CN112122478A

CN112122478A - Sheet positioning structure of stamping multi-station production line

Info

Publication number: CN112122478A
Application number: CN202010908951.4A
Authority: CN
Inventors: 宋成智; 吕思海
Original assignee: Chery Automobile Co Ltd
Current assignee: Chery Automobile Co Ltd
Priority date: 2020-09-02
Filing date: 2020-09-02
Publication date: 2020-12-25
Anticipated expiration: 2040-09-02
Also published as: CN112122478B

Abstract

The invention provides a plate positioning structure of a stamping multi-station production line, which comprises a fixed base, a magnetic force separator and a linkage locking mechanism, wherein the magnetic force separator is arranged on the fixed base; the fixed base is provided with a slideway; the slide way is provided with a tension divider base which can slide along the slide way; the magnetic separator is fixedly arranged on the separator base; the linkage locking mechanism is arranged on the base of the tension divider and can lock the base of the tension divider, so that the relative motion between the base of the tension divider and the slide way is avoided; by adopting the scheme, the magnetic separator can be locked, and the problems that the magnetic separator is labor-consuming to move in the sheet installation process, the labor intensity is high, the positioning of the magnetic separator wastes time and the production efficiency is influenced are effectively solved.

Description

Sheet positioning structure of stamping multi-station production line

Technical Field

The invention belongs to the technical field of rapid positioning of sheet materials in a stamping production line, and particularly relates to a sheet material positioning structure in a stamping multi-station production line.

Background

The existing punching automatic production mostly adopts a magnetic plate separating form, and due to the automatic production, the requirements on the position of plates are strict, the plates are required to be placed by a crane or a forklift as the like, the plates need to be positioned in advance, and a magnetic separator is fixed according to the proper position of a workpiece, so that the operation is complex.

The existing magnetic separator is generally heavy, and when a pair of magnetic separators are close to each other, the strong magnetism is easy to cause safety accidents; meanwhile, in order to offset magnetic force, a large-torque screw is required for fixing, so that labor hour is increased, and labor intensity is high.

The existing multi-station automatic production line completely realizes high-efficiency stamping production for 15-20 times per minute, the replacement of the plate is more frequent under the condition that the production speed is increased, and the increase of the replacement speed of the plate has important significance for increasing the production efficiency of the whole line.

Based on the technical problems in the automatic stamping production, no relevant solution is provided; there is therefore a pressing need to find effective solutions to the above problems.

Disclosure of Invention

The invention aims to provide a sheet positioning structure of a stamping multi-station production line aiming at overcoming the defects in the prior art, and aims to solve one of the problems that the moving of a magnetic separator is labor-consuming and labor-intensive in the existing sheet installation process, the positioning of the magnetic separator wastes time, and the production efficiency is influenced.

The invention provides a plate positioning structure of a stamping multi-station production line, which comprises a fixed base, a magnetic force separator and a linkage locking mechanism, wherein the magnetic force separator is arranged on the fixed base; the fixed base is provided with a slideway; the slide way is provided with a tension divider base which can slide along the slide way; the magnetic separator is fixedly arranged on the separator base; the linkage locking mechanism is arranged on the base of the tension divider and can lock the base of the tension divider, so that the relative movement between the base of the tension divider and the slide way is avoided.

Furthermore, two sides of the slide way are respectively provided with a fixed rack; a supporting column is arranged on the base of the tension divider; the linkage locking mechanism comprises a cam, a linkage mechanism and a sliding rack; the sliding rack is arranged on the bottom surface of the base of the separator and can perform telescopic motion along the horizontal direction relative to the base of the separator, so that the sliding rack is meshed with the fixed rack for locking or separated for unlocking; the cam is rotatably arranged at the top of the supporting column; the linkage mechanism is arranged on the support column and is arranged between the cam and the sliding rack; the cam can trigger the linkage mechanism to act on the sliding rack in the rotating process, so that the sliding rack is spread and meshed and locked with the fixed rack; or the cam can trigger the linkage mechanism to be separated from the sliding rack in the rotating process, so that the sliding rack and the fixed rack are separated and unlocked.

