CN113730978A - Machine tool cutting mixed liquid filtering equipment - Google Patents

Abstract

The invention provides a machine tool cutting mixed liquid filtering device which comprises a rack, a sieve plate, a partition plate, a first elastic component, a spring component and an impact component, wherein a cutting liquid outlet and a scrap outlet are formed in the partition plate, one end of the sieve plate is hinged to one side of the rack, the other end of the sieve plate is fixedly connected with the other side of the rack through the first elastic component, the sieve plate is located above the partition plate, the other end of the sieve plate is located right above the scrap outlet, the spring component is used for driving a spring shaft to rotate through spring elasticity, and the impact component is used for intermittently impacting the sieve plate through rotation of the spring shaft. According to the invention, the sieve plate vibrates by utilizing the spring assembly and the impact assembly to separate the cutting fluid, the lubricating oil and the metal debris, so that the separation efficiency of the mixed liquid can be improved, a vibration motor is not required to be installed, and the filtering cost is reduced.

Description

Machine tool cutting mixed liquid filtering equipment

Technical Field

The invention relates to the technical field of numerical control machines, in particular to a machine tool cutting mixed liquid filtering device.

Background

In the process of machining a part by using a numerically controlled machine tool, a mixed solution of cutting fluid, lubricating oil and metal chips is generated. After the mixed liquid is filtered, the cutting fluid can be recycled again.

One of the conventional methods for filtering mixed liquid is to vibrate a sieve plate or a filter screen at a certain frequency by a vibration motor, so as to better separate cutting fluid, lubricating oil and metal debris. However, this method of filtering mixed liquid requires a vibration motor, which increases the filtering cost, and the structure thereof is still to be improved.

Disclosure of Invention

Based on this, in order to solve the problem that the existing mixed liquid filtering method needs to install a vibration motor and increases the filtering cost, the invention provides a machine tool cutting mixed liquid filtering device, which has the following specific technical scheme:

a machine tool cutting mixed liquid filtering device comprises a rack, a sieve plate, a partition plate and a first elastic component, wherein a cutting liquid outlet and a fragment outlet are formed in the partition plate, one end of the sieve plate is hinged to one side of the rack, the other end of the sieve plate is fixedly connected with the other side of the rack through the first elastic component, the sieve plate is located above the partition plate, and the other end of the sieve plate is located right above the fragment outlet; mixed liquid filtration equipment of lathe cutting still includes clockwork spring subassembly and striking subassembly, the clockwork spring subassembly includes clockwork spring and spring arbor, the clockwork spring subassembly is used for utilizing spring force drive spring arbor to rotate, the striking subassembly is used for utilizing the rotation intermittent type ground striking of spring arbor the sieve.

The mixed liquid of the cutting fluid, the lubricating oil and the metal chips after processing falls onto the sieve plate. The spring assembly drives the spring shaft to rotate through the elastic force generated when the spring is wound and gradually loosened, the spring shaft is in transmission connection with the impact assembly and impacts the sieve plate through driving the impact assembly to vibrate, and then cutting fluid, lubricating oil and metal debris are separated.

That is to say, the machine tool cutting mixed liquid filtering equipment utilizes clockwork spring subassembly and striking subassembly to make the sieve produce vibrations in order to separate cutting fluid, lubricating oil and metal debris, can improve the separation efficiency of mixed liquid, and it need not to install vibrating motor, has reduced the filtration cost.

Further, the machine tool cutting mixed liquor filtering device further comprises a driving assembly, and the driving assembly is used for driving the spring shaft to rotate in a clearance mode and enabling the spring to be wound on the spring shaft.

Further, the clockwork spring assembly further comprises a barrel, an outer hook of the clockwork spring is clamped on the inner side wall of the barrel, and an inner hook of the clockwork spring is sleeved on the clockwork spring shaft.

Furthermore, striking subassembly includes ram, disk cam, plectrum and second elastomeric element, the one end of second elastomeric element with baffle fixed connection, the other end of second elastomeric element with ram fixed connection, the ram is located the baffle with between the sieve, the one end of plectrum with second elastomeric element fixed connection, the disk cam with the one end transmission of spring axle is connected and is located directly over the other end of plectrum.

