KR20190109683A - Device for fitering cutting oil with centrifugation type - Google Patents

Abstract

The present invention relates to a centrifugal type cutting oil filtering apparatus comprising: a cylindrical centrifugal separation unit having an internal space for accommodating a cutting oil and being rotationally driven; a foreign substance removal unit to raise foreign substances separated from the cutting oil in the inner space and discharge the same out of the centrifugal separation unit; and a driving unit for driving the centrifugal separation unit and the foreign substance removal unit. According to the centrifugal type cutting oil filtering apparatus of the present invention, it is possible to continuously filter foreign substances, thereby being able to improve production efficiency.

Description

Centrifugal coolant filtration device {DEVICE FOR FITERING CUTTING OIL WITH CENTRIFUGATION TYPE}

The present invention relates to a centrifugal coolant filtration device.

In general, all machines are finished by machining. Machining refers to a process of machining a machine part made of casting, forging, etc., and a representative machine is a machine tool.

Machine tools can implement the shape of the machine by machining the machine parts in a manner such as cutting, grinding. In the cutting and grinding processing of such machine tools, heat generated by friction between metals and cutting chips, which are processing by-products, are generated.

When excessive heat is generated, it may cause damage to the parts and equipment to be processed, and the generation of cutting chips may cause a decrease in machining accuracy or a build-up edge in which a part of the chips are welded to the tool edge. have.

In order to solve this problem, it is common to supply cutting oil during machining. The cutting oil may include mineral oil, an emulsifier, an extreme pressure agent, a synthetic emulsifier, an oily agent, and the like.

At this time, the supply of cutting oil needs to be made continuously during machining. Therefore, since the production cost is increased when the new coolant is continuously supplied, it is common to include a coolant circulation system for recycling the used coolant in the machining system.

Since the cutting chips are mixed with the cutting oil used in the machining apparatus, the reuse of the cutting oil requires a process of removing foreign substances such as the mixed cutting chips.

In the past, a process for filtering foreign matter impregnated in the coolant using a nonwoven filter has been applied to remove the foreign matter from the coolant.

However, in the process using the nonwoven filter, when the number of times of use exceeds a certain number of times, foreign substances are adsorbed to the nonwoven filter, and the filter is frequently clogged, and thus the daughter filter must be replaced frequently, thus increasing the maintenance cost. I still have

It is an object of the present invention to provide a centrifugal coolant filtration device capable of filtration for foreign matter contained in the coolant without increasing maintenance costs.

Centrifugal type cutting oil filtration device according to an embodiment of the present invention for achieving the above object, the cylindrical centrifugal separation unit having an internal space for accommodating the cutting oil, the rotation drive; A debris removal unit which lifts debris separated from the cutting oil in the inner space and discharges it out of the centrifugal separation unit; And a driving unit for driving the centrifugal separation unit and the foreign matter removing unit.

Here, the foreign matter removing unit may include a screw extending spirally along the inner circumferential surface of the inner space.

Here, the drive unit, the separation rotary shaft coupled to the centrifugal separation unit; A screw rotating shaft coupled to the screw; And a rotation motor connected to the separation rotation shaft and the screw rotation shaft, respectively, to apply rotational force.

Here, the drive unit, the rotary pulley provided on the separate rotating shaft; A screw pulley provided on the screw rotation shaft and having a diameter smaller than that of the rotation pulley; A motor rotating shaft rotated by the rotating motor; And a plurality of rotation belts connecting the motor rotation shaft, the rotation pulley, and the screw pulley, respectively.

The apparatus may further include a support unit configured to support a lower portion of the centrifugal separation unit, wherein the separation rotation shaft extends along the inside of the support unit in the centrifugal separation unit, and the screw rotation shaft may be disposed in the foreign material removal unit. It can extend along the interior of the separate rotating shaft.

