided with a deoiling means for separating the fluid (cutting oil) by centrifugal force. Therefore, since the foreign matter adhering to such a chip is removed secondarily, there is an effect that foreign matter (cutting oil) is removed more reliably.

In the present invention, after the cutting oil is separated by the centrifugal force, the deoiling means is rotated by the rotating means. Therefore, since the chip contained in the oil removal case is automatically discharged to the lower side, there is an advantage that the work efficiency is improved.

In addition, in the present invention, the supply control means is further provided on the lower side of the hopper to which the chip is supplied, to facilitate the supply of the chip and to prevent the introduction of foreign substances. Therefore, since the input of the tool or parts is prevented, there is an advantage that the failure of the machine is prevented, and the waste of the tool or the part is blocked.

As described above, according to the present invention, since cutting oil is effectively separated from the chip and the cutting oil recovery rate is increased, the waste of resources and the processing cost are reduced. At the same time, a pleasant working environment can be realized and work efficiency can be improved.

1 is a perspective view showing the configuration of a preferred embodiment of a cutting oil separating apparatus according to the present invention.
Figure 2 is a front view showing the internal configuration of a preferred embodiment of a cutting oil separation apparatus according to the present invention.
Figure 3 is a plan view showing the configuration of the supply control means constituting the embodiment of the present invention.
Figure 4 is a front sectional view showing the configuration of the supply control means constituting the embodiment of the present invention.
5 is a use state showing a state in which the deoiling means constituting the embodiment of the present invention is separated from the supply pipe.
Figure 6 is a state of use of the deoiling means constituting an embodiment of the present invention showing a 90-degree rotational state.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the cutting oil separating apparatus according to the present invention will be described in detail.

1 to 4 show the configuration of one embodiment of a cutting oil separation apparatus according to the present invention. 1 and 2 respectively show a perspective view and a front view of the cutting oil separating apparatus according to the present invention, and FIGS. 3 and 4 show a plan view and a front view of the supply control means constituting the embodiment of the present invention, respectively. .

As shown in these drawings, the cutting oil separating apparatus according to the present invention includes a main motor 100 for forming rotational power, a supply pipe 200 for guiding the transfer of chips, and the main motor 100. Supply means 210 forcibly supplying the chip (chip) to one side by the rotational force of the compression, the compression crushing tube 220 to compress and crush the chip (chip) guided to one side through the supply pipe 200, Deoiling means 300 for removing foreign matter attached to the chip (chip) moved along the supply pipe 200 by the centrifugal force, and the chip (chip) of the deoiling means 300 by switching the direction of the deoiling means 300 Rotation means 400 to guide the discharge to the lower side, and the deoiling means 300 is composed of a transfer means 500 for controlling to be selectively coupled to one end of the supply pipe (200).

In more detail, as shown, the base 10 having a square plate shape having a predetermined thickness is provided, and the plurality of parts are installed on the base 10.

And, the lower side of the base 10 is provided with four moving wheels 12, so that the transfer is made smoothly.

As shown, the main motor 100 is fixedly mounted at a predetermined height above the right end of the base 10. The main motor 100 generates a rotational power by electricity supplied from the outside to provide to the supply means 210.

The rear side of the main motor 100 is further provided with a reducer 110 to reduce the rotational force generated in the main motor 100, the supply pipe 200 is installed on the left side of the reducer 110. The reducer 110 serves to reduce the rotational force of the main motor 100 and increase the force (torque), and thus the description of further configuration will be omitted here.

As shown in the drawing, the supply pipe 200 is formed in a cylindrical shape and is formed long in left and right. And, the supply pipe 200 is fixedly supported by a pair of body support end 120 on the upper side of the base (10).

On the inner surface of the supply pipe 200, an interference protrusion 202 protruding inwardly is formed in a spiral direction, so as to interfere with a chip moving along the supply pipe 200. That is, the inner surface of the supply pipe 200 is formed so that the interference protrusion 202 having a semi-circular or triangular cross section protrudes inward. Therefore, since the gap between the interference protrusion 202 and the supply propeller 214 to be described below is narrowed, the chip is moved through the gap between the interference protrusion 202 and the supply propeller 214. (chip) is finely cut (cut) effect.

