JP5852861B2 - Filtration device - Google Patents

Description

The present invention relates to a filtration device for removing chips , which are foreign substances of a magnetic substance contained in a coolant used in metal cutting, by a magnetic force of a magnet, and more specifically, after primary filtration, or Furthermore, the present invention relates to a filtration apparatus that can remove fine chips contained in a coolant after secondary filtration.

  As is well known, in metal cutting, cutting oil (hereinafter referred to as “coolant liquid”) is poured into the workpiece and the blade for the purpose of lubrication, cooling, etc. Although reused, since the used coolant liquid contains foreign substances such as chips, magnetic particles such as chips are included. The foreign substance of the magnetic material is removed.

  Some filtering devices that remove foreign substances such as chips from the used coolant liquid adsorb and remove chips and the like by the magnetic force of a magnet.

  For example, in a magnet screw type filter described in Japanese Patent Application Laid-Open No. 2003-33676, a magnet support body in which magnets are spirally arranged on the outer periphery is attached to the inside of a long cylindrical body whose base end and distal end are closed. The rotary shaft is rotatably supported. When removing foreign substances such as chips contained in the coolant with this filter, the tip is immersed in the dirty liquid in the coolant tank. To rotate the cylinder.

  Then, foreign substances such as chips in the dirty liquid are attracted to the outer surface of the cylinder by the magnetic force, and are transported toward the base end on the outer surface of the cylinder, whereby the dirty liquid It can be removed from within.

  In addition, there is a conveying device described in Japanese Patent Laid-Open No. 9-328229 as an invention for conveying an article made of a magnetic material such as a steel ball, a small screw, a bolt, or a nut by a magnetic force. A rotating yoke portion having a cylindrical rotating shaft and a magnetic force generating portion is disposed inside the conveying member, and a conveying path support guide is spirally wound around the outer peripheral surface of the conveying member, and the rotating shaft is rotated. Thus, the article to be conveyed adsorbed on the outer peripheral surface of the conveying member is conveyed toward the upper end along the conveyance path support guide.

Japanese Patent Laid-Open No. 2003-33676 Japanese Patent Laid-Open No. 9-328229

  However, in the above-described filtration apparatus, it is possible to remove relatively large chips contained in the coolant liquid, but the fine particles remaining in the coolant liquid after the primary filtration or after the secondary filtration. It was impossible to remove swarf chips (hereinafter referred to as “sludge”).

  That is, since the sludge remaining in the coolant after the primary filtration or further after the secondary filtration is sludged in the coolant tank, the conventional filtration device described above is used. Then, it is possible to adsorb to the outer surface of the cylindrical body by magnetic force, but the adsorbed sludge cannot be conveyed upward, and as a result, cannot be removed from the coolant.

  Then, this invention makes it a subject to provide the filtration apparatus which can also remove the sludge sludge which remains in a coolant liquid after primary filtration or after secondary filtration.

The filtration device of the present invention is a filtration device for removing chips and sludge contained in the used coolant liquid,
A cylindrical tube with the top and bottom closed;
A conveyance guide disposed in a spiral manner on the outer periphery of the cylindrical body, with the side surface on the inner peripheral side being in contact with or close to the outer surface of the cylindrical body;
A magnetic force generating section comprising a magnet case fixed to the cylinder in the cylinder, and a plurality of magnets disposed on the outer surface of the magnet case,
A main body case housing the upper portion of the cylindrical body;
A discharge portion that is attached to the main body case through the main body case and includes a receiving port that is close to the outer surface of the cylindrical body, and a discharge port that is disposed at a position protruding outside the main body case. When,
Driving means for rotating either the cylindrical body or the conveyance guide,
In the state where the lower part is immersed in the used coolant liquid in the coolant tank, by turning either the cylinder or the conveyance guide, chips that are foreign substances of the magnetic substance in the coolant liquid are removed . It is characterized in that while being adsorbed on the outer surface of the body, it can be transported upward along the transport guide and can be discharged from the discharge section.

According to the experiments of the present inventor, the lower part of the cylindrical body in which the conveyance guide is spirally disposed on the outer periphery and the magnet case having the magnet disposed on the outer surface is fixed inside the used coolant liquid in the coolant tank. In this state, when the cylindrical body is rotated with the magnet case, or when the conveyance guide is rotated with the cylindrical body stationary , the chips that are foreign substances of the magnetic substance in the coolant liquid are It has been found that the sludge in the form of sludge is transported upward along the transport guide while being adsorbed on the outer surface of the cylinder.

  Therefore, in the filtration device of the present invention, sludge sludge remaining in the coolant liquid after primary filtration or after secondary filtration can be reliably removed.

