CN117841380A - Automatic automobile sealing part assembling and buckling integrated machine and use method thereof - Google Patents

Abstract

The invention relates to the field of sealing element processing, in particular to an automatic automobile sealing element assembling and buckling integrated machine and a using method thereof. Comprising the following steps: the riveting machine comprises a bearing box, a riveting machine and a perforating machine; the guide mechanism comprises a bearing base, four extrusion holding claws and a plurality of bearing rollers, wherein the bearing base is fixedly connected with the bottom end inside the bearing box, the plurality of bearing rollers are arranged in a rotary mode at equal intervals along the long side direction of the bearing base, and the four extrusion holding claws are symmetrically arranged on two sides of the sealing element body; the two anti-deformation mechanisms are respectively arranged at the lower ends of the riveting machine and the perforating machine, each anti-deformation mechanism comprises two pushing rollers, and the two pushing rollers are rotatably abutted against the upper end of the sealing piece body; the positioning mechanism is fixedly connected with the lower end of the puncher and can compress and position the rectangular part of the sealing element body; the two clamping and feeding mechanisms comprise two sliding clamping plates which are symmetrically arranged on two sides of the sealing element body, and the two sliding clamping plates can drive the sealing element body to move.

Description

Automatic automobile sealing part assembling and buckling integrated machine and use method thereof

Technical Field

The invention relates to the field of sealing element processing, in particular to an automatic automobile sealing element assembling and buckling integrated machine and a using method thereof.

Background

An automobile sealing member is an important part for sealing, sound insulation and water resistance, and is mainly used for preventing external moisture, dust and noise from entering an automobile and providing a comfortable driving environment. The automobile sealing member has various functions and characteristics, such as good temperature resistance, excellent elasticity and wear resistance, and can bear long-time extrusion and friction, and the service life is prolonged.

However, in the automatic buckling process of the automobile sealing element, if the stamping process is not mature or is not operated properly, the stamping of the sealing element body is possibly uneven, the problems of bulge, dent and the like are possibly caused, and the appearance and the sealing performance of the sealing element are affected. At this time, because the sealing member body is the rubber material, so the deformation appears between the two-layer rubber of sealing member body, and lead to punching press effect not good, even after the rubber strip returns to original state, the condition that the punching press hole between the two-layer rubber takes place the dislocation. Subsequently, the seal body may also experience surface damage or cracking, which may lead to reduced sealing performance or seal failure. This is mainly due to the elasticity and ductility of the rubber material, as well as the structural characteristics of the seal body based on the double layer rubber strip.

When the punched holes are misplaced, the fasteners may not be matched or installed in place later on when the fasteners are installed. This may result in the sealing strip not being normally fastened or fixed, affecting its use and life.

Disclosure of Invention

Based on the above, it is necessary to provide an automatic automobile sealing part assembling and buckling integrated machine and a using method thereof aiming at the problems in the prior art.

In order to solve the problems in the prior art, the invention adopts the following technical scheme:

the utility model provides an automatic dress of car sealing member detains all-in-one, includes the sealing member body, and one side shaping rectangle portion of sealing member body, the opposite side shaping has circular arc portion, includes:

a carrying case;

the riveting machine is arranged in the bearing box;

the puncher is arranged in the bearing box and is positioned beside the riveting machine;

the guide mechanism comprises a bearing base, four extrusion holding claws and a plurality of bearing rollers, wherein the bearing base is fixedly connected with the bottom end inside the bearing box, the plurality of bearing rollers are arranged in a rotating mode at equal intervals along the long side direction of the bearing base, the plurality of bearing rollers are propped against the arc part of the sealing element body, the four extrusion holding claws are in a group of two pairs, and two extrusion holding claws in each group are symmetrically arranged on two sides of the rectangular part of the sealing element body;

the two anti-deformation mechanisms are respectively arranged at the lower ends of the riveting machine and the perforating machine, each anti-deformation mechanism comprises two pushing rollers, and the two pushing rollers are symmetrically arranged and rotationally abutted against the upper end of the rectangular part of the sealing element body;

the positioning mechanism is fixedly connected with the lower end of the puncher and can compress and position the rectangular part of the sealing element body;

two centre gripping feeding mechanism set up respectively in the riveter and the one side that keeps away from mutually of puncher, every centre gripping feeding mechanism all includes two sliding splint, and two sliding splint are the symmetry state setting in the both sides of sealing member body, and two sliding splint can drive the sealing member body and remove.

Further, guiding mechanism still includes a plurality of spacing gyro wheels, four push down the rack, four push down gear and four extrusion racks, four extrusion racks are the horizontality respectively and hold the claw and link firmly with four extrusion, four push down the gear and mesh with four extrusion racks respectively, four push down the gear respectively with bear the support rotation on the base and be connected, four push down the rack and be vertical state respectively and mesh with four push down the gear, four push down the rack two by two a set of, a set of push down the rack and the output of riveter links firmly, another set of push down the rack and the output of puncher links firmly, a plurality of spacing gyro wheels are the symmetry state setting in the inside both sides of bearing the base, a plurality of spacing gyro wheels rotate along bearing the long limit direction equidistant setting of base.

