KR20190051404A - Oil separator - Google Patents

Abstract

The present invention relates to a technology of an oil-water separator, capable of removing various pollutants contained in a cutting oil in order to use the cutting oil (coolant) used in a cutting process by using a machine tool, for a long time, wherein the oil-water separator comprises: a primary filtration module installed in a coolant storage tank, and having a floating suction inducing tool for introducing a floating pollutant mixture solution; a pump for pumping and transferring the pollutant mixture solution introduced into the primary filtration module; a separation tank for introducing the pollutant mixture solution transferred by the pump; a vertical separation membrane for dividing the inside of the separation tank into two spaces, wherein two spaces are allowed to communicate with each other by opening a lower part thereof; a porous media accommodated in a first space divided by the vertical separation membrane; a secondary filtration module installed in the first space to allow the uppermost pollutant to be introduced and discharged; and a recovery port installed in a second space to transmit a coolant, from which the pollutant is removed, to a coolant storage tank again.

Description

Oil separator

The present invention relates to an oil-water separator for removing various pollutants contained in cutting oil used for a long period of use of a cutting oil (coolant) used for cutting work using a machine tool such as a lathe or a CNC Technology.

Cutting oil is used because it requires high cooling because it generates high heat during metal cutting. The machining industry, which is the foundation of almost all industries, is a core area of the metal processing industry.

Processing machines such as machining centers (MCT) and CNC (computerized numerical control) lathes are widely used as well as general purpose lathes, and cutting oil is required to operate the machining centers.

If the cutting oil is not properly supplied during cutting, a high temperature is formed in the bite for cutting as well as the object to be cut, thereby causing poor dimensional and life span. Therefore, the cutting oil must be supplied stably, There is also a need to use.

On the other hand, the cutting oil used during cutting contains not only oil components such as rust-inhibiting oil, but also water and chips, which are contained in the object to be processed. Therefore, the used cutting oil is contaminated with repetitive reuse. none.

The coolant stored in the coolant storage tank is circulated and the contaminated oil is floating on the top surface of the coolant storage tank. When the contaminated oil covers the surface, the inflow of oxygen into the cutting oil is blocked, so that various kinds of bacteria are generated, and odor is generated. In case of physical contact, skin diseases may be caused.

If the contaminated oil is used without being removed, the performance of various parts is rapidly deteriorated and the maintenance cost is increased, and the processing precision and surface roughness may be deteriorated.

In terms of cost and environment, cutting oil should be used for a long period of time through a desirable cleaning process, and a cutting oil purifying device is required for this.

There is a " apparatus for removing sedimentation tank oil for a processing machine " of Korean Registered Patent No. 10-1733363 (registered on Apr. 27, 2017) with respect to the present invention.

FIG. 1 is a schematic view of a conventional apparatus for removing sedimentation tank oil for a machining apparatus, and FIG. 2 is an exploded perspective view of main parts in FIG.

A floater 110 for sucking and removing the oil flow contained in the cutting oil collected in the settling tank 102 of the processing machine 101 and a floater 110 for guiding the lifter of the floater 110 according to the level of the cutting oil, (130), the apparatus comprising: The plotter 110 includes a floater body 111 formed of a material having buoyancy and a suction hole 112 formed so as not to penetrate the center of the body of the plotter body 111 to draw oil flow, A discharge hole 113 for communicating with one side of the suction hole 112 and discharging the oil flow from one side of the floater body 111 and an inclined surface which is lowered toward the suction hole 112 from the four outer sides of the floater body 111, And a concave portion 115 having a width narrower than a width of a mouth of the suction means connected to the suction hole in comparison with the suction hole of the suction means, A connector 118 and a filter 125 coupled to the suction hole 112 to prevent foreign matter from entering the suction hole 112; The floater holder 130 includes a magnet 131 detachably attached to a bottom surface of the settling tank 102 and an attachment 132 protruding from a screw pipe 133 at an upper side thereof. And a guide bar 135 that stands up and connects the floater body 111 to guide the elevator of the floater 110; The connector 118 includes a connecting hole 119 formed in a hemispherical shape at the end of the discharge hole 113 and a connecting pipe 121 for forming a spherical connecting ball 121 corresponding to the connecting hole 119 And a connecting cover 122 for interlocking the connecting pipe 120 with the semi-spherical adhered portion symmetrical to the connecting hole 119 and the expanded portion 123 for expanding the inner diameter to the outside of the adhered portion, .

However, in the case of the prior art, since oil can be primarily filtered in the settling tank, a considerable amount of oil remains. That is, there is a demand for a technique capable of removing the oil flow more precisely.

Korean Patent No. 10-1733363

An object of the present invention is to provide an oil water separator which can effectively separate and treat contaminants from contaminated coolant due to repeated use.