It is a perspective view of the Example of the filtration apparatus of this invention. It is sectional drawing for demonstrating the structure of the Example of the filtration apparatus of this invention. It is a figure for demonstrating the magnetic force generation part in the Example of the filtration apparatus of this invention. It is a figure for demonstrating the magnetic force generation part in the Example of the filtration apparatus of this invention. It is a figure for demonstrating the discharge part in the Example of the filtration apparatus of this invention. It is a figure for demonstrating the discharge part in the Example of the filtration apparatus of this invention. It is a figure for demonstrating the usage method of the Example of the filtration apparatus of this invention.

  The filtration device of the present invention has a cylindrical tube with the top and bottom closed, and a conveying guide is disposed on the outer periphery of the tube.

  The conveying guide is disposed on the outer periphery of the cylindrical body in a spiral shape with the side surface on the inner peripheral side being in contact with or close to the outer surface of the cylindrical body.

  On the other hand, a magnetic force generating part is fixed to the cylindrical body inside the cylindrical body, and this magnetic force generating part is configured by arranging a magnet on the outer surface of the magnet case. The bottom end of the cylinder is close to the ceiling of the body and the bottom is close to the bottom of the cylinder, and is fixed to the inside of the cylinder by bolts or the like.

  The magnet case is in the shape of a square pipe whose upper end is close to the ceiling of the cylinder and whose lower end is close to the bottom of the cylinder, and the magnet is vertically arranged on each surface of the magnet case. It is arranged in multiple stages.

  Further, the filtration device of the present invention includes a main body case, and the main body case accommodates the upper portion of the cylindrical body, and a discharge portion is attached to an arbitrary portion in a form penetrating the main body case. Yes. The discharge portion includes a receiving port and a discharging port, the receiving port is disposed at a position close to the outer surface of the cylindrical body, and the discharging port is disposed at a position protruding to the outside of the main body case.

  Furthermore, the filtration device of the present invention has a drive means, and this drive means rotates either the cylinder or the conveyance guide.

Then, in a state where the lower part of the cylinder is immersed in the used coolant liquid in the coolant tank, the driving means is driven to rotate either the cylinder or the conveyance guide, thereby magnetic properties in the coolant liquid. Chips that are foreign bodies can be transported upward along the transport guide while adsorbing on the outer surface of the cylindrical body, and can be discharged from the discharge section.

Here, when adopting a configuration in which the driving means rotates the cylindrical body, the discharge portion includes a bottom plate whose proximal end side is close to the outer surface of the cylindrical body and whose distal end side protrudes outside the main body case, The outer surface of the cylinder is formed by a pair of side plates that are connected upward at both ends of the bottom plate, and the end on the cylinder side of the front side plate as viewed in the rotation direction of the cylinder is slightly cut away. In this case, an extrusion protrusion is preferably formed at a location where the cylinder can pass through the vicinity of the upper surface of the bottom plate of the discharge portion, so that the magnetic foreign matter conveyed upward along the conveyance guide Certain chips can be reliably discharged from the discharge section.

  An embodiment of the filtration device of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of the filtration device of this embodiment, and FIG. 2 is a partial cross-sectional view for explaining the structure of the filtration device of this embodiment. In the figure, reference numeral 1 denotes the filtration device of this embodiment.

And the filtration apparatus 1 of a present Example has a cylinder, The chip (henceforth only "chip") which adsorb | sucks the foreign material of a magnetic body on the outer surface of this cylinder is conveyed and removed. To do. That is, in the figure, reference numeral 2 denotes a cylindrical body. In this embodiment, the cylindrical body 2 is a stainless steel round pipe, and is attached to the base 3 so as to be rotatable with the top and bottom portions closed.

  Moreover, in the filtration apparatus 1 of a present Example, the magnetic force generation part is provided in the inside of the said cylinder 2, and it can adsorb | suck chip on the outer surface of the said cylinder 2 with the magnetic force of this magnetic force generation part. Yes.

  Here, the magnetic force generating part will be described. In FIG. 2, 4 is the magnetic force generating part, FIG. 3 is a front view of the magnetic force generating part, and FIG. 4 is an enlarged sectional view taken along the line AA in FIG. And the said magnetic force generation part 4 in a present Example has the magnet case 5, This magnet case 5 is made into the shape of an iron square pipe.

  The magnet case 5 has an upper end positioned near the ceiling in the cylinder 2 and a lower end positioned near the bottom in the cylinder 2. The cylinder 2 is fixed.

