JP2018008332A - Chip conveyor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a chip conveyor device that reduces the load of the jetting of a coolant cleaning liquid and can reliably remove chips attached to a filtration drum.SOLUTION: A chip conveyor device has: a filtration drum 3 that filters dirty liquid through mesh-like holes disposed around the rotation axis of a filtration drum 3; and jetting means 811 that removes chips Z attached to the filtration drum 3, the jetting means 811 to remove the chips Z by jetting a coolant cleaning liquid A9 while supplying it with compression air Ar.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a chip conveyor device for filtering out a clean liquid from a used coolant liquid in which chips are mixed and discharged from a machine tool such as a lathe or a milling machine, and a chip cleaning and discharging method using this apparatus.

  In machine tools such as lathes and milling machines, cutting fluid (coolant fluid) is supplied to the machining area where the cutting tool such as a cutting tool or cutter and the workpiece (workpiece) come into contact with each other to suppress the heat generation of the machining area. The wet type to perform has become mainstream. This wet type machine tool is always provided with a chip conveyor device provided with a filtering means. The chip conveyor device separates and discharges chips (unnecessary material removed from the workpiece) from the used coolant liquid (dirty liquid) discharged from the machine tool. It is regenerated into a clean coolant liquid (clean liquid) from which chips are removed by means and returned to the machine tool. In this specification, metal scraps or metal scraps that have been removed from workpieces by machining of machine tools are defined as chips. Regardless of beard shape, curl shape, small lump shape, powder shape, or sludge shape. It is expressed as chips.

  Filters that remove clean liquid from the used coolant liquid (dirty liquid) that is placed on the chip conveyor device and discharged from the machine tool with mixed chips are examples of rotating drum filters, cyclone separators, and magnet filters. It is done. The rotating drum filter rotates by rotating a cylindrical rotating drum with mesh holes formed in its outer periphery with a metal wire (wedge wire), punching metal, etc., around a horizontal axis in a dirty tank containing dirty liquid. The cutting fluid is filtered to the inside of the rotating drum while retaining chips on the mesh surface on the outer periphery of the drum to make a clean fluid, and the filtered clean fluid is discharged from the inner side of the rotating drum in the horizontal axis direction (lateral direction) and adjacent. Discharge into clean tank. The cyclone separator pours the dirty liquid discharged from the machine tool mixed with chips under pressure from the inlet on the side of the case, generates a spiral flow (cyclone) inside the case, and separates the clean liquid. The concentrated dirty liquid is discharged downward from the separation discharge port (dirty liquid discharge port) at the lower end of the casing while being discharged above the cyclone separator. The magnet filter discharges the clean liquid out of the magnet filter while retaining iron chips on the magnetic body incorporated in the housing. Each of these filters separates and removes the clean liquid from a part of the dirty liquid.

  In the chip conveyor apparatus, chain conveyors, coil-type conveyors, screw-type conveyors, and the like can be cited as examples of the conveyance mechanism that separates and conveys the chips from the used coolant liquid that has been discharged from the machine tool. A chain conveyor has a plurality of plate plates that continuously convey dirty liquid discharged from a machine tool mixed with chips, and spans between a drive shaft and a driven shaft. The cutting fluid is passed below the plurality of plate plates while being discharged from the total discharge port above the conveyor while being conveyed on the plate. As the chip conveyor mechanism of the chain conveyor, there are a scraper type conveyor in which a scraping member (scraper) for scraping scraps is attached to a conveyor belt, and a magnet type conveyor in which a magnet is attached. The screw type conveyor rotates the screw with a spiral propeller above the rotating shaft, compresses the chips while conveying them, and discharges them from the discharge port above the conveyor. Is moved down the conveyor. The coil conveyor compresses chips while conveying them with a rotating shaft formed in a spiral coil and discharges them from the discharge port above the conveyor. It is to be moved. In any of these transport mechanisms, the cutting fluid is moved below the conveyor while moving the chips to the discharge port above the conveyor, and the chips are separated and removed from the dirty liquid.

  In the conventional chip conveyor device, the size (area) of the conveyance path is increased in order to increase the processing capacity of the used liquid discharged by mixing the chips. On the other hand, there are a wide variety of specifications such as the shape, material, and surface roughness of the workpiece (workpiece) processed by the machine tool, and there is a large amount of chips generated from the workpiece depending on the progress of processing. Unlikely, the amount of cutting fluid (coolant) to be supplied greatly increases or decreases according to the heat generation amount of the workpiece. In other words, the amount of dirty coolant liquid discharged from the machine tool mixed with chips rapidly increases and decreases, and the ratio of chips in the dirty coolant liquid usually varies greatly. In order to cope with this sudden increase / decrease in the amount of dirty coolant liquid, a large-size transport path with a margin is provided in accordance with the instantaneous maximum value of the amount of dirty coolant liquid discharged from the machine tool. Or the capacity of the dirty liquid tank for temporarily storing the dirty coolant liquid must be sufficiently increased, or both of them must be carried out. There is a concern that will become.

