KR200439794Y1 - Cutting oil filtering device - Google Patents

Abstract

The present invention is a housing, a drive roller fastened to one side of the housing and rotated by the power of a drive motor, driven rollers installed on the other side of the housing, mesh belt wound around the drive and driven rollers, and the housing In the coolant filtering device comprising a filter installed on one side and covered with an upper surface of the mesh belt, a plurality of sprockets are coupled to the outer diameter of the drive roller while maintaining a constant interval, and the peripheral surface of the sprocket is hooked to the mesh belt A plurality of gear teeth are formed to protrude from the mesh belt in accordance with the rotation of the drive roller in the state of being in the state, and the outer periphery of the gear is configured to be formed round, cutting oil to prevent the mesh belt from being torn or broken due to overload Provide a filtering device.

Coolant, drive roller, sprocket, mesh belt, filter, plot

Description

Coolant Filtering Device {CUTTING OIL FILTERING DEVICE}

1 is a view three-dimensionally showing the configuration of a cutting fluid filtering device according to an embodiment of the present invention.

2 is a view taken along the line A-A of FIG.

3 is a view taken along the line B-B of FIG.

Figure 4 is a view showing in detail the configuration of the drive roller used in the present invention.

Figures 5a and 5b respectively show the operation of the sprocket coupled to the drive roller.

6 is a view showing in detail the configuration of the plot used in the present invention.

<Description of the symbols for the main parts of the drawings>

10: housing 14: drive motor

16: driven roller 18: driven roller

20: Sprocket 20a: Gear

R: round 24: mesh belt

26: Filter 34: Frame

40: bracket 44: sensor

48: Link 52: Plot

54: balance weight 100: coolant filtering device

The present invention relates to a coolant filtering device, and relates to a coolant filtering device which prevents sagging of a mesh belt supplying a filter to a housing and damage of the mesh belt through an overload.

In general, machining such as grinding, discharging, honing, etc. is to cut metal to form a certain shape. In this machining process, high heat is inevitably generated. Spray into the machining site.

Meanwhile, the cutting oil used for machining includes metal chips or foreign substances. Therefore, when reusing the cutting oil, the metal chips or foreign substances are removed through a filtering device and then reused.

However, the conventional coolant filtering device has a problem that the mesh belt is easily torn or damaged by the gear of the sprocket when an overload occurs while moving the mesh belt to replace the filter, and the mesh belt is separated from the roller during use. Accidents occurred frequently.

In addition, the conventional cutting oil filtering device has a disadvantage that the front and rear ends of the mesh belt is easily sag due to the weight of the cutting oil, and thus the cutting oil does not pass through the filter and flows directly into the tank, thereby effectively filtering the cutting oil.

In addition, the conventional coolant filtering device is provided with a plot so that the sensor can detect the filter replacement time, the plot has a structure that operates vertically in accordance with the level of the coolant, the direction of movement of the mesh belt (that is, the horizontal movement direction) It is easily affected by) and causes frequent malfunctions, and also has a disadvantage in that it is not desirable in terms of durability.

Therefore, an object of the present invention for solving the above problems is to provide a cutting oil filtering device to prevent damage to the mesh belt through overloading the gear teeth of the chain sprocket.

Another object of the present invention is to provide a coolant filtering device for preventing sagging of the front and rear ends of the mesh belt.

Another technical problem to be achieved by the present invention is to provide a coolant filtering device that can prevent the malfunction of the plot.

Another technical problem to be achieved by the present invention is to provide a coolant filtering device that prevents the mesh belt from being separated from the driving roller and the driven roller.

Another technical problem to be achieved by the present invention is to provide a coolant filtering device that eliminates the inconvenience of assembling the guide roll and the mesh belt by covering the entire upper surface of the housing with a mesh belt without using a guide roll in the center. have.