In addition, a plurality of drainage holes 204 are formed through the lower end of the supply pipe 200. The drain hole 204 is a hole through which the cutting oil (liquid) separated from the chip in the supply pipe 200 is discharged downward.

Coupling 130 is further provided between the supply pipe 200 and the reducer 110 as shown. The coupling 130 is connected to the reducer 110 and the motor shaft 102 to transmit the rotational force generated from the main motor 100 to the outside, and the main shaft 212 to be described below to each other It plays a role.

The supply means 210 is provided inside the supply pipe 200.

The supply means 210 is composed of a main shaft 212 rotated by the rotational force of the main motor 100 and a supply propeller 214 formed in a spiral direction on the outer surface of the main shaft 212. do.

The main shaft 212 is a rotational central axis that is rotated by receiving the rotational force of the main motor 100. In addition, the supply propeller 214 is fixedly mounted integrally with the outer surface of the main shaft 212 spirally.

The compression pulverization tube 220 is further provided inside the supply pipe 200, so that chips guided to the left through the supply pipe 200 are pulverized at the same time as the compression, and the cutting oil is separated by the compression. do.

The compression pulverization tube 220 is provided with at least one or the inner end portion of the supply pipe 200. That is, the compression pulverization tube 220, one or two are provided in the interior of the supply pipe 200, it is preferable that also provided in the left end. In this embodiment, the compression pulverization tube 220 is exemplified in the case where one is mounted on each of the inner and left ends of the supply pipe 200 (see Fig. 2).

The compression pulverization tube 220 is composed of an inclined tube 222 that gradually decreases in diameter toward one side, and a small tube 224 having a smaller diameter than the supply pipe 200.

Specifically, as shown, the compression pulverization tube 220 is a funnel-shaped inclined tube 222 gradually narrowing toward the left side, and the left end of the inclined tube 222 (in Figure 2) It consists of a small tube 224 formed. In addition, a coupling part 226 fixed to the inner surface of the supply pipe 200 is further formed at the right end (in FIG. 2) of the inclined pipe 222.

The supply propeller 214 and the interference protrusion 202 described above are also provided inside the compression crushing tube 220, respectively.

Looking in more detail, the inner side of the inclined tube 222 and the small tube 224, the supply propeller 214 is formed to have a size corresponding to the diameter size of the inclined tube 222 and the small tube (224). do. That is, the supply propellers 214 having an outer diameter smaller than the supply propellers 214 of relatively other portions are respectively provided.

The interference protrusions 202 formed on the inner surface of the supply pipe 200 are also formed in the spiral direction on the inner surfaces of the inclined pipe 222 and the small pipe 224.

As such, since the supply propeller 214 and the interference protrusion 202 are formed at positions corresponding to each other in the compression pulverization tube 220, chips are cut while passing through the compression pulverization tube 220. (Cutting) is made, resulting in more grinding.

In addition, a support bearing 230 is further provided inside the left end of the supply pipe 200.

Looking in more detail, the support bearing 230 is installed on the outside of the compression crushing tube 220 provided on the left end of the supply pipe 200. That is, as shown, the support bearing 230 is fixedly mounted on the outer surface of the small tube 224 constituting the compression crushing tube 220.

The support bearing 230 serves to rotatably support the right end of the oil removal case 310 to be described below. Therefore, a predetermined gap is formed between the support bearing 230 and the left end of the supply pipe 200 so that the right end of the oil removal case 310 to be described below is inserted.

On the other hand, the upper side of the supply pipe 200, the hopper 240 for guiding the introduction of the chip (chip) to the supply pipe 200 is further provided. As shown in the figure, the hopper 240 is configured to have a shape in which the cross-sectional area of the inside gradually decreases toward the lower side, so that the chip supplied from the upper side is introduced into the lower supply pipe 200. .

In addition, the lower end of the hopper 240, the supply control means 250 to facilitate the introduction of the chip (chip) supplied to the supply pipe 200 and to filter out the solid foreign matter in the chip (chip) is provided. .