  The rotating drum filter has a drawback that the mesh is easily clogged, but is suitable for filtering out the dirty liquid and taking out the clean liquid. A conveyance mechanism such as a screw type conveyor is suitable for discharging chips as compressed chips while conveying the chips. For this reason, after combining these both, the chip conveyor apparatus which eliminated the clogging of the mesh with the air injection nozzle or the washing | cleaning liquid injection nozzle is examined (patent document 1 and patent document 2).

  Patent Document 1 includes a rotating drum having a mesh formed on the outer periphery of a cylindrical shape, and a screw type conveyor is arranged coaxially with the rotating drum, and chips on the inner peripheral side of the rotating drum at predetermined intervals in the rotation direction. An apparatus having a configuration in which a rake plate is disposed and a gutter communicated with an inflow pipe is disposed below the screw type conveyor. In Patent Document 1, the dirty liquid supplied from the inflow pipe is collected through a clean tank disposed below by being filtered through the mesh of the rotating drum through the hole in the tub, and as a clean liquid. When the chip slab disposed on the inner peripheral side of the rotating drum scoops the accumulated chips and reaches the upper part, the chips fall and are received and conveyed by the screw conveyor and discharged. The outside of the rotating drum is provided with either one or both of an air injection nozzle and a cleaning liquid injection nozzle, and the mesh of the rotating drum is clogged by injecting air or cleaning liquid. There is a description that it will be resolved (see detailed explanation of the device).

In Patent Document 2, a scraper type conveyor having a rotating drum having a mesh formed on the outer periphery of a cylindrical shape and having a scraper plate attached to a conveying belt is passed through the rotating drum, and an intermediate plate is provided below the conveying belt. An apparatus having a configuration in which is arranged is described. In Patent Document 2, the supplied dirty liquid passes through a hole in the intermediate plate, is filtered through the mesh of the rotating drum, is collected as a clean liquid, and is collected in a clean tank disposed below. There is a description that when the chips accumulated on the inner peripheral side of the drum are at the top, the chips fall on the intermediate plate, are received by the scraper type conveyor, and are discharged. There is a description that one or both of an air injection nozzle and a cleaning liquid injection nozzle are provided outside the rotating drum, and the clogging of the mesh of the rotating drum is eliminated by injecting air or cleaning liquid (paragraph) 0017-paragraph 0020 etc.).
In Patent Document 1, as a coolant cleaning device 10 that efficiently separates coolant and chips at a low cost, a first tank 21 that stores coolant and separates chips and coolant remaining in the coolant. And a micro compressed air pump 23 for generating micro bubbles in the first tank 21 for adsorbing to the chips remaining in the coolant and causing the chips to float on the coolant level, and filtering in the first tank 21. The first tank recovery device 31 that recovers the remaining chips near the coolant level together with the coolant, and the remaining chips are removed from the coolant recovered by the first tank recovery device 31 and separated from the remaining chips. And a filter device 41 for returning the coolant to the first tank 21.
In addition, the applicant of the present application has applied for Patent Document 3 (Japanese Patent Laid-Open No. 2015-9338), and the content of the chip conveyor device in which the filtration drum and the transport tray are combined eliminates the drawbacks of the cylindrical drum. It is a chip conveyor device with a novel structure, and transports while compressing chips in a filtration drum 3 that filters dirty liquid through a mesh 3m arranged around the rotation axis, and a transport tray 5c inserted through the filtration drum 3. The coil conveyor 51 that discharges from the discharge port of the transport path and the driving means 8M that drives these are provided. The filtration drum 3 is formed in a regular polygonal shape in the rotation axis direction, and the dirty liquid supplied into the filtration drum 3 Is filtered through the mesh 3m and taken out as a clean liquid, and the chips in the filtration drum 3 are moved upward as the filtration drum 3 rotates. Is discharged is conveyed compressed by the conveyed from falling into the conveyance tray 51 coil conveyor 51.