The cutting oil discharge unit may further include a cutting oil discharge unit extending in a height direction in the inner space of the centrifugal separation unit to discharge the cutting oil from which the foreign matter is removed.

Here, the cutting oil discharge unit may be formed to extend along the inside of the screw rotation shaft.

Here, the centrifugal separation unit, the body having an opening in which the inner space is opened upwards; And a cover coupled to the body to cover the inner space.

Here, further comprising a foreign matter discharge unit for forming a receiving space for receiving the foreign matter discharged from the opening along the outer surface of the cover, wherein the foreign matter discharge unit, the foreign matter discharge port for guiding the foreign matter out of the receiving space; can do.

According to the centrifugal cutting oil filtration device of the present invention configured as described above it is possible to filter the foreign matter continuously without additional maintenance it is possible to improve the production efficiency.

In addition, by setting the rotational speed of the configuration for accommodating the cutting oil and the configuration for removing the foreign matter contained in the cutting oil differently, the foreign matter can be more easily removed from the cutting oil.

1 is a conceptual diagram illustrating the principle of a centrifugal coolant filtration device 100 interlocked with a machining apparatus M according to an embodiment of the present invention.
Figure 2 is an external perspective view for explaining the structure of the centrifugal coolant filtration device 100 according to an embodiment of the present invention.
3 is a cross-sectional view for explaining the centrifugal cutting oil filtration device structure 100 according to an embodiment of the present invention.
4 is a view for explaining the foreign material removal unit 120 according to an embodiment of the present invention.
5 to 7 are views for sequentially explaining the operation method of the centrifugal cutting oil filtration device (! 00) according to an embodiment of the present invention.
8 is a view for explaining the foreign matter removal unit 320 of the elevating method according to another embodiment of the present invention.

Hereinafter, a centrifugal cutting oil filtration device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are assigned to the same or similar configurations in different embodiments, and the description thereof is replaced with the first description.

1 is a conceptual diagram illustrating the principle of a centrifugal coolant filtration device 100 interlocked with a machining apparatus M according to an embodiment of the present invention.

As shown in FIG. 1, the machining system 10 may be a system for machining an object O, such as a metal. Specifically, the machining system 10 includes a machining device M for processing the shape of the object O, a cutting oil supply device G for providing the cutting oil C to the machining device M, and a cutting oil ( It may be composed of a centrifugal type cutting oil filtration device 100 (hereinafter cutting oil filtration device) for removing the foreign matter (P) contained in C).

The machining apparatus M may receive an object O, such as a metal machine part, and process it according to a set shape. At this time, the processing method may be applied to various methods such as cutting, polishing, drilling.

Cutting oil C may be provided to prevent damage to the parts and the machining apparatus M due to excessive heat during machining of the object O using the machining apparatus M. FIG.

The cutting oil C may be provided from the cutting oil supply device G to the machining device M, and may be injected onto the contact surface between the object O and the machining device M. FIG.

As such, the cutting oil C injected during the processing of the object O may be moved to the cutting oil filtration apparatus 100 while impregnating foreign matter P such as a cutting chip generated during the processing of the object O.

The cutting oil filtration device 100 may be a device for recycling the cutting oil C by removing the foreign matter P included in the cutting oil C. Therefore, the cutting oil filtration device 100 may rotate the motor such that the cutting oil C and the foreign matter P are moved in the inner surface direction when the cutting oil C including the foreign matter P is supplied to the internal space. At this time, the foreign matter (P) can be removed from the cutting oil (C) by receiving and discharging the foreign matter (P) centrifuged through the foreign matter removal unit (FIG. 2, 120) provided in the inner space.

The cutting oil C from which the foreign matter P is removed is moved to the cutting oil supply device G along the cutting oil discharge unit (FIGS. 2 and 150) provided in the housing, thereby circulating and recycling the cutting oil C. have.

According to such a machining system 10, by removing the foreign matter (P) contained in the cutting oil (C) automatically by centrifugal separation, it is possible to improve the foreign matter (P) filtration efficiency to increase the overall equipment operating efficiency.