As shown in FIG. 3 and FIG. 4, the supply control means 250 includes a pair of supply rollers 252 and a supply protrusion protruding in a spiral direction on an outer surface of the supply roller 252. 254).

The pair of feed rollers 252 are installed to be adjacent to each other as shown, the feed projections 254 formed in the pair of feed rollers 252 are installed so that their positions cross each other. Therefore, parts and tools such as bolts or drivers cannot pass through the gap between the pair of feed rollers 252.

On the other hand, the pair of feed roller 252 is formed to be inclined so that its height is gradually lowered or higher toward one side. That is, as shown, the height is lowered toward the left side, the feed roller 252 has a predetermined inclination angle (α) with respect to the horizontal. In addition, the inclination angle α preferably has a size of about 5 to 10 degrees.

The lower left side of the pair of feed rollers 252 is further provided with a tool die 260 in which tools or parts are discharged.

In addition, the pair of feed rollers 252 are configured to rotate at a slow speed by the rotational force of a motor (not shown).

Therefore, when the pair of feed rollers 252 are rotated in opposite directions (see arrows in FIG. 3) while being inclined, the upper chip is lowered through the gap between the pair of feed rollers 252. It is pushed down, and parts or tools such as bolts do not pass through the gap between the pair of feed rollers 252 and gradually move to the left and are discharged to the tool die 260.

The deoiling means 300 is installed on the left side of the supply means 210 and has a function of removing foreign matter attached to a chip moved along the supply pipe 200 to the left by centrifugal force.

The deoiling means 300 includes a deoiling case 310 in which a chip supplied through the supply pipe 200 is accommodated, a deoiling motor 320 providing rotational force to the deoiling case 310, and the It is composed of a deoiling shaft 330 for transmitting the rotational force of the deoiling motor 320 to the deoiling case 310, and a deoiling support end 340 for supporting the deoiling motor 320 and the deoiling case 310.

The deoiling case 310 corresponds to a dehydrating container such as a washing machine, and has a cylindrical shape in which a right end is opened and a left end is shielded. In this deoiling case 310, a plurality of deoiling holes 312 through which a fluid such as cutting oil is discharged is formed.

The deoiling case 310 is selectively in contact with the left end of the supply pipe (200). That is, the right end of the deoiling case 310 and the left end of the supply pipe 200 overlap each other by the transfer means 500.

In detail, the left end inner surface of the supply pipe 200 has a predetermined gap with the outer surface of the support bearing 230, and the right end of the oil removal case 310 is inserted into the gap.

And, more preferably, the right end of the oil removal case 310 may be mounted to the outer surface of the support bearing 230 with a slight interference fit. Therefore, when the oil loss case 310 is rotated, the support bearing 230 is to rotatably support the right end of the oil loss case 310.

The deoiling motor 320 is provided on the left side of the deoiling case 310 to provide rotational force to the deoiling case 310.

In addition, the deoiling shaft 330 serves to connect the deoiling motor 320 and the deoiling case 310 installed to be spaced apart from each other. That is, the left end of the deoiling shaft 330 is connected to the deoiling motor 320, and the right end is connected to the left end of the deoiling case 310. Therefore, as the deoiling motor 320 rotates, the deoiling case 310 rotates.

On the outside of the deoiling shaft 330, the deoiling support end 340 is provided.

The deoiling support 340 is formed in a 'U' shape (as seen from the upper left side), as shown, and the deoiling shaft 330 is rotatably penetrated through the deoiling support 340.

The rotating means 400, as shown, is provided on the rear side of the deoiling means 300 to control the deoiling means 300 to rotate 90 degrees.

The rotation means 400, as shown, the upright cylinder 410, the connecting table 420 connected to the deoiling support end 340, the connecting table 420 and the upright cylinder 410 rotate with each other The coupling link 430 to be connected to the possible, and the rotary support shaft 440 is provided on the rod portion of the upright cylinder 410 so that the upright cylinder 410 is rotatably supported.