Furthermore, with respect to an apparatus for cleaning a dirty coolant liquid in which ultrafine bubbles such as microbubbles and nanobubbles are generated and chips are mixed, those related to Patent Document 4 and Patent Document 5 are disclosed.
Patent document 4 separates coolant and chips efficiently and at low cost. This coolant cleaning device 10 stores coolant and separates chips and coolant remaining in the coolant. The first tank 21, a micro compressed air pump 23 that generates microbubbles in the first tank 21 for adsorbing to the chips remaining in the coolant and floating the chips on the coolant level, and the first tank 21. The first tank recovery device 31 that collects the remaining chips near the coolant level filtered in the tank together with the coolant, and the residual chips are removed from the coolant recovered by the first tank recovery device 31 and the remaining chips. A filter device 41 for returning the coolant separated from the waste to the first tank 21;
Patent Document 5 provides a water treatment apparatus and a water treatment method that can effectively remove contaminants (for example, organic matter) contained in treated water, and a micro / nano bubble generating unit that generates micro / nano bubbles in treated water. 43 or a nanobubble generating part 42 for generating nanobubbles, a second tank 15 for introducing treated water after the generation of micro-nanobubbles or nanobubbles, and a treated water introduced into the second tank 15 are provided in contact with each other. And a carrier 16 made of polyvinyl alcohol. The carrier 16 has pores, and microorganisms are immobilized above the carrier 16.

Japanese Patent Laid-Open No. 5-116734 JP-A-8-283734 Japanese Patent Laying-Open No. 2015-9338 JP2013-163249A JP 2009-195887 A

In Patent Document 3 disclosed by the applicant of the present application, the filtration drum rotates to convey the chips upward, and the mesh cleaning pipe and the nozzle are arranged above the filtration drum by the injection means. The mesh hole of the filtration drum is air-injected downward from the outside or the cleaning liquid is injected. Thus, in order to remove the dirty liquid adhering to the chips, it is efficient to spray the chips directly and drop them.
However, the conventional injection means has a problem that a high output is required to increase the injection efficiency and the cost is increased. In addition, the filtration drum is conveyed upward by a rectangular portion protruding to the outer periphery at a predetermined interval in the rotation axis direction. However, this rectangular shape has a surface that is difficult to remove by injection by the injection means.
In addition, the filtration drum (mesh) needs to be replaced in the filtration drum, but in the conventional device, the type in which chips are wound up is often forced to be replaced.
In Patent Documents 4 and 5, ultrafine bubbles such as microbubbles and nanobubbles are generated in the liquid tank to clean the coolant liquid in which chips are mixed. However, in the liquid phase only, the chips are cleaned. The removal is not sufficient, and on the other hand, even with the injection alone, the chips are not efficiently washed and removed.

  Therefore, an object of the present invention is to provide a chip conveyor device that can reduce the burden of spraying the coolant cleaning liquid and can reliably remove chips adhering to the filtration drum.

The chip conveying conveyor of the present invention is a chip conveyor device that filters used coolant liquid (dirty liquid) discharged from a machine tool such as a lathe or a milling machine to remove clean liquid and discharge chips. A filtering drum for filtering the dirty liquid through mesh holes arranged around the rotation shaft, and an injection means for removing chips adhering to the filtration drum, wherein the injection means supplies compressed air to the coolant cleaning liquid. It is characterized by removing chips by spraying while supplying. Here, the position of the ejection means may be outside or inside the filtration drum. The compressed air only needs to be mixed with low-pressure compressed air (0.1 to 0.2 MPa).
According to the present invention, since compressed air is supplied to the injection means, the injection load of the coolant cleaning liquid by the injection means can be reduced. The supply of compressed air according to the present invention has a role different from that of a conventional compressed air pump that generates ultrafine bubbles such as microbubbles and nanobubbles as in Patent Documents 4 and 5 connected to the supply pipe of the injection means. . That is, the supply of compressed air of the present invention results in the generation of ultrafine bubbles such as microbubbles and nanobubbles, but the primary role is to widen the range of impact force and diffusion of the injection means. is there. For example, in the present invention, as a mixed fluid in which low-pressure compressed air (0.1 to 0.2 MPa) is mixed with coolant liquid (flow rate 15 to 18 liters / min and discharge pressure 0.1 to 0.3 MPa), the nozzle of the injection unit When the liquid is continuously ejected from the nozzle (when the mixed fluid is ejected from the nozzle to the atmospheric pressure), the liquid rapidly increases in the liquid injection speed due to the rapid expansion of the volume of the air, and the impact force of the liquid increases. At the same time, since the diffusion region becomes wide, foreign matters (chips) adhering to the filtration drum can be efficiently removed. The conventional cleaning method is liquid cleaning with a liquid nozzle or air blow with air, whereas in the case of the cleaning method of mixing compressed air and liquid of the present invention, The flow rate and pressure are 1/5 to 1/10 or less, and the flow rate and pressure of air are 1/10 to 1/20 or less, thereby greatly reducing energy consumption. This is a cleaning method that can eliminate wasteful resources such as rebounding when cleaning liquid and air, and is a cleaning method that increases the generation of bubbles and increases the cleaning effect when sprayed onto mesh-like holes. That is, in the present invention, the generation of bubbles is remarkably increased due to the correlation between the spraying by the spraying means and the mesh-shaped holes of the filtration drum, and the cleaning and cleaning of the chips are remarkably improved.

