CN109304418B

CN109304418B - Automatic riveting assembly line for clutch driven disc

Info

Publication number: CN109304418B
Application number: CN201811492056.8A
Authority: CN
Inventors: 李广平; 葛正; 杨利利; 王维镝; 吴日远; 陈其; 崔坤彤; 王维锐; 徐子轩
Original assignee: Research Institute of Zhejiang University Taizhou
Current assignee: Research Institute of Zhejiang University Taizhou
Priority date: 2018-12-07
Filing date: 2018-12-07
Publication date: 2020-01-03
Anticipated expiration: 2038-12-07
Also published as: CN109304418A

Abstract

The invention provides an automatic riveting assembly line of a clutch driven plate, which comprises a runway-type conveying belt, wherein a first riveting station is arranged at the leftmost part of the front end surface of the runway-type conveying belt, then a first friction plate installing station, a spring plate installing station, a first riveting station, a turning station, a second riveting station, a second friction plate installing station, a fitting station, a second riveting station and a product off-line station are sequentially arranged on the front end surface of the runway-type conveying belt from the first riveting station in a clockwise direction, the first riveting station and the second riveting station are both arranged on the inner side of the runway-type conveying belt, and the second riveting station is arranged at the rightmost part of the front end surface of the runway-type conveying belt.

Description

Automatic riveting assembly line for clutch driven disc

Technical Field

The invention relates to an automatic riveting assembly line for a clutch driven plate, belonging to the field of clutch driven plate production equipment.

Background

In the prior art, rivets, friction plates and spring pieces are generally manually assembled and riveted in the assembly process of the conventional automobile clutch, the operation is complex, the workload is high, and the working efficiency is low, so that an automatic riveting assembly line of a clutch driven plate is needed to solve the problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an automatic riveting production line for a clutch driven disc, which is used for solving the problems in the background art.

In order to achieve the purpose, the invention is realized by the following technical scheme: automatic assembly line that rivets of clutch driven plate, including runway type conveyer belt, the first dress rivet station is placed to runway type conveyer belt front end face leftmost portion, then the first dress rivet station of terminal surface according to clockwise beginning from the first dress rivet station before the runway type conveyer belt, arranges dress first piece friction disc station, dress spring plate station, the first riveting station in proper order, upset station, the second dress rivet station, dress second piece friction disc station, laminating station, the second time riveting station and the product station of inserting the production line, the first time riveting station and the second time riveting station equipartition are arranged at runway type conveyer belt inboardly, the second time dress rivet station is arranged at runway type conveyer belt front end face rightmost portion.

In an embodiment, dress rivet station includes full-automatic rivet material loading machine and frock board for the first time, the terminal surface before runway type conveyer belt is placed to the frock board, and the fixed eight location axles that have the step of terminal surface equidistance before the frock board.

In an embodiment, dress first friction disc station includes friction disc rack, friction disc transfer mechanism and friction disc conveying mechanism, friction disc transfer mechanism includes friction disc, friction disc rotation axis, servo motor one, sensor mounting panel one and sensor one, the friction disc is arranged to the terminal surface before the friction disc rotation axis, servo motor one is fixed to friction disc rotation axis rear end, servo motor one annular side fixed sensor mounting panel one, sensor mounting panel one is fixed to the terminal surface before one, and sensor one arranges at friction disc rotation axis rear side, friction disc conveying mechanism includes clamp plate one, cylinder one, gripper jaw one and guiding orientation cotter board one.

In an embodiment, the spring piece loading station comprises a spring piece placing frame, a spring piece transfer mechanism and a spring piece conveying mechanism, the spring piece transfer mechanism comprises a spring piece, a spring piece rotating shaft, a second servo motor, a second sensor mounting plate, a second sensor and a third sensor, the spring piece is arranged on the front end face of the spring piece rotating shaft, the second servo motor is fixed on the rear end of the spring piece rotating shaft, the second servo motor is fixed on the annular side face of the second servo motor, the third sensor is fixed on the front end face of the second sensor mounting plate, the third sensor is arranged on the rear side of the spring piece rotating shaft, the second sensor is fixed on the middle position of.

In one embodiment, the first riveting station comprises a squeeze riveter.