Further, the anti-deformation mechanism further comprises a connection clamping plate, two connection clamping boxes, two first push rods, two second push rods, four limit sliding rails and two reset springs, wherein the connection clamping plates in the two anti-deformation mechanisms are fixedly connected with the side walls of the output ends of the riveting machine and the punching machine respectively, the two first push rods are in symmetrical states and fixedly connected with the connection clamping plates respectively, the two connection clamping boxes are in sliding connection with the two sides of the connection clamping plates respectively, the four limit sliding rails are fixedly connected with the two connection clamping boxes respectively, the two second push rods are in sliding connection with the four limit sliding rails respectively, the lower ends of the two second push rods are in rotating connection with corresponding pushing rollers respectively, one ends of the two reset springs are fixedly connected with the two second push rods respectively, the other ends of the two reset springs are fixedly connected with the inner walls of the connection clamping boxes respectively, one ends of the first push rods, which are close to the second push rods, are formed with first inclined surfaces, and one ends of the second push rods, which are close to the first push rods, are formed with second inclined surfaces, and the first inclined surfaces and the second inclined surfaces slide against the second inclined surfaces.

Further, positioning mechanism still includes positioning spring, location ring and two positioning pin axles, and the setting of location ring links up the below of cardboard, and positioning spring's upper end links firmly with linking the cardboard, and the lower extreme links firmly with the location ring, and two positioning pin axles are symmetrical state setting in positioning spring's both sides, and the lower extreme and the location ring of two positioning pin axles link firmly, upper end and linking cardboard sliding connection.

Further, the clamping feeding mechanism further comprises a driving motor, a reciprocating screw rod, a reciprocating rod sleeve, two limiting inserted rods, two limiting supports and two traction pull plates, wherein the two limiting supports are symmetrically arranged above the bearing base, the driving motor is fixedly connected with one limiting support, the reciprocating screw rod is rotatably arranged between the two limiting supports, the output end of the driving motor is fixedly connected with one end of the reciprocating screw rod, the reciprocating rod sleeve is in threaded connection with the reciprocating screw rod, the two limiting inserted rods are symmetrically arranged on two sides of the reciprocating screw rod, two sides of the reciprocating rod sleeve are respectively in sliding connection with the two limiting inserted rods, the two traction pull plates are symmetrically arranged below the reciprocating rod sleeve, and the two traction pull plates are respectively fixedly connected with the lower end of the reciprocating rod sleeve.

Further, the clamping feeding mechanism further comprises two limiting bottom plates, two sliding short shafts, two sliding connecting plates, two pushing arc strips, two tensioning racks and two loosening racks, wherein the two limiting bottom plates are symmetrically fixedly arranged above the bearing base, the two limiting bottom plates are respectively and slidably connected with the two traction pull plates, the two sliding connecting plates are respectively and slidably connected with the lower ends of the two limiting bottom plates, limiting through holes are formed in the traction pull plates, oblique guide holes are formed in the limiting bottom plates, the upper parts of the sliding short shafts are slidably connected with the limiting through holes, the middle parts of the sliding short shafts are slidably connected with the oblique guide holes, the lower parts of the sliding short shafts are fixedly connected with the sliding connecting plates, the two pushing arc strips are fixedly connected with the lower ends of the two limiting bottom plates, the two tensioning racks are fixedly connected with one sides of the two pushing arc strips, which are close to the bearing base, and the two loosening racks are fixedly connected with one sides of the two pushing arc strips, which are far away from the bearing base.

Further, the clamping feeding mechanism further comprises two first gears, two second gears, two first bevel gears, two second bevel gears, two sliding gears, two positioning racks and two sliding boxes, wherein the two sliding boxes are respectively and fixedly arranged below the two sliding connecting plates, the two first gears are respectively and rotatably connected with the lower ends of the two sliding connecting plates, the two first gears are respectively and coaxially connected with the two second gears through ratchet wheels, the two first bevel gears are rotatably arranged in the two sliding boxes, the two first bevel gears are respectively and coaxially fixedly connected with the two second gears, the two second bevel gears are respectively meshed with the two first bevel gears, the two sliding gears are respectively and fixedly connected with the two second bevel gears, the two positioning racks are respectively and slidably connected with the bottoms of the two sliding boxes, the two positioning racks are respectively and fixedly connected with the two clamping plates, the two tensioning racks can be respectively meshed with the two second gears, and the two loosening racks can be respectively meshed with the two first gears.

