CN118204829B

CN118204829B - Numerical control machine tool with cutting fluid treatment function

Info

Publication number: CN118204829B
Application number: CN202410606334.7A
Authority: CN
Inventors: 周铭扬
Original assignee: NANTONG KEDING COMPOSITE MATERIALS TECHNOLOGY CO LTD
Current assignee: NANTONG KEDING COMPOSITE MATERIALS TECHNOLOGY CO LTD
Priority date: 2024-05-16
Filing date: 2024-05-16
Publication date: 2024-08-02
Anticipated expiration: 2044-05-16
Also published as: CN118204829A

Abstract

The invention relates to a numerical control machine tool with a cutting fluid treatment function, which is applied to the technical field of numerical control machine tools.

Description

Numerical control machine tool with cutting fluid treatment function

Technical Field

The invention relates to a numerical control machine tool, in particular to a numerical control machine tool with a cutting fluid treatment function, which is applied to the technical field of numerical control machine tools.

Background

The cutting fluid is an industrial fluid used for cooling and lubricating a cutter and a workpiece in the metal cutting and grinding process, is formed by scientifically compounding and matching a plurality of super functional auxiliary agents, has the characteristics of good cooling performance, lubricating performance, rust resistance, oil removal and cleaning functions, corrosion resistance, easy dilution and the like, and can bring a large amount of metal fragments when the cutting fluid is used in a machine tool, so that the recovered cutting fluid needs to be separated from the cutting fluid through a filter screen, but the filter screen is easily blocked by the fragments in the cutting fluid, and the separation treatment of the cutting fluid is not facilitated.

The specification of Chinese patent No. 202121976001.1 discloses a cutting fluid solid-liquid separation device for a numerical control machine tool, which uses a support frame to drive an upper scraping blade and a lower scraping blade to move, the upper scraping blade scrapes scrap iron at the bottom end of a feed port to a second diversion trench, an external water inlet device flushes scrap iron in the second diversion trench to the first diversion trench through a first water pipe, the lower scraping blade scrapes scrap iron on a lower filter plate to the first diversion trench, the scrap iron is flushed into a scrap iron box from the first diversion trench, cutting fluid flows into a liquid storage tank through a lower filter plate, and the filter plate is blocked.

Because metal fragments particles are harder, when the scraping plate pushes the metal fragments to move on the filter plate, the meshes of the filter plate are easy to damage, so that the service life of the filter structure is influenced, and the numerical control machine tool is not beneficial to use.

Content of the application

Aiming at the prior art, the invention aims to solve the technical problems that the filter screen is easy to be blocked by scraps in the cutting fluid, and the separation treatment of the cutting fluid is not facilitated.

In order to solve the problems, the invention provides a numerical control machine tool with a cutting fluid treatment function, which comprises a machine tool body, wherein a cutting pool is movably connected in the middle of the machine tool body, partition plates are fixedly connected in the left end and the right end of the cutting pool, a placing plate is fixedly connected between the tops of the two partition plates, the bottom of the placing plate is in sliding connection with a pushing plate, the bottom of the pushing plate is in close contact with the cutting pool, electric rails are fixedly connected at the front end and the rear end of the cutting pool, the two ends of the pushing plate are respectively fixedly connected with the moving ends of the two electric rails, and sedimentation concentration pipes are fixedly connected at the bottoms of the left end and the right end of the cutting pool; the filter core rod is inserted to one side that the division board kept away from the place board, and a plurality of honeycomb ducts of both ends top fixedly connected with equidistance range about the cutting pond, and the one end fixedly connected with temporary storage tube of cutting pond is kept away from to the honeycomb duct, and the equal sliding connection in both ends has the extrusion piece about the electronic rail, and the extrusion piece corresponds with push plate contact, and the equal fixedly connected with hoisting frame in top four corners in cutting pond, fixedly connected with connecting cable between extrusion piece and the temporary storage tube, and the top that the connecting cable runs through the hoisting frame.

