CN218613003U - Part positioning tool for machining - Google Patents

Abstract

The utility model provides a part location frock for machining relates to part location technical field, the on-line screen storage device comprises a base, the equal fixed mounting in base upper surface both sides has the backup pad, two the spout has all been seted up, two to the relative side surface of backup pad all slide in the spout and be provided with the slider. The utility model discloses in after the lathe cutter is processed the part, the staff is through launching drive assembly, make the slider rise along the spout, the staff rotates the pivot afterwards, make it use the pivot to rotate as the benchmark to bear the seat, thereby make the part by the face of cutter processing downwards, the staff launches the promotion subassembly afterwards, make it promote the clamping component, thereby make clamping component and part reciprocating vibration, thereby make the piece in the part drop under the effect of gravity and vibration, thereby realize the clearance to metal clastic in the part, staff's the amount of labour has significantly reduced.

Description

Part positioning tool for machining

Technical Field

The utility model relates to a part location technical field particularly, relates to a part location frock for machining.

Background

With the rapid development of economy in China, the machining industry is also rapidly developed, and in the machining process, in order to ensure the product quality and the production rate, a process device for fixing the machine tool, a cutter and a workpiece to keep correct relative positions is often needed to ensure the machining accuracy, improve the labor efficiency, enlarge the operation range of the tool, improve the labor condition and reduce the product cost, and a positioning tool is needed. The metal piece that current location frock can't be in to machine part after the cutter is to machine part machining clears up, needs the staff to accomplish at machine part machining after manual take off it and clear up metal piece, greatly increased staff's the amount of labour.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a part location frock for machining can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the technical proposal that:

a part positioning tool for machining comprises a base, wherein supporting plates are fixedly arranged on two sides of the upper surface of the base, sliding grooves are formed in the surfaces of the two opposite sides of the supporting plates, sliding blocks are arranged in the two sliding grooves in a sliding mode, rotating shafts are movably arranged on the opposite sides of the two sliding blocks, and a bearing seat is fixedly arranged between the two rotating shafts;

the upper surface of the bearing seat is provided with moving grooves, two moving blocks are arranged in the two moving grooves in a sliding manner, a double-shaft motor is fixedly arranged at the bottom in the moving grooves, two output shaft ends of the double-shaft motor are respectively and fixedly provided with a threaded rod, one end of each threaded rod, which is far away from each other, is respectively and rotatably connected with two sides of the inner wall of the moving groove, and the two moving blocks are respectively and threadedly arranged on one side of the corresponding threaded rod body;

transverse plates are fixedly arranged on the upper surfaces of the two moving blocks, clamping assemblies for clamping parts are movably arranged on the upper surfaces of the two transverse plates, and pushing assemblies for pushing the clamping assemblies are arranged on one sides of the two transverse plates;

and a driving component for driving the sliding block to move along the sliding groove is arranged at the top in one sliding groove.

Preferably, the driving assembly comprises a first motor, the first motor is fixedly installed at the top in one of the chutes, a lead screw is fixedly installed at an output shaft end of the first motor, the slider thread close to the lead screw is arranged on one side of a lead screw rod body, and the lower end of the lead screw is rotatably installed at the bottom in the corresponding chute.

Preferably, the clamping assembly comprises a clamping jaw cylinder, and clamping plates are fixedly mounted at the output ends of the clamping jaw cylinder.

Preferably, the upper surfaces of the two transverse plates are respectively provided with a connecting groove, connecting blocks are arranged in the two connecting grooves in a sliding manner, and the upper surfaces of the two connecting blocks are respectively fixedly connected with the corresponding clamping jaw cylinders;

two equal fixed mounting in spread groove inner wall both sides has the connecting rod, two the connecting block slides respectively and sets up in the connecting rod body one side that corresponds, two connecting rod body opposite side all overlaps and is equipped with the elastic component that can stretch and reset.

Preferably, the elastic member is a spring.

Preferably, the pushing assembly comprises partition plates which are fixedly arranged on one sides of the corresponding transverse plates respectively, second motors are fixedly arranged on the upper surfaces of the partition plates respectively, and eccentric wheels are sleeved on output shaft bodies of the second motors.

Preferably, the two rotating shafts are respectively rotatably installed on one side, opposite to the two sliding blocks, of the two sliding blocks, a gear is sleeved on the shaft body of one of the rotating shafts, an air cylinder is fixedly installed on one side, close to the gear, of the sliding block through a right-angle frame, a toothed plate is fixedly installed at the output end of the air cylinder, and the toothed plate is meshed with the gear.