  In this embodiment, a large number of magnets are arranged on the outer surface of the magnet case 5. That is, in the figure, 6 is a magnet, and in the present embodiment, the magnet 6 has a rectangular shape with a predetermined size, and on each of the four surfaces of the magnet case 5 at a predetermined interval and in multiple upper and lower stages. It is attached.

  In this embodiment, a long plate-like fixed seat 7 is welded to each of the four surfaces of the magnet case 5, and a tapped hole is formed in the fixed seat 7, and a bolt or the like is inserted through the tapped hole. Thus, a magnet is fixed to the fixed seat 7. Each of the magnets 6 is arranged so that the surface thereof is close to the inner wall of the cylinder 2, and with this configuration, chips can be attracted to the outer surface of the cylinder 2 by the magnetic force of the magnet 6. In the present embodiment, the magnet 6 is a rare earth magnet having a strong magnetic force.

  Next, in FIGS. 1 and 2, four support columns 12 are erected above the base 3, and a fixed base 11 is attached to the upper end of the support column 12. The main body case 10 is provided.

  The main body case 10 is made of iron or stainless steel, has a ceiling portion, and has a box shape whose bottom is closed by the fixed base 11, and an insertion hole 1101 formed in the fixed base 11 is formed therein. The upper portion of the penetrating cylinder 2 is accommodated.

  Further, in the main body case 10, a coupling 13 is connected to the upper portion of the cylindrical body 2, and the coupling 13 is connected to a motor 14 as a driving unit disposed on the upper portion of the main body case 10. Thus, the cylinder body 2 can be rotated by driving the motor 14.

  Next, 9 is a conveyance guide in the figure. That is, in the filtration device 1 of the present embodiment, the conveyance guide 9 is disposed on the outer periphery of the cylinder 2, and the chips adsorbed on the outer surface of the cylinder 2 are moved upward along the conveyance guide 9. To be transported to.

  Here, the conveyance guide 9 will be described. In the present embodiment, the conveyance guide 9 is a long stainless steel plate, and its side surface is brought into contact with the outer surface of the cylindrical body 2, or It is arranged in a spiral manner on the outer periphery of the cylinder 2 while being close to each other. The lower end portion 9 a is fixed to the base 3, and the upper end portion 9 b is fixed to the inner wall of the main body case 10. When the cylindrical body 2 is rotated with this configuration, the magnetic force generator 4 fixed to the cylindrical body 2 is also rotated inside the cylindrical body 2, and the chips adsorbed on the outer surface of the cylindrical body 2 Is transported upward along the transport guide 9 along the transport guide 9 while rotating together with the transport body 2.

  Next, in the figure, 15 is a discharge part for discharging the chips conveyed above the cylindrical body 2, and in this embodiment, this discharge part 15 is inserted into the mounting hole 1001 formed in the main body case 10. It is attached through the inner wall of the main body case 10 and has a receiving port 15a and a discharging port 15b. And the receiving port 15a is located in the location close | similar to the outer surface of the said cylinder 2, and the discharge port 15b is arrange | positioned in the position which protruded the said main body case 10 outside.

  Here, the discharge portion 15 will be described in detail. FIG. 5 is a perspective view of the discharge portion 15 in the present embodiment, and the discharge portion 15 has a bottom plate 16 having a flat plate shape. Is attached to the main body case 10 in such a manner that the base end side is close to the outer surface of the cylindrical body 2 and the front end side protrudes to the outside of the main body case 10, and as is clear from FIG. It is inclined downward at an angle of about 45 degrees toward the tip side.

  A side plate 17 is connected to both ends of the bottom plate 16 upward, and the bottom plate 16 and the pair of side plates 17 constitute a discharge portion 15.

  Further, in the side plate 17, the side plate 17 a on the near side as viewed in the rotation direction of the cylinder 2 slightly cuts off the end portion on the cylinder 2 side as shown in FIG. 5. And thereby, the chips adsorbed on the outer surface of the cylinder 2 are guided onto the bottom plate 16, and the chips guided on the bottom plate 16 are moved by the side plate 17b on the front side as viewed in the rotation direction of the cylinder 2. It is supposed to be peeled off from the outer surface of the cylinder 2

  On the other hand, when the cylindrical body 2 is rotated on the outer surface of the cylindrical body 2, an extrusion protrusion 18 is projected toward the outer peripheral side at a position where the vicinity of the upper surface of the bottom plate 16 can pass. It is possible to pass over the upper portion 16, thereby allowing chips that accumulate on the bottom plate 16 to fall along the bottom plate 16.

