CN113714835A - Metal machining positioning structure - Google Patents

Abstract

The invention discloses a metal machining positioning structure, which comprises a base, wherein the top of the base is fixedly connected with a mounting plate, the surface of the mounting plate is connected with a sliding plate in a sliding manner, a first connecting plate is fixedly connected above the sliding plate, the top of the first connecting plate is fixedly connected with a fixed frame, the inner wall of the top of the fixed frame is rotatably connected with a rotating ring which drives a lifting rod and a transmission rod to horizontally lift, the bottom of the transmission rod is fixedly connected with a first stressed plate which drives a first embedded rod to lift, the metal machining positioning structure has high practicability, when in use, workpieces with different shapes can be clamped through an elastic movable rod, and when in machining, a clamping point can be adjusted through an adjusting mechanism, so that the flexibility of the metal machining positioning structure is further improved, and a control mechanism is arranged at the top of a support frame, the position of the processing equipment can be adjusted in real time, so that the usability of the equipment is further improved.

Description

Metal machining positioning structure

Technical Field

The invention relates to the field of metal machining, in particular to a metal machining positioning structure.

Background

Metal working refers to the production activities of human beings working on materials with metallic properties, which are composed mainly of metallic elements or metallic elements. The technology is a technology for processing metal materials into objects, parts and components, and comprises large parts of bridges, ships and the like, and even fine components of engines, jewels and wristwatches. It is widely used in different fields of science, industry, artworks, handicraft and the like.

However, when the existing metal processing equipment is used, a plurality of defects exist, such as the position of the clamp cannot be adjusted according to actual conditions, and the clamp is not easy to clamp when facing metals with various shapes, so that a metal machining positioning structure is provided.

Disclosure of Invention

The invention aims to provide a metal machining positioning structure to solve the problems that the existing metal machining equipment in the background art cannot adjust the position of a clamp according to actual conditions and is difficult to clamp when facing metals in various shapes when in use.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a metal machining location structure, includes the base, the top fixedly connected with mounting panel of base, the sliding surface of mounting panel is connected with the slide, the first linkage plate of top fixedly connected with of slide, the fixed frame of top fixedly connected with of first linkage plate, the top inner wall swivelling joint of fixed frame has the drive the lifter with the rotatory ring of transfer line horizontal lift, the bottom fixedly connected with of transfer line drives the first atress board of first embedding pole lift, the sliding surface of first embedding pole is connected with the drive the first limiting plate of push pedal horizontal slide, the side laminating of push pedal has the drive the driven plate that splint go up and down, the bottom fixedly connected with movable rod of splint.

Preferably, the side that the surface of base is located the mounting panel is provided with adjustment mechanism, and the another side that the surface of base is located the mounting panel is provided with the support frame, the top of support frame is provided with control mechanism, and control mechanism is located the surface of support frame and is provided with the processing equipment main part.

Preferably, the bottom of the rotating ring is an inclined plane, the top of the lifting rod is attached to the bottom of the rotating ring, and the first limiting plate is arranged obliquely relative to the surface of the first stress plate.

Preferably, first embedding pole embedding advances the inside of first limiting plate and rather than sliding connection, the contact surface of push pedal and driven plate each other is the inclined plane, and the driven plate drives splint through the push pedal and constitutes elevation structure.

Preferably, adjustment mechanism includes control panel, fly leaf, rotary disk, joint pole, swing board, second atress board, arm-tie and first slider, the control panel sets up in the top of base, and the fixed surface of control panel is connected with the fly leaf, the rotatory surface connection of fly leaf has the rotary disk, and the fixed surface of rotary disk is connected with the joint pole, the sliding surface connection of joint pole has the swing board, and the fixed surface of swing board is connected with the second atress board, the fixed surface of second atress board is connected with the arm-tie, and the rotatory surface connection of arm-tie has first slider.

Preferably, the surface of the swing plate is provided with a groove matched with the connecting rod, the pulling plate is deviated from the circle center of the second stress plate, and the pulling plate drives the first sliding block through the second stress plate to form a sliding structure.