Further, drive assembly includes drive arrangement, gear and rack, the gear with the other end transmission of spring axle is connected, rack slidable mounting in the frame and with gear engagement, drive arrangement install in the frame and be used for intermittently driving the rack is toward being close to the gear direction removes in order to drive the gear rotates.

Further, digit control machine tool includes workstation, cutter, X axle removes subassembly, Y axle and removes subassembly and Z axle and removes the subassembly, X axle removes the subassembly and is used for the drive workstation is along X axle direction reciprocating motion, Y axle removes the subassembly and is used for the drive X axle removes the subassembly along Y axle direction reciprocating motion, Z axle removes the subassembly and is used for driving cutter along Z axle direction reciprocating motion.

Further, the drive means is the Z-axis moving assembly, the rack is parallel to a stroke direction of the Z-axis moving assembly and the rack is at least partially located in a stroke range of the Z-axis moving assembly when the clock spring is in a fully relaxed state.

Further, the driving device is a telescopic cylinder.

Further, the first elastic member and the second elastic member are both coil springs.

Drawings

The invention will be further understood from the following description in conjunction with the accompanying drawings. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the embodiments. Like reference numerals designate corresponding parts throughout the different views.

FIG. 1 is a schematic diagram of the overall structure of a mixed liquid filtering apparatus for machine tool cutting according to an embodiment of the present invention;

FIG. 2 is a top view of a mixed liquor filtration apparatus for machine cutting in accordance with one embodiment of the present invention;

FIG. 3 is a schematic diagram of the structural relationship between the spring and barrel of a machine tool cutting mixed liquor filtration apparatus in accordance with one embodiment of the present invention;

FIG. 4 is a schematic diagram of the structural relationship between the spring, gear and rack of a machine tool cutting mixed liquor filtering apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of the first and second transmission assemblies of a machine tool cutting mixed liquor filtering apparatus according to an embodiment of the present invention.

Description of reference numerals:

1. a frame; 2. a sieve plate; 3. a partition plate; 4. a first elastic member; 5. a clockwork spring assembly; 6. an impact assembly; 7. a cutting fluid outlet; 8. a debris outlet; 9. a drive assembly; 10. a work table; 11. a cutter; 12. an X-axis moving assembly; 13. a Y-axis moving assembly; 14. a Z-axis moving assembly; 15. a circular tube; 16. a first piston; 17. a second piston; 18. a push rod; 50. a barrel; 51. a clockwork spring; 52. a spring shaft; 60. a ram; 61. a disc cam; 62. a toggle sheet; 63. a second elastic member; 90. a gear; 91. a rack.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to embodiments thereof. It should be understood that the detailed description and specific examples, while indicating the scope of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The terms "first" and "second" used herein do not denote any particular order or quantity, but rather are used to distinguish one element from another.

As shown in fig. 1 and 2, a machine tool cutting mixed liquor filtering apparatus according to an embodiment of the present invention includes a frame 1, a sieve plate 2, a partition plate 3, a first elastic member 4, a spring assembly 5, and an impact assembly 6, a cutting fluid outlet 7 and a scrap outlet 8 are arranged on the partition plate 3, one end of the sieve plate 2 is hinged with one side of the frame 1, the other end of the sieve plate 2 is fixedly connected with the other side of the frame 1 through the first elastic component 4, the sieve plate 2 is positioned above the clapboard 3, the other end of the sieve plate 2 is positioned right above the scrap outlet 8, the spring assembly 5 comprises a spring 51 and a spring shaft 5, the spring assembly 5 is used for driving the spring shaft 52 to rotate by the elastic force of the spring 51, the striking assembly 6 is adapted to strike the screen plate 2 intermittently by rotation of the barrel shaft 52.

The first elastic component 4 is vertically or obliquely arranged, and the first elastic component 4 can be a spiral spring, an annular spring or a disc spring. The sieve 2 is located the below of digit control machine tool processing work piece, cutting fluid export 7 is located sieve 2 under, clockwork spring subassembly 5 and striking subassembly 6 all can be installed on frame 1 or on baffle 3. Preferably, spring assembly 5 and impact assembly 6 are both mounted on partition 3 and both located between partition 3 and screen plate 2.

The screening deck 2 is made of stainless steel sheet and has a certain elasticity so that the striking assembly 3 can better vibrate the screening deck 2 when striking the screening deck 2.