  That is, according to the experiment of the present inventor, the chips introduced onto the bottom plate 16 are accumulated in the vicinity of the receiving port 15a in the bottom plate 16 and do not move to the discharge port 15b side when no allowance is given. There was found. FIG. 6 shows this state. As shown in FIG. 6, the chips 19 conveyed to the receiving port 15 a of the discharge unit 15 theoretically move toward the discharge port 15 b due to the inclination of the bottom plate 16. In practice, however, it stays in the vicinity of the receiving port 15a and accumulates.

  Therefore, in the filtering device 1 of the present embodiment, the extrusion protrusion 18 is projected on the outer surface of the cylinder 2 so as to pass through the upper surface of the bottom plate 16 when the cylinder 2 is rotated. The protrusion 18 pushes the chips remaining in the vicinity of the receiving port 15a toward the discharge port 15b.

  In the present embodiment, the conveying guide 9 is disposed up to the vicinity of the receiving port 15a of the discharge portion 15 on the outer surface of the cylindrical body 2. Further, the magnet 6 is disposed up to the vicinity of the receiving port 15 a of the discharge portion 15 inside the cylindrical body 2, and the uppermost magnet 6 is only one of the four surfaces of the magnet case 5. It is arranged.

  Next, the operation of the thus configured filtering device 1 of the present embodiment will be described. When the cylindrical body 2 is rotated in a state where chips are adsorbed on the outer surface of the cylindrical body 2, the cylindrical body 2 The magnetic force generator 4 fixed to the cylinder 2 inside also rotates in the same manner as the cylinder 2, and the chips adsorbed on the outer surface of the cylinder 2 along with the rotation are adsorbed to the cylinder 2. In this state, it is rotated together with the cylindrical body 2, but since the conveying guide 9 is spirally arranged on the outer periphery of the cylindrical body 2, it is rotated with the rotation of the cylindrical body 2. The chips are conveyed upward along the conveyance guide 9.

  Then, after the chips conveyed to the receiving port 15a of the discharge port 15 are transferred to the bottom plate 16 of the discharge unit 15, the vicinity of the cylinder side end portion of the front side plate 17b viewed in the rotation direction of the cylinder 2 As a result, it is peeled off from the cylinder 2 and collected in the vicinity of the receiving port 15a on the bottom plate 16.

  Then, the chips collected in the vicinity of the receiving port 15a on the bottom plate 16 are pushed out to the discharge port 15b side by the extrusion protrusion 18 passing on the bottom plate 16 as the cylinder 2 rotates, and fall on the bottom plate 16 Then, it moves on the bottom plate 16 toward the discharge port 15b and is then discharged from the discharge port 15b.

  Therefore, according to the filtration device 1 of the present embodiment, it is possible to efficiently remove the chips contained in the coolant liquid, and according to the experiment of the present inventor, the cylindrical body is rotated together with the magnetic force generator. In the filtering device of the present embodiment, sludge that has become sludge can be transported upward along the transport guide 9 on the outer surface of the cylindrical body 2. It is also possible to reliably remove sludge sludge remaining in the coolant liquid after the secondary filtration.

  Next, a method for removing chips contained in the coolant tank using the filtration device 1 of this embodiment will be described with reference to FIG. 7. In FIG. 7, reference numeral 21 denotes a coolant tank. The used coolant liquid 22 is placed in the coolant liquid 22, and chips 23 are contained in the coolant liquid 22.

  When filtering the coolant liquid 22 in the coolant tank 21, the tubular body 2 is immersed in the coolant liquid 22, and the filtration device 1 of this embodiment is attached to the coolant tank 21 by the fixed base 11. Further, although not shown, a means for receiving the chips removed from the coolant liquid or a means such as a conveyer is disposed below the discharge port in the discharge unit 15.

  In this state, the motor 14 is driven to rotate the cylinder 2 together with the magnetic force generator 4. Then, as described above, the chips adsorbed on the outer surface of the cylindrical body 2 are transported upward on the outer surface of the cylindrical body 2 while being guided by the transport guide 9, and on the bottom plate 16 of the discharge unit 15. By being discharged and further pushed out by the pushing projection 18, the sheet is discharged from the discharge port 15b after moving on the bottom plate 16 toward the discharge port 15b.

  As described above, in the filtration device of the present embodiment, the conveyance guide is disposed in a spiral shape on the outer periphery of the cylinder, and the magnetic force generator including the magnet is fixed inside the cylinder, together with the magnetic force generator. By turning the cylinder, sludge that has become sludge can be transported upward along the transport guide, so that the sludge is transferred into the coolant after the primary filtration or after the secondary filtration. The remaining sludge sludge can be reliably removed.