The application method of the automatic automobile sealing part buckling integrated machine further comprises the following application steps:

s1: an operator puts the sealing element body into the upper end of the bearing base and then pushes the sealing element body to move along the long side direction of the bearing base;

s2: when the sealing element body is positioned and clamped by the clamping feeding mechanism close to the inlet of the bearing box, the clamping feeding mechanism is started to drive the sealing element body to move through the two sliding clamping plates;

s3: the sealing member body can pass through puncher and riveter in proper order after moving, and after the puncher punched on the sealing member body, the riveter opportunity presses the buckle in corresponding hole.

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

the method comprises the following steps: according to the device, the extrusion holding claw is matched with the pushing roller, so that when the riveting machine and the puncher process the sealing element body, the acting force is applied to the two sides of the hollow sealing element body, so that the flow and deformation of materials in the punching process can be effectively controlled, the deviation and dislocation of punching positions are reduced, the punching precision can be improved, and the two punching holes are closer to a coaxial line;

and two,: according to the device, the positioning circular ring is matched with the positioning spring, when the riveting machine and the perforating machine process the sealing element body, the positioning spring can apply acting force to the positioning circular ring to apply pressure to the upper end of the sealing element body, so that the situation that the sealing element body is stressed and deformed too much due to rapid stamping is avoided, the sealing element body is damaged or broken on the surface is avoided, and the product quality is improved;

and thirdly,: this device realizes the continuous traction to sealing member body through centre gripping feeding mechanism, compares in traditional conveyer belt extrusion traction, and two centre gripping feeding mechanism in this device can drive the traction strip and remove, avoids the traction strip to produce deformation because of the both sides continuously receive the extrusion force, and then influences puncher and riveter normal work.

Drawings

FIG. 1 is a schematic perspective view of an embodiment;

FIG. 2 is a front view of an embodiment;

FIG. 3 is an internal structural view of the carrying case in the embodiment;

FIG. 4 is a front view of a load-bearing base in an embodiment;

FIG. 5 is an enlarged view of the structure of FIG. 4 at A;

FIG. 6 is a schematic perspective view of an anti-deformation mechanism and a positioning mechanism in an embodiment;

FIG. 7 is a schematic perspective view of a clamping feeding mechanism in an embodiment;

FIG. 8 is a top view of the clamp feed mechanism in an embodiment;

FIG. 9 is an exploded perspective view of the clamp feed mechanism in an embodiment;

fig. 10 is an enlarged view of the structure at B in fig. 9.

The reference numerals in the figures are:

1. a seal body; 2. a rectangular portion; 3. an arc part; 4. a carrying case; 5. a riveter; 6. a puncher; 7. a guide mechanism; 8. a load-bearing base; 9. limiting idler wheels; 10. pressing down the rack; 11. pressing down the gear; 12. extruding the rack; 13. extruding the holding claw; 14. carrying rollers; 15. an anti-deformation mechanism; 16. a connecting clamping plate; 17. a connection cartridge; 18. a first push rod; 19. a first inclined surface; 20. a second push rod; 21. a second inclined surface; 22. a limit sliding rail; 23. a return spring; 24. pushing rollers; 25. a positioning mechanism; 26. a positioning spring; 27. positioning a circular ring; 28. positioning pin shafts; 29. clamping and feeding mechanisms; 30. a driving motor; 31. a reciprocating screw rod; 32. a reciprocating rod sleeve; 33. a limit inserted link; 34. a limit support; 35. traction pulling plate; 36. limiting perforation; 37. a limiting bottom plate; 38. an inclined guide hole; 39. a sliding short shaft; 40. a slip joint plate; 41. pushing the arc strip; 42. tensioning the rack; 43. loosening the rack; 44. a first gear; 45. a ratchet wheel; 46. a second gear; 47. a first bevel gear; 48. a second bevel gear; 49. a slipping gear; 50. positioning a rack; 51. a slip case; 52. and a sliding clamping plate.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

Referring to fig. 1 to 10, an automatic car seal dress detains all-in-one, including seal body 1, one side shaping rectangle portion 2 of seal body 1, the opposite side shaping has circular arc portion 3, includes:

a carrying case 4;

a riveting machine 5 provided inside the carrying case 4;

the puncher 6 is arranged in the bearing box 4 and is positioned beside the riveting machine 5;

the guide mechanism 7 comprises a bearing base 8, four extrusion holding claws 13 and a plurality of bearing rollers 14, wherein the bearing base 8 is fixedly connected with the bottom end inside the bearing box 4, the plurality of bearing rollers 14 are arranged in a rotating mode at equal intervals along the long side direction of the bearing base 8, the plurality of bearing rollers 14 are propped against the arc part 3 of the sealing element body 1, the four extrusion holding claws 13 are arranged in pairs, and two extrusion holding claws 13 in each group are symmetrically arranged on two sides of the rectangular part 2 of the sealing element body 1;

the two anti-deformation mechanisms 15 are respectively arranged at the lower ends of the riveting machine 5 and the perforating machine 6, each anti-deformation mechanism 15 comprises two pushing rollers 24, and the two pushing rollers 24 are symmetrically arranged and rotationally abutted against the upper end of the rectangular part 2 of the sealing element body 1;

the positioning mechanism 25 is fixedly connected with the lower end of the puncher 6 and can compress and position the rectangular part 2 of the sealing element body 1;

the two clamping and feeding mechanisms 29 are respectively arranged on one side, far away from each other, of the riveting machine 5 and the punching machine 6, each clamping and feeding mechanism 29 comprises two sliding clamping plates 52, the two sliding clamping plates 52 are symmetrically arranged on two sides of the sealing element body 1, and the two sliding clamping plates 52 can drive the sealing element body 1 to move.

