KR20080069012A - Apparatus for separating chips in coolant oil - Google Patents

Abstract

An apparatus of automatically discharging chips in cooing oil is provided to automatically discharge the chips to the outside by separating chips including impurities from the cooling oil using a plurality of electromagnets and then changing magnetization of the electromagnet. An apparatus of automatically discharging chips in a cooling oil comprises a separation plate(19) and a discharge plate(20) that are integrally connected to each other and mounted to an opening of a cooling oil tank(10). A plurality of electromagnets(23,24) are installed on the bottom surface of the separation plate and the discharge plate. All of the electromagnets attached to the bottom surface of the separation plate are magnetized to separate the chip including impurities. The electromagnets are magnetized in the sequence of the electromagnet farthest from the discharge plate and the electromagnet farthest from the separation plate to discharge the chips.

Description

Apparatus for separating chips in coolant oil}

1 is a schematic diagram of a conventional apparatus for chip detachment mounted in a grinding machine.

2 is a block diagram of a chip separating device in a conventional coolant oil installed in a centerless grinding machine.

3 is a perspective view of an apparatus for separating and automatically discharging chips in coolant oil according to the present invention.

4 is an exploded perspective view of an apparatus for separating and automatically discharging chips in coolant oil according to the present invention.

5 is a plan view of an apparatus for separating and automatically discharging chips in coolant oil according to the present invention.

6 and 7 are cross-sectional views of an apparatus for separating and automatically discharging chips in coolant oil according to the present invention.

-Explanation of symbols for the main parts of the drawings

10: coolant oil tank 11: chip separation and discharge device

12, 13 bulkhead 14: circulation pump

15, 16: opening 17: support jaw

18: Chip collection box 19: Separating plate

20: discharge plate 21: guide

22: handle 23, 24: electromagnet

The present invention relates to an apparatus for separating and automatically discharging chips in coolant oil. In particular, the present invention is to separate the chips containing iron and impurities from the coolant oil flowing through the inclined surface using a plurality of electromagnets, and to change the magnetization state of the plurality of electromagnets sequentially, the chip comprising iron and impurities separated The present invention relates to a device for separating and automatically discharging a chip in coolant oil that enables the discharge of the same to the outside.

In general, a chip separating device uses a magnet to contain iron, impurities, and the like contained in coolant oil used in general industrial equipment such as plastic processing machines such as grinding machines, metal cutting machines, and rolling mills. It is a device that separates and removes them so that they can be kept and used with clean coolant oil.

The chip separation apparatus in the conventional coolant oil for removing chips including iron, impurities, and the like incorporated into the coolant oil is as shown in FIG. 1.

That is, the structure is a magnetic drum 103 is mounted in the frame body portion 102 of the chip separation device 100, a ringer roll 104 on the upper side of the magnetic drum 103 and the outer peripheral surface The chip separating guide plate 105 is installed in the opposite direction to the opposite side, and the bottom of the magnetic drum 103 is provided through the coolant oil inlet 106 provided at one side of the frame main body 102. The coolant oil is introduced into the formed coolant oil passage 107, and a coolant oil outlet 109 is provided at one side of the coolant oil inlet 106 to discharge discharge wall 108.

In the chip separating apparatus having such a configuration, as shown in FIG. 1, the coolant oil used in the operation of the grinding machine or the rolling mill is provided at the coolant oil inlet 106 provided at one side of the frame main body 102 of the chip separating apparatus 100. Through the coolant oil passage in the bottom of the magnetic drum 103 through the chip and coolant oil is separated, the chip is completely removed through the upper ringer roll 104 and the chip separating guide plate 105, The removed coolant oil is discharged to the coolant oil outlet 109 through the upper part of the discharge partition 108 installed on the discharge port side.

However, since the chip separation device as described above requires a driving device such as a motor, the manufacturing cost is high, the structure is complicated, and the chip separation guide plate made of brass adheres closely to the magnetic drum, causing damage to the magnetic drum periodically. Since it requires calibration or replacement, the working efficiency is low and economical. Above all, the chip is removed while rotating the magnetic drum, so the separation force is lowered and the efficiency is reduced. When water-insoluble coolant oil is used, the removal rate is high. Only about 10%.

Applicant has developed an apparatus for separating chips from coolant oil, which is mounted on a centerless grinder 208 or the like, which is configured as shown in FIG.