Further, the linkage mechanism comprises a bearing, a linkage block and a first spring; the bearing is arranged on the supporting column in a lifting manner along the vertical direction, and the bottom of the bearing is abutted against the linkage block; the top end of the bearing is abutted against the cam and can extrude the linkage block to move downwards in the rotating process of the cam, so that the sliding rack is spread and meshed and locked with the fixed rack; the linkage block is arranged on the support column in a lifting manner along the vertical direction; one end of the first spring is arranged in the linkage block, and the other end of the first spring is arranged on the base of the tension divider along the vertical direction; the first spring can enable the linkage block to reset upwards in a natural state, so that the sliding rack and the fixed rack are separated and unlocked.

Furthermore, a bolt is arranged at the bottom of the linkage block, and a bolt inclined plane is arranged at the bottom of the bolt; the sliding rack comprises a first sliding rack and a second sliding rack; the first sliding rack is arranged on the left side of the bottom surface of the base of the distractor in a telescopic mode through a second spring, the second sliding rack is arranged on the right side of the bottom surface of the base of the distractor in a telescopic mode through the second spring, and the first sliding rack and the second sliding rack can be attached to or separated from each other during telescopic movement; rack inclined planes are respectively arranged at the upper ends of the opposite sides of the first sliding rack and the second sliding rack; when the bearing downwards extrudes the linkage block to move, the bolt extrudes the inclined plane through the inclined plane of the bolt, so that the first sliding rack and the second sliding rack overcome the second spring to be unfolded and are respectively meshed and locked with the fixed racks on the two sides of the slideway; when the bearing moves upwards, the linkage block moves upwards under the restoring force of the first spring, and the bolt is separated from the first sliding rack and the second sliding rack, so that the first sliding rack and the second sliding rack are attached to each other under the restoring force of the second spring and separated and unlocked from the fixed racks on two sides of the slide way respectively.

Furthermore, the cam is rotatably arranged at the top of the supporting column through a rotating shaft; the cam is also provided with a handle; the cam is an eccentric cam, and a groove is also formed in the circumferential direction of the cam; when the handle rotates the cam to enable the bearing to abut against the groove, the sliding rack and the fixed rack are in a meshed and locked state; when the handle rotates the cam to enable the bearing to be separated from the groove, the sliding rack and the fixed rack are in a separated unlocking state.

Furthermore, a scale is arranged on the side face, located on the slide way, of the upper end face of the fixed base, and the scale is parallel to the slide way.

Furthermore, a waist-shaped groove is formed in the support column in the vertical direction, the bearing is arranged in the waist-shaped groove through a pin shaft, and the pin shaft can slide up and down in the waist-shaped groove.

Further, the magnetic separator is arranged on the separator base along the vertical direction through a screw; the fixed rack is fixedly arranged on the fixed base through a screw; the sliding rack is arranged on the split charging device base through the sliding rack fixing block.

Furthermore, a lubricating oil groove is also arranged in the base of the tension divider.

Compared with the prior art, the scheme provided by the invention has the following technical effects:

firstly, the scheme provided by the invention changes manual carrying into a sliding mode, so that a large amount of time is saved, and the labor intensity is reduced;

secondly, according to the scheme provided by the invention, the manual screw tightening and fixing mode is changed into a cam self-locking mechanism, so that the labor intensity is saved, and the rotation locking can be realized;

thirdly, the scheme provided by the invention ensures that no safety accident occurs even if the positive electrode and the negative electrode of the magnetic force separator are close to each other through design.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

The invention will be further explained with reference to the drawings, in which:

FIG. 1 is a front view of a plate positioning structure of a stamping multi-station production line according to the present invention;