With regard to the spring 51 in the spring assembly 5, the spring shaft 52 may be driven to rotate by a manual force or a mechanical power to wind the spring 51 around the spring shaft 52. The wound spring 51 stores elastic potential energy and releases the elastic potential energy in the process of gradual release, and the spring shaft 52 is driven to rotate.

The mixed liquid of the cutting fluid, the lubricating oil and the metal chips after processing falls onto the sieve plate 2 and flows into the cutting fluid outlet 7 through the through holes on the sieve plate 2. And the cutting fluid outlet 7 is communicated with a cutting fluid storage tank so as to store the filtered cutting fluid and the lubricating oil. The spring assembly 5 drives the spring shaft 52 to rotate through the elastic force generated when the spring 51 is wound and loosened gradually, and the spring shaft 52 is in transmission connection with the impact assembly 6 and drives the impact assembly 6 to intermittently act to impact the screen plate 2 so as to enable the screen plate 2 to vibrate, so that the cutting fluid, the lubricating oil and the metal debris are separated.

That is, the machine tool cutting mixed liquid filtering device utilizes the spring assembly 5 and the impact assembly 6 to enable the sieve plate 2 to generate vibration to separate cutting liquid, lubricating oil and metal debris, so that the separation efficiency of the mixed liquid can be improved, a vibration motor does not need to be installed, and the filtering cost is reduced.

In one embodiment, the machine tool cutting mixed liquor filtering device further comprises a driving assembly 9, wherein the driving assembly 9 is used for intermittently driving the spring shaft 52 to rotate and winding the spring 51 on the spring shaft 52.

In particular, the drive assembly 9 is in driving connection with the spring shaft 52. After the driving assembly 9 drives the spring shaft 52 to rotate and the spring 51 is wound on the spring shaft 52, the driving assembly 9 is disconnected from the transmission connection with the spring shaft 52. At this point, the spring 51 of the spring assembly 5 will gradually unwind and drive the rotation of the spring shaft 52, which in turn will impact the screen panel 2 by driving the striking assembly 6 in an intermittent motion to vibrate the screen panel 2.

By means of the driving assembly 9, it is possible to better drive the spring shaft 52 to rotate and wind the spring 51 on the spring shaft 52, so as to strike the screen plate 2 at a certain frequency and vibrate the screen plate 2 through the spring assembly 5 and the striking assembly 6.

In one embodiment, as shown in fig. 1 and 3, the spring assembly 5 further includes a barrel 50, an outer hook of the spring 51 is clamped on an inner side wall of the barrel 50, and an inner hook of the spring 51 is sleeved on the spring shaft 52 and is fixedly connected with the spring shaft 52. The spring shaft 52 penetrates through the barrel 50, one end of the spring shaft 52 is in transmission connection with the striking assembly 6, and the other end of the spring shaft 52 is in transmission connection with the driving assembly 9. The spring assembly 5 comprises a barrel 50, a spring 51 and a spring shaft 52, has the characteristic of simple structure, can simplify the overall structure of the machine tool cutting mixed liquid filtering equipment, and is convenient to install and maintain.

One end of the spring shaft 52 can be in driving connection with the striking assembly 6 via a gear transmission. The gear transmission is a first gear accelerator. By means of the first gear accelerator, the frequency with which the striking assembly 6 strikes the screen plate 2 can be increased. Since the transmission ratio of the first gear transmission can be set according to actual needs, further description is omitted here.

In one embodiment, the spring assembly 5 includes a barrel 50, a spring 51 and a spring shaft 52, an outer hook of the spring 51 is clamped on an inner side wall of the barrel 50, an inner hook of the spring 51 is sleeved on the spring shaft 52 and fixedly connected with the spring shaft 52, one end of the spring shaft 52 is in transmission connection with the impact assembly 6 through a first gear accelerator, and the other end of the spring shaft 52 is fixedly connected with the inner hook of the spring 51. The driving assembly 9 is in transmission connection with the other end of the spring shaft 52 through a second gear accelerator, and drives the spring shaft 52 to rotate so as to wind the spring 51 on the spring shaft 52. In this way, the spring 51 can be wound up on the spring shaft 52 more quickly by the second gear accelerator. Since the transmission ratio of the second gear transmission can be set according to actual needs, further description is omitted here.