Preferably, control mechanism includes rotary rod, bent plate, second embedding pole, second linkage board, meshing piece, motion board, second slider and second limiting plate, the rotary rod sets up in the surface of base, and the fixed surface of rotary rod is connected with the bent plate, the afterbody swivelling joint of bent plate has second embedding pole, and the afterbody fixedly connected with second linkage board of second embedding pole, the inner wall swivelling joint of second linkage board has the meshing piece, and the top fixedly connected with motion board of meshing piece, the bottom swivelling joint of motion board has the second slider, and the sliding surface of second slider has the second limiting plate.

Preferably, the included angle between the rotating rod and the bent plate is 130 degrees, the inclined angle between the bent plate and the second embedding rod is consistent, and the second embedding rod drives the meshing block to form a rotating structure through the second connecting plate.

Preferably, the second slider is deviated from the setting of the rotation central point of the motion plate, and the second slider is embedded into the vertical sliding groove in the surface of the second limiting plate and is connected with the vertical sliding groove in the surface of the second limiting plate in a sliding manner, and the second limiting plate drives the processing equipment main body through the second slider to form a left-right sliding structure.

Compared with the prior art, the invention has the beneficial effects that:

1. this metal machining location structure, through setting up rotatory ring, because the bottom of rotatory ring sets up for the slope, when it is rotatory, can drive the lifter with self inclined plane laminating and descend, the transfer line of lifter bottom can exert thrust downwards to first atress board afterwards, makes first embedding pole slide in the inside of first limiting plate, because first limiting plate is the slope and places, when first embedding pole moves down, can drive the push pedal through first limiting plate and draw close to the driven plate.

2. This metal machining location structure, through the setting of push pedal, receives the influence on push pedal and driven plate inclined plane, and the driven plate can drive splint downstream, and the movable rod can carry out the centre gripping to the work piece along with the decline of splint afterwards because the movable rod sets up for elasticity, when the movable rod was to the work piece centre gripping, can change self shape according to the shape of work piece, better carry out the centre gripping to the work piece.

3. This metal machining location structure, through setting up the joint pole, because the joint pole embedding is inside the recess that sets up on the swing board, when the rotary disk was rotatory, can drive the inside slip of spout of joint pole on the swing board, and exert thrust to the swing board thereupon, make the swing board drive second atress board and begin to rotate, because two sets of arm-tie all deviate from the central point setting in second atress board, when the second atress board is rotatory, can exert pulling force to two sets of arm-tie, make two sets of first sliders of two sets of arm-tie pulling slide on the base.

4. This metal machining location structure, through setting up second embedding pole, because second embedding pole is swivelling joint with the bent plate, so the second embedding pole can be rotatory along with the rotation of bent plate and continue to drive the meshing piece through the second linkage plate, also can begin rotatoryly of its fixed connection's motion board afterwards, because with motion board swivelling joint's second slider embedding in the vertical spout of the spacing board surface setting of second.

5. This metal machining location structure, the practicality is high, and when using, the work piece of accessible elastic movable rod to different shapes carries out the centre gripping, and can add man-hour, adjusts the centre gripping point through adjustment mechanism, further improves the flexibility of this equipment, and sets up in the control mechanism at support frame top, can adjust the position of processing equipment in real time, makes the usability of this equipment further improve.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a rear view of the present invention;

FIG. 3 is a schematic view of the control mechanism of the present invention;

FIG. 4 is a schematic view of the splint of the present invention;

FIG. 5 is a schematic diagram of a limiting plate according to the present invention;

FIG. 6 is a schematic view of a first perspective structure of the adjustment mechanism of the present invention;

fig. 7 is a schematic view of a second perspective structure of the adjusting mechanism of the present invention.