FIG. 2 is a top view of the base track positioning structure of the present invention;

FIG. 3 is a side view of a plate positioning structure of a stamping multi-station production line of the present invention;

FIG. 4 is a partially enlarged schematic view of a sheet positioning structure in a stamping multi-station production line according to the present invention in a locking state;

FIG. 5 is a schematic view showing a sliding state of a sheet positioning structure of a stamping multi-station production line according to the present invention;

FIG. 6 is a partially enlarged view of the locking state of the positioning structure of the base slideway in accordance with the present invention;

fig. 7 is a partially enlarged schematic view of the sliding state of the base slide positioning structure according to the present invention.

In the figure: 1. a fixed base; 10. a slideway; 11. a scale bar; 12. a lubricating oil groove; 13. a first spring; 14. a positioning column; 15. a second spring; 16. a screw; 2. a magnetic separator; 3. a distractor base; 4. a sliding rack; 41. a rack bevel; 42. a sliding rack fixing block; 5. a cam; 51. a groove; 52. a handle; 6. a bearing; 7. a support pillar; 71. a waist-shaped groove; 72. a pin shaft; 8. fixing a rack; 9. a linkage block; 91. a bolt; 92. a latch bevel.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1 to 7, the invention provides a plate positioning structure of a stamping multi-station production line, which specifically comprises a fixed base 1, a magnetic force separator 2 and a linkage locking mechanism; wherein, the fixed base 1 is provided with a slideway 10; the slideway 10 is provided with a slidable separator base 3, and the separator base 3 can be arranged along the slideway 10 in a sliding manner; further, the magnetic separator 2 is fixedly arranged on the separator base 3 and slides along with the separator base 3; specifically, a lubricating oil groove 12 is also arranged in the tensioner base 3; the lubricating oil groove 12 is a storage area for lubricating and changing oil between the slideways, and the slideways are lubricated by solid glycerol, so that a groove is needed, and the lubricating time can be prolonged; specifically, the linkage locking mechanism is arranged on the base 3 of the tension divider and can lock the base 3 of the tension divider, so that the relative movement between the base 3 of the tension divider and the slide way 10 is avoided, and the magnetic tension divider 2 keeps a distance and avoids mutual approaching; the invention provides a plate positioning structure of a stamping multi-station production line, which solves the problems that the moving of a magnetic separator is labor-consuming and has high labor intensity, the positioning of the magnetic separator wastes time and the production efficiency is influenced in the existing plate installation process; meanwhile, the problem that potential safety hazards exist when the magnetic distractors 2 are close to each other can be solved.

Preferably, in combination with the above scheme, as shown in fig. 1 to 7, two sides of the slide way 10 are respectively provided with a fixed rack 8; a support column 7 is arranged on the base 3 of the tension divider; further, the linkage locking mechanism comprises a cam 5, a linkage mechanism and a sliding rack 4; the sliding rack 4 is arranged on the bottom surface of the base 3 of the separator and can move relative to the base 3 of the separator in a telescopic manner along the horizontal direction, so that the sliding rack is meshed with the fixed rack 8 for locking or separated for unlocking; specifically, the moving direction of the sliding rack 4 is perpendicular to the sliding direction of the distractor base 3; further, the cam 5 is rotatably arranged on the top of the supporting column 7; the linkage mechanism is arranged on the support column 7 and is arranged between the cam 5 and the sliding rack 4; therefore, the cam 5 can trigger the linkage mechanism to act on the sliding rack 4 in the rotating process, so that the sliding rack 4 is unfolded and meshed with the fixed rack 8 for locking; or the cam 5 can trigger the linkage mechanism to be separated from the sliding rack 4 in the rotating process, so that the sliding rack 4 is separated from the fixed rack 8 for unlocking.