The present invention for achieving the above objects is a housing, a drive roller fastened to one side of the housing and rotated by the power of a drive motor, driven rollers installed on the other side of the housing, and wound around the drive and driven rollers In a coolant filtering device comprising a mesh belt and a filter installed on one side of the housing and covered on an upper surface of the mesh belt, a plurality of sprockets are coupled to an outer diameter of the driving roller while maintaining a predetermined interval, and the circumference of the sprocket In the surface is caught in the mesh belt is a plurality of gear teeth are formed protruding to pull the mesh belt in accordance with the rotation of the driving roller, the outer periphery of the gear is characterized in that the molded round.

The front and rear ends of the housing are preferably configured to be inclined upwardly attached to a support pad supporting the front and rear ends of the mesh belt.

The frame is installed across the upper center of the housing, the bracket is installed on the upper end of the frame, the hinge is fastened to the bracket and the end is attached to the floating float in accordance with the level of the coolant accumulated above the filter, the other end There is further installed a link with a balance weight, so that the end of the link is rotated down around the hinge according to the injury of the plot to automatically operate the drive motor by touching the sensor installed in the bracket. This is preferred.

Both ends of the drive roller is preferably provided with a departure prevention jaw to prevent the separation of the mesh belt.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 to 3 are views showing the configuration of the coolant filtering device to be implemented in the present invention.

As shown, the cutting oil filtering device 100 includes a housing 10 configured by opening the upper and lower surfaces in a rectangular shape. The cutting oil used for machining is supplied to the housing 10, and the supplied cutting oil is stored in the tank 12 mounted at the lower end of the housing 10.

On the other hand, the housing 10 is equipped with a means for automatically replacing the filter for filtering foreign substances, such as metal chips contained in the cutting oil supplied.

The filter replacement means comprises a drive and driven roller (16, 18), the mesh belt (24).

The driving and driven rollers 16 and 18 are means mounted on both sides of the housing 10, respectively, and the driving roller 16 is rotated by the power of the driving motor 14 in a state in which the driving rollers 16 are installed on one side of the housing 10. And, the driven roller 18 is idling in accordance with the operation of the drive roller 16 through the mesh belt 24 in the state installed on the other side of the housing (10).

The mesh belt 24 is a means for moving the filter 26 to one side while rotating in an orbital manner while being wound around the driving and driven rollers 16 and 18. The mesh belt 24 is manufactured in the form of a mesh so as to pass the cutting oil supplied to the housing 10 and is configured to cover the entire upper surface of the housing 10.

On the other hand, the outer diameter of the above-described driving roller 16 is formed as a plurality of sprockets 20 are protruded while maintaining a constant interval as shown in FIG. A plurality of gears 20a are protruded from the circumferential surface of the sprocket 20, and the mesh belts 24 are transmitted by transmitting the rotational force of the driving roller 16 to the mesh belts 24 through the gears 20a. Can be rotated.

That is, as shown in FIG. 5A, when the driving roller 16 rotates, the sprocket 20 is interlocked with each other. In this process, the gears 20a of the sprocket 20 are caught by the mesh belt 24, thereby meshing the mesh. The belt 24 is rotated by receiving the rotational force of the driving roller 16.

The gear teeth 20a of the sprocket 20 are characterized in that the outer periphery is rounded (R), which is in the process of the gears 20a being caught by the mesh belt 24 by the rotation of the driving roller 16. If an overload occurs, the mesh belt 24 is not continuously caught, and the gear 20a is separated from the mesh belt 24 through the rounding portion R as shown in FIG. 5B, thereby overloading the mesh belt 24. Is so as not to be transmitted, and thus, the mesh belt 24 may be prevented from being torn or broken due to overload during use.

The sprockets 20 of the above-described configuration are mounted on the outer diameter of the driven roller 18 in the same shape, and the sprockets mounted on the driven rollers 18 are the same as the sprockets 20 of the driving roller 16 described above. It will have the same function and effect, the description thereof will be omitted.

Both end portions of the driving roller 16 are further provided with a separation prevention jaw 22. The release preventing jaw 22 prevents the mesh belt 24 wound around the driving roller 16 from being separated from the driving roller 16 during the rotational movement. In addition, the driven roller 18 is preferably further provided with another departure prevention jaw performing the same function as the departure prevention jaw of the driving roller.