In the numerical control machine tool with the cutting fluid treatment function, the cutting fluid is received through the cutting pool, the follow-up pushing plate slowly pushes the cutting fluid to move, so that the cutting fluid passes through the filtering core rod behind the separation plate to filter and overflow, metal chips sink and drop into the sedimentation concentration pipe, the overflowed cutting fluid enters the temporary storage pipe through the guide pipe, when the pushing plate is pressed to the extrusion block to move, the connecting rope is tightened, and then the temporary storage pipe is pulled to turn upwards, so that the cutting fluid in the temporary storage pipe reversely washes the filtering core rod, the blocking condition of the filtering core rod is effectively cleared, and the filtering core rod is effectively prevented from being damaged due to blockage clearing.

As a further improvement of the application, the height of the front end and the rear end of the cutting pool is larger than that of the left end and the right end, and the middle part of the bottom end of the cutting pool is fixedly embedded with a magnetic plate, so that cutting fluid can overflow from the left end and the right end of the cutting pool conveniently, and the magnetic plate attracts metal scraps, thereby effectively improving the sinking speed of the metal scraps.

As a still further improvement of the application, the height of the temporary storage pipe is lower than the height of the upper opening of the cutting pool, the guide pipe is made of rubber corrugated pipe, the cutting fluid which is convenient for overflowing is collected into the temporary storage pipe by the guide pipe, and the guide pipe made of the rubber corrugated pipe is convenient for bending deformation.

As a further improvement of the application, the front end of the cutting pool is fixedly connected with the recovery pipe, and the connecting pipes are fixedly connected between the two temporary storage pipes and the recovery pipe, so that the cutting fluid in the two temporary storage pipes is conveniently recovered intensively by the recovery pipe, and the recovery efficiency of the cutting fluid is effectively improved.

As a further improvement of the application, the height of the recovery pipe is higher than that of the temporary storage pipe, the height of the recovery pipe is lower than that of the upper opening of the cutting pool, the connecting pipe is made of rubber corrugated pipe, so that the temporary storage pipe stores a proper amount of cutting fluid firstly, then the cutting fluid overflows into the recovery pipe, and the temporary storage pipe stores the cutting fluid which is sufficiently washed.

In addition to the improvement of the application, one end of the sedimentation concentration tube is sleeved with a tube end cover, the bottom of the tube end cover is provided with a discharge port, a sealing plug is inserted in the discharge port, the middle part of the tube end cover is rotationally connected with a conveying screw shaft, the conveying screw shaft is sleeved with the sedimentation concentration tube, and metal scraps in the sedimentation concentration tube are driven by the conveying screw shaft to be discharged and collected from the discharge port, so that the recovery efficiency of the metal scraps is effectively improved.

In addition to the improvement of the application, one end of the conveying screw shaft far away from the pipe end cover is rotationally connected with a piston, the piston is in close contact with the inner wall of the sedimentation concentrated pipe, and when the sedimentation concentrated pipe is cleaned, the piston is pulled out to realize the removal of the metal scraps in the sedimentation concentrated pipe, so that the cleaning effect of the metal scraps is effectively improved.

As a further improvement of the application, the outside of the sedimentation concentration tube is fixedly connected with a pushing cylinder, the output end of the pushing cylinder is fixedly connected with the tube end cover, and the pushing cylinder drives the tube end cover, so that the piston is conveniently driven to move by the conveying screw shaft.

In addition to the improvement of the application, the end of the sedimentation concentration tube far away from the tube end cover is inserted with a plug end, the plug end is inserted with a piston, the end of the sedimentation concentration tube far away from the tube end cover is sealed by the plug end, and the piston is inserted at the same time, so that the rotation of the piston is effectively avoided, and the use of the conveying screw shaft is effectively influenced.

In addition to the improvement of the application, the bottom of the plug end is provided with a through hole, the through hole corresponds to the bottom surface of the sedimentation concentration tube in parallel, the through hole realizes the balance of the internal and external air pressure of the sedimentation concentration tube, and meanwhile, metal scraps accidentally falling into the sedimentation concentration tube are extruded from the through hole when the piston is in reset motion, so that the cleaning effect of the sedimentation concentration tube is effectively improved.