In the above, the whole operation method of the machining system 10 was demonstrated. 2 to 4, the specific configuration of the cutting oil filtration device 100 will be described.

Figure 2 is an external perspective view for explaining the structure of the centrifugal cutting oil filtration device 100 according to an embodiment of the present invention, Figure 3 is a structure of a centrifugal cutting oil filtration device 100 according to an embodiment of the present invention. 4 is a cross-sectional view for explaining a foreign material removal unit 120 according to an embodiment of the present invention.

As shown, the cutting oil filtration apparatus 100 receives the cutting oil C including the foreign matter P from the machining apparatus M to filter the foreign matter P, and supplies the filtered cutting oil C to the cutting oil. It is a device for circulating to the device (G).

To this end, the coolant filtration device 100 includes a centrifugal separation unit 110, a foreign material removal unit 120, a support unit 130, a drive unit 140, a coolant discharge unit 150, and a foreign material discharge unit 160. It may include.

The centrifugal separation unit 110 may be formed in a cylindrical shape in which the internal space I is formed as a means for accommodating the cutting oil C.

The centrifugal separation unit 110 may include a body 111 and a cover 113.

The body 111 may be formed in a cylindrical shape formed by an opening 111a having an open upper portion. Here, the opening 111a may be formed to unfold toward the outer space. Therefore, the body 111 may have a larger diameter of the opening 111a than the diameter of the internal space I.

The cover 113 may be formed to cover the opening 111a of the body 111. In addition, the cover 113 may have a cutting oil supply hole 113a through which the cutting oil C may be supplied to the internal space I of the body 111. Therefore, when the cover 113 is coupled to the body 111, the cutting oil C may be supplied to the internal space I of the body 111 through the cutting oil supply port 113a.

The foreign material removing unit 120 is installed in the inner space (I) of the centrifugal separation unit (110) to raise the foreign matter (P) contained in the cutting oil (C), and discharge the raised foreign matter (P) out of the body (111). It is meant for. For this purpose, the foreign material removing unit 120 may include a screw 121 and a shaft connecting rod 123.

The screw 121 may have a structure spirally extending along the inner circumferential surface of the inner space I of the body 111. In this case, the screw 121 may have a screw wall 121a extending in a height direction from one side facing the inner circumferential surface of the body 111 as shown in FIG. 4.

The screw wall 121a can prevent the foreign matter P contained in the surface of the screw 121 facing the opening 111a from being separated into the space between the screw 121 and the inner circumferential surface. In this case, the screw wall 121a may not be formed in the region of the screw 121 in which the opening 111a of the body 111 is located.

In addition, although not specifically illustrated in the present embodiment, the screw 121 may be formed to be inclined toward the inner circumferential surface of the body 111. In other words, the other side surface, which is the opposite side of one side facing the inner surface of the body 111 is formed higher, so that the foreign matter P formed in the screw 121 may be inclined to continuously move in the inner surface direction. In particular, the end of the screw 121 formed adjacent to the opening 111a may be formed to be more inclined toward the opening 111a. That is, when the inclination angle of the screw 121 positioned in the internal space I of the body 111 toward the inner circumferential surface is the first angle, the inclination angle of the screw 121 positioned in the opening 111a is set to the first angle. It may be formed to have a second angle that is greater than one angle. Accordingly, the foreign matter P accommodated in the screw 121 may be more smoothly discharged toward the outside of the opening 111a.

The shaft connector 123 is a means for connecting the screw rotation shaft 142 and the screw 121 to be described later, one side is connected to the screw 121, the other side may be connected to the screw rotation shaft 142. Accordingly, the screw 121 may be provided with the rotational force of the screw rotating shaft 142 by the shaft connecting rod 123.

The support unit 130 may be connected to simultaneously support the lower portion of the rotary motor 143 of the driving unit 140, which is a means for supporting the lower portion of the centrifugal separation unit 110.