In the figure: 1. a base; 2. mounting a plate; 3. a slide plate; 4. a first connector tile; 5. a fixing frame; 6. a rotating ring; 7. a lifting rod; 8. a transmission rod; 9. a first force-bearing plate; 10. a first embedded rod; 11. a first limit plate; 12. pushing the plate; 13. a driven plate; 14. a splint; 15. a movable rod; 16. an adjustment mechanism; 1601. a control panel; 1602. a movable plate; 1603. rotating the disc; 1604. a connecting rod; 1605. a swing plate; 1606. a second force-bearing plate; 1607. pulling a plate; 1608. a first slider; 17. a support frame; 18. a control mechanism; 1801. rotating the rod; 1802. bending a plate; 1803. a second embedded rod; 1804. a second connector tile; 1805. an engagement block; 1806. a motion plate; 1807. a second slider; 1808. a second limiting plate; 19. and (5) processing equipment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 7, in the embodiment of the present invention, a metal machining positioning structure includes a base 1, a mounting plate 2 is fixedly connected to the top of the base 1, a sliding plate 3 is slidably connected to the surface of the mounting plate 2, a first connecting plate 4 is fixedly connected to the upper side of the sliding plate 3, a fixing frame 5 is fixedly connected to the top of the connecting plate 4, a rotating ring 6 for driving a lifting rod 7 and a transmission rod 8 to horizontally lift is rotatably connected to the inner wall of the top of the fixing frame 5, a first stressed plate 9 for driving a first embedded rod 10 to lift is fixedly connected to the bottom of the transmission rod 8, a first limiting plate 11 for driving a push plate 12 to horizontally slide is slidably connected to the surface of the first embedded rod 10, a driven plate 13 for driving a clamping plate 14 to lift is attached to the side of the push plate 12, and a movable rod 15 is fixedly connected to the bottom of the clamping plate 14.

Furthermore, an adjusting mechanism 16 is arranged on the side surface of the base 1, which is located on the mounting plate 2, a supporting frame 17 is arranged on the other side surface of the base 1, which is located on the mounting plate 2, a control mechanism 18 is arranged on the top of the supporting frame 17, a processing equipment main body 19 is arranged on the surface of the control mechanism 18, which is located on the supporting frame 17, and by arranging the adjusting mechanism 16 and the control mechanism 18, the processing equipment 19 has the function of adjusting the clamping point and the processing head, so that the workability is greatly improved.

Further, the bottom of rotatory ring 6 is the inclined plane setting, and the top of lifter 7 is laminated with the bottom of rotatory ring 6 mutually, first limiting plate 11 is the slope setting about the surface of first atress board 9, because the bottom of rotatory ring 6 is the slope setting, when it is rotatory, can drive the lifter 7 decline with the laminating of self inclined plane, the transfer line 8 of lifter 7 bottom can exert thrust downwards to first atress board 9 afterwards, make first embedding pole 10 slide in the inside of first limiting plate 11, because first limiting plate 11 is the slope and places, when first embedding pole 10 moves down, can drive push pedal 12 through first limiting plate 11 and draw close to driven plate 13.

Further, first embedded rod 10 imbeds into the inside of first limiting plate 11 and rather than sliding connection, push pedal 12 and driven plate 13's contact surface each other is the inclined plane, and driven plate 13 passes through push pedal 12 and drives splint 14 and constitute elevation structure, receive the influence on push pedal 12 and driven plate 13 inclined plane, driven plate 13 can drive splint 14 downstream, movable rod 15 can be along with splint 14's decline and carry out the centre gripping to the work piece afterwards, because movable rod 15 is the elasticity setting, when movable rod 15 was to the work piece centre gripping, can change self shape according to the shape of work piece, better carry out the centre gripping to the work piece.