Further, the present invention provides a water-oil separator that can enhance the competitiveness of a company by making it possible to reuse a coolant having a large cost burden to dispose of the pollutant contained in the coolant more reliably for a long time as long as possible I want to.

The oil separator for achieving the above-mentioned object includes a primary filtration module installed in a coolant storage tank and equipped with a floating suction oil tool which functions to allow a floating pollutant mixture to flow therein; A pump for pumping and transporting the pollutant mixture introduced into the primary filtration module; A separation tank into which the contaminated mixed liquor transferred by the pump flows; A vertical separator for separating the interior of the separator into two spaces, and a lower portion of the separator is opened to allow the two spaces to communicate with each other; A porous medium accommodated in a first space defined by the vertical separation membrane; A second filtration module installed in the first space to allow the contaminants in the uppermost layer to flow in and be discharged; And a recovery port installed in the second space to return the coolant from which the pollutants have been removed to the coolant storage tank again.

Preferably, the primary filtration module is installed to be submerged in the coolant storage tank, has a top opening and a bottom pipe connection port; And a floating suction tool inserted through the upper end of the body and having a plurality of ribs spaced apart from each other with a circle along a top edge thereof and an inlet port communicating with the inside of the body is formed at a central portion thereof.

Preferably, the pump is an air pump, and a strainer for filtering particulate matter is provided between the primary filtration module and the pump.

Preferably, the secondary filtration module is fixedly installed in the first space so as to allow the contaminants to be introduced to be discharged to the outside of the separating tank, and the upper end thereof is opened, and a female screw is formed on the upper inner diameter surface The body being; A plurality of ribs formed along the upper edge of the body and having a plurality of ribs spaced apart from each other, the ribs being inserted into the ribs, And a sucking oil tool for allowing the contaminants to flow into the body through the opening hole.

Preferably, the floating suction induction port is lowered by the suction force when the suction stroke of the pump is lowered, and then raised again when the suction stroke is repeated.

Preferably, the pollutants filtered by the secondary filtration module are discharged into a waste tank, and when the amount of the waste tank collected in the waste tank exceeds a predetermined weight, a contact is formed to stop the operation of the pump .

The oil-water separator according to the present invention can provide a water-oil separator having a high efficiency of removing contaminants by performing filtration action twice.

According to the oil water separator of the present invention, the floating suction oil tool moves up and down according to the suction stroke and the discharge stroke by using the air pump, so that the contaminant forming the uppermost layer can be sucked smoothly.

1 is a block diagram of a conventional apparatus for removing sedimentation tank oil for a machining apparatus.
Fig. 2 is an exploded perspective view of the main part in Fig. 1; Fig.
3 is a conceptual diagram of an oil water separator according to the present invention.
4 is a schematic view showing the internal structure of the separation tank;
5 is a general flow diagram of an oil water separator according to the present invention.
6 is an exemplary view of a modified embodiment of the primary filtration module;
7 is an enlarged sectional view of the floating inhaler;
8 is an enlarged sectional view of the suction inhaler.

Hereinafter, the oil-water separator according to the present invention will be described in more detail with reference to the accompanying drawings. It should be understood, however, that the drawings and detailed description thereof illustrate one feasible example according to the technical idea of the present invention, and the technical scope of protection of the present invention is not limited thereto.

The oil-water separator according to the present invention can be used in a coolant to be used in order to reuse a coolant (cutting oil) required for metal cutting using various machine tools such as NC, CNC, lathe, MCT It is for removing various pollutants.

Here, the term " pollutant " refers to particles or oil, and the oil may flow from the machine tool itself or may be formed by incorporating anti-corrosive oil or the like as the material becomes rustproof.

Coolant is usually diluted by mixing water with a coolant, which is about 90% water. Therefore, since coolant has a larger specific gravity than contaminants, the pollutants collect on the uppermost layer.

FIG. 3 is a conceptual diagram of the oil water separator according to the present invention, FIG. 4 is a structural view showing the internal structure of the separation vessel, FIG. 5 is an overall flowchart of the oil water separator according to the present invention, Fig. 7 is an enlarged sectional view of the floating suction inhaler, and Fig. 8 is an enlarged sectional view of the suction inhaler.

The oil water separator according to the present invention mainly includes a primary filtration module 100, a pump 200, a separation tank 300, a vertical separation membrane 400, a porous medium 500, a secondary filtration module 600, (700).

The primary filtration module 100 is installed in the coolant storage tank 10. The coolant storage tank 10 collects coolant used as a container having a predetermined size and light pollutants float on the uppermost layer, Layer. The pollutant mixed solution is sucked by the primary filtration module 100 and transferred to the separation tank 300 to be described later.