In summary, the cutting fluid is received through the cutting pool, the cutting fluid is placed in the cutting pool for precipitation, the electric rail slowly drives the pushing plate to move, the pushing plate slowly pushes the cutting fluid to move, and further the liquid level of the cutting fluid is improved, so that the cutting fluid passes through the filtering core rod behind the partition plate for filtration and overflow, metal scraps sink and fall into the precipitation concentration pipe, the overflowed cutting fluid enters the temporary storage pipe from the guide pipe, when the pushing plate moves to the terminal end position of the electric rail, the pushing plate presses the extrusion block to move, the temporary storage pipe is pulled to turn upwards through tightening the connecting rope, the cutting fluid in the temporary storage pipe reversely washes the filtering core rod, the blocking condition of the filtering core rod is effectively cleaned, and damage to the filtering core rod due to blockage is effectively avoided.

Drawings

Fig. 1 is a perspective view of a first embodiment of the present application;

FIG. 2 is a perspective view showing a construction of a cutting pool according to a first embodiment of the present application;

FIG. 3 is a side cross-sectional view of a cutting pool according to a first embodiment of the present application;

fig. 4 is an enlarged view of a portion of fig. 3 according to a first embodiment of the present application;

Fig. 5 is a perspective view showing a structure of an electric rail according to a first embodiment of the present application;

FIG. 6 is a schematic illustration of a first embodiment of the present application showing a filter plug backflushing;

FIG. 7 is a bottom perspective view of a cutting pool according to a second embodiment of the present application;

FIG. 8 is a side cross-sectional view of a sedimentation concentrator tube in accordance with a second embodiment of the present application;

FIG. 9 is a perspective view showing a sedimentation concentration tube according to a second embodiment of the present application;

fig. 10 is a perspective view of a piston and plug head according to a second embodiment of the present application.

The reference numerals in the figures illustrate:

1. A machine tool body; 2. a cutting pool; 201. a partition plate; 202. placing a plate; 203. a pushing plate; 204. an electric rail; 205. filtering the core rod; 206. a magnetic plate; 3. a sedimentation concentration tube; 301. a tube end cap; 302. a discharge port; 303. a conveying screw shaft; 304. a piston; 305. a pushing cylinder; 306. a plug end; 307. a through port; 4. a flow guiding pipe; 401. a temporary storage tube; 402. extruding a block; 403. a lifting frame; 404. a connecting cable; 405. a recovery pipe; 406. and (5) connecting pipes.

Detailed Description

Two embodiments of the present application will be described in detail with reference to the accompanying drawings.

First embodiment:

1-3 show, a digit control machine tool with cutting fluid treatment function, including lathe body 1, lathe body 1's middle part swing joint has cutting pond 2, the inside division board 201 of all fixedly connected with in both ends about cutting pond 2, fixedly connected with places board 202 between the top of two division boards 201, place the bottom sliding connection of board 202 has push plate 203, push plate 203's bottom and cutting pond 2 are hugged closely the contact, the both ends are all fixedly connected with electric rail 204 about cutting pond 2, push plate 203's both ends are fixedly connected with the motion end of two electric rails 204 respectively, cutting pond 2 is left and right sides both ends bottom fixedly connected with sedimentation concentration pipe 3, cutting pond 2's front and back end height is greater than the height of left and right ends, cutting pond 2's bottom middle part is fixedly inlayed with magnetic plate 206, be convenient for cutting fluid overflows from cutting pond 2's both ends about, magnetic plate 206 is to the metal chip attraction, effectively improve the sinking rate of metal chip;

When the numerical control machine tool performs cutting operation, a workpiece to be processed is placed on the placing plate 202, used cutting fluid falls into the cutting pool 2 for collection, the cutting fluid is placed in the cutting pool 2 for precipitation, the magnetic plate 206 attracts metal scraps, the sinking speed of the metal scraps is effectively improved, then the electric rail 204 slowly drives the pushing plate 203 to horizontally move, the pushing plate 203 pushes the cutting fluid, the liquid level of the cutting fluid is raised, and the cutting fluid on the upper layer overflows and separates.