When the device is operated, an operator puts the sealing element body 1 into the upper end of the bearing base 8, and then pushes the sealing element body 1 to move for a short distance along the long side direction of the bearing base 8 until the sealing element body 1 is positioned and clamped by the clamping feeding mechanism 29 close to the inlet of the bearing box 4, and the clamping feeding mechanism 29 is started to drive the sealing element body 1 to move through the two sliding clamping plates 52.

And sealing member body 1 removes the back and can pass through puncher 6 and riveter 5 in proper order, and when sealing member body 1 passed through puncher 6, puncher 6 can drive and prevent deformation mechanism 15 downwardly moving, prevents deformation mechanism 15 and positioning mechanism 25 cooperation, can exert the effort in sealing member body 1 both sides and upper end, can control the flow and the deformation of punching press in-process material effectively to reduce the deviation and the dislocation of punching a hole the position. This can improve the punching accuracy for two punches a hole closer to the coaxial line, and after punching on the seal member body 1, the riveting machine 5 can press the fastener in the corresponding hole, and at this time, the automatic fastening of the seal member body 1 ends.

In order to supplement the specific structure of the guide mechanism 7, the following features are specifically provided:

the guiding mechanism 7 further comprises a plurality of limiting idler wheels 9, four pressing racks 10, four pressing gears 11 and four pressing racks 12, wherein the four pressing racks 12 are respectively in a horizontal state and fixedly connected with four pressing holding claws 13, the four pressing gears 11 are respectively meshed with the four pressing racks 12, the four pressing gears 11 are respectively rotatably connected with a support on the bearing base 8, the four pressing racks 10 are respectively meshed with the four pressing gears 11 in a vertical state, the four pressing racks 10 are in two groups, one group of pressing racks 10 is fixedly connected with the output end of the riveting machine 5, the other group of pressing racks 10 is fixedly connected with the output end of the punching machine 6, the limiting idler wheels 9 are symmetrically arranged on two sides inside the bearing base 8, and the limiting idler wheels 9 are uniformly and rotatably arranged along the long side direction of the bearing base 8. When the output ends of the riveting machine 5 and the punching machine 6 move downwards, a corresponding group of pressing racks 10 move downwards, the pressing racks 10 drive the pressing racks 12 to move through the pressing gears 11, the pressing racks 12 drive the corresponding pressing holding claws 13 to abut against the two sides of the sealing element body 1 after moving, so that when the riveting machine 5 and the punching machine 6 work, the two sides of the sealing element body 1 can be ensured to receive acting force, the acting force can effectively control the flow and deformation of materials in the punching process, thereby reducing deviation and dislocation of punching positions, improving the punching precision and enabling two punching holes to be closer to a coaxial line;

in order to supplement the specific structure of the deformation preventing mechanism 15, the following features are specifically provided:

the anti-deformation mechanism 15 further comprises a connecting clamping plate 16, two connecting clamping boxes 17, two first push rods 18, two second push rods 20, four limiting slide rails 22 and two reset springs 23, the connecting clamping plate 16 in the two anti-deformation mechanisms 15 is fixedly connected with the side walls of the output ends of the riveting machine 5 and the punching machine 6 respectively, the two first push rods 18 are symmetrically fixedly connected with the connecting clamping plate 16 respectively, the two connecting clamping boxes 17 are respectively connected with two sides of the connecting clamping plate 16 in a sliding mode, the four limiting slide rails 22 are respectively fixedly connected with the two connecting clamping boxes 17, the two second push rods 20 are respectively connected with the four limiting slide rails 22 in a sliding mode, the lower ends of the two second push rods 20 are respectively connected with corresponding pushing rollers 24 in a rotating mode, one ends of the two reset springs 23 are respectively fixedly connected with the two second push rods 20, the other ends of the two reset springs are respectively fixedly connected with the inner walls of the connecting clamping boxes 17, one ends of the first push rods 18, which are close to the second push rods 20, one ends of the second push rods 20 are close to the first inclined surfaces 19 are formed, the second inclined surfaces 21 are respectively, and the first inclined surfaces 19 are respectively arranged at one ends of the second push rods 20 which are close to the first push rods 18. When the riveting machine 5 and the punching machine 6 process the sealing element body 1, along with the fact that the output ends of the riveting machine 5 and the punching machine 6 are close to the sealing element body 1, the pushing roller 24 at the lower end of the second push rod 20 is propped against the upper end of the sealing element body 1, then when the output ends of the riveting machine 5 and the punching machine 6 continue to move downwards, the two first push rods 18 fixedly connected with the connecting clamping plate 16 push the two second push rods 20 to move, at the moment, the first inclined surface 19 and the second inclined surface 21 are in sliding fit, the two second push rods 20 drive the corresponding pushing roller 24 to roll along the upper end of the sealing element body 1, at the moment, the rectangular part 2 of the sealing element body 1 is subjected to stable extrusion force, and local deformation is prevented (through rolling extrusion, rubber materials can become more uniform in a certain area), and non-uniformity of internal stress is reduced, and the uniformity can improve stability and durability of materials in a punching process. And the return spring 23 is used for the subsequent return of the second push rod 20.