More specifically, the primary filtration module 100 may include a body 110 and a floating suction oil tool 120.

The body 110 is installed so as to be submerged in the coolant storage tank 10 and may be fixedly installed on the bottom surface of the coolant storage tank 10 and may be fixed to the bottom surface of the coolant storage tank 10 using a magnet Or the body 110 may be suspended in the coolant storage tank 10 in an excited state using an arm. Preferably, the adapter 110 can be connected to the body 110 so that the height of the body 110 can be adjusted as needed.

The upper end of the body 110 is opened and the inside of the body 110 is hollow and a pipe connection port 111 is formed at the lower end and a pipe 20 directed to the outside of the coolant storage tank 10 is connected to the pipe connection port 111 .

The floating suction oil tool 120 is inserted through the upper end of the body 110 so that the floating suction oil tool 120 is formed of a material that is lighter than water and floats on the water. In this embodiment, the floating suction oil tool 120 is made of P.E material, and its specific gravity is about 0.96.

A plurality of ribs 122 are formed along the upper edge of the floating suction oil tool 120 so as to form a plurality of ribs 122, 122 are formed at a predetermined distance from each other and the pollutant mixture flows into the body 110 through the gap between the rib 122 and the rib 122.

This is because what is sucked through the floating suction oil tool 120 is called a pollutant mixed liquid because the coolant is also sucked together with the pollutant at the uppermost layer. That is, since it is not easy to separate and inhale only the uppermost pollutant, the primary filtration module 100 sucks the pollutant mixture.

The floating suction oil tool 120 is inserted into the body 110 and floated by the buoyancy force and the coolant flows through the gap between the upper end of the body 110 and the outer surface of the floating suction oil tool 120, The contaminated material is mainly sucked through the gap between the ribs, so that the contaminated material mixture flows into the inside of the body.

The pollutant mixed solution flowing into the primary filtration module 100 is pumped by the pump 200 and supplied to the separating tank 300 to be described later.

Preferably, the pump 200 may utilize an air pump, and a strainer 800 may be installed to filter particulate matter in the middle of the piping connecting the pump 200 and the primary filtration module 100. The strainer (8000) filters out small particles in microns.

An air regulator 210 is provided to stabilize the air supply for driving the pump by using the air pump as the pump 200. Air is supplied to the air pump 200. Due to the nature of the air pump 200, And pumping is performed.

Accordingly, when the air pump 200 performs the suction stroke, the suction force acts to cause the floating suction oil tool 120 of the primary filtration module 100 to be downwardly moved downward to a predetermined depth, and then the air pump 200 When the ejection stroke is performed, the operation to rise again is repeated. The floating suction oil tool 120 moves up and down by using the suction force by the air pump 200 so that the contaminant in the uppermost layer flows smoothly into the floating suction oil tool 120. [

The pollutant mixed liquid transferred by the pump 200 flows into the separating tank 300. The separation vessel 300 is a vessel having an inner hollow space and a vertical separation membrane 400 is installed in the separation vessel 300 to divide the inside of the separation vessel 300 into two spaces. However, the lower part of the two spaces separated by the vertical separation membrane 400 is open to communicate with each other.

Two spaces separated by the vertical separation membrane 400 are referred to as a first space 310 and a second space 320 for convenience of explanation.

Particularly, the first space 310 has a larger space than that of the second space 320, and the first space 310 is filled with a proper amount of the porous media 500. The porous medium 500 has a large surface area, and contaminants attach to the surface of the porous medium 500. When the contaminants adhere to the porous medium 500, they are aggregated and floated upward. In other words, since pollutants are mixed with coolant, it takes a long time to separate them into pollutants and coolants. Therefore, it is possible to utilize the porous media 500 to increase pollutants, especially oil, .

Preferably, the separation tank inlet 301, which is pumped by the pump 200 and flows into the separation tank 300, is located in the first space 310, and mainly contaminants are collected in the upper part of the first space 310 And clean coolant is collected in the second space 320.

A secondary filtration module 600 for filtering and collecting pollutants collected in the first space 310 is provided. The secondary filtration module 600 is installed in the first space 310 to discharge contaminants in the uppermost layer.

Specifically, the secondary filtration module 600 includes a body 610 and a suction oil tool 620. The body 610 is fixedly installed in the first space 310 and is immersed in the pollutant mixture. The upper end of the body 610 is opened and the pipe is formed so that contaminants flowing into the body 610 are discharged to the outside of the separating tank 300. A male screw 611 is formed on the upper outer surface of the body 610.

The suction oil tool 620 coupled to the upper end of the body 610 is formed with a female screw 621 at the lower end inner diameter so as to be coupled to the male screw 611 formed on the outer surface of the upper end of the body 610, Its height can be adjusted.