According to the conventional chip separating apparatus as shown in FIG. 2, when a workpiece, such as a round bar, is supplied from the product supply hopper 204 to the input conveyor 205, the workpiece is moved on the input conveyor 205 to move over the blade 206. As it is thrown between the two abrasive grindstone 207 and grinds, it passes through the blade 206, whereby the workpiece passed through the grinding machine 208 is moved to the product exit conveyor 209 to proceed to the next process step.

Coolant oil is supplied on the grinding machine 208 while the workpiece is being ground, and chips generated by the grinding process are mixed into the coolant oil and discharged. Coolant oil containing chips discharged from the grinding machine 208 is supplied to the chip separator, which is a first chip separator 201 for separating the thick chips and a second chip for separating the fine chips. It consists of a chip separator 202. The coolant oil is discharged from the grinding machine 208 and passes through the primary chip separator 201 and the secondary chip separator 202 in order to enter the coolant oil tank 203 and the coolant oil tank 203. The coolant oil collected therein is configured to return back to the grinding machine 208 by the circulation pump 210.

The conventional chip separator as described above has the advantage that it is not necessary to have a separate power source such as a motor because the chip is separated from the coolant oil using a magnet, but if the chips separated from the coolant oil are accumulated Since the separation efficiency is significantly reduced, the operator (manager) has to remove the separated chip from time to time.

The present invention for solving the various problems that occur in the conventional chip separation device as described above, as well as not having a power source such as a motor, as well as workers containing chips containing iron and impurities separated from coolant oil (an administrator The purpose is to change the magnetization state of a plurality of electromagnets and to discharge them automatically even without scraping them directly.

An apparatus for separating and automatically discharging chips in coolant oil according to the present invention for achieving the above object is discharged from a general industrial equipment such as a plastic processing machine including a grinding machine, a metal cutting machine and a rolling mill. An apparatus for separating and automatically discharging chips in coolant oil capable of separating and discharging chips containing iron and impurities in coolant oil, comprising: separating and discharging chips containing iron and impurities from the coolant oil The separation plate and the discharge plate are integrally connected and seated in the opening of the coolant oil tank; A plurality of electromagnets which can be magnetized independently are provided on the bottom surface of the separation plate and the discharge plate; The plurality of electromagnets attached to the bottom of the separation plate are all magnetized to separate chips containing iron and impurities from coolant oil, and the separation from the electromagnet located at the bottom of the separation plate farthest from the discharge plate. Chips containing iron and impurities which are magnetized sequentially and separated from coolant oil are discharged to the electromagnet located at the bottom of the discharge plate farthest from the plate.

In the present invention, it is preferable that the contaminated coolant oil does not flow into the separation plate while the plurality of electromagnets are sequentially magnetized.

In the present invention, when the contaminated coolant oil is continuously introduced into the separation plate, the plurality of electromagnets are discharged while the coolant oil flowing into the upper portion of the separation plate flows down to the lower portion of the separation plate The magnetization is preferably sequentially magnetized from the electromagnet located at the bottom of the separation plate farthest from the plate to the electromagnet located at the bottom of the discharge plate farthest from the separation plate.

In addition, the apparatus for separating and automatically discharging the chip in the coolant oil according to the present invention, the iron and impurities in the coolant oil discharged from the general industrial equipment, such as a plastic processing machine including a grinding machine, a metal cutting machine and a rolling mill. An apparatus for separating and automatically discharging chips in coolant oil capable of separating and discharging chips, wherein the separating plate and the discharge plate for separating and discharging chips containing iron and impurities from the coolant oil are integrally formed. Connected to the opening of the coolant oil tank; A plurality of electromagnets which can be magnetized independently are provided on the bottom surface of the separation plate and the discharge plate; The plurality of electromagnets attached to the bottom of the separation plate are all magnetized to separate chips containing iron and impurities from coolant oil, and from the electromagnet located at the bottom of the separation plate farthest from the discharge plate. The magnetic force is sequentially lost to the electromagnet located at the bottom of the discharge plate farthest from the separation plate, and chips containing iron and impurities separated from the coolant oil are discharged to the outside.

In addition, in the present invention, the end of the separation plate is preferably disposed to be located in the opening lower than the end connected to the discharge plate.

In addition, in the present invention, the end of the discharge plate is preferably disposed to be located outside the opening lower than the end connected to the separation plate.

In addition, in the present invention, the separation plate and the discharge plate is preferably made of a nonmagnetic material.

Hereinafter, the present invention will be described in detail.

