KR20060010980A - A bag filter device for filtering of cutting oil - Google Patents

Abstract

Determining the contamination level of the filter element by using the pressure difference between the internal pressure of the filter element and the atmospheric pressure, and then driving the cleaning means configured separately to clean the filter element, thereby enabling semi-permanent use;

A main body having a space formed therein, the filter element and an outer mesh basket mounted thereon, and having a cover formed thereon to seal the space; A supply pipe configured at a lower center of the main body and including a supply valve to supply contaminated cutting oil into the filter element; In the bag filter device for cutting oil filtration comprising a discharge pipe configured to discharge the filtered cutting oil is configured on one side of the lower portion of the main body,

A differential pressure sensor configured at one side of the cover to detect a pressure inside the filter element and output a differential pressure signal to atmospheric pressure; The suction pipe is rotatably mounted to penetrate the center of the cover in a vertical direction to the center of the inside of the filter element, and sucks foreign matter attached to the inner surface of the filter element due to the difference between the internal pressure of the filter element and the atmospheric pressure. Cleaning means for discharging through the discharge pipe is configured to drain valve; Rotary driving means for rotating the suction pipe of the cleaning means at a constant speed using a driving force of a motor; And a controller for controlling the operation of the cleaning means and the rotary drive means in accordance with the detection signal of the differential pressure sensor.

Bag Filter Units, Cleaning, Drains, Filter Elements

Description

Bag filter device for cutting oil filtration {A BAG FILTER DEVICE FOR FILTERING OF CUTTING OIL}

1 is a cross-sectional configuration diagram of a bag filter device for cutting oil filtration according to the prior art.

2 is a cross-sectional configuration of a bag filter device for cutting oil filtration according to an embodiment of the present invention.

3 is a partial perspective view of a filter element applied to the present invention;

4 is a perspective view of a gear unit applied to the present invention, and

5 is a cleaning operation state diagram of a bag filter device for filtration of cutting oil according to an embodiment of the present invention.

The present invention relates to a bag filter device for cutting oil filtration, and more particularly, to a semi-permanent use of a filter element for constructing a separate cleaning means to filter semi-permanently using a filter element for filtering impurities in the device. It is about.

In general, a bag filter device for cutting oil filtration is a name given to the shape of a filter element as a bag, and is a filtration device that separates impurities such as chips generated in a metal working process from cutting oil.

Such a coolant filter bag filter device is mainly used in a precision machining process, and the impurities to be filtered are filtered in the range of 5 to 20 ?? depending on the size of the particle of the filter element.

As shown in FIG. 1, the main body 101 is formed of a metal material, and a space 103 is formed therein to form a filter element 105 and an outer mesh basket. 107 is mounted, the cover 109 is formed on the upper portion of the main body 101 to seal the inside.

The upper side of the main body 101 is formed with a supply pipe 113 including a supply valve 111 to supply the contaminated cutting oil from the facility or dirty tank (Dirty Tank), the lower side cleans the cutting oil in which impurities are filtered A discharge pipe 117 including a discharge valve 115 is formed to discharge to a clean tank.

In addition, a drain pipe 121 including a drain valve 119 is formed at a lower portion of the main body 101, and a pressure gauge for displaying an internal pressure at one side of the cover 109 of the cutting oil filtering bag filter device ( 123 is mounted.

Therefore, in the conventional bag filter apparatus for cutting oil filtration as described above, impurities filtered by the filter element 105 in the main body 101 remain in the filter element 105, which filter element 105 is The degree of filtration is so precise that clogging occurs in the filtration membrane to increase the internal pressure, it is difficult to perform any further filtration. The operator checks this through the pressure gauge 123, and then replaces the filter element 105, the replacement cycle is about 7 to 20 days.

However, the conventional cutting oil filtration bag filter device as described above is too short to replace the filter element because the replacement cycle is too short, causing frequent inconvenience and lowering the operation rate of the filter element, the filter Although the element can be recycled and used, it poses a problem of wasting resources.

Therefore, the present invention was created to solve the above problems, and an object of the present invention is to determine the degree of contamination of the filter element by using the pressure difference between the internal pressure of the filter element and the atmospheric pressure, and then drive the cleaning means configured separately. The present invention provides a bag filter device for cutting oil filtration that allows semi-permanent use by cleaning the filter element.