Preferably, the middle part of the upper surface of the base is provided with a chip groove.

(1) After the lathe cutter is processed the part, the staff is through launching drive assembly, make the slider rise along the spout, the staff rotates the pivot afterwards, make and bear the seat and use the pivot to rotate as the benchmark, thereby make the part by the face of cutter processing downwards, the staff launches the promotion subassembly afterwards, make it promote the clamping component, thereby make clamping component and part reciprocating vibration, thereby make the piece in the part drop under the effect of gravity and vibration, thereby realize the clearance to metallic debris in the part, do not need the staff to manually take off the part from the frock and clear up metallic debris, staff's the amount of labour has significantly reduced.

(2) The staff makes its output drive the pinion rack and removes through starting the cylinder, and under the mating reaction of pinion rack and gear, the pivot drives bears the weight of the seat and rotates to do not need the staff to rotate bearing the weight of the seat manually, further reduced staff's the amount of labour.

Drawings

Fig. 1 is a schematic view of the overall structure of a part positioning tool for machining according to the present invention;

fig. 2 is a schematic front view of the part positioning tool for machining according to the present invention;

fig. 3 isbase:Sub>A schematic cross-sectional structure diagram ofbase:Sub>A part positioning tool for machining atbase:Sub>A positionbase:Sub>A-base:Sub>A in fig. 2 according to the present invention;

fig. 4 is a schematic view of a cross-sectional structure at B-B in fig. 2 of the part positioning tool for machining according to the present invention.

In the figure: 1. a base; 2. a support plate; 201. a chute; 202. a slider; 203. a rotating shaft; 3. a drive assembly; 301. a first motor; 302. a screw rod; 4. a bearing seat; 401. a moving groove; 402. a moving block; 403. a dual-axis motor; 404. a threaded rod; 405. a transverse plate; 4051. connecting grooves; 4052. connecting blocks; 4053. a connecting rod; 4054. an elastic member; 5. a clamping assembly; 501. a clamping jaw cylinder; 502. a splint; 6. a pushing assembly; 601. a partition plate; 602. a second motor; 603. an eccentric wheel; 7. a gear; 8. a right-angle frame; 801. a cylinder; 802. a toothed plate; 9. a chip breaking groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-4, the embodiment of the utility model provides a part location frock for machining, including base 1, the equal fixed mounting in base 1 upper surface both sides has backup pad 2, and spout 201 has all been seted up on the relative side surface of two backup pads 2, all slides in two spout 201 and is provided with slider 202, and the equal movable mounting in the relative one side of two sliders 202 has pivot 203, and fixed mounting has the seat of holding 4 between two pivot 203. In the initial state, the lower surface of the bearing seat 4 is attached to the upper surface of the base 1.

Bear 4 upper surfaces of seat and seted up shifting chute 401, it is provided with two movable blocks 402 to slide in two shifting chutes 401, bottom fixed mounting has biaxial motor 403 in shifting chute 401, the equal fixed mounting of two output shaft ends of biaxial motor 403 has threaded rod 404, two threaded rods 404 keep away from one end each other and rotate with shifting chute 401 inner wall both sides respectively and be connected, two movable blocks 402 screw thread settings are in corresponding threaded rod 404 pole body one side respectively. The two threaded rods 404 are oppositely threaded.

The upper surfaces of the two moving blocks 402 are fixedly provided with transverse plates 405, the upper surfaces of the two transverse plates 405 are movably provided with clamping assemblies 5 used for clamping parts, and one sides of the two transverse plates 405 are provided with pushing assemblies 6 used for pushing the clamping assemblies 5.

The top of one of the sliding grooves 201 is provided with a driving assembly 3 for driving the sliding block 202 to move along the sliding groove 201.

A worker places a part to be machined on the bearing seat 4, then starts the double-shaft motor 403, the output shaft end of the double-shaft motor 403 drives the two threaded rods 404 to rotate, so that the clamping component 5 moves to the position of the part to be machined, and then the worker starts the clamping component 5 to clamp the part, so that a lathe tool can conveniently machine the part;

after the lathe cutter processed the part, the staff launches drive assembly 3, make slider 202 rise along spout 201, the staff rotates pivot 203 afterwards, make bearing seat 4 use pivot 203 to rotate as the benchmark, thereby make the part by the face of cutter processing downwards, the staff launches push assembly 6 afterwards, make it promote clamping assembly 5, thereby make clamping assembly 5 and part reciprocating vibration, thereby make the piece in the part drop under the effect of gravity and vibration, thereby realize the clearance to metal clastic in the part, do not need the staff to manually take off the part from the frock and clear up metal clastic, the staff's the amount of labour that has significantly reduced.