Preferably, in combination with the above solution, as shown in fig. 1 to 7, in the present embodiment, the linkage mechanism includes a bearing 6, a linkage block 9, and a first spring 13; the bearing 6 is arranged on the supporting column 7 in a lifting manner along the vertical direction, and the bottom of the bearing 6 abuts against the linkage block 9; the top end of the bearing 6 is abutted against the cam 5 and can extrude the linkage block 9 to move downwards in the rotating process of the cam 5, so that the sliding rack 4 is spread and meshed with the fixed rack 8 for locking; furthermore, the linkage block 9 is arranged on the support column 7 in a lifting manner along the vertical direction; one end of a first spring 13 is arranged in the linkage block 9, and the other end of the first spring 13 extends to the base 3 of the separator along the vertical direction; the design is such that the first spring 13 can reset the linkage block 9 upwards under the natural state, thereby separating and unlocking the sliding rack 4 and the fixed rack 8.

Preferably, in combination with the above solution, as shown in fig. 1 to 7, the bottom of the linkage block 9 is provided with a plug 91, and the bottom of the plug 91 is provided with a plug inclined plane 92; further, the slide rack 4 includes a first slide rack and a second slide rack; the first sliding rack is arranged on the left side of the bottom surface of the distractor base 3 in a telescopic mode through a second spring 14, the second sliding rack is arranged on the right side of the bottom surface of the distractor base 3 in a telescopic mode through the second spring 14, and the first sliding rack and the second sliding rack can be attached to or separated from each other during telescopic movement, so that meshing locking and separation unlocking are achieved; further, a second spring 14 is sleeved on the positioning column 13, so as to be horizontally arranged on the bottom surface of the base 3 of the separator; further, rack inclined planes 41 are respectively arranged at the upper ends of the opposite sides of the first sliding rack and the second sliding rack, the design of the rack inclined planes 41 is mainly matched with the bolt inclined plane 92, so that the bolt 91 can extrude the rack inclined plane 41 through the bolt inclined plane 92 when moving downwards, and the first sliding rack and the second sliding rack are unfolded; specifically, when the bearing 6 presses the linkage block 9 downwards to move, the latch 91 presses the inclined surface 41 through the latch inclined surface 92, so that the first sliding rack and the second sliding rack are opened against the second spring 14 and are respectively meshed and locked with the fixed racks 8 on two sides of the slideway 10; when the bearing 6 moves upwards, the linkage block 9 moves upwards under the restoring force of the first spring 13, and the latch 91 is separated from the first sliding rack and the second sliding rack, so that the first sliding rack and the second sliding rack are attached to each other under the restoring force of the second spring 14 and are separated from and unlocked from the fixed racks 8 on both sides of the slide way 10 respectively.

Preferably, in combination with the above solution, as shown in fig. 1 to 7, the cam 5 is rotatably disposed on the top of the supporting column 7 through a rotating shaft; the cam 5 is also provided with a handle 52; specifically, the cam 5 is an eccentric cam, and a groove 51 is further formed in the circumferential direction of the cam 5, wherein the groove 51 is a smooth arc-shaped groove, so that sliding is facilitated; when the cam 5 is rotated, the bolt of the linkage block 9 moves up and down to complete the locking and unlocking processes of the rack; specifically, when the handle 52 rotates the cam 5 to abut the bearing 6 in the groove 51, the sliding rack 4 and the fixed rack 8 are in a meshing locking state; when the handle 52 rotates the cam 5 to disengage the bearing 6 from the groove 51, the sliding rack 4 and the fixed rack 8 are in a separated unlocked state.

Preferably, in combination with the above solutions, as shown in fig. 1 to 7, the upper end surface of the fixed base 1 is provided with a scale 11 at the side surface of the slideway 10, the scale 11 is a sheet metal ruler, and the scale 11 is parallel to the slideway 10, so that the moving distance can be seen during the sliding process of the distractor base 3.