According to an aspect of the present invention, there is provided a bag filter device for cutting oil filtration, wherein the filter element and the outer mesh basket are mounted to form a space therein, and a cover is formed on the top thereof to seal the space; A supply pipe configured at a lower center of the main body and including a supply valve to supply contaminated cutting oil into the filter element; In the bag filter device for filtration of cutting oil comprising a discharge pipe configured to discharge the filtered cutting oil is configured on one side of the lower portion of the main body, the discharge valve,

A differential pressure sensor configured at one side of the cover to detect a pressure inside the filter element and output a differential pressure signal to atmospheric pressure; The suction pipe is rotatably mounted to penetrate the center of the cover in a vertical direction to the center of the inside of the filter element, and sucks foreign matter attached to the inner surface of the filter element due to the difference between the internal pressure of the filter element and the atmospheric pressure. Cleaning means for discharging through the discharge pipe is configured to drain valve; Rotary driving means for rotating the suction pipe of the cleaning means at a constant speed using a driving force of a motor; And a controller for controlling the operation of the cleaning means and the rotation driving means according to the detection signal of the differential pressure sensor.

The cleaning means is disposed in the vertical direction in the inner center of the filter element, a plurality of branch pipes are formed at regular intervals along the longitudinal direction, the cover is a suction pipe rotatably mounted through the bearing means and the sealing means; An outlet pipe connected to a front end of the suction pipe and a rotary joint outside the main body; And a drain valve mounted to one side of the discharge pipe to open and close the discharge pipe according to a control signal of the controller.

The rotation drive means is mounted to one side of the cover for driving the drive rotation in accordance with the control signal of the controller; And a gear unit configured between the rotating shaft of the drive motor and the upper one side of the suction tube to transmit the rotational force of the driving motor to the suction tube as a rotational force.

The controller is characterized in that the control logic is configured to open-control the drain valve of the cleaning means and operate the rotation driving means when the detected value of the differential pressure sensor is equal to or greater than a set value.

The filter element is characterized in that the material is made of a wire mesh filter made of metal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional configuration diagram of a bag filter apparatus for cutting oil filtration according to an embodiment of the present invention. In the structure of the bag filter apparatus for cutting oil filtration according to the present invention, a main body 1 forming a space 3 therein first ) Is provided.

An outer mesh basket 5 and a filter element 7 are mounted inside the space 3 of the main body 1, and a cover 11 is formed on the upper portion so that the space 3 is sealed. Is done.

In the lower center of the main body 1, a supply pipe 15 having a supply valve 13 is formed at one side to supply contaminated cutting oil from a facility or a dirty tank into the filter element 7. .

The lower one side of the main body 1 is provided with a discharge valve 17 on one side to discharge the cutting oil filtered by the filter element 7 in the inside of the main body 1 to a clean tank. The discharge pipe 19 is formed.

Here, it is preferable that the said filter element 7 consists of the wire mesh filter whose material is a metal as shown in FIG.

One side of the cover 11 is equipped with a differential pressure sensor 9 for detecting a pressure inside the filter element 7 and outputting a differential pressure signal with atmospheric pressure.

In addition, the suction element 21 is rotatably mounted in the filter element 7 so as to penetrate the center of the cover 11 in a vertical direction at the center thereof, so that the internal pressure and the atmospheric pressure of the filter element 7 are increased. The cleaning means is provided with a cleaning means for sucking the foreign matter attached to the inner surface of the filter element 7 and discharging it to the drain tank through the discharge pipe 25 in which the drain valve 23 is formed.

More specifically, the configuration of the cleaning means, the suction pipe 21 is disposed in the vertical direction in the inner center of the filter element 7, the upper side of the suction pipe 21 penetrates the cover 11 In one state, it is rotatably mounted between the cover 11 through a bearing means and a sealing means.

The suction pipe 21 is formed with a plurality of branch pipes 27 along the longitudinal direction at regular intervals.

Here, it is preferable that only one branch pipe 27 is formed on the same outer circumference line of the suction pipe 21, and the front end thereof is opened to be formed in an oblique direction corresponding to the inner surface of the filter element 7.

And the bearing means is preferably made of a ball bearing 29 which is installed between the cover 11 and the suction pipe (21).