In one embodiment, as shown in fig. 1, the striking assembly 6 includes a ram 60, a disc cam 61, a dial 62, and a second elastic member 63, one end of the second elastic member 63 is fixedly connected to the partition plate 3, the other end of the second elastic member 63 is fixedly connected to the ram 60, the ram 60 is located between the partition plate 3 and the screen plate 2, one end of the dial 62 is fixedly connected to the second elastic member 63, and the disc cam 61 is in transmission connection with one end of the spring shaft 52 and is located right above the other end of the dial 62.

The second elastic member 63 is vertically disposed and may be a coil spring, a ring spring, or a disc spring. When the disc cam 61 is not in contact with the paddle 62, the second resilient member 63 is in a contracted state and the ram 60 is in contact with the lower surface of the screen panel 2. When the cam disc 61 is driven to rotate by the spring shaft 52 directly or through the second gear accelerator, the cam disc 61 will dial the striking plate 62 at a certain frequency and make the second elastic member 63 in a continuous compression release state, so as to drive the hammer 60 to strike the screen plate 2 intermittently.

Specifically, when the disc cam 61 is rotated to a certain position and the protruding portion of the disc cam 61 comes into contact with the paddle 62, the paddle 62 is pushed toward the partition plate 3 to further compress the second elastic member. After the disc cam 61 continues to rotate and the protruding portion of the disc cam 61 is separated from the paddle 62, the second elastic member 62 is released and the hammer 60 will strike the screen plate 2 under the elastic force of the second elastic member 62.

When the ram 60 is in contact with the lower surface of the screening deck 2, the ram 60 will exert an upward force on the screening deck 2 under the spring force of the second resilient member 62. At this time, the first elastic member 4 may be in an extended, freely extended or contracted state. When the ram 60 moves downwards, the first resilient member 4 will elongate under the weight of the screening deck 2.

The impact assembly 6 comprises a ram 60, a disc cam 61, a poking sheet 62 and a second elastic component 63, has the characteristic of simple structure, can simplify the overall structure of the machine tool cutting mixed liquid filtering equipment, and is convenient to mount and maintain.

In one embodiment, as shown in fig. 4, the driving assembly 9 includes a driving device (not shown), a gear 90 and a rack 91, one end of the spring shaft 52 is in transmission connection with the striking assembly 6, the gear 90 is in transmission connection with the other end of the spring shaft 52, the rack 91 is slidably mounted on the frame 1 and engaged with the gear 90, and the driving device is mounted on the frame 1 and is configured to intermittently drive the rack 91 to move toward the gear 90 to drive the gear 90 to rotate. In this embodiment, the barrel 52 passes through the barrel 50 and the other end of the barrel 52 is drivingly connected to the gear 90 through a third gear accelerator to more quickly wind the spring 51 onto the barrel 52. Of course, the other end of the spring shaft 52 may be directly and fixedly connected to the axial center of the gear 90.

Specifically, the numerical control machine tool comprises a workbench 10, a cutter 11, an X-axis moving assembly 12, a Y-axis moving assembly 13 and a Z-axis moving assembly 14, wherein the X-axis moving assembly 12 is used for driving the workbench 10 to reciprocate along the X-axis direction, the Y-axis moving assembly 13 is used for driving the X-axis moving assembly 12 to reciprocate along the Y-axis direction, and the Z-axis moving assembly 14 is used for driving the cutter 11 to reciprocate along the Z-axis direction. The driving device can be the Z-axis moving assembly 14 or a telescopic air cylinder.

When the driving device is the Z-axis moving assembly 14, the rack 91 is parallel to the stroke direction of the Z-axis moving assembly 14 and when the clockwork spring 51 is in a fully relaxed state, the rack 91 is at least partially located in the stroke range of the Z-axis moving assembly 14. That is, when the spring 51 is in a completely relaxed state, the rack 91 is pushed by driving the Z-axis moving member 14 to move toward the beginning or end of the stroke, so that the gear 90 and the spring shaft 52 are rotated, and the spring 51 is wound around the spring shaft 52.

The Z-axis moving assembly 14 is used as a driving device to wind the spring 51 on the spring shaft 52, so that the function and the use of the Z-axis moving assembly 14 are increased, a separate driving device is not required to be additionally installed, the overall structure of the machine tool cutting mixed liquid filtering equipment can be simplified, and the overall cost is reduced.