In one embodiment, the overturning station comprises an assembly clamping and overturning mechanism, an assembly conveying mechanism and an assembly transfer mechanism, the assembly transfer mechanism comprises an assembly rotating shaft, a third servo motor, a third sensor mounting plate, a fourth sensor and a fifth sensor, the assembly formed by combining a spring piece and a friction piece is arranged on the front end face of the assembly rotating shaft, the third servo motor is fixed on the rear end of the assembly rotating shaft, the third sensor mounting plate is fixed on the annular side face of the third servo motor, the fifth sensor is fixed on the front end face of the third sensor mounting plate, the fifth sensor is arranged on the rear side of the assembly rotating shaft, and the fourth sensor is fixed in the middle position of the front.

In an embodiment, the second riveting station has the same structure as the first riveting station, the second friction plate loading station has the same structure as the first friction plate loading station, the second riveting station has the same structure as the first riveting station, and the product unloading station comprises a product unloading mechanism and a product frame.

The invention has the beneficial effects that: according to the automatic riveting assembly line for the clutch driven plate, the first riveting station, the first friction plate mounting station, the spring plate mounting station, the first riveting station, the overturning station, the second riveting station, the second friction plate mounting station, the attaching station, the second riveting station and the product offline station are added, the automatic assembling and riveting of the clutch driven plate are realized through the design, the automatic riveting assembly line is simple to operate, short in working time and high in working efficiency, and the problems that the rivet, the friction plate and the spring plate are generally manually assembled and riveted in the assembling process of the conventional automobile clutch, the operation is complex and the workload is large are solved.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic view of a system for an automatic riveting line of a clutch driven plate according to the present invention;

FIG. 2 is a schematic structural view of an automatic riveting production line of a clutch driven plate according to the present invention;

FIG. 3 is a schematic front view of a tooling plate in the automatic clutch driven plate riveting line of the present invention;

FIG. 4 is a schematic top view of a tooling plate in the automatic clutch driven plate riveting line of the present invention;

FIG. 5 is a schematic cross-sectional view of a tooling plate and a positioning shaft in the automatic riveting production line of the clutch driven plate according to the present invention;

FIG. 6 is a schematic view of a friction plate transfer mechanism in the clutch driven plate automatic riveting assembly line according to the present invention;

FIG. 7 is a schematic view of the clamping and positioning of friction plates in the automatic riveting assembly line of the clutch driven plate according to the present invention;

FIG. 8 is a schematic front view of a first guide locating pin plate in the automatic riveting assembly line of the clutch driven plate according to the invention;

FIG. 9 is a schematic bottom view of a first guide locating pin plate in the automatic clutch driven plate riveting line of the present invention;

FIG. 10 is a schematic view of a first friction plate loading station in the automatic clutch driven plate riveting line of the present invention;

FIG. 11 is a schematic view of the spring plate rotating shaft in the clutch driven plate automatic riveting assembly line of the present invention;

FIG. 12 is a schematic view of a spring plate pivoting mechanism in the clutch driven plate automatic riveting assembly line of the present invention;

FIG. 13 is a schematic view of the assembly of the vacuum chuck and the spring plate in the automatic riveting line of the clutch driven plate according to the present invention;

FIG. 14 is a schematic front view of a second guide positioning pin plate in the automatic riveting assembly line of the clutch driven plate according to the invention;

FIG. 15 is a schematic bottom view of a second guide positioning pin plate in the automatic riveting assembly line of the clutch driven plate according to the present invention;

FIG. 16 is a schematic view of a spring plate loading station in the automatic clutch driven plate riveting line of the present invention;

FIG. 17 is a schematic view of the transfer mechanism of the assembly in the automatic riveting production line of the clutch driven plate according to the invention.

In the figure: 1-a first rivet loading station, 2-a first friction plate loading station, 3-a spring plate loading station, 4-a first riveting station, 5-a turning station, 6-a second rivet loading station, 7-a second friction plate loading station, 8-a laminating station, 9-a second riveting station, 10-a product unloading station, 11-a full-automatic rivet feeding machine, 12-a tooling plate, 21-a friction plate conveying mechanism, 22-a friction plate transfer mechanism, 23-a friction plate placing frame, 31-a spring plate conveying mechanism, 32-a spring plate placing frame, 33-a spring plate transfer mechanism, 41-a rivet pressing machine, 51-an assembly clamping and turning mechanism, 52-a conveying assembly mechanism, 53-an assembly transfer mechanism, 101-a product unloading mechanism, a rivet loading mechanism, 102-product rack, 211-first pressing plate, 213-first clamping jaw, 214-first guide positioning pin plate, 221-friction plate, 222-friction plate rotating shaft, 223-first servo motor, 224-first sensor mounting plate, 225-first sensor, 311-second pressing plate, 314-second guide positioning pin plate, 315-vacuum chuck, 331-spring plate, 332-spring plate rotating shaft, 333-second servo motor, 334-second sensor mounting plate, 335-second sensor, 336-third sensor, 531-assembly rotating shaft, 532-third servo motor, 533-third sensor mounting plate, 534-fourth sensor and 535-fifth sensor.