As shown in fig. 1 and fig. 3, in another embodiment of the present invention, the driving assembly 3 includes a first motor 301, the first motor 301 is fixedly installed at the top of one of the sliding chutes 201, an output shaft of the first motor 301 is fixedly installed with a screw 302, a thread of the slider 202 close to the screw 302 is disposed on one side of a rod body of the screw 302, and a lower end of the screw 302 is rotatably installed at the bottom of the corresponding sliding chute 201.

The worker starts the first motor 301, so that the output shaft end of the first motor drives the screw rod 302 to rotate, and the rotating screw rod 302 drives the sliding block 202 to move along the sliding groove 201 in a threaded precession mode.

As shown in fig. 1, fig. 3 and fig. 4, in another embodiment of the present invention, the clamping assembly 5 includes a clamping jaw cylinder 501, and a clamping plate 502 is fixedly mounted at the output end of the two clamping jaw cylinders 501.

Connecting groove 4051 has all been seted up to two diaphragm 405 upper surfaces, all slides in two connecting grooves 4051 and is provided with connecting block 4052, two connecting block 4052 upper surfaces respectively with the clamping jaw cylinder 501 fixed connection that corresponds.

Two equal fixed mounting in connecting groove 4051 inner wall both sides have connecting rod 4053, and two connecting blocks 4052 slide respectively and set up in connecting rod 4053 pole body one side that corresponds, and two connecting rod 4053 pole body opposite sides all overlap and are equipped with the elastic component 4054 that can stretch and reset.

The resilient member 4054 is a spring.

After the clamping plate 502 moves to the part position, a worker starts the clamping jaw air cylinder 501, so that the output end of the clamping jaw air cylinder drives the clamping plate 502 to move, and the clamping plate 502 clamps the part;

the staff starts push assembly 6, makes it promote the back to gripper cylinder 501, and under the mating action of spring and connecting block 4052 and connecting groove 4051, splint 502 along connecting groove 4051 direction reciprocating vibration for piece in the part drops under the vibration effect.

As shown in fig. 1, fig. 3 and fig. 4, in another embodiment of the present invention, the pushing assembly 6 includes a partition 601, two partitions 601 are respectively and fixedly installed on one side of the corresponding transverse plate 405, two partitions 601 have the second motor 602 respectively and fixedly installed on the upper surfaces thereof, and the shaft body of the output shaft of the two second motors 602 is provided with an eccentric wheel 603.

After the worker starts the second motor 602, the output shaft of the second motor drives the eccentric wheel 603 to rotate, and the rotating eccentric wheel 603 can push the clamping jaw cylinder 501;

in an initial state, the eccentric wheel 603 tightly pushes the clamping jaw cylinder 501, so that one side of the connecting block 4052 is tightly attached to the surface of one side of the inner wall of the connecting groove 4051, and the clamping plate 502 clamps a part, so that the part is not easy to shake when being machined by a cutter.

As shown in fig. 1 and 4, in another embodiment of the present invention, two rotating shafts 203 are respectively installed on one side of two opposite sliding blocks 202, one of the rotating shafts 203 is sleeved with a gear 7, one side of the sliding block 202 close to the gear 7 is fixedly installed with a cylinder 801 through a right-angle frame 8, the output end of the cylinder 801 is fixedly installed with a toothed plate 802, and the toothed plate 802 is meshed with the gear 7.

The staff starts cylinder 801, makes its output drive pinion rack 802 remove, and under pinion rack 802 and gear 7's mating reaction, pivot 203 drives and bears seat 4 and rotate to do not need the staff to rotate bearing seat 4 manually, further reduced staff's the amount of labour.

As shown in fig. 1, in another embodiment of the present invention, a chip breaker 9 is disposed in the middle of the upper surface of the base 1.

Through setting up garrulous chip groove 9, make things convenient for the staff to retrieve the piece.

This machining is with theory of operation of part location frock:

during the use, the staff will wait to process the part and place on bearing seat 4, start biax motor 403 after that, biax motor 403 output shaft end drives two threaded rods 404 and rotates, make clamping jaw cylinder 501 remove to waiting to process the part position, then the staff starts clamping jaw cylinder 501, make its output end drive splint 502 and remove, make splint 502 carry out the centre gripping to the part, make things convenient for the lathe cutter to process the part, after the lathe cutter processed the part, the staff starts first motor 301, make its output shaft end drive lead screw 302 and rotate, pivoted lead screw 302 drives slider 202 through the mode of screw precession and moves along spout 201, then the staff rotates pivot 203, make bearing seat 4 use pivot 203 as the benchmark to rotate, thereby make the part by the face that the cutter was processed face downwards, then the staff starts second motor 602, its output shaft drives eccentric wheel 603 and rotates, pivoted eccentric wheel 603 can push clamping jaw cylinder 501, make the part reciprocating vibration, thereby make the piece in the part drop under the effect of gravity and vibration, thereby realize the clearance to the metal piece in the part, do not need the manual clearance of getting the part from the staff and greatly reduced the frock piece.