The drive unit 140 is a means for driving the centrifugal separation unit 110 and the foreign matter removal unit 120. The driving unit 140 in the present embodiment may be a means for rotating the centrifugal separation unit 110 and the foreign material removal unit 120, respectively. To this end, the driving unit 140 may include a separate rotating shaft 141, a screw rotating shaft 142, a rotating motor 143, a motor rotating shaft 144, and a rotating belt 145.

The separation rotation shaft 141 may be coupled to the centrifugal separation unit 110 to rotate the centrifugal separation unit 110. To this end, the separating rotary shaft 141 may be coupled to the lower portion of the centrifugal separation unit (110). When the separation rotation shaft 141 extends vertically toward the bottom of the centrifugal separation unit 110, the rotation pulley 141a may be coupled to one side extending downward.

The screw rotation shaft 142 may be an axis coupled to the screw 121 to rotate the screw 121. The screw rotation shaft 142 is formed to protrude in the height direction from the center of the inner space (I) of the body 111, it may extend downward. In particular, the screw rotating shaft 142 may be formed to extend along the inside of the separating rotary shaft 141 at the bottom of the centrifugal separation unit (110). In other words, the separating rotary shaft 141 may be formed to have a first diameter, and the screw rotating shaft 142 may be formed to have a second diameter smaller than the first diameter, and may extend downward along the inside of the separating rotary shaft 141. In addition, the screw rotation shaft 142 may be coupled to the screw pulley 142a on one side extending downward.

Since the diameter of the separate rotary shaft 141 is formed larger than the diameter of the screw rotary shaft 142, the diameter of the rotary pulley 141a may also be larger than the screw pulley 142a. In addition, the screw rotation shaft 142 extends downwardly longer than the separation rotation shaft 141, the screw pulley 142a may be installed on the screw rotation shaft 142 outside the separation rotation shaft 141.

The rotary motor 143 is connected to the separate rotary shaft 141 and the screw rotary shaft 142, respectively, and is a means for applying rotational force.

The motor rotation shaft 144 may be combined with the rotation motor 143 to be rotated by the rotation motor 143. In other words, the motor rotation shaft 144 may be coupled and rotated to extend in a vertical direction toward the bottom of the rotation motor 143.

The motor rotation shaft 144 may be coupled to the first motor pulley 144a and the second motor pulley 144b having the same diameter, respectively. The first motor pulley 144a may be disposed to be colinear with the rotary pulley 141a, and the second motor pulley 144b may be disposed to be collinear with the screw pulley 142a.

The rotating belt 145 is a means for connecting the motor rotating shaft 144, the rotating pulley 141a, and the screw pulley 142a, respectively. In detail, the rotation belt 145 may include a first rotation belt 145a and a second rotation belt 145b. Therefore, the first rotation belt 145a may connect the first motor pulley 144a and the rotation pulley 141a with each other. In addition, the second rotation belt 145b may connect the second motor pulley 144b and the screw pulley 142a to each other. Accordingly, when the motor rotation shaft 144 is rotated by the motor rotation, the rotational force of the motor rotation shaft 144 may be transmitted to the rotation pulley 141a and the screw pulley 142a by the rotation belt 145, respectively. Since the rotary pulley 141a and the screw pulley 142a are coupled to the separate rotary shaft 141 and the screw rotary shaft 142, respectively, as a result, the centrifugal separation unit 110 and the foreign matter removal unit are rotated by the rotation of the single rotary motor 143. 120 can be rotated simultaneously.

Here, since the rotary pulley 141a has a larger diameter than the screw pulley 142a, the foreign matter removing unit 120 may be rotated faster relative to the centrifugal separation unit 110.

The cutting oil discharge unit 150 is a means for discharging the cutting oil C installed in the internal space I of the body 111 to remove the foreign matter P to the outside. To this end, the coolant discharge unit 150 may include a coolant discharge pipe 151 and a cover 153.