Detailed Description

Before the embodiments are described in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings. The invention is capable of embodiments in other forms of implementation. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of "including," "comprising," "having," and the like, herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. In particular, when "a certain element" is described, the present invention is not limited to the number of the element being one, and may include a plurality of the elements.

Referring to fig. 1-17, the present invention provides a technical solution: the automatic riveting assembly line of the clutch driven plate comprises a runway-type conveying belt, wherein a first riveting station 1 is arranged at the leftmost part of the front end face of the runway-type conveying belt, then a first friction plate mounting station 2, a spring plate mounting station 3, a first riveting station 4, a turning station 5, a second riveting station 6, a second friction plate mounting station 7, a laminating station 8, a second riveting station 9 and a product unloading station 10 are sequentially arranged on the front end face of the runway-type conveying belt from the first riveting station 1 in a clockwise direction, the first riveting station 4 and the second riveting station 9 are uniformly arranged on the inner side of the runway-type conveying belt, the second riveting station 6 is arranged at the rightmost part of the front end face of the runway-type conveying belt, a full-automatic riveting machine is convenient for sleeving rivets on positioning shafts on a tooling plate 12, and then the tooling plate 12 is driven to move by the runway-type conveying belt, then the rivet is driven to move, then the friction plate conveying mechanism 21 takes the friction plate 221 off the friction plate placing frame 23 and is sleeved on the friction plate rotating shaft 222, then the friction plate rotating shaft 222 is rotated through a servo motor I223 to drive the friction plate 221 to rotate, then the position of the friction plate 221 is detected through a sensor I225 to adjust the position of the friction plate 221, then a clamping claw I213 is driven by an air cylinder to move so as to clamp the friction plate 221, a guiding and positioning pin plate I214 penetrates through the friction plate 221 to guide the friction plate 221, then the friction plate conveying mechanism 21 drives the friction plate 221 to move right above the tool plate 12, then a pin shaft at the lower end of the guiding and positioning pin plate I214 extends into an inner hole in the rivet, then the pressure plate I211 is driven by the air cylinder to move downwards so as to drive the friction plate 221 to move downwards, therefore, the friction plate 221 is sleeved on the rivet, the tooling plate 12 is continuously moved, then the spring piece 331 is taken down from the spring piece placing frame 32 by the spring piece conveying mechanism 31 and moved to the position above the spring piece transferring mechanism 33, the second sensor 335 rotates and monitors the position of the spring piece, the spring piece is sleeved on the rotating shaft 332 after the positions are aligned, then the position of the spring piece 331 is detected by the third sensor 336, then the rotating shaft 332 of the spring piece is rotated by the second servo motor 333 to drive the spring piece 331 to rotate, so that the position of the spring piece 331 is adjusted and positioned, then the vacuum suction cup 315 is driven to move by the second cylinder of the spring piece conveying mechanism 31 to further perform vacuum suction on the spring piece 331, and the second guiding and positioning pin plate 314 passes through the spring piece 331 to guide the spring piece 331, and then the spring piece 331 is moved to the position above the tooling plate, then a pin shaft at the lower end of the second guide positioning pin plate 314 extends into an inner hole on the rivet, then the second pressing plate 311 is driven to move downwards through the second air cylinder, and further the spring leaf 331 is driven to move downwards, so that the spring leaf 331 is sleeved on the rivet, then the tooling plate 12 is continuously moved, then the friction plate 221 and the spring leaf 331 are pressed and riveted through the riveting press 41, then the assembly formed by the friction plate 221 and the spring leaf 331 is overturned for 180 degrees through the assembly clamping and overturning mechanism 51, then the assembly conveying mechanism 52 is conveyed to the upper part of the assembly transfer mechanism 53, the sensor four 534 is rotationally positioned and aligned to the positioning hole through the third servo motor 532, the assembly is sleeved on the assembly rotating shaft 531, the position of the assembly is adjusted through the third servo motor 532, then the assembly is conveyed to the tooling plate 12, then the tooling plate 12 is continuously moved, so that the rivet mounting for the second time and the second friction, the working principle of the second riveting station 6 is the same as that of the first riveting station 1, the working principle of the second friction plate installing station 7 is the same as that of the first friction plate installing station 2, then the tooling plate 12 provided with the rivet and the second friction plate 221 is conveyed to the fitting station 8 firstly, the rivet penetrates through the assembly, the working principle of the second riveting station 9 is the same as that of the first riveting station 4, and then the product is taken off line through the product off-line mechanism 101 and the product frame 102.