Obviously, the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it is obvious for those skilled in the art to make other variations or changes based on the above description, and all embodiments cannot be exhausted here, and all obvious variations or changes are still in the protection scope of the present invention.

Claims (8)

1. The utility model provides a part location frock for machining, includes base (1), its characterized in that: supporting plates (2) are fixedly mounted on two sides of the upper surface of the base (1), sliding grooves (201) are formed in the surfaces of the two opposite sides of the two supporting plates (2), sliding blocks (202) are arranged in the two sliding grooves (201) in a sliding mode, rotating shafts (203) are movably mounted on the opposite sides of the two sliding blocks (202), and a bearing seat (4) is fixedly mounted between the two rotating shafts (203);

the upper surface of the bearing seat (4) is provided with moving grooves (401), two moving blocks (402) are arranged in the two moving grooves (401) in a sliding manner, a double-shaft motor (403) is fixedly arranged at the bottom in the moving grooves (401), threaded rods (404) are fixedly arranged at two output shaft ends of the double-shaft motor (403), one ends, far away from each other, of the two threaded rods (404) are respectively and rotatably connected with two sides of the inner wall of the moving grooves (401), and the two moving blocks (402) are respectively arranged on one side of the rod body of the corresponding threaded rod (404) in a threaded manner;

transverse plates (405) are fixedly mounted on the upper surfaces of the two moving blocks (402), clamping assemblies (5) for clamping parts are movably mounted on the upper surfaces of the two transverse plates (405), and pushing assemblies (6) for pushing the clamping assemblies (5) are mounted on one sides of the two transverse plates (405);

and a driving assembly (3) for driving the sliding block (202) to move along the sliding groove (201) is arranged at the top in one sliding groove (201).

2. The part positioning tool for machining according to claim 1, characterized in that: the driving assembly (3) comprises a first motor (301), the first motor (301) is fixedly installed at the top of one sliding groove (201), a screw rod (302) is fixedly installed at an output shaft end of the first motor (301), the sliding block (202) close to the screw rod (302) is arranged on one side of a rod body of the screw rod (302), and the lower end of the screw rod (302) is rotatably installed at the bottom of the corresponding sliding groove (201).

3. The part positioning tool for machining according to claim 1, characterized in that: the clamping assembly (5) comprises a clamping jaw cylinder (501), and clamping plates (502) are fixedly mounted at the output ends of the clamping jaw cylinder (501).

4. The part positioning tool for machining according to claim 3, characterized in that: connecting grooves (4051) are formed in the upper surfaces of the two transverse plates (405), connecting blocks (4052) are arranged in the two connecting grooves (4051) in a sliding mode, and the upper surfaces of the two connecting blocks (4052) are fixedly connected with corresponding clamping jaw cylinders (501) respectively;

two equal fixed mounting in spread groove (4051) inner wall both sides has connecting rod (4053), two connecting block (4052) slide respectively and set up in connecting rod (4053) the pole body one side that corresponds, two connecting rod (4053) pole body opposite side all is equipped with elastic component (4054) that can stretch and reset.

5. The part positioning tool for machining according to claim 4, characterized in that: the elastic member (4054) is a spring.

6. The part positioning tool for machining according to claim 1, characterized in that: the pushing assembly (6) comprises a partition plate (601), two partition plates (601) are respectively and fixedly installed on one side of corresponding transverse plates (405), two second motors (602) are respectively and fixedly installed on the upper surfaces of the partition plates (601), and two eccentric wheels (603) are respectively sleeved on output shaft bodies of the second motors (602).

7. The part positioning tool for machining according to claim 1, characterized in that: two pivot (203) rotate respectively and install in two slider (202) opposite sides, one of them pivot (203) shaft body cover is equipped with gear (7), is close to gear (7) slider (202) one side has cylinder (801) through right angle frame (8) fixed mounting, cylinder (801) output end fixed mounting has pinion rack (802), pinion rack (802) mesh mutually with gear (7).

8. The part positioning tool for machining according to claim 1, characterized in that: a scrap groove (9) is formed in the middle of the upper surface of the base (1).

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