In one embodiment, the machine tool cutting mixed liquor filtering device comprises three sets of driving assemblies 9, three sets of spring assemblies 5 and three sets of impact assemblies 6, and each set of driving assemblies 9, spring assemblies 5 and impact assemblies 6 are matched for use. The driving devices of the three sets of driving assemblies 9 are the X-axis moving assembly 12, the Y-axis moving assembly 13 and the Z-axis moving assembly 14, respectively. Namely, the driving device in the first group of driving units 9 is the Z-axis moving unit 14, the driving device in the second group of driving units 9 is the X-axis moving unit 12, and the driving device in the third group of driving units 9 is the Y-axis moving unit 13.

For first set of drive assembly 9, spring assembly 5 and strike assembly 6, rack 91 of first set of drive assembly 9 is parallel to the direction of travel of Z-axis movement assembly 14 and rack 91 of first set of drive assembly 9 is at least partially within the range of travel of Z-axis movement assembly 14 when spring 51 of first set of spring assembly 5 is in a fully relaxed state. That is, when spring 51 of first spring assembly 5 is in a fully relaxed state, gear 90 of first spring assembly 9 and spring shaft 52 of first spring assembly 5 can be rotated by driving Z-axis moving assembly 14 to move toward the beginning or end of travel to push rack 91 of first spring assembly 9, thereby winding spring 51 of first spring assembly 5 around spring shaft 52 of first spring assembly 5.

For second set of drive assembly 9, spring assembly 5 and strike assembly 6, the first drive assembly is mounted at the beginning or end of travel of X-axis moving assembly 12 when spring 51 of second set of spring assembly 5 is in a fully relaxed state. The first transmission assembly is located at least partially within the range of travel of the X-axis motion assembly 12. That is, when the spring 51 of the second spring assembly 5 is in a fully relaxed state, the first transmission assembly is driven to move by driving the X-axis moving assembly 12 to the beginning or end of the stroke, and the rack 91 of the second spring assembly 9 is driven, so that the gear 90 of the second spring assembly 9 and the spring shaft 52 of the second spring assembly 5 are rotated, and the spring 51 of the second spring assembly 5 is wound around the spring shaft 52 of the second spring assembly 5.

For third set of drive assembly 9, spring assembly 5 and strike assembly 6, the start or end of travel of said Y-axis moving assembly 13 is fitted with a second transmission assembly when spring 51 of third set of spring assembly 5 is in a fully relaxed state. The second transmission assembly is located at least partially within the range of travel of the Y-axis motion assembly 13. That is, when the spring 51 of the third spring assembly 5 is in the fully relaxed state, the Y-axis moving assembly 13 is driven to move to the beginning or end of the stroke to drive the second transmission assembly to move and further to drive the rack 91 of the third spring assembly 9, so that the gear 90 of the third spring assembly 9 and the spring shaft 52 of the third spring assembly 5 can be rotated and the spring 51 of the third spring assembly 5 can be wound around the spring shaft 52 of the third spring assembly 5.

As shown in fig. 5, each of the first transmission assembly and the second transmission assembly includes a circular tube 15, a first piston 16, a second piston 17, and a push rod 18, the first piston 16 and the second piston 17 are connected to the inner wall of the circular tube 15 in a sliding and sealing manner, lubricating oil or gas is filled between the inner cavities of the first piston 16, the second piston 17, and the circular tube 15, one end of the push rod 18 is fixedly connected to the first piston 16, and the second piston 17 is fixedly connected to one end of the rack 91. The first piston 16, the second piston 17 and the circular tube 15 can realize synchronous transmission of the push rod 18 and the rack 91.

Specifically, one end of the push rod 18 of the first transmission assembly is fixedly connected with the first piston 16 of the first transmission assembly, and the other end of the push rod 18 of the first transmission assembly is at least partially located in the stroke range of the X-axis moving assembly 12. The other end of the push rod 18 of the first transmission assembly is at least partially located at the beginning or end of the stroke of the X-axis moving assembly 12. The second piston 17 of the first transmission assembly is fixedly connected with one end of the rack 91 of the second group of driving assemblies 9.