First dress rivet station 1 includes full-automatic rivet material loading machine 11 and frock board 12, and the terminal surface before runway type conveyer belt is placed to frock board 12, and the fixed eight location axles that have the step of terminal surface equidistance before the frock board 12.

The first friction plate mounting station 2 comprises a friction plate placing frame 23, a friction plate transfer mechanism 22 and a friction plate conveying mechanism 21, the friction plate transfer mechanism 22 comprises a friction plate 221, a friction plate rotating shaft 222, a first servo motor 223, a first sensor mounting plate 224 and a first sensor 225, the friction plate 221 is arranged on the front end face of the friction plate rotating shaft 222, the first servo motor 223 is fixed on the rear end of the friction plate rotating shaft 222, the first sensor mounting plate 224 is fixed on the annular side face of the first servo motor 223, the first sensor 225 is fixed on the front end face of the first sensor mounting plate 224, the first sensor 225 is arranged on the rear side of the friction plate rotating shaft 222, and the friction plate conveying mechanism 21 comprises a first pressing plate 211, a.

The spring piece loading station 3 comprises a spring piece placing frame 32, a spring piece transfer mechanism 33 and a spring piece conveying mechanism 31, wherein the spring piece transfer mechanism 33 comprises a spring piece 331, a spring piece rotating shaft 332, a second servo motor 333, a second sensor mounting plate 334, a second sensor 335 and a third sensor 336, the spring piece 331 is arranged on the front end face of the spring piece rotating shaft 332, the second servo motor 333 is fixed on the rear end of the spring piece rotating shaft 332, the second sensor mounting plate 334 is fixed on the annular side face of the second servo motor 333, the third sensor 336 is fixed on the front end face of the second sensor mounting plate 334, the third sensor 336 is arranged on the rear side of the spring piece rotating shaft 332, the second sensor 335 is fixed in the middle of the front end face of the spring piece rotating shaft 332, and the.

The first riveting station 4 comprises a squeeze riveter 41.

The overturning station 5 comprises an assembly clamping and overturning mechanism 51, an assembly conveying mechanism 52 and an assembly transfer mechanism 53, wherein the assembly transfer mechanism 53 comprises an assembly rotating shaft 531, a three servo motor 532, a three sensor mounting plate 533, a four sensor 534 and a five sensor 535, the assembly formed by combining the spring piece 331 and the friction plate 221 is arranged on the front end face of the assembly rotating shaft 531, the three servo motor 532 is fixed on the rear end of the assembly rotating shaft 531, the three servo motor 532 is fixed on the annular side face of the three servo motor 533, the five sensor 535 is fixed on the front end face of the three sensor mounting plate 533, the five sensor 535 is arranged on the rear side of the assembly rotating shaft 531, and the four sensor 534 is fixed in.

The second riveting station 6 is the same as the first riveting station 1 in structure, the second friction plate installing station 7 is the same as the first friction plate installing station 2 in structure, the second riveting station 9 is the same as the first riveting station 4 in structure, and the product unloading station 10 comprises a product unloading mechanism 101 and a product frame 102.