The present invention is characterized in that chips in the filtration drum are conveyed upward as the filtration drum rotates, and the compressed air is jetted downward from above on the outside of the filtration drum.
According to the present invention, since the mesh-shaped hole of the filtration drum is sprayed downward from the upper side of the outside, the chips attached to the filtration filter of the filtration drum are dropped downward, so that the most effective removal It is. In addition, the cleaning liquid containing the compressed air of the injection means can be directed downward to increase the impact force, and can be injected with a wide diffusion region.

According to the present invention, a mesh-like hole is formed by a metal wire on the outer periphery of the filtration drum, and the mesh-like hole is formed in the center mesh layer, and inside and outside the center mesh layer than the mesh mesh of the center mesh layer. It is characterized by comprising an inner mesh layer and an outer mesh layer of small mesh holes, which are sintered.
According to the present invention, when the cleaning liquid mixed with compressed air is sprayed by the spraying means, the generation of bubbles is remarkably increased by the structure of the plurality of mesh-shaped holes of the filtration drum, and the cleaning power is exerted on the mesh-shaped holes. Let it show off dramatically.
According to the present invention, the filtration drum is formed with a substantially U-shaped continuous shape on the outer periphery at predetermined intervals in the rotation axis direction, and chips are captured at the position of the substantially U-shaped continuous shape. The chips are separated and removed by spraying by the spraying means. The U-shape is a continuous oval shape (substantially U-shape in the forward direction and vice versa), and is fan-shaped spreading toward the chip discharge side. It is also effective for discharging by means, and it is a shape that does not easily damage the mesh.
According to the present invention, even when the chips are collected, the chips adhering in a substantially U shape by the ejecting means can be effectively separated and removed.

According to the present invention, there is provided a water storage area in which used coolant liquid (dirty liquid) discharged with mixed chips is stored below the filtration drum, and the coolant liquid containing compressed air from the injection means stores water. When mixed into the region, it is preferable to separate and remove used coolant liquid (dirty liquid) attached to the chips by generating ultrafine bubbles such as microbubbles and nanobubbles.
According to the present invention, chips can be washed and discharged by efficiently using one of the jetting means. That is, when coolant liquid containing compressed air from the spraying means is mixed into the water storage region, ultrafine bubbles such as microbubbles and nanobubbles are generated to separate and remove used coolant liquid (dirty liquid) attached to the chips. However, the chips that have been cleaned in this way are transported upward, and are reliably cleaned and separated by cleaning by the spraying means, and are discharged.

According to the chip conveyor device of the present invention, the supply load of the coolant cleaning liquid by the spraying means can be reduced, and the dirty liquid to which chips and the like are attached is efficiently separated and removed. The conventional cleaning method is liquid cleaning with a liquid nozzle or air blow with compressed air, whereas in the cleaning method of mixing compressed air and liquid of the present invention, a liquid is used. The flow rate and pressure of 1/5 to 1/10 or less, and the flow rate and pressure of air become 1/10 to 1/20 or less, thereby greatly reducing energy consumption.
Further, according to the chip cleaning and discharging method in the chip conveyor device of the present invention, when coolant liquid containing compressed air from the spraying means is mixed into the water storage region, micro bubbles such as micro bubbles and nano bubbles are generated. The used coolant liquid (dirty liquid) adhering to the chips is separated and removed, but the chips that have been washed in this way are transported upward, and are reliably washed and separated by washing by the jetting means and discharged. Will be.