The cutting oil discharge pipe 151 may be formed in a tubular shape in which the internal space I of the body 111 extends downward from the center thereof. One end of the cutting oil discharge pipe 151 positioned in the internal space I may be formed as an opening. Therefore, when the cutting oil C from which the foreign matter P is removed in the internal space I of the body 111 has a higher level than the cutting oil discharge pipe 151, the cutting oil C flows through the opening of the cutting oil discharge pipe 151 and discharges it. Can be. At this time, the cutting oil discharge pipe 151 in the internal space (I) of the body 111 may be installed to be disposed inside the skew flow rotating shaft 142. Therefore, the screw rotation shaft 142 extends in the height direction in the internal space I of the body 111, and the coolant discharge unit 150 may be disposed at the center of the screw rotation shaft 142.

The cover 153 is a means for preventing the cutting oil C supplied through the cutting oil supply port 113a from being immediately introduced into the cutting oil discharge pipe 151. To this end, the cover 153 may be installed to cover the opening of the cutting oil discharge pipe 151 on the cutting oil discharge pipe 151. In this case, the cover 153 may be installed to be spaced apart from the cutting oil discharge pipe 151 through a support extending in the height direction from the screw rotation shaft 142. Therefore, since the cutting oil discharge pipe 151 prevents the cutting oil C falling from the upper portion through the cover 153 from entering the opening of the cutting oil discharge pipe 151, the cutting oil discharge pipe 151 receives and discharges only the cutting oil C filled and introduced from the lower portion. You can.

The foreign matter discharge unit 160 is a means for accommodating and discharging the foreign matter P discharged from the opening 111a of the centrifugal separation unit 110. To this end, the foreign substance discharge unit 160 may be formed to extend downward along the outer surface of the cover 113, and may include a receiving space S communicating with the opening 111a. In other words, the foreign substance discharge unit 160 forms an accommodation space S extending downward along the circumference of the lid 113, and the accommodation space S is the opening 111a of the centrifugal separation unit 110. Can be communicated with.

Therefore, when the foreign matter (P) is discharged from the opening 111a of the centrifugal separation unit 110, the foreign matter discharge unit 160 may accommodate it in the accommodation space (S). In addition, the foreign matter discharge unit 160 may be provided with a foreign matter discharge port 161 penetrating the receiving space (S), it is possible to discharge the foreign matter (P) accommodated in the receiving space (S) to the foreign matter discharge port (161).

At this time, although not shown in the present embodiment, the foreign matter outlet 161 may be formed in plural, and the accommodation space S may be inclined to face the foreign matter outlet 161.

According to the cutting oil filtration device 100 as described above, the cutting oil C may be accommodated, and the foreign matter contained in the cutting oil C may be centrifuged at a different speed by a single motor, and at the same time, the cutting oil C may be discharged upwardly.

In the above, the structure of the cutting oil filtration apparatus 100 was demonstrated. 5 to 7 to sequentially describe the operation method of the cutting oil filtration device 100 according to the movement of the cutting oil (C).

5 to 7 are views for sequentially explaining the operation method of the centrifugal cutting oil filtration device 100 according to an embodiment of the present invention.

First, as shown in FIG. 5, the cutting oil C, which is used for machining the mechanical parts in the machining device, includes foreign materials such as cutting tips, moves to the accommodation space S of the centrifugal separation unit 110 through the cutting oil supply port 113a. Can be.

Since the body 111 of the centrifugal separation unit 110 is cylindrical, the supplied cutting oil C may be sequentially stored according to the shape of the internal space I.

When the cutting oil (C) is supplied in this way, as shown in FIG. 6, the centrifugal separation unit 110 and the foreign material removal unit 120 may be rotated at the same time by the driving unit 140.