An opening hole 622 is formed in the center of the suction oil tool 620 in the vertical direction, and the opening hole 622 communicates with the inside of the body 610. A plurality of ribs 623 are formed along the upper edge of the suction oil tool 620 so as to be spaced apart from each other. The contaminants are introduced into the gap between the ribs 623, And flows into the inside.

The suction oil tool 620 constituting the secondary filtration module 600 can adjust the height of the suction oil tool 620 according to need. To this end, a handle 624 for rotation is connected to the upper end of one of the ribs 623 . The height of the suction oil tool 620 may be adjusted in consideration of the level of the contaminants forming the uppermost layer of the first space 310. Allowing the gap between the ribs 623 of the suction oil tool 620 to be located slightly below the water surface of the contaminant, the contaminants can flow into the gap between the ribs and flow out.

Meanwhile, in the second space 320, a recovery tool 700 is installed, and in the recovery tool 700, relatively clean coolant collected in the second space 320 is returned to the coolant storage tank 10.

The pollutants such as oil contained in the coolant can be very effectively removed through the structure and operation as described above, and the coolant can be prevented from being decayed, thereby enabling long-time use.

Meanwhile, when the amount of the pollutant collected in the waste tank 900 becomes equal to or greater than a predetermined weight, the pollutant that is caught and discharged by the secondary filtration module 600 is discharged to the waste tank 900. So that the operation can be stopped. If a continuous operation is performed on a production line such as a night work, if the pollutants having a capacity equal to or greater than the capacity of the waste tank 900 are collected, the waste water overflows and causes a problem. So that the pollutant mixed solution is no longer supplied from the coolant storage tank 10.

To this end, when a contact point is formed by using a sensor such as a sensor for sensing a certain weight or more, the mechanical valve 220 is operated to stop the operation of the air regulator 210 for driving the air pump 200 It is provided on the air line so that the air supply can be stopped. That is, when the contact of the waste tank 900 is connected, the mechanical valve 220 receives the signal and operates to stop the air supply.

The present invention can be used as an oil water separator for various industrial cutting equipment.

100: Primary filtration module
110: body 111: pipe connector
112: Adapter 120: Floating Suction Tool
121: inlet 122: rib
200: Pump 210: Air regulator
220: Mechanical valve
300: separator 310: first space
320: second space 301: separation tank inlet
400: vertical separation membrane 500: porous media
600: Secondary filtration module
610: Body 611: Male thread
620: Suction oil tool 621: Female thread
622: aperture hole 623: rib
624: Handle
700: Collection port 800: Strainer
900: Disposal vessel
10: Coolant storage tank 20: Piping

Claims (6)

A primary filtration module installed in the coolant storage tank and provided with a floating suction oil tool functioning to allow a floating pollutant mixture to flow therein;
A pump for pumping and transporting the pollutant mixture introduced into the primary filtration module;
A separation tank into which the contaminated mixed liquor transferred by the pump flows;
A vertical separator for separating the interior of the separator into two spaces, and a lower portion of the separator is opened to allow the two spaces to communicate with each other;
A porous medium accommodated in a first space defined by the vertical separation membrane;
A second filtration module installed in the first space to allow the contaminants in the uppermost layer to flow in and be discharged;
And a recovery port installed in the second space to return the coolant from which the contaminants have been removed to the coolant storage tank. The method according to claim 1,
The primary filtration module comprises:
A body installed to be submerged in the coolant storage tank, having an upper opening and a lower pipe end;
And a floating suction tool inserted through the upper end of the body and having a plurality of ribs spaced apart from each other with a circle along the upper edge thereof and having an inlet communicating with the inside of the body at a central portion thereof, Separator. The method according to claim 1,
Wherein the pump is an air pump, and a strainer for filtering particulate matter is provided between the primary filtration module and the pump. 4. The method according to any one of claims 1 to 3,
The secondary filtration module includes:
A body fixedly installed in the first space so as to be submerged so as to allow the contaminants to be introduced to be discharged to the outside of the separating tank, an upper end opened and a female screw formed on the upper inner circumferential surface;
A plurality of ribs formed along the upper edge of the body and having a plurality of ribs spaced apart from each other, the ribs being inserted into the ribs, And a suction oil tool for allowing the contaminants to flow into the body through the opening hole. 4. The method according to any one of claims 1 to 3,
Wherein the floating suction induction port is lowered by a suction force when the suction stroke of the pump is lowered, and then is raised again when the suction stroke is repeated. 4. The method according to any one of claims 1 to 3,
Wherein the pollutant filtered by the secondary filtration module is discharged to a waste tank, and when the amount of the waste tank collected in the waste tank becomes a predetermined weight or more, a contact is formed to stop the operation of the pump. .

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