In addition, the rotation means 400 is supported by the rotation support 450 having a predetermined height up and down. The rotary support 450 is installed to be movable left and right, such as the transfer support end 510 to be described below.

The transfer means 500 is provided at the left front side of the supply pipe 200, so that the deoiling means 300 is selectively coupled to the left end of the supply pipe 200.

The conveying means 500 is provided on one side of the conveying support end 510 and the conveying support end 510 coupled to the deoiling means 300, and a conveying rail for guiding the movement of the conveying support end 510. 520 and a transfer cylinder 530 provided on one side of the transfer support 510 to force the transfer support 510 to flow along the transfer rail 520.

As shown in the drawing, the conveying rails 520 are installed on the top and rear ends of the upper surface of the base 10, respectively, and are long left and right, along the conveying rail 520, the conveying support end 510 and the rotating support. 450 flows from side to side. Therefore, a rail wheel 512 may be further provided at the lower ends of the transfer support end 510 and the rotary support 450.

The transfer cylinder 530 is fixed to the body support end 120 or the base 10. That is, the right end of the transfer cylinder 530 is fixed to the body support end 120 or the base 10, and the rod of the left end is fixed to the transfer support end 510.

In addition, the transfer support end 510 is rotatably connected to the right end of the front end of the deoiling support end 340. Therefore, when the transfer support end 510 is moved left and right by the transfer cylinder 530, the deoiling means 300 is moved to the left and right.

Hereinafter, the operation of the cutting oil separator of the present invention having the configuration as described above will be described with reference to FIGS. 1 to 6.

First, a chip is introduced from the upper side of the hopper 240 in the same state as in FIGS. 1 and 2. In this case, as the pair of feed rollers 252 rotate, the chip is guided downward through the pair of feed rollers 252 and flows into the right side of the supply pipe 200.

In addition, since the main shaft 212 and the supply propeller 214 rotate as the main motor 100 rotates, the chip introduced into the right side of the supply pipe 200 gradually moves to the left side. do.

When the chip inside the supply pipe 200 moves to the left side, the gap between the supply propeller 214 and the interference protrusion 202 is narrow, so that a part of the chip is crushed (cut out) in this process. And split.

In addition, the grinding (cutting) of the chip is increased while passing through the compression crushing tube 220. That is, since the supply propeller 214 and the interference protrusion 202 are also provided inside the compression pulverization tube 220, when the compression pulverization tube 220 passes, the chip is compressed and the cutting oil is separated and the chip ( Many incisions of the chip also occur.

The liquid (cutting oil) separated while passing through the compression pulverization tube 220 is discharged downward through the drain hole 204.

A chip moved to the left through the supply pipe 200 is disposed inside the deoiling case 310. After a chip having a predetermined capacity flows into the deoiling case 310, the main motor 100 stops, and the deoiling means 300 operates from this time.

According to the rotation of the deoiling motor 320 of the deoiling means 300, the deoiling case 310 is rotated. Therefore, the liquid (cutting oil) attached to the chip introduced into the deoiling case 310 is separated and discharged to the outside through the deoiling hole 312.

Then, the deoiling means 300 is moved to the left by the conveying means 500. That is, when the transfer cylinder 530 pushes the transfer support end 510, the transfer support end 510 and the rotary support 450 move to the left side, so that the deoiling means 300 and the rotating means ( 400 all move to the left.

As such, when the deoiling means 300 and the rotating means 400 move to the left side, as shown in FIG. 5, the right end of the deoiling case 310 is completely separated from the left end of the supply pipe 200.

Then, the rotating means 400 is operated to rotate the deoiling means 300 by 90 degrees. That is, when the upright cylinder 410 pulls the coupling link 430, the degreasing support end 340 rotates clockwise around the right end, so that the deoiling case 310 is vertical as shown in FIG. Upright.

As described above, when the deoiling case 310 is rotated to the state as shown in FIG. 6, the right end of the deoiling case 310 is opened, so that the chip inside thereof falls down. Of course, if the internal chip does not fall naturally due to the frictional force, it may be forcibly pulled down, but it is obvious that the work becomes convenient.