As described above, the centrifugal separation unit 110 and the foreign matter removal unit 120 may be connected to the separation rotation shaft 141 and the screw rotation shaft 142 which are rotation shafts of different diameters, respectively, and may be rotated.

At this time, the rotating pulley 141a and the screw pulley 142a, which are pulleys of the respective rotating shafts connected to the rotating motor 143, have different diameters, and the rotating shaft pulley 141a has a larger diameter, so the screw rotating shaft 142 ) Can be rotated faster.

When the centrifugal separation unit 110 is rotated as described above, the cutting oil C accommodated in the internal space I may move and rotate toward the inner circumferential surface of the body 111 by centrifugal force. On the inner circumferential surface of the body 111 is disposed a spiral screw 121 that rotates faster than the body 111, foreign matter contained in the cutting oil (C) is rotated up along the screw 121.

Since the end of the screw 121 is rotated so as to face the opening 111a of the body 111, the foreign matter P rotated up along the screw 121 is centrifugal force at the end of the screw 121 as shown in FIG. It is thrown out toward the foreign matter discharge unit 160 installed in the cover 113 by.

The foreign substance discharge unit 160 accommodates the foreign substance P, which is squeezed out from the opening 111a, in the accommodation space S, and the foreign substance P accommodated therein is formed through the foreign substance discharge unit 160. 161 may be discharged to the outside.

Even while the foreign matter P is removed from the cutting oil C, the supply of the cutting oil C may be continued through the cutting oil supply port 113a. Therefore, the level of the cutting oil C accommodated in the internal space I is increased, and when the central water level of the internal space I is higher than the cutting oil discharge pipe 151 of the cutting oil discharge unit 150, the cutting oil C having foreign matters removed therefrom. ) May flow into the opening of the cutting oil discharge pipe 151 and be discharged. The discharged coolant may be moved back to the coolant supply device (FIG. 1, G) and recycled.

According to the operation of the cutting oil filtration device 100 as described above, the foreign matter (P) by the centrifugal force moving toward the inner surface of the foreign matter body 111, according to the lifting operation of the screw 121 is rotated faster than the body 111. ), The foreign material (P) can be removed from the cutting oil (C) by automatically raising and discharging.

In the above, the operation method of the cutting oil filtration apparatus 100 was demonstrated. In FIG. 8, a cutting oil filtration device having a foreign matter discharge unit operating in a different manner from the foreign matter discharge unit 160 of FIGS. 1 to 7 will be described.

8 is a view for explaining the foreign matter removal unit 320 of the elevating method according to another embodiment of the present invention.

As shown in FIG. 8, the coolant filtration device 300 is generally the same as the coolant filtration device (FIGS. 2 and 100) of FIGS. 1 to 7, but there are some differences in the foreign material removal unit 320 and the driving structure for driving the coolant. have.

The foreign material removing unit 320 of the present embodiment is coupled to the guide rail 321 is installed in the height direction along the inner circumferential surface in the inner space (I) of the centrifugal separation unit 310, the guide rail 321 is elevated 323.

The guide rail 321 may extend in the height direction along the inner circumferential surface to correspond to each other in the internal space I of the body 311, and the end may extend to the opening 311a of the body 311.

When the foreign matter moving body 323 is coupled to the guide rail 321 and is formed to be movable up and down, it may be formed in a shape corresponding to the cross-sectional shape of the internal space I. In other words, the foreign matter moving body 323 is formed in the shape of a donut with an empty center, or when a plurality of guide rails 321 are installed corresponding to each other, a pair of horseshoe shapes coupled to the respective guide rails 321. Can be formed. That is, the foreign matter moving body 323 may be formed to extend by a predetermined width along the circumference of the inner circumferential surface of the internal space (I).

In addition, the foreign matter removal unit 320 is connected to the drive unit 340 for rotating the centrifugal separation unit 310 may be a guide rail 321 is moved up and down, or a separate additional drive means is added to the guide The rail 321 may be driven.