Fig. 2-6 show that a filtering core rod 205 is inserted into one side of the partition plate 201 far away from the placing plate 202, a plurality of guide pipes 4 are fixedly connected to the tops of the left end and the right end of the cutting pool 2 in an equidistant manner, a temporary storage pipe 401 is fixedly connected to one end of the guide pipe 4 far away from the cutting pool 2, the height of the temporary storage pipe 401 is lower than the height of an upper opening of the cutting pool 2, the guide pipes 4 are made of rubber corrugated pipes, cutting fluid which is convenient to overflow is collected into the temporary storage pipe 401 by the guide pipes 4, the guide pipes 4 made of the rubber corrugated pipes are convenient to bend and deform, extrusion blocks 402 are slidably connected to the left end and the right end of the electric rail 204, the extrusion blocks 402 are in contact with the pushing plate 203 correspondingly, lifting frames 403 are fixedly connected to the four corners of the top of the cutting pool 2, connecting ropes 404 are fixedly connected between the extrusion blocks 402 and the temporary storage pipe 401, and the connecting ropes 404 penetrate through the top ends of the lifting frames 403;

When the liquid level of cutting fluid rises, the upper cutting fluid in the cutting pool 2 passes through the filtering core rod 205 behind the partition plate 201 to filter and overflow, the filtering separation of the cutting fluid is realized, the subsequent cutting fluid enters the temporary storage pipe 401 from the guide pipe 4, when the pushing plate 203 moves to the terminal end position of the electric rail 204, the pushing plate 203 applies pressure to the extrusion block 402, thereby tightening the connecting cable 404, the temporary storage pipe 401 is pulled to be overturned upwards by the connecting cable 404, the temporary storage pipe 401 with the originally lower height is higher than the cutting pool 2, the cutting fluid in the temporary storage pipe 401 reversely washes the filtering core rod 205, the blocking condition of the filtering core rod 205 is effectively cleared, and the filtering core rod 205 is effectively prevented from being damaged due to blocking clearing.

Fig. 4 and 6 show that the front end of the cutting pool 2 is fixedly connected with a recovery pipe 405, a connecting pipe 406 is fixedly connected between two temporary storage pipes 401 and the recovery pipe 405, so that cutting fluid in the two temporary storage pipes 401 is intensively recovered by the recovery pipe 405, the recovery efficiency of the cutting fluid is effectively improved, the height of the recovery pipe 405 is higher than that of the temporary storage pipe 401, the height of the recovery pipe 405 is lower than that of an upper opening of the cutting pool 2, the connecting pipe 406 is made of a rubber corrugated pipe, the temporary storage pipe 401 stores a proper amount of cutting fluid firstly, then the cutting fluid overflows into the recovery pipe 405, and the temporary storage pipe 401 stores the cutting fluid which is sufficiently washed;

Because the height of the recovery pipe 405 is between the cutting pool 2 and the temporary storage pipe 401, the temporary storage pipe 401 stores a proper amount of cutting fluid, then the cutting fluid overflows into the recovery pipe 405, the cutting fluid which is sufficiently flushed exists in the temporary storage pipe 401, and the recovery pipe 405 receives the cutting fluid in the temporary storage pipe 401, so that the cutting fluid is conveniently recovered in a concentrated mode, and the recovery efficiency of the cutting fluid is effectively improved.

Second embodiment:

In the present embodiment, the pipe end cap 301 and the conveying screw shaft 303 are mainly newly added as compared with the first embodiment, and the specific newly added structure is as follows, and the other structures are the same as those in the first embodiment.