One end of the push rod 18 of the second transmission assembly is fixedly connected with the first piston 16 of the second transmission assembly, and the other end of the push rod 18 of the second transmission assembly is at least partially positioned in the stroke range of the Y-axis moving assembly 13. The other end of the push rod 18 of the second transmission assembly is at least partially located at the starting end or the end of the stroke of the Y-axis moving assembly 13. The second piston 17 of the second transmission assembly is fixedly connected with one end of the rack 91 of the second group of driving assemblies 9.

The shape and length of the circular tube 15 can be set according to the relative position between the push rod 18 and the rack 91, and will not be described in detail herein.

Through setting up three drive assembly 9, clockwork spring subassembly 5 and striking subassembly 6, and by X axle removes drive assembly 12, Y axle and removes drive arrangement among subassembly 13 and the Z axle of subassembly 14 conduct three sets of drive assembly 9 respectively, not only can increase the function usage of X axle removes subassembly 12, Y axle and removes subassembly 13 and Z axle and removes subassembly 14, can also be on simplifying on the basis of lathe cutting mixed liquid filtration equipment's overall structure, reduce filtration cost, reinforcing sieve 2's vibration degree carries out the separation operation to cutting fluid, lubricating oil and metal debris better.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (9)

1. The utility model provides a mixed liquid filtration equipment of lathe cutting, includes frame, sieve, baffle and first elastomeric element, be equipped with cutting fluid export and piece export on the baffle, the one end of sieve with one side of frame is articulated, the other end of sieve passes through first elastomeric element with the opposite side fixed connection of frame, the sieve is located the top of baffle just the other end of sieve is located directly over the piece export, its characterized in that, mixed liquid filtration equipment of lathe cutting still includes clockwork spring subassembly and striking subassembly, the clockwork spring subassembly includes clockwork spring and clockwork spring shaft, the clockwork spring subassembly is used for utilizing clockwork spring elasticity drive clockwork spring shaft to rotate, the striking subassembly is used for utilizing the rotation intermittent type nature striking of clockwork spring shaft the sieve.

2. A machine tool cutting mix filtration apparatus as claimed in claim 1 further comprising a drive assembly for interstitially driving said spring shaft in rotation and winding said spring onto said spring shaft.

3. The mixed liquor filtering apparatus for machine cutting according to claim 2 wherein said spring assembly further comprises a barrel, an outer hook of said spring is engaged with an inner sidewall of said barrel, and an inner hook of said spring is engaged with said spring shaft.

4. The mixed liquor filtering apparatus for machine tool cutting according to claim 3, wherein the striking assembly includes a striker, a disk cam, a dial plate, and a second elastic member, one end of the second elastic member is fixedly connected to the partition plate, the other end of the second elastic member is fixedly connected to the striker, the striker is located between the partition plate and the sieve plate, one end of the dial plate is fixedly connected to the second elastic member, and the disk cam is in transmission connection with one end of the spring shaft and is located directly above the other end of the dial plate.

5. The mixed liquor filtering apparatus for machine cutting as claimed in claim 4, wherein said driving assembly includes a driving device, a gear and a rack, said gear is in transmission connection with the other end of said spring shaft, said rack is slidably mounted on said frame and engaged with said gear, said driving device is mounted on said frame and used for intermittently driving said rack to move toward said gear to drive said gear to rotate.

6. The mixed liquid filtering apparatus for machine cutting according to claim 5, wherein said numerically controlled machine tool comprises a table, a tool, an X-axis moving assembly for driving said table to reciprocate along an X-axis direction, a Y-axis moving assembly for driving said X-axis moving assembly to reciprocate along a Y-axis direction, and a Z-axis moving assembly for driving said tool to reciprocate along a Z-axis direction.

7. The machine-cut mixed liquor filter apparatus of claim 6 wherein said drive means is said Z-axis moving assembly, said rack being parallel to the direction of travel of said Z-axis moving assembly and being at least partially within the range of travel of said Z-axis moving assembly when said spring is in a fully relaxed state.

8. The mixed liquor filtering apparatus for machine cutting as claimed in claim 6, wherein said driving means is a telescopic cylinder.

9. The machine tool cutting mix filtration apparatus of claim 4 wherein said first resilient member and said second resilient member are each a coil spring.

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