It is a structural diagram which shows the internal structure of the filtration drum of the 1st Embodiment of this invention from the side surface side. It is a structural diagram which shows the internal structure of the filtration drum of the said embodiment from the back side. It is a figure explaining the positional relationship of the injection means and filter drum of the said embodiment, Fig.3 (a) is a front view, FIG.3 (b) is a side view. It is structural drawing which shows the filtration drum of the 2nd Embodiment of this invention. It is structural drawing which shows the other example of the filtration drum of the said embodiment. It is structural drawing which shows the other example of the filtration drum of the said embodiment. It is the photograph of the mesh structure which copied the substantially U-shaped protrusion part of the filtration drum of the said 2nd Embodiment. It is a particle size distribution map of the separated clean liquid filtered by the filtration drum of the second embodiment. It is sectional drawing explaining the conventional chip conveyor apparatus.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. In this embodiment, a used coolant liquid (dirty liquid) discharged from a machine tool such as a lathe or a milling machine is described as an object to be filtered indicated by reference numeral L1.

(Chip conveyor device)
1A and 1B are structural views showing a chip conveyor device 1 according to an embodiment of the present invention. FIG. 2 is a structural diagram showing the internal structure of the filtration drum 3 of the present embodiment from the back side. FIGS. 3A and 3B are views for explaining the positional relationship between the filtration drum 3 and the ejection unit 81 of the present embodiment, FIG. 3A is a front view, and FIG. 3B is a side view. FIG. 4 shows another example of the present invention, which is different from FIG. 1 in the direction in which the coolant cleaning liquid and the compressed air pump Mv1 are merged.
In the present embodiment, the filtration drum 3 is disposed in the housing 2, and is a rotary type that conveys the chips Z while compressing the chips Z in the conveyance tray 50 b inserted through the filtration drum 3 and discharges the chips Z from the discharge port of the conveyance path 5. Coil conveyor 51 and driving means (motor) M for driving them. The filtration drum 3 filters the dirty liquid L1 through a mesh 3m disposed around the rotation axis. The mesh of the rotary filter can have a double or triple structure, and in this embodiment, the mesh has a triple structure in which meshes having different mesh sizes are joined by sintering. The drum filter 3m is a rotating drum having a mesh formed on its outer periphery with a metal wire (wedge wire), punching metal, or the like. The cutting fluid is filtered to the inside of the rotating drum 3 while being clamped to obtain a clean cutting fluid, and the filtered clean cutting fluid is discharged from the inner side of the rotating drum in the horizontal axis direction (lateral direction) and discharged into the clean tank 2. .

  In the example shown in FIG. 1, a coil conveyor 51 is disposed in the center of the rotary filter drum 3 in a predetermined pipe 50 b and is driven by a drive motor M on the back side. When the conveyor 51 is driven to rotate, the chips collected by the collection hopper 7 are discharged while being compressed. Further, on the back side of the coil conveyor 51, a drive shaft J is disposed in a predetermined pipe line (conveyance tray) 50b. The pipe line 50b collects used coolant liquid (dirty liquid) L1 discharged from a machine tool such as a lathe or a milling machine and is drawn into the inside of the filtration drum 3 and below the filtration drum 3. It is discharged to the side and enters the area of the water storage state W. Reference numeral F1 represents a supply path of used coolant liquid (dirty liquid) discharged from a machine tool such as a lathe or a milling machine to the filtration drum 3 (FIG. 1). The motor M and the filtration drum 3 are belt-driven, gear-driven, or chain-driven. Similarly, the motor M and the rotary conveyor 51 are driven by a belt, a gear, or a chain.

Above the filtration drum 3, a coolant cleaning liquid supply pipe 81 and an injection nozzle 811 are attached. Water (coolant liquid) A9 to be injected is supplied to the supply pipe 81, and compressed air is added by the compressed air pump Mb to be supplied to the supply pipe A9 for injection. In the example of FIG. 4, the compressed air can be directly directed to the injection means 811 and can be supplied.

The compressed air pump Mv1 of the present embodiment includes supply means for supplying air or gas, and the coolant liquid from the coolant storage tank is injected. As the compressed air pump Mv1, it is possible to supply a small amount of air that can be supplied to a water tank used for breeding tropical fish, but a gas-liquid two-phase swirl type may also be used. The gas-liquid two-phase flow swirl type utilizes a phenomenon in which a water flow is generated to generate a vortex, a gas (large bubble) is entrained in the vortex, and the bubble breaks apart when the vortex is collapsed. Ultrafine bubbles have an excellent effect of cleaning oil and the like by the force of ions present at the interface. In addition, the compressed air pump Mv1 can be replaced with a drain cap having a connection port, and a drain valve can be attached. Further, a constant flow device can be attached using a joint, and an actuator is installed to adjust the air supply as an automatic valve. You may go.