On the other hand, a plurality of support shafts 27 are installed on the bottom surface of the housing 10 in a horizontal direction while maintaining a constant interval, and the support shafts 27 have a plurality of guide rails for guiding the movement of the mesh belt 24. 27a are mounted.

The filter 26 is covered on the upper surface of the mesh belt 24. The filter 26 is a means for filtering foreign matter such as metal chips contained in the cutting oil supplied to the housing 10. The filter 26 is configured to be covered on the upper surface of the mesh belt 24 in a state in which a predetermined amount is wound around the filter winding roll 30 embedded in the filter supply unit 28 installed on the other side of the housing 10, In addition, when the mesh belt 24 is rotated by the operation of the driving roller 16 is moved in conjunction with one side.

On the other hand, the frame 34 is installed horizontally across the center of the upper end of the housing 10. A flow path 34a is formed in the frame 34, and cutting oil for filtering flows into the flow path 34a. The cutting oil introduced into the flow path 34a is supplied to the housing through a discharge hole 34b formed at the center lower end of the frame 34.

A plurality of push rolls 36 are mounted to the bottom of the frame 34 in a state in which the brackets 38 are coupled to the bracket 38. The push rolls 36 press the filter 26 which is covered on the upper surface of the mesh belt 24 so that the mesh belt 24 and the filter 26 have a concave cross-sectional shape as a whole. As such, the front and rear ends are formed to be inclined upwardly from the center to prevent the cutting oil supplied to the housing 10 from overflowing from the filter 26 and the mesh belt 24 and flowing straight into the tank 12. Done.

On the other hand, the front and rear ends of the housing 10, the support pad 32 is installed in a state inclined upward by a predetermined angle. The support pad 32 sags the front and rear ends of the mesh belt 24 through the weight of the cutting oil supplied to the housing 10 while being in contact with the front and rear end surfaces of the mesh belt 24 described above. The front and rear ends of the mesh belt 24 are supported.

On the other hand, the center of the frame 34 includes a plot 52 is installed. The plot 52 is a means mounted to automatically replace the filter 26 by operating the drive motor 14 at the time of replacement of the filter 26.

That is, when the water holes formed in the filter 26 are blocked by foreign substances such as metal chips included in the cutting oil in the process of repeatedly filtering the cutting oil, the cutting oil does not pass through the filter 26, and the cutting oil does not pass on the filter 26. Gradually, the plot 52 rises due to the level of coolant accumulated in the filter 26 and touches the sensor 44 so that the sensor 44 outputs a signal to a controller (not shown). By operating the drive motor 14 automatically to rotate the mesh belt 24 to rotate the filter 26 is drawn out from the housing (10). The withdrawn filter 26 is collected in a collection box 60 provided on one side of the housing 10, and a new filter wound on the filter feed roll 30 is continuously connected to the upper surface of the mesh belt 24. By being covered, the replacement of the filter 26 can be performed automatically.

Meanwhile, the detailed coupling structure of the plot 52 and the frame 34 is as shown in FIG. 6.

As shown, a bracket 40 having a sensor 44 is installed at the center of the upper end of the frame 34, and a link 48 connected to the plot 52 is hinged to the bracket 40. 50 is fastened, the link has a configuration that further includes a balance weight (54).

When the coolant is accumulated in the filter 26 through the above coupling structure, the plot 52 rotates upward in one direction and floats. At this time, the end of the link 48 is reversed downwardly around the hinge 50. By rotating and touching the sensor 44, the driving motor 14 is automatically operated.

On the other hand, the plot 52 of the present invention does not move vertically and vertically as in the prior art, but rotates inclined upward in the same direction as the moving direction of the mesh belt 24, thereby affecting the operation of the mesh belt 24. In order to reduce the risk of malfunction by receiving less, in particular, due to the weight of the balance weight 54 installed on the link 48, the operation of the mesh belt 24, the plot 52 does not rotate, cutting oil By supporting the plot 52 so that it can float and rotate only through the water level, the malfunction of the plot 52 can be prevented more effectively. At this time, the balance weight 54 is preferably manufactured so that the plot 52 has a weight enough to be rotated by the level of the cutting oil.