To further supplement the specific structure of the positioning mechanism 25, the following features are specifically provided:

the positioning mechanism 25 further comprises a positioning spring 26, a positioning circular ring 27 and two positioning pin shafts 28, wherein the positioning circular ring 27 is arranged below the connecting clamping plate 16, the upper end of the positioning spring 26 is fixedly connected with the connecting clamping plate 16, the lower end of the positioning spring is fixedly connected with the positioning circular ring 27, the two positioning pin shafts 28 are symmetrically arranged on two sides of the positioning spring 26, the lower ends of the two positioning pin shafts 28 are fixedly connected with the positioning circular ring 27, and the upper end of the positioning pin shafts are in sliding connection with the connecting clamping plate 16. Before the sealing element body 1 is extruded, the positioning circular ring 27 can be propped against the upper end of the sealing element body 1, then when the output ends of the riveting machine 5 and the punching machine 6 continue to move downwards, the positioning circular ring 27 can apply acting force to the sealing element body 1 under the action of the positioning spring 26 to press the upper end of the sealing element body 1, so that the situation that the sealing element body 1 is damaged or broken due to the fact that the sealing element body 1 is stressed and deformed too much caused by rapid punching is avoided, and the product quality is improved.

To supplement the specific structure of the clamp feed mechanism 29, the following features are specifically provided:

the clamping feeding mechanism 29 further comprises a driving motor 30, a reciprocating screw rod 31, a reciprocating rod sleeve 32, two limiting inserting rods 33, two limiting supports 34 and two traction pull plates 35, wherein the two limiting supports 34 are symmetrically fixedly arranged above the bearing base 8, the driving motor 30 is fixedly connected with one limiting support 34, the reciprocating screw rod 31 is rotatably arranged between the two limiting supports 34, the output end of the driving motor 30 is fixedly connected with one end of the reciprocating screw rod 31, the reciprocating rod sleeve 32 is in threaded connection with the reciprocating screw rod 31, the two limiting inserting rods 33 are symmetrically fixedly arranged on two sides of the reciprocating screw rod 31, two sides of the reciprocating rod sleeve 32 are respectively in sliding connection with the two limiting inserting rods 33, the two traction pull plates 35 are symmetrically arranged below the reciprocating rod sleeve 32, and the two traction pull plates 35 are respectively fixedly connected with the lower end of the reciprocating rod sleeve 32. After the driving motor 30 is started, the driving motor 30 drives the reciprocating rod sleeve 32 to perform reciprocating displacement in the horizontal direction through the reciprocating screw rod 31, the two limiting inserting rods 33 provide limiting for the movement of the reciprocating rod sleeve 32, and then the movement of the reciprocating rod sleeve 32 drives the two traction pull plates 35 to perform reciprocating displacement in the horizontal direction.

To further supplement the specific structure of the clamp feed mechanism 29, the following features are provided:

the clamping and feeding mechanism 29 further comprises two limiting bottom plates 37, two sliding short shafts 39, two sliding connecting plates 40, two pushing arc strips 41, two tensioning racks 42 and two loosening racks 43, wherein the two limiting bottom plates 37 are symmetrically fixedly arranged above the bearing base 8, the two limiting bottom plates 37 are respectively connected with the two traction pull plates 35 in a sliding mode, the two sliding connecting plates 40 are respectively connected with the lower ends of the two limiting bottom plates 37 in a sliding mode, limiting through holes 36 are formed in the traction pull plates 35, oblique guide holes 38 are formed in the limiting bottom plates 37 in a forming mode, the upper portions of the sliding short shafts 39 are connected with the limiting through holes 36 in a sliding mode, the middle portions of the sliding short shafts are connected with the oblique guide holes 38 in a sliding mode, the lower portions of the sliding short shafts 39 are connected with the sliding connecting plates 40, the two pushing arc strips 41 are respectively connected with the lower ends of the two limiting bottom plates 37 in a fixing mode, the two tensioning racks 42 are respectively connected with one sides of the two pushing arc strips 41, which are close to the bearing base 8, and the two loosening racks 43 are respectively connected with one sides of the two pushing arc strips 41, which are far away from the bearing base 8. When the two traction pulling plates 35 move, the two traction pulling plates 35 drive the two sliding connecting plates 40 to move through the two sliding short shafts 39, and the two sliding connecting plates 40 move along the inclined guide holes 38 when moving, here referring to fig. 8 and 9, the inclined guide holes 38 are divided into arc parts and straight parts, when the sliding short shafts 39 move in the arc parts of the inclined guide holes 38, the sliding connecting plates 40 move close to the seal body 1 or far away from the seal body 1, and when the sliding short shafts 39 move in the straight parts of the inclined guide holes 38, the sliding connecting plates 40 move along the long plate direction of the seal body 1, namely, the corresponding sliding clamping plates 52 clamp the seal body 1.