  In the present embodiment, the cleaning liquid A9 is discharged for a predetermined time at a timing at which each top of the filtration drum 3 is directly above the transport tray 50a, so that it can be easily dropped into the transport tray 50a at a more accurate position. Yes. The predetermined timing can be easily detected by arranging a contact sensor such as a micro switch or a non-contact sensor such as an optical sensor in the vicinity of the upper side of the filtration drum 3.

Above the filtration drum 3, a coolant liquid supply pipe 81 and a nozzle 811 that is an injection unit are arranged to inject the mesh 3 m of the filtration drum 3 downward from the outside. According to this embodiment, Then, the mesh surface 31 of the filtration drum 3 is periodically cleaned while the chips Z carried upward along with the rotation of the filtration drum 3 are surely dropped into the transport tray 50b. As the injection nozzle 811, the cleaning liquid and the compressed air Ar are separately pumped and mixed in the vicinity of the nozzle or the nozzle 811, and when the jetting is performed, the cleaning water is atomized by gas expansion, or the compressed cleaning water has a diameter. A structure in which injection is performed from an injection nozzle having an orifice of several hundred μm can be employed.
In the present embodiment, the dirty liquid L1 supplied from the inflow pipe into the filtration drum 3 is filtered through the mesh 3m, becomes the clean liquid L9, is stored in the clean tank, is taken out from the discharge pipe 91, and is filtered. 3 is moved upward with the rotation of the filtration drum 3 and falls into the transport tray 50b, and is discharged out of the machine as the compressed scrap Z transported by the coil conveyor 51. (FIGS. 1 and 2).

  FIG. 5 is a view showing another example of the filtration drum 3 according to the filtration drum 3 of the above embodiment, FIG. 5 (a) is a front view, and FIG. 5 (b) is a side view. In the example shown in FIG. 5, the filtration drum 3 is provided with a U-shaped protrusion Dt in the rotation axis direction, and the filtration area is increased while increasing the number of arrangement of each top (projection) Dt in the filtration drum 3. Easy to do. As this U-shape, it is a fan-shaped fan that spreads toward the discharge side of the chips Z. (By forming a gentle wave shape over the entire circumference, chips can be captured both inside and outside. The shape is effective in both the recovery of the chips Z and the discharge by the injection means 811 and does not damage the mesh. Compared with the example shown in FIG. 3, the example shown in FIGS. 5 (a) and 5 (b) is a continuous U-shaped cross section that has a fan shape that spreads toward the discharge side of the chips Z. Although common, the number of arrangement | positioning of each top part (protrusion part) Dt of an ellipse (U-shape) is large in a cross section.