Hereinafter, the operation of the cutting fluid filtering device 100 according to the present invention will be described.

First, the cutting oil introduced into the flow path 34a of the frame 34 is supplied to the housing 10 through the discharge port 34b, and the supplied cutting oil passes through the filter 26 and the mesh belt 24 sequentially. It is stored in the tank 12. At this time, the cutting oil is filtered through a variety of foreign substances such as metal chips in the process of passing through the filter (26).

On the other hand, when the coolant is accumulated over the filter 26 at the end of the life of the filter 26, the plot 52 rotates upward according to the coolant level, so that the end of the link 48 is centered on the hinge 50. By rotating downward and touching the sensor 44, the driving motor 14 is operated.

When the driving motor 14 operates, the driving roller 16 rotates, and thus the gears 20a of the sprocket 20 installed on the driving roller 16 are driven while being caught by the mesh belt 24. By pulling the mesh belt 24 by the rotation of the roller 16, the mesh belt 24 is rotated while being wound around the driving and driven rollers (16, 18) in a caterpillar manner.

At the same time, the filter 26 mounted on the upper surface of the mesh belt 24 is interlocked and moved to one side according to the rotational movement of the mesh belt 26, and then collected by the collection box 60, and together with the filter winding roll ( The new filter wound on 30 is continuously drawn out and covered by the upper surface of the mesh belt 24 so that the replacement of the filter is automatically performed.

At this time, if the driving roller 16 is overloaded in the process of rotating the mesh belt 24, the gear 20a of the sprocket 20 is caught on the mesh belt 24 through a round (R) formed on the outer circumference. The separation from the state can prevent the mesh belt 24 from being torn or broken.

As described above, the present invention has the effect of preventing the damage to the mesh belt in the use process by causing the gear sprocket of the chain sprocket to be released from the mesh belt when an overload of a certain pressure is applied.

In addition, the present invention has an effect of preventing the front and rear ends of the mesh belt from sagging by the weight of the cutting oil through the support pads supporting the front and rear ends of the mesh belt.

It also has the effect of improving the structure of the plot so that the plot does not malfunction during use.

Finally, it has a synergistic effect to prevent the mesh belt from being separated from the driving roller in the process of use through the separation prevention jaw installed at both ends of the driving roller.

Claims (4)

A housing roller 10, a driving roller 16 fastened to one side of the housing 10 and rotating by the power of the driving motor 14, and a driven roller 18 installed on the other side of the housing 10; Cutting oil filtering device comprising a mesh belt 24 wound around the driving and driven rollers 16 and 18 and a filter 26 installed on one side of the housing 10 and covered by an upper surface of the mesh belt 24. To A plurality of sprockets 20 are coupled to the outer diameter of the drive roller 16 while maintaining a constant interval; A plurality of gears 20a protruding from the sprocket 20 to pull the mesh belt 24 according to the rotation of the driving roller 16 in the state of being caught by the mesh belt 24; Cooling oil filtering device, characterized in that the outer periphery of the gears (20a) is formed to be round (R). The method of claim 1, Cutting oil filtering device, characterized in that the front and rear ends of the housing 10, the support pads 32 supporting the front and rear ends of the mesh belt 24 are inclined upwardly. The method according to claim 1 or 2, A frame 34 installed across the upper center of the housing 10; A bracket (40) installed on the top of the frame (34); The hinge 50 is fastened to the bracket 40, and a float 52 is attached to the front end thereof in accordance with the level of the coolant accumulated above the filter 26, and the other end is provided with a link weight 54 mounted thereon. 48) by installing more; As the float 52 rises, the end 48a of the link 48 rotates down about the hinge 50 and touches the sensor 44 installed on the bracket 40 to drive the motor. Coolant filtering device, characterized in that to automatically operate. The method of claim 3, wherein Cutting oil filtering device, characterized in that the both ends of the drive roller 16 is provided with a departure prevention jaw 22 to prevent the separation of the mesh belt (24).

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