In order to move the seal body 1 by means of the two sliding clamping plates 52, the following features are provided:

the clamping feeding mechanism 29 further comprises two first gears 44, two second gears 46, two first bevel gears 47, two second bevel gears 48, two sliding gears 49, two positioning racks 50 and two sliding boxes 51, wherein the two sliding boxes 51 are respectively and fixedly arranged below the two sliding connecting plates 40, the two first gears 44 are respectively and rotatably connected with the lower ends of the two sliding connecting plates 40, the two first gears 44 are respectively and coaxially connected with the two second gears 46 through ratchet wheels 45, the two first bevel gears 47 are rotatably arranged inside the two sliding boxes 51, the two first bevel gears 47 are respectively and coaxially connected with the two second gears 46, the two second bevel gears 48 are respectively meshed with the two first bevel gears 47, the two sliding gears 49 are respectively and coaxially connected with the two second bevel gears 48, the two positioning racks 50 are respectively and slidably connected with the bottom ends of the two boxes 51, the two positioning racks 50 are respectively and fixedly connected with the two sliding clamping plates 52, the two tensioning racks 42 can be respectively and loosely meshed with the two second bevel gears 46, and the two tensioning racks 46 can be respectively meshed with the two second bevel gears 43. When the sliding connecting plate 40 drives the sliding box 51 to move, when the sliding connecting plate 40 drives the second gear 46 to be meshed with the tensioning rack 42, the second gear 46 sequentially passes through the first bevel gear 47, the second bevel gear 48, the sliding gear 49 and the positioning rack 50, and finally drives the sliding clamping plates 52 to abut against the side wall of the sealing element body 1, and when the two sliding clamping plates 52 abut against the side wall of the sealing element body 1 at the same time, the movement of the two sliding clamping plates 52 can drive the sealing element body 1 to move.

In this process, when the first gear 44 and the slack rack 43 are engaged, the first gear 44 rotates under the action of the ratchet 45 without driving the second gear 46 to rotate, but when the sliding engagement plate 40 moves in the opposite direction, the first gear 44 rotates under the action of the ratchet 45 with the second gear 46 being driven to rotate due to the reverse engagement of the first gear 44 and the slack rack 43 (the "when the sliding engagement plate 40 drives the second gear 46 to engage with the tension rack 42" described above by default) at this time, and the two sliding engagement plates 52 move away from the seal body 1, and ensure that the two sliding engagement plates 52 do not drive the seal body 1 to displace during the movement.

The application method of the automatic automobile sealing part buckling integrated machine further comprises the following application steps:

s1: the operator puts the sealing element body 1 into the upper end of the bearing base 8, and then pushes the sealing element body 1 to move along the long side direction of the bearing base 8;

s2: when the sealing element body 1 is positioned and clamped by the clamping feeding mechanism 29 close to the inlet of the carrying box 4, the clamping feeding mechanism 29 is started to drive the sealing element body 1 to move through the two sliding clamping plates 52;

s3: after the sealing element body 1 moves, the sealing element body can sequentially pass through the puncher 6 and the riveting machine 5, and after the puncher 6 punches holes on the sealing element body 1, the riveting machine 5 can press the buckle in the corresponding hole.

The theory of operation of this device is, and this device is when the operation, and operating personnel puts into the upper end that bears base 8 with sealing member body 1, promotes sealing member body 1 and carries out the short distance along bearing base 8 long limit direction afterwards and remove until sealing member body 1 is close to the two slip splint 52 location clamp that bear the entry of case 4 after, driving motor 30 starts and can drive sealing member body 1 through two slip splint 52 and remove.