Preferably, in combination with the above solutions, as shown in fig. 1 to 7, a waist-shaped groove 71 is vertically arranged on the support column 7, the bearing 6 is arranged in the waist-shaped groove 71 through a pin 72, and the pin 72 can slide up and down in the waist-shaped groove 71, so as to drive the bearing 6 to move up and down.

Preferably, in combination with the above solution, as shown in fig. 1 to 7, the magnetic separator 2 is arranged on the separator base 3 in the vertical direction by means of screws 16; the fixed rack 8 is fixedly arranged on the fixed base 1 through a screw 16; the sliding rack 4 is installed on the dispenser base 3 through the sliding rack fixing block 42, thereby realizing assembly.

When the plate positioning structure of the stamping multi-station production line is used, only the cam needs to be rotated to the horizontal position, the linkage mechanism bounces upwards under the action of the spring, the bolt is separated from the sliding rack, and the fixed rack is separated from the sliding rack to complete unlocking; after unlocking, the base of the distractor can slide back and forth in the slideway, the position is adjusted, and the size of the plate is different according to different workpieces and can be adjusted to a required position according to the scale; the cam handle is rotated by 90 degrees upwards or downwards, the cam is connected with the linkage mechanism to carry out self-locking, and the sliding rack and the fixed rack mechanism can generate enough force to ensure that the magnetic force separating device cannot be adsorbed together, so that safety accidents are caused.

According to the scheme provided by the invention, the positioning form of the magnetic force distracter is changed, the magnetic force distracter base is made into a slide way type, the cam locking mechanism is added, the cam is connected with the lower linkage mechanism, the cam can be rotated to realize self-locking, the screw does not need to be screwed up manually, the rack can be used for effectively preventing personnel from being injured due to strong magnetic force when magnets attract each other, the scale and the number of production pieces are added on two sides, the measurement and adjustment process is saved, and one labor is saved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way. Those skilled in the art can make numerous possible variations and modifications to the described embodiments, or modify equivalent embodiments, without departing from the scope of the invention. Therefore, any modification, equivalent change and modification made to the above embodiments according to the technology of the present invention are within the protection scope of the present invention, unless the content of the technical solution of the present invention is departed from.

Claims

1. A sheet positioning structure of a stamping multi-station production line is characterized by comprising a fixed base (1), a magnetic force separator (2) and a linkage locking mechanism; a slideway (10) is arranged on the fixed base (1); the slide way (10) is provided with a tension divider base (3), and the tension divider base (3) can be arranged along the slide way (10) in a sliding manner; the magnetic separator (2) is fixedly arranged on the separator base (3); the linkage locking mechanism is arranged on the tension divider base (3) and can lock the tension divider base (3) so as to avoid relative movement between the tension divider base (3) and the slide way (10).

2. The plate positioning structure of the punching multi-station production line according to claim 1, characterized in that two sides of the slide way (10) are respectively provided with a fixed rack (8); a support column (7) is arranged on the base (3) of the tension divider; the linkage locking mechanism comprises a cam (5), a linkage mechanism and a sliding rack (4); the sliding rack (4) is arranged on the bottom surface of the base (3) of the separator and can move in a telescopic mode along the horizontal direction relative to the base (3) of the separator, so that the sliding rack is meshed with the fixed rack (8) to be locked or separated to be unlocked; the cam (5) is rotatably arranged at the top of the supporting column (7); the linkage mechanism is arranged on the supporting column (7) and is arranged between the cam (5) and the sliding rack (4); the cam (5) can trigger the linkage mechanism to act on the sliding rack (4) in the rotating process, so that the sliding rack (4) is spread and meshed with the fixed rack (8) for locking; or the cam (5) can trigger the linkage mechanism to be separated from the sliding rack (4) during the rotation process, so that the sliding rack (4) is separated from the fixed rack (8) for unlocking.