The concepts described herein may be embodied in other forms without departing from the spirit or characteristics thereof. The particular embodiments disclosed should be considered illustrative rather than limiting. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. Any changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims

1. Automatic assembly line that rivets of clutch driven plate, including runway type conveyer belt, its characterized in that: a first rivet installing station is arranged at the leftmost part of the front end face of the runway type conveying belt and comprises a full-automatic rivet feeding machine and a tooling plate, the tooling plate is arranged on the front end face of the runway type conveying belt, and eight positioning shafts with steps are fixed on the front end face of the tooling plate at equal intervals; then, the front end face of the runway type conveyor belt is sequentially provided with a first friction plate mounting station, a spring plate mounting station, a first riveting station, a turning station, a second riveting station, a second friction plate mounting station, a fitting station, a second riveting station and a product off-line station from a first riveting station in a clockwise direction, wherein the first riveting station and the second riveting station are both arranged on the inner side of the runway type conveyor belt, and the second riveting station is arranged on the rightmost part of the front end face of the runway type conveyor belt; the station for mounting the first friction plate comprises a friction plate placing frame, a friction plate transfer mechanism and a friction plate conveying mechanism, wherein the friction plate transfer mechanism comprises a friction plate, a friction plate rotating shaft, a first servo motor, a first sensor mounting plate and a first sensor, the friction plate is arranged on the front end face of the friction plate rotating shaft, the first servo motor is fixed on the rear end of the friction plate rotating shaft, the first sensor mounting plate is fixed on the annular side face of the first servo motor, the first sensor is fixed on the front end face of the first sensor mounting plate, the first sensor is arranged on the rear side of the friction plate rotating shaft, the friction plate conveying mechanism comprises a first pressing plate, a first air cylinder, a first clamping jaw and a first guiding and positioning pin plate, the first friction plate rotating shaft is rotated through the first servo motor to drive the friction plate, then, the first clamping claw is driven to move through the air cylinder, the friction plate is clamped, the first guiding and positioning pin plate penetrates through the friction plate, the friction plate is guided, then the friction plate conveying mechanism drives the friction plate to move right above the tooling plate, then a pin shaft at the lower end of the first guiding and positioning pin plate extends into an inner hole in the rivet, then the first driving plate is driven to move downwards through the air cylinder, the friction plate is driven to move downwards, and therefore the friction plate is sleeved on the rivet.

2. The automatic riveting line for clutch driven plates according to claim 1, characterized in that: the spring piece loading station comprises a spring piece placing rack, a spring piece transfer mechanism and a spring piece conveying mechanism, the spring piece transfer mechanism comprises a spring piece, a spring piece rotating shaft, a second servo motor, a second sensor mounting plate, a second sensor and a third sensor, the spring piece is arranged on the front end face of the spring piece rotating shaft, the second servo motor is fixed on the rear end face of the spring piece rotating shaft, the second sensor mounting plate is fixed on the annular side face of the second servo motor, the third sensor is fixed on the front end face of the second sensor mounting plate, the second sensor is fixed on the middle position of the front end face of the spring piece rotating shaft, the spring piece conveying mechanism comprises a second pressing plate, a second air cylinder, a second guiding positioning pin plate and a vacuum sucking disc, thereby lead to the spring leaf, then move the spring leaf directly over the frock board, then the round pin axle of two lower extremes of direction locating pin board stretches into the downthehole on the rivet, then drive clamp plate two through cylinder two and move down, and then drive the spring leaf and move down to realize the spring leaf suit on the rivet.

3. The automatic riveting line for clutch driven plates according to claim 1, characterized in that: the first riveting station comprises a squeeze riveter.

4. The automatic riveting line for clutch driven plates according to claim 1, characterized in that: the turnover station comprises a combined piece clamping turnover mechanism, a combined piece conveying mechanism and a combined piece transfer mechanism, wherein the combined piece transfer mechanism comprises a combined piece rotating shaft, a third servo motor, a third sensor mounting plate, a fourth sensor and a fifth sensor, the combined piece formed by combining a spring piece and a friction piece is arranged on the front end face of the combined piece rotating shaft, the third servo motor is fixed on the rear end of the combined piece rotating shaft, the third sensor mounting plate is fixed on the three annular side face of the servo motor, the fifth sensor is fixed on the front end face of the third sensor mounting plate, the fifth sensor is arranged on the rear side of the combined piece rotating shaft, and the fourth sensor.

5. The automatic riveting line for clutch driven plates according to claim 1, characterized in that: the second riveting station is the same as the first riveting station in structure, the second friction plate loading station is the same as the first friction plate loading station in structure, the second riveting station is the same as the first riveting station in structure, and the product inserting station comprises a product inserting mechanism and a product frame.