  In the above description, the form in which the cylindrical body 2 is rotated has been described, but in addition, the cylindrical body may be fixed and the conveyance guide may be rotated. A rotation base or the like may be attached to the upper and lower ends of the guide, and the rotation base may be connected to a motor.

  In addition, the magnet case 5 in the magnetic force generation unit 4 does not necessarily have a square pipe shape. The magnet case has a round pipe shape, and the outer periphery of the magnet case 5 is spaced apart in the circumferential direction and has an arc shape extending in multiple stages. A large number of magnets having an inner surface may be provided.

  The filtration device of the present invention can remove sludge sludge contained in the coolant liquid by using the magnetic force of the magnet, and therefore can be applied to all filtration devices using the magnetic force of the magnet. .

DESCRIPTION OF SYMBOLS 1 Filtration apparatus 2 Cylindrical body 3 Base 4 Magnetic force generation part 5 Magnet case 6 Magnet 7 Fixed seat 8 Bolt 9 Transfer guide 10 Main body case 11 Fixed base 12 Strut 13 Coupling 14 Motor 15 Discharge part 16 Bottom plate 17 Side plate 18 Extrusion protrusion 19 Chip 21 Coolant tank 22 Coolant liquid 23 Chip

Claims (3)

A filtration device for removing chips that are foreign substances in the magnetic substance contained in the used coolant liquid,
A cylindrical tube (2) with the top and bottom closed;
A conveying guide (9) spirally disposed on the outer periphery of the cylindrical body (2), with an inner peripheral side surface being in contact with or close to the outer surface of the cylindrical body (2);
Magnetic force comprising a magnet case (5) fixed to the cylinder (2) in the cylinder (2) and a plurality of magnets (6) disposed on the outer surface of the magnet case (5). Generating part (4);
A body case (10) that houses an upper portion of the cylindrical body (2);
The main body case (10) is attached through the main body case (10), and protrudes to the outside of the main body case (10) and the receiving port (15a) close to the outer surface of the cylindrical body (2). A discharge portion (15) having a discharge port (15b) disposed at a position;
Drive means (14) for rotating either the cylinder (2) or the conveyance guide (9),
By rotating either the cylindrical body (2) or the conveyance guide (9) with the lower part immersed in the used coolant liquid in the coolant tank, foreign matter of the magnetic substance in the coolant liquid can be obtained. Filtration characterized in that a certain chip is adsorbed to the outer surface of the cylinder (2) and conveyed upward along the conveyance guide (9) to be discharged from the discharge part (15). apparatus. A filtration device for removing chips that are foreign substances in the magnetic substance contained in the used coolant liquid,
A cylindrical tube (2) with the top and bottom closed;
A conveying guide (9) spirally disposed on the outer periphery of the cylindrical body (2), with an inner peripheral side surface being in contact with or close to the outer surface of the cylindrical body (2);
Magnetic force comprising a magnet case (5) fixed to the cylinder (2) in the cylinder (2) and a plurality of magnets (6) disposed on the outer surface of the magnet case (5). Generating part (4);
A body case (10) that houses an upper portion of the cylindrical body (2);
The main body case (10) is attached through the main body case (10), and protrudes to the outside of the main body case (10) and the receiving port (15a) close to the outer surface of the cylindrical body (2). A discharge portion (15) having a discharge port (15b) disposed at a position;
Driving means (14) for rotating the cylindrical body (2),
By rotating the cylinder (2) in a state where the lower part is immersed in the used coolant liquid in the coolant tank, the chips that are foreign substances of the magnetic substance in the coolant liquid are removed. While being adsorbed to the outer surface of the sheet, it can be conveyed upward along the conveyance guide (9) and discharged from the discharge part (15)
The discharge portion (15) includes a bottom plate (16) whose proximal end is close to the outer surface of the cylindrical body (2) and whose distal end protrudes outside the main body case (10), and both ends of the bottom plate (16). a pair of side plates (17) which is continuously provided upward in parts, in addition to forming, cylindrical body of the front side of the plate as viewed in the direction of rotation of the cylindrical body (2) (17a) (2) side of the end portion Cut out slightly,
The outer surface of the cylindrical body (2), the formation of the bottom plate protrusion extruded into passable places the vicinity of the upper surface of (16) the cylindrical body (2) upon rotation (18), characterized in that Filtration device.   The magnetic force generator (4) includes a rectangular pipe-shaped magnet case (5), and a plurality of magnets (6) arranged in multiple stages in the vertical direction on each surface of the magnet case (5), The filtration device according to claim 1, wherein the filtration device is provided.

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