3 to 7 show an apparatus for separating and automatically discharging chips in coolant oil according to the present invention, as shown in FIG. 2, which may be mounted on a centerless grinder or the like together with a primary chip separating apparatus. It can also be equipped to directly filter coolant oil from a centerless grinder, etc. without passing through a secondary chip separator.

The apparatus for separating and automatically discharging chips in the coolant oil shown in FIGS. 3 to 7 includes a chip separating and discharging device 11 mounted on the coolant oil tank 10. The oil tank 10 may use an existing general tank as it is.

The partition walls 12 and 13 are installed in the coolant oil tank 10, and the partition walls 12 and 13 cool all of the coolant oil introduced through the chip separating and discharging device 11. Instead of flowing directly under the circulating pump 14 installed above the runt oil tank 10, foreign matters heavier than the coolant oil contained in the coolant oil sink down, and light foreign matters float up, so that the circulation pump 14 Do not flow into the installed space.

The upper part of the coolant oil tank 10 in which the chip separating and discharging device 11 is mounted is collected in the opening 15 and the coolant oil tank 10 for separating and coupling the chip separating and discharging device 11. An opening 16 capable of coupling a circulation pump 14 for circulating the clean coolant oil back to the centerless grinder is formed in communication with the coolant oil tank 10. In particular, the support jaw 17 for supporting the chip separating and discharging device 10 which is seated in the opening 15 does not fall below a certain height is formed horizontally on the inner surface of the opening 15. Of course, it is obvious that the opening 15 in which the chip separating and discharging device 11 is mounted should be higher than the opening 16 in which the circulation pump 14 is coupled.

In addition, at one side of the coolant oil tank 11, a chip collection box 18 for collecting chips separated and discharged from the coolant oil by the chip separating and discharging device 11 is disposed.

The chip separating and discharging device 11 seated at the opening 15 of the coolant oil tank 10 has a separating plate 19 for discharging and separating chips containing iron and impurities from the coolant oil. As the plate 20 is integrally connected to have an angle of about 90 degrees, the end of the separation plate 19 is located in the opening 15 of the coolant oil tank 10 lower than the end connected with the discharge plate 20, The end of the discharge plate 20 is located outside the opening 15 of the coolant oil tank 10 lower than the end connected to the separation plate 19. That is, the end of the discharge plate 20 is located at the upper end of the chip collection box 18.

Guide plates 21 for guiding the flow of coolant oil are provided at both sides of the separation plate 19 and the discharge plate 20 made of a nonmagnetic material such as SUS, and at the center of the guide 21, chip separation and When the outlet device 11 is coupled to the opening 15 of the coolant oil tank 10, a handle 22 that can be held by hand is installed.

A plurality of electromagnets 23 and 24 which can be magnetized independently are installed on the bottom of the separation plate 19 and the discharge plate 20. Iron and impurities from the coolant oil flowing through the separation plate 19 are installed. When separating the chips containing the electromagnets 23 on the bottom of the separation plate 19 is all magnetized, the chips containing iron and impurities separated from the coolant oil to be discharged to the chip collection box (18). The electromagnet 24 located at the bottom of the discharge plate 20 at a distance from the separation plate 19 from the electromagnet 23 located at the bottom of the separation plate 19 at the farthest distance from the discharge plate 20. It will be magnetized sequentially as it goes.

That is, the plurality of electromagnets 23 and 24 are magnetized sequentially in the separating plate 19 while going in the opposite direction of the flow of coolant oil, and downwardly in the discharge plate 20 along the inclination angle, Chips containing iron and impurities located above are collected in the chip collection box 18 on the separation plate 19 and the discharge plate 20.

In this case, when the plurality of electromagnets 23 and 24 are magnetized sequentially to transfer chips including iron and impurities to the chip collection box 18, the contaminated coolant oil should not flow into the separation plate 19. This is because chips containing iron and impurities are not separated from the coolant oil flowing through the separation plate 19 because the remaining electromagnet loses its magnetic force.

In addition, when the contaminated coolant oil is continuously introduced into the separation plate 19, the plurality of electromagnets 23 and 24 have the coolant oil introduced into the upper portion of the separation plate 19 at the lower portion of the separation plate 19. From the electromagnet 23 at the bottom of the separation plate 19 farthest from the discharge plate 20 to the electromagnet 24 at the bottom of the discharge plate 20 farthest from the separation plate 19 while flowing down to The magnetized sequential magnetization should not be introduced into the coolant oil tank 10 as it is being filtered.

In the above description, the electromagnets 23 and 24 are sequentially magnetized to move chips including iron and impurities to the chip collection box 18, but the present invention is not limited thereto, and the magnetized electromagnets 23 ( The same effect can be obtained if 24) loses the magnetic force sequentially.