According to the foreign matter removal unit 320, when the centrifugal separation unit 310 is rotated by the drive unit 340 as in the past, the cutting oil (C) including the foreign matter (P) toward the inner peripheral surface of the inner space (I). You can. At this time, the foreign matter moving unit 320 is located on the bottom surface of the internal space (I), the foreign matter conveying body 323 may be raised by the driving of the guide rail 321.

The foreign matter conveying body 323 may rise while receiving the foreign matter P rotating on the inner circumferential surface, and discharge the foreign matter P accommodated in the opening 311a of the body 311 to the foreign matter discharge unit 360. have.

The opening 311a is formed in a structure in which the circumference extends to the outside, and since the guide rail 321 is provided up to the opening 311a, the foreign matter conveying body 323 which rises horizontally in the internal space I is an opening ( According to the inclination angle of 311a), the foreign substance P may be dropped toward the foreign substance discharge unit 360.

In addition, in order to improve the discharge efficiency of the foreign matter (P) is configured to adjust the angle of the foreign matter transporting body 323, the foreign matter transporting body 323 toward the foreign matter discharge unit 360 in a state located on the opening 311a side. The angle adjustment may be performed to incline).

According to such a cutting oil filtration device 300, it is possible to raise and discharge the foreign matter (P) of the cutting oil (C) through various methods, it is possible to ensure a variety of product configuration.

The centrifugal coolant filtration device as described above is not limited to the configuration and operation of the embodiments described above. The above embodiments may be configured such that various modifications may be made by selectively combining all or part of the embodiments.

10: machining system
100, 300: coolant filtration device
110: centrifugal separation unit
120: foreign material removal unit
130: support unit
140: drive unit
150: coolant discharge unit
160: foreign substance discharge unit

Claims (9)

A cylindrical centrifugal separation unit having an internal space accommodating the cutting oil and being rotationally driven;
A debris removal unit which lifts debris separated from the cutting oil in the inner space and discharges it out of the centrifugal separation unit; And
And a drive unit for driving the centrifugal separation unit and the foreign material removal unit.
The method of claim 1,
The foreign material removal unit,
And a screw extending spirally along an inner circumferential surface of the inner space.
The method of claim 2,
The drive unit,
A separation rotating shaft coupled to the centrifugal separation unit;
A screw rotating shaft coupled to the screw; And
And a rotary motor connected to each of the separate rotating shaft and the screw rotating shaft to apply rotational force.
The method of claim 3,
The drive unit,
A rotary pulley provided on the separate rotating shaft;
A screw pulley provided on the screw rotation shaft and having a diameter smaller than that of the rotation pulley;
A motor rotating shaft rotated by the rotating motor; And
And a plurality of rotation belts connecting the motor rotation shaft, the rotation pulley, and the screw pulley, respectively.
The method of claim 4, wherein
Further comprising a support unit formed to support the lower portion of the centrifugal separation unit,
The separate rotating shaft,
Extend along the inside of the support unit in the centrifugal separation unit,
The screw axis of rotation,
Centrifugal cutting oil filtration device extending along the inside of the separation rotary shaft in the foreign matter removal unit.
The method of claim 5,
And a cutting oil discharge unit extending in a height direction in the inner space of the centrifugal separation unit to discharge the cutting oil from which the foreign matter has been removed.
The method of claim 6,
The cutting oil discharge unit,
Centrifugal coolant filtration device is formed to extend along the inside of the screw rotation shaft.
The method of claim 1,
The centrifugal separation unit,
A body having an opening in which the inner space is opened upward; And
And a cover coupled to the body to cover the inner space.
The method of claim 8,
Further comprising a foreign matter discharge unit to form a receiving space for receiving the foreign matter discharged from the opening along the outer surface of the cover,
The foreign substance discharge unit,
Centrifugal coolant filtration device comprising a foreign material outlet for guiding the foreign matter out of the receiving space.

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