Further, the adjusting mechanism 16 includes a control board 1601, a movable board 1602, a rotating board 1603, an engaging rod 1604, a swinging board 1605, a second stressed board 1606, a pulling board 1607 and a first slider 1608, the control board 1601 is disposed above the base 1, the movable board 1602 is fixedly connected to the surface of the control board 1601, the rotating board 1603 is rotatably connected to the surface of the movable board 1602, the engaging rod 1604 is fixedly connected to the surface of the rotating board 1603, the swinging board 1605 is slidably connected to the surface of the engaging rod 1604, the second stressed board 1606 is fixedly connected to the surface of the swinging board 1605, the pulling board 1607 is fixedly connected to the surface of the second stressed board 1606, the first slider 1608 is rotatably connected to the surface of the pulling board 1607, by disposing the adjusting mechanism 16, because the engaging rod 1604 is embedded in a groove provided on the swinging board 1605, when the rotating board 1603 rotates, the engaging rod 1604 is driven to slide in a sliding groove on the swinging board 1605 and applies a pushing force to the swinging board 1605 therewith, the swinging plate 1605 drives the second stress plate 1606 to rotate, because the two sets of pulling plates 1607 are both deviated from the central point of the second stress plate 1606, when the second stress plate 1606 rotates, the pulling force can be applied to the two sets of pulling plates 1607, so that the two sets of pulling plates 1607 pull the two sets of first sliding blocks 1608 to slide on the base 1, and then the sliding plate 3 fixedly connected with the sliding plate can slide along with the sliding plate, thereby achieving the purpose of adjusting the clamping point of the device.

Further, the surface of swing board 1605 is provided with the recess with linking pole 1604 assorted, and arm-tie 1607 deviates from the centre of a circle setting in second atress board 1606, and arm-tie 1607 drives first slider 1608 through second atress board 1606 and constitutes sliding structure, because it is inside that linking pole 1604 imbeds the recess that sets up on swing board 1605, when rotary disk 1603 is rotatory, can drive linking pole 1604 and slide in the spout on swing board 1605 is inside, and exert thrust to swing board 1605 thereupon, make swing board 1605 drive second atress board 1606 start to rotate.

Further, the control mechanism 18 includes a rotating rod 1801, a curved plate 1802, a second embedding rod 1803, a second connecting plate 1804, an engaging block 1805, a moving plate 1806, a second sliding block 1807 and a second limiting plate 1808, the rotating rod 1801 is disposed on the surface of the base 1, the surface of the rotating rod 1801 is fixedly connected with the curved plate 1802, the tail of the curved plate 1802 is rotatably connected with the second embedding rod 1803, the tail of the second embedding rod 1803 is fixedly connected with the second connecting plate 1804, the inner wall of the second connecting plate 1804 is rotatably connected with the engaging block 1805, the top of the engaging block 1805 is fixedly connected with the moving plate 1806, the bottom of the moving plate 1806 is rotatably connected with the second sliding block 1807, the surface of the second sliding block 1807 is slidably connected with the second limiting plate 1808, by providing the control mechanism 18, since the second embedding rod 1803 and the curved plate 1804 are rotatably connected, the second embedding rod 1803 will drive the engaging plate 1805 to rotate with the curved plate 1802 along with the rotation of the curved plate, then the motion board 1806 fixedly connected with it also can begin to rotate, because the second slider 1807 rotatably connected with the motion board 1806 is embedded in the vertical chute arranged on the surface of the second limiting plate 1808, when the motion board 1806 rotates, the second slider 1807 is driven to slide on the surface of the second limiting plate 1808, and then the second limiting plate 1808 is driven to slide on the surface of the supporting frame 17, and then the processing equipment 19 fixedly connected with the second limiting plate 1808 also can move along with the second limiting plate 1808, so that the equipment has the function of adjusting the processing equipment 19 in real time.

Further, the angle between the rotating rod 1801 and the bending plate 1802 is 130 °, and the angle between the bending plate 1802 and the second embedded rod 1803 is consistent, the second embedded rod 1803 drives the engaging block 1805 through the second connecting plate 1804 to form a rotating structure, and the second embedded rod 1803 is rotatably connected with the bending plate 1802, so that the second embedded rod 1803 will rotate with the rotation of the bending plate 1802 and then drive the engaging block 1805 through the second connecting plate 1804, and then the moving plate 1806 fixedly connected with the second embedded rod will also start to rotate.