That is, when the chips containing iron and impurities are separated from the coolant oil flowing through the separation plate 19, the electromagnets 23 on the bottom of the separation plate 19 remain magnetized as in the above case. When the chips containing iron and impurities separated from the coolant oil are discharged to the chip collection box 18, the separation plate (from the electromagnet 23 on the bottom of the separation plate 19, which is farthest from the discharge plate 20) One or two electromagnets 23, 24 lose their magnetic force sequentially as they go to the electromagnet 24 at the bottom of the discharge plate 20 at the furthest distance from 19).

Accordingly, the chips containing iron and impurities in the electromagnets 23 and 24 which have lost their magnetic force move toward the adjacent electromagnets 23 and 24 where they are magnetized, thereby removing the iron and impurities located above the separation plate 19. The containing chips are moved to the chip collection box 18 by the separation plate 19 and the discharge plate 20.

In addition, a method of changing the magnetization state of the electromagnets 23 and 24 to move the chips containing iron and impurities toward the chip collection box 18 may be variously modified.

Therefore, according to the present invention, unlike the prior art in which a worker (manager) scrapes the iron and impurities chips from the coolant oil by using a magnet, the present invention uses a plurality of electromagnets to ride a slope. After separating the chips containing iron and impurities from the flowing coolant oil, the magnetization state of the plurality of electromagnets is sequentially changed to automatically discharge the chips containing iron and impurities to the outside, thereby removing the iron and the coolant oil. The unnecessary work of the operator (administrator) for discharging chips containing impurities can be eliminated.

Claims (7)

Separating and automatically discharging chips in coolant oil that can separate and discharge chips containing iron and impurities in coolant oil discharged from general industrial equipment such as grinding machines, plastic cutting machines including rolling mills and rolling mills In the device for A separation plate and an exhaust plate for separating and discharging chips containing iron and impurities from the coolant oil are integrally connected and seated at an opening of the coolant oil tank; A plurality of electromagnets which can be magnetized independently are provided on the bottom surface of the separation plate and the discharge plate; The plurality of electromagnets attached to the bottom of the separation plate are all magnetized to separate chips containing iron and impurities from coolant oil, and the separation from the electromagnet located at the bottom of the separation plate farthest from the discharge plate. By separating the chips in the coolant oil characterized in that the chips containing iron and impurities separated from the coolant oil are sequentially discharged to the electromagnet located on the bottom of the discharge plate farthest from the plate Device for automatic ejection. The method of claim 1, And the contaminated coolant oil does not flow into the separation plate while the plurality of electromagnets are magnetized sequentially. The method of claim 1, When contaminated coolant oil is continuously introduced into the separating plate, the plurality of electromagnets are disposed at the longest distance from the discharge plate while the coolant oil flowing into the upper portion of the separating plate flows down to the lower portion of the separating plate. A device for separating and automatically discharging chips in coolant oil, characterized in that the magnetization is sequentially magnetized from the electromagnet located on the bottom of the separation plate to the electromagnet located on the bottom of the discharge plate farthest from the separation plate. . Separating and automatically discharging chips in coolant oil that can separate and discharge chips containing iron and impurities in coolant oil discharged from general industrial equipment such as grinding machines, plastic cutting machines including rolling mills and rolling mills In the device for A separation plate and an exhaust plate for separating and discharging chips containing iron and impurities from the coolant oil are integrally connected and seated at an opening of the coolant oil tank; A plurality of electromagnets which can be magnetized independently are provided on the bottom surface of the separation plate and the discharge plate; The plurality of electromagnets attached to the bottom of the separation plate are all magnetized to separate chips containing iron and impurities from coolant oil, and the separation from the electromagnet located at the bottom of the separation plate farthest from the discharge plate. The chips in the coolant oil are discharged to the outside, where the magnetic force is sequentially lost to the electromagnet located at the bottom of the discharge plate farthest from the plate, and the chips containing iron and impurities separated from the coolant oil are discharged to the outside. Device for automatic discharge. The method according to claim 1 or 4, And the end of the separation plate is positioned to be in the opening lower than the end connected to the discharge plate. The method according to claim 1 or 4, And the end of the discharge plate is positioned to be outside of the opening lower than the end connected with the separation plate. The method according to claim 1 or 4, And the separation plate and the discharge plate are made of a non-magnetic material to automatically separate and discharge chips in coolant oil.

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