As shown in fig. 7, one end of the sedimentation concentration tube 3 is sleeved with a tube end cover 301, the bottom of the tube end cover 301 is provided with a discharge outlet 302, a plugging plug is inserted into the discharge outlet 302, the middle part of the tube end cover 301 is rotatably connected with a conveying screw shaft 303, the conveying screw shaft 303 is sleeved with the sedimentation concentration tube 3, and metal scraps in the sedimentation concentration tube 3, which are sedimented, are driven by the conveying screw shaft 303 and discharged and collected from the discharge outlet 302, so that the recovery efficiency of the metal scraps is effectively improved;

When the metal chip sediment in the sediment concentration pipe 3 reaches the cleaning amount, the conveying screw shaft 303 rotates to drive the metal chip sediment and part of cutting fluid to be discharged from the discharge outlet 302, so that the numerical control machine is not required to be stopped, and the working efficiency of the numerical control machine is effectively improved.

Fig. 7-8 show that one end of the conveying screw shaft 303 far away from the pipe end cover 301 is rotationally connected with a piston 304, the piston 304 is in close contact with the inner wall of the sedimentation concentration pipe 3, when the sedimentation concentration pipe 3 is cleaned, the piston 304 is pulled out to realize the removal of metal scraps in the sedimentation concentration pipe 3, the cleaning effect of the metal scraps is effectively improved, the outer part of the sedimentation concentration pipe 3 is fixedly connected with a pushing cylinder 305, the output end of the pushing cylinder 305 is fixedly connected with the pipe end cover 301, the pushing cylinder 305 drives the pipe end cover 301, and the piston 304 is conveniently driven to move by the conveying screw shaft 303;

When the numerical control machine tool is shut down and cleaned, the discharge port 302 is opened firstly, the residual cutting fluid in the sedimentation concentration tube 3 is discharged, and then the pushing cylinder 305 pushes the tube end cover 301 to leave the sedimentation concentration tube 3, so that the piston 304 is pulled out through the conveying screw shaft 303, and metal scraps in the sedimentation concentration tube 3 are taken out through the piston 304, thereby effectively improving the cleaning efficiency of the sedimentation concentration tube 3.

Fig. 9-10 show that a plug end 306 is inserted into one end of the sedimentation concentration tube 3 far away from the tube end cover 301, the plug end 306 is inserted into the piston 304, the end of the sedimentation concentration tube 3 far away from the tube end cover 301 is closed by the plug end 306, meanwhile, the piston 304 is inserted into the plug end, so that the rotation of the piston 304 is effectively avoided, the use of the conveying screw shaft 303 is effectively influenced, a slot is formed in the middle of the specific piston 304, an insert block is fixedly arranged in the middle of the plug end 306, then the insert block is inserted into the slot, a through hole 307 is formed in the bottom of the plug end 306, the through hole 307 corresponds to the bottom surface of the sedimentation concentration tube 3 in parallel, the through hole 307 realizes the balance of the internal and external air pressure of the sedimentation concentration tube 3, and meanwhile, metal chips accidentally falling into the sedimentation concentration tube 3 are extruded from the through hole 307 when the piston 304 is in a reset motion, so that the cleaning effect of the sedimentation concentration tube 3 is effectively improved;

the other end of the sedimentation concentration tube 3 is closed by utilizing the plug end 306, and meanwhile, the piston 304 is inserted, so that the rotation of the piston 304 is effectively avoided, the use of the conveying screw shaft 303 is effectively influenced, when the piston 304 moves, the air pressure difference at the two ends of the piston 304 is balanced by the through hole 307, and meanwhile, after the sedimentation concentration tube 3 is cleaned, when the piston 304 moves in a resetting mode, metal scraps in the sedimentation concentration tube 3 are pushed out of the through hole 307, and the cleaning effect of the sedimentation concentration tube 3 is effectively improved.

The present application is not limited to the above-described embodiments, which are adopted in connection with the actual demands, and various changes made by the person skilled in the art without departing from the spirit of the present application are still within the scope of the present application.