The sealing element body 1 moves and then sequentially passes through the puncher 6 and the riveting machine 5, when the sealing element body 1 passes through the puncher 6, the puncher 6 can drive the corresponding pushing roller 24 to roll along the upper end of the sealing element body 1, at the moment, the rectangular part 2 of the sealing element body 1 can be subjected to stable extrusion force, and further local deformation is prevented (through rolling extrusion, rubber materials can be more uniform in a certain area, the non-uniformity of internal stress is reduced, the uniformity can improve the stability and durability of the materials in the punching process, the pushing roller 24 rolls along the upper end of the sealing element body 1, so that the materials can be guided to flow in the punching process, the pushing roller is more orderly and controllable, the problem that the materials are stacked or flow is not uniform in the punching process can be reduced, and the sealing element body 1 cannot shift in the position of holes due to the deformation of the rectangular part 2 after the sealing element body 1 receives acting force is facilitated. And the return spring 23 is used for the subsequent return of the second push rod 20.

After the sealing element body 1 is perforated, the riveting machine 5 presses the buckle in the corresponding hole, and at the moment, the automatic buckling of the sealing element body 1 is finished.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (8)

1. The utility model provides an automatic dress of car sealing member detains all-in-one, includes sealing member body (1), and one side shaping rectangle portion (2) of sealing member body (1), and the opposite side shaping has circular arc portion (3), its characterized in that still includes:

a carrying case (4);

the riveting machine (5) is arranged in the bearing box (4);

the puncher (6) is arranged in the bearing box (4) and is positioned beside the riveting machine (5);

the guide mechanism (7) comprises a bearing base (8), four extrusion holding claws (13) and a plurality of bearing rollers (14), wherein the bearing base (8) is fixedly connected with the bottom end inside the bearing box (4), the plurality of bearing rollers (14) are arranged in a rotating mode at equal intervals along the long side direction of the bearing base (8), the plurality of bearing rollers (14) are propped against the arc part (3) of the sealing element body (1), the four extrusion holding claws (13) are arranged in pairs in one group, and two extrusion holding claws (13) in each group are symmetrically arranged on two sides of the rectangular part (2) of the sealing element body (1);

the two anti-deformation mechanisms (15) are respectively arranged at the lower ends of the riveting machine (5) and the perforating machine (6), each anti-deformation mechanism (15) comprises two pushing rollers (24), and the two pushing rollers (24) are symmetrically arranged and are abutted against the upper end of the rectangular part (2) of the sealing element body (1) in a rotating way;

the positioning mechanism (25) is fixedly connected with the lower end of the puncher (6) and can compress and position the rectangular part (2) of the sealing element body (1);

two centre gripping feeding mechanism (29) set up respectively in the side that keeps away from mutually of riveter (5) and puncher (6), and every centre gripping feeding mechanism (29) all include two slip splint (52), and two slip splint (52) are the both sides of symmetry state setting in sealing member body (1), and two slip splint (52) can drive sealing member body (1) and remove.

2. The automatic automobile sealing part assembling and buckling integrated machine according to claim 1, wherein the guiding mechanism (7) further comprises a plurality of limiting idler wheels (9), four pressing racks (10), four pressing gears (11) and four pressing racks (12), the four pressing racks (12) are respectively and horizontally fixedly connected with the four pressing holding claws (13), the four pressing gears (11) are respectively meshed with the four pressing racks (12), the four pressing gears (11) are respectively and rotatably connected with a support on the bearing base (8), the four pressing racks (10) are respectively and vertically meshed with the four pressing gears (11), the four pressing racks (10) are in a group of two pressing racks, one group of pressing racks (10) are fixedly connected with the output end of the riveting machine (5), the other group of pressing racks (10) are fixedly connected with the output end of the punching machine (6), the plurality of limiting idler wheels (9) are symmetrically arranged on two sides inside the bearing base (8), and the plurality of limiting idler wheels (9) are rotatably arranged at equal intervals along the length direction of the bearing base (8).

3. The automatic assembling and buckling integrated machine for automobile sealing parts according to claim 1, wherein the anti-deformation mechanism (15) further comprises an assembling clamping plate (16), two assembling clamping boxes (17), two first push rods (18), two second push rods (20), four limit sliding rails (22) and two return springs (23), the assembling clamping plate (16) in the two anti-deformation mechanisms (15) is respectively fixedly connected with the side walls of the output ends of the riveting machine (5) and the punching machine (6), the two first push rods (18) are respectively fixedly connected with the assembling clamping plate (16) in a symmetrical state, the two assembling clamping boxes (17) are respectively and slidably connected with two sides of the assembling clamping plate (16), the four limit sliding rails (22) are respectively and fixedly connected with the two assembling clamping boxes (17), the two second push rods (20) are respectively and slidably connected with the four limit sliding rails (22), the lower ends of the two second push rods (20) are respectively and rotatably connected with corresponding pushing rollers (24), one ends of the two return springs (23) are respectively and fixedly connected with the two second push rods (20) at two ends, the other ends of the two second push rods (20) are respectively fixedly connected with the second push rods (19) close to the first end (20) and are fixedly connected with the second push rods (18) at two ends of the second push rods (20), the first inclined surface (19) and the second inclined surface (21) slide against each other.