3. The stamping multi-station production line plate material positioning structure as claimed in claim 2, wherein the linkage mechanism comprises a bearing (6), a linkage block (9) and a first spring (13); the bearing (6) is arranged on the supporting column (7) in a lifting manner along the vertical direction, and the bottom of the bearing (6) abuts against the linkage block (9); the top end of the bearing (6) is abutted against the cam (5) and can extrude the linkage block (9) to move downwards in the rotating process of the cam (5), so that the sliding rack (4) is unfolded to be meshed and locked with the fixed rack (8); the linkage block (9) is arranged on the supporting column (7) in a lifting manner along the vertical direction; one end of the first spring (13) is arranged in the linkage block (9), and the other end of the first spring (13) is arranged on the base (3) of the tension divider along the vertical direction; the first spring (13) can enable the linkage block (9) to reset upwards in a natural state, so that the sliding rack (4) is separated from the fixed rack (8) to be unlocked.

4. The plate positioning structure of the punching multi-station production line according to claim 3, characterized in that a plug pin (91) is arranged at the bottom of the linkage block (9), and a plug pin inclined plane (92) is arranged at the bottom of the plug pin (91); the sliding rack (4) comprises a first sliding rack and a second sliding rack; the first sliding rack is arranged on the left side of the bottom surface of the distractor base (3) in a telescopic mode through a second spring (14), the second sliding rack is arranged on the right side of the bottom surface of the distractor base (3) in a telescopic mode through a second spring (14), and the first sliding rack and the second sliding rack can be attached to or separated from each other in the telescopic motion; rack inclined planes (41) are respectively arranged at the upper ends of the opposite sides of the first sliding rack and the second sliding rack; when the bearing (6) presses the linkage block (9) downwards to move, the bolt (91) presses the inclined surface (41) through the bolt inclined surface (92), so that the first sliding rack and the second sliding rack are spread against the second spring (14) and are respectively meshed and locked with the fixed racks (8) on two sides of the slideway (10); when the bearing (6) moves upwards, the linkage block (9) moves upwards under the restoring force of the first spring (13), and the bolt (91) is separated from the first sliding rack and the second sliding rack, so that the first sliding rack and the second sliding rack are attached to each other under the restoring force of the second spring (14) and are separated from and unlocked from the fixed racks (8) on two sides of the slide way (10) respectively.

5. The stamping multi-station production line plate material positioning structure as claimed in claim 3, wherein the cam (5) is rotatably arranged on the top of the supporting column (7) through a rotating shaft; the cam (5) is also provided with a handle (52); the cam (5) is an eccentric cam, and a groove (51) is further formed in the circumferential direction of the cam (5); when the handle (52) rotates the cam (5) to enable the bearing (6) to abut in the groove (51), the sliding rack (4) and the fixed rack (8) are in a meshing locking state; when the handle (52) rotates the cam (5) to enable the bearing (6) to be disengaged from the groove (51), the sliding rack (4) and the fixed rack (8) are in a separated unlocking state.

6. The plate positioning structure of the punching multi-station production line according to claim 1, wherein a scale (11) is arranged on the upper end face of the fixed base (1) and on the side face of the slideway (10), and the scale (11) is parallel to the slideway (10).

7. The plate positioning structure of the punching multi-station production line according to claim 1, wherein a waist-shaped groove (71) is vertically arranged on the supporting column (7), the bearing (6) is arranged in the waist-shaped groove (71) through a pin shaft (72), and the pin shaft (72) can slide up and down in the waist-shaped groove (71).

8. The stamping multi-station production line plate material positioning structure as claimed in claim 2, wherein the magnetic separator (2) is arranged on the separator base (3) along a vertical direction through a screw (16); the fixed rack (8) is fixedly arranged on the fixed base (1) through a screw (16); the sliding rack (4) is arranged on the sub-packaging device base (3) through a sliding rack fixing block (42).

9. The stamping multi-station production line plate material positioning structure as claimed in claim 1, wherein a lubricating oil groove (12) is further formed in the base (3) of the separator.