Here, according to the present embodiment, the filtration drum 3 has a substantially U-shaped continuous shape (or a continuous elliptical shape) in the rotation axis direction. The chips Z in the filtration drum 3 can be utilized and carried upward with the rotation of the filtration drum 3 and dropped into the transport tray 50b. Further, the substantially U shape has an effect of reducing the surface tension of the coolant liquid while increasing the filtration area with respect to the cylindrical shape, and can increase the filtration ability.
Then, as the substantially U-shaped (or elliptical continuous) filtration filter 3m, several meshes (mesh) are sintered and adhered to form a multilayer structure. For example, if the size of the chips removed by the mesh 3 m of the filtration drum 3 is 10 to 30 μm, it is preferable that the size of the mesh-shaped hole of the central mesh layer 3A is 200 to 600 mesh. The inner mesh layer (inner side of the drum) 3C has a mesh structure of 60 to 30 μm, and the outer side (outer side of the drum) 3B has a mesh of 30 to 60 μm. With such a structure, it is highly accurate for joining wires by sintering, the filtration accuracy of the filtration filter 3m is high, it is sturdy even if it is U-shaped or square-shaped, and chips can be easily discharged. It is suitable for cleaning fine bubbles such as bubbles and nanobubbles.
Here, in patent document 6, although two mesh layers are sintered, it attaches via a frame (frame body 30 of four circumferences), and maintenance of intensity | strength is aimed at only by a mesh layer. It wasn't.
On the other hand, the present invention can be strongly sintered by sintering only three mesh layers, and the upper and lower mesh layers 3B and 3C as reinforcing materials are not only reinforcing the mesh 3A in the center. It also serves as a mesh (FIG. 7B). And even if it carries out the filtration process at 200L / min, about 20 micrometers of chips can be isolate | separated and removed stably. This is because the upper and lower mesh layers 3B and 3C can control the flow rate of the dirty liquid whose mesh-shaped holes are different in size, and it is covered that large-sized chips come into contact with the center mesh 3A. Therefore (which also plays a role as a mesh), high-accuracy filtration with the central mesh 3A is possible. As shown in Table 1, when the central mesh layer 3A is used as a reference for filtering and removing the chips Z, the outer mesh layer 3B and the inner and outer mesh layers 3B are five times larger in size (for example, 20 to 60). Mesh) is preferred. This is to maintain the bonding strength of the sintering and to prevent influence on the standard when the central mesh layer 3A is used as a standard for filtering and removing the chips Z. In the present embodiment, the inner mesh layer 3C is 60 mesh, and the outer mesh layer 3B is 20 mesh. The processing amount (used coolant liquid (dirty liquid) is 200 L / min, and the filtration accuracy of chips (the size of chips to be filtered) is 10 to 30 μm. The type of wire mesh is SUS wire mesh, Copper, etc. may be sufficient.The experiment example (Example) from these points is a combination of a plurality of mesh layers of Table 1. Based on the combination of the mesh layers of Example 3 (400 mesh is a wire diameter) 0.03, the aperture is 0.034, the aperture ratio is 28.2), the mesh-like hole of the central mesh layer 3A is 200 to 600 mesh, and the inner mesh layer 3C is arranged on the inner side. The mesh-like holes of the outer mesh layer 3B arranged on the outside are 5 to 15 times the size of the mesh-like holes of the central mesh layer 3A (about 10 times is the standard) And before The diameter of the wire of the central mesh layer 3A was larger than the thickness of the wires of the inner mesh layer 3C and the outer mesh layer 3B. In addition, the accuracy of filtering by the inner mesh layer 3C and the outer mesh layer 3B is not affected, and on the other hand, the strength of the sintered bond is ensured. 03, the aperture is 0.034, the aperture ratio is 28.2, and the inner mesh 3C is 40 mesh, the wire diameter is 0.25, the aperture is 0.039, and the aperture ratio Is 37.1, the outer side 3B is 60 mesh, the wire diameter is 0.14, the mesh opening is 0.028, and the aperture ratio is 44.4 (conforming to the JIS standard for meshes).
The size of the mesh-shaped holes of the inner mesh layer 3C and the outer mesh layer 3B in Table 1 should be set to the opposite sizes in relation to the direction of passage of the used coolant liquid (dirty liquid) and the injection direction by the injection means. You can also.
FIG. 7 is a photograph of a mesh structure in which a substantially U-shaped protrusion of the filtration drum is copied. FIG. 8 is a particle size distribution diagram of the separated clean liquid filtered by the filtration drum 3. In the examples shown in Table 2, the filtration accuracy of the swarf Z (the size of the swarf to be filtered) is 10 to 30 μm, and even if it is filtered at 200 L per minute, the swarf is stably separated by about 20 μm. It can be removed (FIG. 9).
In addition, on the left and right sides of the filtration drum 3, metal outer peripheral covers are attached to the filtration drum 3 at the outer peripheral ends where the substantially U-shaped forward and reverse are repeated. A three-layered mesh structure is formed by the outer peripheral covers covering these left and right end surfaces (FIGS. 3C and 6C). However, there is no cover member other than that, and it is configured only as the filtration drum 3 of the three-layer mesh layers 3A, 3B, 3C.

In Patent Document 3 (the patent application of the present applicant), the filtration drum 3 has a square shape in the direction of the rotation axis, and therefore, the chips in the filtration drum 3 are removed from the filtration drum 3 by using the square top portions Dt. Although it was a structure which was easy to carry upward with rotation of 3, it had a surface where it was difficult to remove chips from the filtration drum 3 (FIGS. 7A, 7 </ b> B, and 7 </ b> C). On the other hand, in the present invention, if the chips are easily put into the substantially U-shaped projecting portion and carried upward, and are ejected onto the chips by the injection means 811, the discharge and removal from the substantially U-shaped portion is also easy. is there.