In the sealing means, a sealing disc 31 is integrally mounted on the inner surface of the cover 11 in the main body 1, and a medal bearing 33 in frictional contact with the sealing disc 31 is provided. It is made mounted on the upper one side of the suction pipe (21).

And outside of the main body 1, the discharge pipe 25 is connected to the front end of the suction pipe 21 through the rotary joint 35, the discharge pipe 25 is configured to maintain a fixed position.

In addition, a drain valve 23 is mounted on one side of the discharge pipe 25, and the drain valve 23 opens and operates the discharge pipe 25 according to a control signal of the controller 40.

Here, the drain valve 23 is preferably made of a solenoid valve to operate on and off in accordance with the control signal of the controller 40.

In addition, the suction pipe 21 is preferably formed at least twice as large as the diameter of the branch pipe (27).

In addition, a rotation driving means for rotating the suction pipe 21 of the cleaning means at a constant speed by using the driving force of the motor is provided. A specific configuration of the rotation driving means includes a driving motor 41 on one side of the cover 11. It is mounted to generate a rotational driving force in accordance with the control signal of the controller 40.

Here, the drive motor 41 is preferably made of a step motor capable of controlling the rotation speed.

Between the rotating shaft of the drive motor 41 and the upper one side of the suction pipe 21 is provided with a gear unit for transmitting the rotational force of the drive motor 41 to the suction pipe 21 as a rotational force, the gear unit, FIG. As shown in 4, it is preferable that it consists of a hypoid gear.

That is, the gear unit is mounted on a rotary shaft of the hypoid rack gear 43 and the drive motor 41 which are key-coupled to an upper side of the suction pipe 21 at the upper center of the cover 11 and the hypoid. It consists of a hypoid pinion gear 45 meshed with the rack gear 43.

And the controller 40 for controlling the operation of the drain valve 23 of the cleaning means and the drive motor 41 of the rotary drive means in accordance with the detection signal of the differential pressure sensor (9).

That is, the controller 40 controls the opening of the drain valve 23 of the cleaning means when the detected value of the differential pressure sensor 9 is equal to or larger than a set value, and simultaneously controls the drive motor 41 of the rotation driving means. It has a control logic to drive rotation.

Here, the set value is preferably set to 1.5 bar.

Accordingly, the filtration operation of the contaminated cutting oil and the cleaning operation of the filter element 7 by the cutting oil filtration bag filter device having the above-described configuration will be described with reference to FIGS. 2 and 5.

First, the filtration operation of the contaminated cutting oil, as shown in FIG. 2, opens the supply valve 13 and the discharge valve 17, and the drain valve 23 controls the control of the controller 40. When the coolant contaminated from the facility or the dirty tank is supplied through the supply pipe 15 while the valve is closed off, the coolant flows into the filter element 7 and is included in the coolant by the supply pressure of the coolant. The impurity is filtered by the filter element 7, and only clean cutting oil is discharged through the discharge pipe 25 to the clean tank.

When the filtration operation of the cutting oil is performed for a long time, the filter element 7 is blocked by the impurities, and the pressure inside the filter element 7 is increased.

At this time, when the differential pressure sensor 9 detects the pressure inside the filter element 7 and outputs it to the controller 40, the controller 40 causes the pressure inside the filter element 7 to be 1.5 bar or more than atmospheric pressure. In the case of forming, it is determined that it is time to perform cleaning of the filtration membrane of the filter element 7.

That is, the controller 40 controls the opening of the drain valve 23, and simultaneously rotates the driving motor 41 to rotate the suction pipe 21.

Then, the pressure inside the filter element 7 is 1.5 bar or more higher than the outside atmospheric pressure, and by using this pressure difference, the suction pipe 21 is attached to the inner surface of the filter element 7 through the plurality of branch pipes 27. The absorbed impurities are discharged to the drain tank through the discharge pipe 25.

At the same time, the suction pipe 21 is rotated by the drive of the drive motor 41, the rotation of the suction pipe 21 is the plurality of branch pipes 27 the inner circumferential direction of the inner surface of the filter element (7) As you move along, it allows you to inhale impurities.

As such, even when impurities attached to the filter element 7 are removed, the filter element 7 may continue to perform filtration of contaminated cutting oil supplied through the supply pipe and discharge the discharged through the discharge pipe 25. There is no need to stop the device for the cleaning operation of the filter element 7.