Further, the second slider 1807 is disposed deviating from the rotation center point of the moving plate 1806, and the second slider 1807 is embedded into the vertical sliding slot on the surface of the second limiting plate 1808 and is slidably connected to the vertical sliding slot, the second limiting plate 1808 drives the processing device 19 to form a left-right sliding structure through the second slider 1807, because the second slider 1807 rotatably connected to the moving plate 1806 is embedded in the vertical sliding slot disposed on the surface of the second limiting plate 1808, when the moving plate 1806 rotates, the second slider 1807 is driven to slide on the surface of the second limiting plate 1808, and then the second limiting plate 1808 is driven to slide on the surface of the supporting frame 17, and then the processing device 19 fixedly connected to the second limiting plate 1808 also moves along with the second slider, so that the device has a function of adjusting the processing device 19 in real time.

The working principle of the invention is as follows: when the metal machining positioning structure is used, firstly, the movable rod 15 is controlled to clamp a workpiece, the rotating ring 6 is controlled to rotate, as the bottom of the rotating ring 6 is obliquely arranged, when the rotating ring rotates, the lifting rod 7 attached to the inclined surface of the rotating ring can be driven to descend, then the transmission rod 8 at the bottom of the lifting rod 7 can downwards apply thrust to the first stress plate 9, so that the first embedded rod 10 slides in the first limiting plate 11, as the first limiting plate 11 is obliquely arranged, when the first embedded rod 10 moves downwards, the push plate 12 can be driven to approach the driven plate 13 through the first limiting plate 11, and under the influence of the inclined surfaces of the push plate 12 and the driven plate 13, the driven plate 13 can drive the clamping plate 14 to move downwards, then, the movable rod 15 can clamp the workpiece along with the descending of the clamping plate 14, as the movable rod 15 is elastically arranged, when the movable rod 15 clamps the workpiece, the shape of the clamp can be changed according to the shape of the workpiece, and the workpiece can be better clamped.

Then, the position of the clamping point is adjusted, the control board 1601 is rotated, and then the control board 1601 drives the rotating disc 1603 to rotate around the rotating point with the base 1 through the moving plate 1602, because the connecting rod 1604 is embedded inside the groove provided on the swinging plate 1605, when the rotating disc 1603 rotates, the connecting rod 1604 is driven to slide inside the sliding groove on the swinging plate 1605, and then thrust is applied to the swinging plate 1605, so that the swinging plate 1605 drives the second stressed plate 1606 to start rotating, because both sets of pulling plates 1607 are arranged offset from the central point of the second stressed plate 1606, when the second stressed plate 1606 rotates, tension is applied to both sets of pulling plates 1607, so that both sets of pulling plates 1607 pull both sets of first sliding blocks 1608 to slide on the base 1, and then the sliding plate 3 fixedly connected with the sliding plates will slide together, thereby achieving the purpose of adjusting the clamping point of the device.

Finally, the position of the processing device 19 is adjusted by first rotating the rotating rod 1801 via the motor, and then the rotating rod 1801 will rotate the bending plate 1802, since the second embedded rod 1803 is rotatably connected to the bending plate 1802, the second embedding rod 1803 rotates with the rotation of the curved plate 1802 and then the engagement block 1805 is rotated by the second engaging plate 1804, and then the moving plate 1806 fixedly connected thereto also starts to rotate, since the second sliding block 1807 rotatably connected to the moving plate 1806 is embedded in the vertical sliding groove provided on the surface of the second limiting plate 1808, when the moving plate 1806 rotates, the second sliding block 1807 is driven to slide on the surface of the second limiting plate 1808, and then the second limiting plate 1808 is driven to slide on the surface of the supporting frame 17, and then the processing equipment main body 19 fixedly connected with the second limiting plate 1808 moves along with the second limiting plate 1808, so that the equipment has the function of adjusting the processing equipment 19 in real time.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (9)

1. The utility model provides a metal machining location structure, includes base (1), its characterized in that: the top of the base (1) is fixedly connected with an installation plate (2), the surface of the installation plate (2) is connected with a sliding plate (3) in a sliding way, a first connecting plate (4) is fixedly connected above the sliding plate (3), a fixing frame (5) is fixedly connected at the top of the first connecting plate (4), the inner wall of the top of the fixed frame (5) is rotationally connected with a rotating ring (6) which drives the lifting rod (7) and the transmission rod (8) to horizontally lift, the bottom of the transmission rod (8) is fixedly connected with a first stress plate (9) which drives the first embedded rod (10) to lift, the surface of the first embedding rod (10) is connected with a first limit plate (11) which drives the push plate (12) to horizontally slide in a sliding way, the side of push pedal (12) is laminated with the drive splint (14) driven plate (13) that goes up and down, the bottom fixedly connected with movable rod (15) of splint (14).