Here, as the ejection means 811, the conventional cleaning method is liquid cleaning using a liquid nozzle, or air blow using air (Patent Document 3 or the like). Moreover, the filtration drum of the Example of patent document 3 equips the outer periphery with the square shape which protrudes at predetermined intervals.
On the other hand, in the continuous ejection from the nozzle 811 of the ejection means 81 of the present invention, the liquid rapidly increases in the liquid ejection speed due to the rapid expansion of the volume of the air, and the impact force of the liquid increases, and the diffusion. The region K1 becomes a wide range. It is preferable that the diffusive injection is performed over a range H1 of the radius of the substantially U-shaped protrusion, and more preferably, it extends to the U-shaped discharge side which is the end-widening side which becomes the discharge side of the chips Z ( For example, it is more preferable that the U-shaped projecting portion Dt and the projecting portion Dt are diffused so as to extend to H2 (FIG. 3A). 4 are arranged continuously above, but the longitudinal direction K1 and K1 in the band shape (widths of H1 and H2) are overlapped within a predetermined range, that is, the nozzle of the injection means 81. It is sprayed laterally from 811 and diffused and sprayed so that the diffusion pattern becomes a band (flat shape) (FIG. 3B). In the invention, the supply of compressed air The spray nozzle (diffusion nozzle) 811 used here has a plurality of fine pores such as a rain dew type, a one having a plurality of linear spray orifices, and a slit orifice. What is sprayed in the form of a film can be used.

  According to the present embodiment, the mesh surface 31 of the filtration drum 3 is periodically dropped while reliably dropping the chips carried upward along with the rotation of the filtration drum 3 from the U-shaped protrusion. Will be washed. Since the cleaning liquid is jetted downward from the outside of the mesh of the filtration drum 3, the cooling load of the coolant cleaning liquid is reduced, and the coolant liquid and chips that efficiently separate and remove the dirty liquid mixed with the chips L3 are efficiently removed. And separation at low cost. For example, in the present invention, as a mixed fluid in which low-pressure compressed air (0.1 to 0.2 MPa) Ar is mixed with coolant liquid (flow rate 15 to 18 liters / min and discharge pressure 0.1 to 0.2 MPa), When continuously ejected from a certain ejection nozzle 811 (when the mixed fluid is ejected from the nozzle under atmospheric pressure), the liquid ejection speed increases rapidly due to the rapid expansion of the volume of the air, and the impact of the liquid As the force increases and the diffusion region becomes wide, foreign matters (chips) adhering to the filtration drum can be efficiently removed.

  As described above, the present invention is not limited to the embodiment described above. In the above-described embodiment, the coil conveyor is exemplified as the rotary filter drum 3, but a screw conveyor may be applied as the rotary filter drum 3. In the above-described embodiment, the spraying means sprays from the outside of the filtration drum, but the position of the spraying means may be outside or inside the filtration drum. Thus, it goes without saying that the present invention can be modified as appropriate without departing from the spirit of the present invention.

1 Chip conveyor device,
3 Filtration drum (rotating drum)
3m mesh (filter),
3A center mesh layer,
3B outer mesh layer,
3C inner mesh layer,
50a Carry tray (pipe),
7 Recovery hopper,
81 coolant liquid supply piping,
811 injection means (injection nozzle),
A9 Coolant liquid (clean liquid for new cleaning)
Dt U-shaped top,
L1 Used liquid (coolant liquid discharged from the machine tool),
L9 clean liquid (clean liquid filtered with a filtration drum),
Mv1 compressed air pump,
W Coolant liquid is in the water storage area,
Z chips,

Claims (5)

  A chip conveyor device that filters out used coolant fluid (dirty fluid) discharged from machine tools such as lathes and milling machines, removes clean fluid, and discharges chips. A filtration drum for filtering the dirty liquid through the mesh-shaped holes and an injection means for removing chips adhering to the filtration drum, and the injection means injects the coolant while supplying compressed air to the coolant cleaning liquid. A chip conveyor apparatus characterized by removing the slag.   The chips in the filtration drum are conveyed upward as the filtration drum rotates, and the compressed air is jetted downward from above on the outside of the mesh hole of the filtration drum. Chip conveyor equipment.   A mesh-like hole is formed on the outer periphery of the filtration drum by a metal wire, and the mesh-like hole is formed in a center mesh layer and mesh holes smaller than the mesh mesh of the center mesh layer inside and outside the center mesh layer. The chip conveyor apparatus according to claim 1, further comprising an inner mesh layer and an outer mesh layer, which are sintered.   The filtration drum has a substantially U-shaped continuous shape formed on the outer periphery at predetermined intervals in the rotation axis direction, captures the chips at the position of the substantially U-shaped continuous shape, and removes the chips at this position. 3. The chip conveyor apparatus according to claim 1, wherein separation and removal are performed by spraying by a spraying means. A transport tray inserted through the filtration drum, a coil conveyor that transports the chips while compressing them and discharges them from the discharge port of the transport path, a driving means for driving them, and a recovery for collecting the chips to the transport tray The chip conveyor apparatus according to claim 1, further comprising a hopper for use.