When the chip inside the deoiling case 310 is removed by the above process, the deoiling means 300 is rotated counterclockwise to the state as shown in FIG. 5, and then transferred to the conveying means 500. By returning to the original position as shown in Figure 1, the operation is made from the beginning.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

For example, the above embodiment illustrates a number of configurations including an upright cylinder 410 as the rotating means 400, but a rotary motor having a function capable of rotating the deoiling means 300 by 90 degrees. Of course, it can be replaced by a variety of mechanisms and configurations, such as.

100. Main motor 110. Reducer
120. Body support 200. Supply pipe
210. Supply means 220. Compression mill
230. Bearing 240. Hopper
250. Supply control means 300. Deoiling means
310. Deoiling case 400. Rotating means
500. Means of Transport

Claims (5)

A main motor 100 for forming rotational power;
A supply pipe 200 provided at one side of the main motor 100 to guide a transfer of a chip;
A supply means (210) provided at one side of the supply pipe (200) and forcibly supplying a chip to one side by the rotational force of the main motor (100);
A compression pulverization tube 220 provided at one side of the supply pipe 200 and configured to compress and crush a chip guided to one side through the supply pipe 200;
Deoiling means 300 is provided on one side of the supply means 210, and removes the foreign matter attached to the chip (moved) along the supply pipe 200 by centrifugal force;
It is provided on one side of the deoiling means 300, the rotation means 400 for guiding the chip of the deoiling means 300 is discharged to the lower side by switching the direction of the deoiling means 300;
Cutting oil separating apparatus is provided on one side of the supply pipe (200), the supply means for controlling the deoiling means 300 is selectively coupled to one end of the supply pipe (200). The method of claim 1, wherein the supply means 210,
A main shaft (212) rotated by the rotational force of the main motor (100) and a supply propeller (214) formed in a spiral direction on an outer surface of the main shaft (212);
On the inner surface of the supply pipe 200,
Cutting oil separation device, characterized in that the interference protrusion (202) protruding inwardly formed in a spiral direction, so as to interfere with the chip moving along the supply pipe (200). The method of claim 2, wherein the compression crushing tube 220,
At least one or more is provided at the inner side or the end of the supply pipe 200, the inclination pipe 222 gradually decreases in diameter toward one side and includes a small pipe 224 having a smaller diameter than the supply pipe 200 Has a configuration;
Inside the inclined tube 222 and the small tube 224,
The feed propeller 214 is formed to have a size corresponding to the diameter of the inclined pipe 222 and the small pipe 224;
In the inner surface of the inclined tube 222 and the small tube 224,
Cutting oil separation device, characterized in that the interference projections formed on the inner surface of the supply pipe 200 is formed in a spiral direction. According to any one of claims 1 to 3, The deoiling means 300,
A deoiling case 310 selectively contacting one side of the supply pipe 200 and accommodating a chip supplied through the supply pipe 200;
A deoiling motor 320 provided at one side of the deoiling case 310 and providing rotational force to the deoiling case 310;
A deoiling shaft 330 connected to one end of the deoiling case 310 and transmitting a rotational force of the deoiling motor 320 to the deoiling case 310;
Cutting oil separating apparatus is provided on one side of the deoiling shaft (330), and a deoiling support end (340) for supporting the deoiling motor (320) and the deoiling case (310). The method of claim 4, wherein the transfer means 500,
A transfer support end 510 coupled to the deoiling means 300, a transfer rail 520 provided at one side of the transfer support end 510 to guide movement of the transfer support end 510, and the transfer support It is provided on one side of the stage (510) has a configuration including a transfer cylinder (530) for forcing the transfer support end (510) to flow along the transfer rail (520);
On the upper side of the supply pipe 200,
A hopper 240 for guiding the introduction of chips into the supply pipe 200 is further provided;
At the lower end of the hopper 240,
Cutting oil separating apparatus characterized in that the supply control means 250 for facilitating the input of the chip (chip) supplied to the supply pipe 200 and at the same time to filter out the solid foreign matter in the chip (chip).

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