4. The automatic automobile sealing part assembling and buckling integrated machine according to claim 3, wherein the positioning mechanism (25) further comprises a positioning spring (26), a positioning circular ring (27) and two positioning pin shafts (28), the positioning circular ring (27) is arranged below the connecting clamping plate (16), the upper end of the positioning spring (26) is fixedly connected with the connecting clamping plate (16), the lower end of the positioning spring is fixedly connected with the positioning circular ring (27), the two positioning pin shafts (28) are symmetrically arranged on two sides of the positioning spring (26), the lower ends of the two positioning pin shafts (28) are fixedly connected with the positioning circular ring (27), and the upper ends of the positioning pin shafts are in sliding connection with the connecting clamping plate (16).

5. The automatic car sealing part assembling and buckling integrated machine according to claim 1, wherein the clamping and feeding mechanism (29) further comprises a driving motor (30), a reciprocating screw (31), a reciprocating screw sleeve (32), two limiting inserting rods (33), two limiting supports (34) and two traction pull plates (35), the two limiting supports (34) are symmetrically fixedly arranged above the bearing base (8), the driving motor (30) is fixedly connected with one limiting support (34), the reciprocating screw (31) is rotatably arranged between the two limiting supports (34), the output end of the driving motor (30) is fixedly connected with one end of the reciprocating screw (31), the reciprocating screw sleeve (32) is in threaded connection with the reciprocating screw (31), the two limiting inserting rods (33) are symmetrically fixedly arranged on two sides of the reciprocating screw (31), the two sides of the reciprocating screw sleeve (32) are respectively and slidably connected with the two limiting inserting rods (33), the two traction pull plates (35) are symmetrically arranged below the reciprocating screw sleeve (32), and the two traction pull plates (35) are respectively fixedly connected with the lower end of the reciprocating screw sleeve (32).

6. The automatic assembling and buckling integrated machine for automobile sealing parts according to claim 5, wherein the clamping and feeding mechanism (29) further comprises two limiting bottom plates (37), two sliding short shafts (39), two sliding connecting plates (40), two pushing arc strips (41), two tensioning racks (42) and two loosening racks (43), the two limiting bottom plates (37) are symmetrically fixedly arranged above the bearing base (8), the two limiting bottom plates (37) are respectively and slidably connected with the two traction pulling plates (35), the two sliding connecting plates (40) are respectively and slidably connected with the lower ends of the two limiting bottom plates (37), limiting through holes (36) are formed in the traction pulling plates (35), oblique guide holes (38) are formed in the limiting bottom plates (37), the upper parts of the sliding short shafts (39) are slidably connected with the limiting through holes (36), the middle parts are slidably connected with the oblique guide holes (38), the lower parts of the sliding connecting plates (40) are fixedly connected with the two pushing arc strips (41) respectively, the two pushing arc strips (41) are respectively and fixedly connected with the lower ends of the two limiting bottom plates (37), the two sliding arc strips (42) are respectively and fixedly connected with one sides of the two sliding arc strips (8) far away from the bearing base (8).

7. The automatic assembling and buckling integrated machine for automobile sealing parts according to claim 6, wherein the clamping and feeding mechanism (29) further comprises two first gears (44), two second gears (46), two first bevel gears (47), two second bevel gears (48), two sliding gears (49), two positioning racks (50) and two sliding box bodies (51), the two sliding box bodies (51) are respectively fixedly arranged below the two sliding joint plates (40), the two first gears (44) are respectively connected with the lower ends of the two sliding joint plates (40) in a rotating way, the two first gears (44) are respectively connected with the two second gears (46) in a coaxial way through ratchet wheels (45), the two first bevel gears (47) are respectively connected with the two second gears (46) in a coaxial way, the two second bevel gears (48) are respectively meshed with the two first bevel gears (47) in a coaxial way, the two first bevel gears (47) are respectively connected with the two second bevel gears (46) in a coaxial way, the two sliding racks (50) are respectively meshed with the two sliding racks (50) in a fixed way, the two first bevel gears (48) are respectively meshed with the two sliding racks (50) in a fixed way, the two loose racks (43) can be respectively meshed with the two first gears (44).

8. The application method of the automatic automobile sealing part assembling and buckling integrated machine comprises the following application steps:

s1: an operator puts the sealing element body (1) into the upper end of the bearing base (8), and then pushes the sealing element body (1) to move along the long side direction of the bearing base (8);

s2: when the sealing element body (1) is positioned and clamped by a clamping and feeding mechanism (29) close to the inlet of the bearing box (4), the clamping and feeding mechanism (29) is started to drive the sealing element body (1) to move through two sliding clamping plates (52);

s3: the sealing element body (1) can sequentially pass through the puncher (6) and the riveting machine (5) after moving, and after the puncher (6) punches on the sealing element body (1), the riveting machine (5) can press the buckle in the corresponding hole.