As described above, according to the bag filter apparatus for cutting oil filtration according to the present invention, after determining the contamination level of the filter element by using the pressure difference between the internal pressure of the filter element and the atmospheric pressure, the filter element inner surface is rotated while rotating the cleaning means configured separately. By allowing the impurities to be sucked out and discharged, there is an effect of enabling semi-permanent use without replacing the filter element.

In addition, even during the cleaning of the filter element, it is possible to continue to perform the filtration operation of the contaminated cutting oil supplied through the supply pipe, there is an effect that can increase the use efficiency of the device.

Claims (15)

A main body having a space formed therein, the filter element and an outer mesh basket mounted thereon, and having a cover formed thereon to seal the space; A supply pipe configured at a lower center of the main body and including a supply valve to supply contaminated cutting oil into the filter element; In the bag filter device for cutting oil filtration comprising a discharge pipe configured to discharge the filtered cutting oil is configured on one side of the lower portion of the main body, A differential pressure sensor configured at one side of the cover to detect a pressure inside the filter element and output a differential pressure signal to atmospheric pressure; The suction pipe is rotatably mounted to penetrate the center of the cover in a vertical direction to the center of the inside of the filter element, and sucks foreign matter attached to the inner surface of the filter element due to the difference between the internal pressure of the filter element and the atmospheric pressure. Cleaning means for discharging through the discharge pipe is configured to drain valve; Rotary driving means for rotating the suction pipe of the cleaning means at a constant speed using a driving force of a motor; And a controller for controlling the operation of the cleaning means and the rotary drive means according to the detection signal of the differential pressure sensor. The method of claim 1, wherein the cleaning means A suction pipe disposed in a vertical direction at an inner center of the filter element, and a plurality of branch pipes are formed at a predetermined interval along a length direction thereof, and the cover includes a suction pipe rotatably mounted through bearing means and sealing means; An outlet pipe connected to a front end of the suction pipe and a rotary joint outside the main body; And a drain valve mounted to one side of the discharge pipe to open and close the discharge pipe according to a control signal of the controller. The method according to claim 2, wherein the branch pipe Bag filter device for filtration of cutting oil, characterized in that only one is formed on the same outer periphery of the suction pipe. The method according to claim 2, wherein the branch pipe A cutting-edge filtration bag filter device, characterized in that the tip is opened and formed in an oblique direction corresponding to the inner surface of the filter element. The method of claim 2, wherein the bearing means Bag filter device for filtration of cutting oil, characterized in that the ball bearing is provided between the cover and the suction pipe. The method of claim 2, wherein the sealing means Inside the main body, a sealing disk integrally mounted to the inner surface of the cover; Bag filter device for filtration oil, characterized in that consisting of; medal bearing mounted to the upper side of the suction pipe in a frictional contact with the sealing disk. The method of claim 2, wherein the drain valve Cutting oil filtration bag filter device, characterized in that consisting of a solenoid valve that operates on and off in accordance with the control signal of the controller. The method of claim 2, wherein the suction pipe A bag filter device for cutting oil filtration, the diameter of which is formed at least two times larger than the diameter of the branch pipe. The method of claim 1, wherein the rotation drive means A driving motor mounted to one side of the cover to rotate in accordance with a control signal of the controller; And a gear unit configured between the rotating shaft of the drive motor and the upper one side of the suction pipe to transfer the rotational force of the driving motor to the suction pipe as a rotational force. The method of claim 9, wherein the drive motor A bag filter device for cutting oil filtration, comprising a step motor capable of controlling the rotation speed thereof. The method of claim 9, wherein the gear unit Bag filter device for filtration of coolant, characterized in that the hypoid gear. The method of claim 9, wherein the gear unit A hypoid rack gear that is keyed to an upper side of the suction pipe at an upper center of the cover; Bag filter device for filtration oil, characterized in that consisting of; a hypoid pinion gear is mounted to the rotary shaft of the drive motor and meshed with the hypoid rack gear. The method of claim 1, wherein the controller And a control logic configured to control opening of the drain valve of the cleaning means when the detected value of the differential pressure sensor is equal to or larger than a set value, and to operate the rotation driving means. The method according to claim 13, wherein the set value Bag filter device for filtration coolant, characterized in that 1.5bar. The method of claim 1, wherein the filter element A bag filter device for cutting oil filtration, the material comprising a wire mesh filter made of metal.

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