2. A metal machining locating structure according to claim 1, wherein: the side that the surface of base (1) is located mounting panel (2) is provided with adjustment mechanism (16), and the another side that the surface of base (1) is located mounting panel (2) is provided with support frame (17), the top of support frame (17) is provided with control mechanism (18), and the surface that control mechanism (18) are located support frame (17) is provided with processing equipment main part (19).

3. A metal machining locating structure according to claim 1, wherein: the bottom of the rotating ring (6) is an inclined plane, the top of the lifting rod (7) is attached to the bottom of the rotating ring (6), and the first limiting plate (11) is obliquely arranged on the surface of the first stress plate (9).

4. A metal machining locating structure according to claim 1, wherein: first embedding pole (10) embedding is advanced the inside of first limiting plate (11) and rather than sliding connection, the contact surface of push pedal (12) and driven plate (13) each other is the inclined plane, and driven plate (13) drive splint (14) through push pedal (12) and constitute elevation structure.

5. A metal machining positioning structure as defined in claim 2, wherein: adjustment mechanism (16) include control panel (1601), fly leaf (1602), rotary disk (1603), link pole (1604), swing board (1605), second atress board (1606), arm-tie (1607) and first slider (1608), control panel (1601) set up in the top of base (1), and the fixed surface of control panel (1601) is connected with fly leaf (1602), the fixed surface of fly leaf (1602) is connected with rotary disk (1603), and the fixed surface of rotary disk (1603) is connected with link pole (1604), the sliding surface of link pole (1604) is connected with swing board (1605), and the fixed surface of swing board (1605) is connected with second atress board (1606), the fixed surface of second atress board (1606) is connected with arm-tie (1607), and the rotary surface of arm-tie (1607) is connected with first slider (1608).

6. A metal machining locating structure according to claim 5, wherein: the surface of swing board (1605) is provided with and links up pole (1604) assorted recess, arm-tie (1607) deviate from the centre of a circle setting in second atress board (1606), and arm-tie (1607) pass through second atress board (1606) and drive first slider (1608) constitution sliding structure.

7. A metal machining positioning structure as defined in claim 2, wherein: the control mechanism (18) comprises a rotating rod (1801), a bending plate (1802), a second embedded rod (1803), a second connecting plate (1804), a meshing block (1805), a moving plate (1806), a second sliding block (1807) and a second limiting plate (1808), the rotating rod (1801) is arranged on the surface of the base (1), and the surface of the rotating rod (1801) is fixedly connected with a bending plate (1802), the tail part of the bending plate (1802) is rotatably connected with a second embedded rod (1803), and the tail part of the second embedded rod (1803) is fixedly connected with a second connecting plate (1804), the inner wall of the second connecting plate (1804) is rotatably connected with an engaging block (1805), the top of the meshing block (1805) is fixedly connected with a moving plate (1806), the bottom of the moving plate (1806) is rotatably connected with a second sliding block (1807), and the surface of the second slider (1807) is connected with a second limit plate (1808) in a sliding manner.

8. A metal machining locating structure according to claim 7, wherein: the included angle between the rotating rod (1801) and the bending plate (1802) is 130 degrees, the inclination angles of the bending plate (1802) and the second embedded rod (1803) are consistent, and the second embedded rod (1803) drives the engaging block (1805) through the second connecting plate (1804) to form a rotating structure.

9. A metal machining locating structure according to claim 7, wherein: the second slider (1807) is deviated from the setting of the rotation center point of moving plate (1806), and second slider (1807) imbeds inside the vertical spout in second limiting plate (1808) surface and rather than sliding connection, second limiting plate (1808) drive processing equipment main part (19) through second slider (1807) and constitute left and right sliding structure.

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