Claims

1. The utility model provides a digit control machine tool with cutting fluid processing function which characterized in that: the novel multifunctional cutting machine comprises a machine tool body (1), wherein a cutting pool (2) is movably connected to the middle of the machine tool body (1), partition plates (201) are fixedly connected to the inner parts of the left end and the right end of the cutting pool (2), a placement plate (202) is fixedly connected between the tops of the partition plates (201), a pushing plate (203) is slidably connected to the bottom of the placement plate (202), the bottom of the pushing plate (203) is in close contact with the cutting pool (2), electric rails (204) are fixedly connected to the front end and the rear end of the cutting pool (2), the two ends of the pushing plate (203) are fixedly connected with the moving ends of the two electric rails (204) respectively, and sedimentation concentration pipes (3) are fixedly connected to the bottoms of the left end and the right end of the cutting pool (2);

the utility model discloses a cutting device, including cutting pond (2), division board (201), push plate (203), connecting rope (404) and connecting rope (404), filtering core rod (205) is inserted in one side that division board (201) kept away from place board (202), a plurality of honeycomb ducts (4) that are connected with equidistantly in both ends top fixedly connected with about cutting pond (2), one end that cutting pond (2) was kept away from to honeycomb duct (4) is fixedly connected with temporary storage tube (401), both ends all sliding connection have extrusion piece (402) about electronic rail (204), and extrusion piece (402) contact with push plate (203) corresponds, all fixedly connected with hoisting frame (403) in top four corners of cutting pond (2), fixedly connected with connecting rope (404) between extrusion piece (402) and temporary storage tube (401), and connecting rope (404) run through the top of hoisting frame (403);

The utility model discloses a cutting pool, including cutting pool (2) and honeycomb duct, the height of keeping in pipe (401) is less than the top mouth height of cutting pool (2), honeycomb duct (4) are made by rubber bellows, the outside fixedly connected with of front end of cutting pool (2) retrieves pipe (405), two equal fixedly connected with connecting pipe (406) between keeping in pipe (401) and the recovery pipe (405), the height of recovery pipe (405) is higher than the height of keeping in pipe (401), and the height of recovery pipe (405) is less than the top mouth height of cutting pool (2), connecting pipe (406) are made by rubber bellows.

2. The numerical control machine tool with a cutting fluid processing function according to claim 1, wherein: the height of the front end and the rear end of the cutting pool (2) is larger than that of the left end and the right end, and a magnetic plate (206) is fixedly inlaid in the middle of the bottom end of the cutting pool (2).

3. The numerical control machine tool with a cutting fluid processing function according to claim 1, wherein: one end of the sedimentation concentration tube (3) is sleeved with a tube end cover (301), the bottom of the tube end cover (301) is provided with a discharge outlet (302), a sealing plug is inserted in the discharge outlet (302), the middle part of the tube end cover (301) is rotatably connected with a conveying screw shaft (303), and the conveying screw shaft (303) is sleeved with the sedimentation concentration tube (3).

4. A numerical control machine tool having a cutting fluid processing function according to claim 3, characterized in that: one end of the conveying screw shaft (303) far away from the pipe end cover (301) is rotatably connected with a piston (304), and the piston (304) is in close contact with the inner wall of the sedimentation concentration pipe (3).

5. A numerical control machine tool having a cutting fluid processing function according to claim 3, characterized in that: the outside fixedly connected with propelling movement cylinder (305) of sediment center tube (3), the output of propelling movement cylinder (305) is connected with pipe end cover (301) fixed.

6. The numerical control machine tool with a cutting fluid processing function according to claim 4, wherein: and a plug end head (306) is inserted into one end, far away from the pipe end cover (301), of the sedimentation concentration pipe (3), and the plug end head (306) is inserted into the piston (304).

7. The numerical control machine tool with a cutting fluid processing function according to claim 6, wherein: the bottom of the plug end (306) is provided with a through hole (307), and the through hole (307) corresponds to the bottom surface of the sedimentation concentration tube (3) in parallel.