CN115890125A - Welding device for machining outer cylinder of automobile shock absorber - Google Patents

Abstract

The invention provides a welding device for processing an outer cylinder of an automobile shock absorber, which relates to the field of processing machinery of the automobile shock absorber and comprises the following components: welding a pedestal; the right side of the welding pedestal is fixedly connected with a control panel through a screw; the automatic welding arm is fixedly connected to the rear side of the upper surface of the welding pedestal through a bolt and is connected with the control panel through an electric connecting line; in the process of fixing two sections of outer cylinders of the shock absorber with different outer diameters, the coaxiality deviation of the two sections of the outer cylinders can be guaranteed to be unchanged, welding deviation caused by different outer diameters of two workpieces to be welded can not be received when the cylinders are welded, the two workpieces are driven to synchronously rotate at a constant speed, the welding seam structure in the girth welding process is uniform, the problems that the adjustment mode of the workpieces to be welded after the outer cylinders are fixed is troublesome, the operation is difficult, when the welding seam is to be girth welded after the workpieces are fixed, the workpieces are not easy to drive to rotate at the constant speed, and the welding precision is not easy to control are solved.

Description

Welding device for machining outer cylinder of automobile shock absorber

Technical Field

The invention relates to the technical field of automobile shock absorber machining machinery, in particular to a welding device for machining an outer cylinder of an automobile shock absorber.

Background

The bumper shock absorber is used for suppressing the shock of spring when inhaling the shock-absorbing back bounce and the impact that comes from the road surface, extensively be used for the car, for the decay of accelerating frame and automobile body vibration, in order to improve the ride comfort of car, when the road surface is uneven, the bumper shock absorber can be used for suppressing spring self reciprocating motion jump, the outer tube of automobile bumper shock absorber passes through the fixed equipment connection of mode of girth welding, in actual operation, need use anchor clamps to fix the bumper shock absorber outer tube, then carry out the whole week girth welding along the butt joint through artifical or welding robot.

However, in the existing welding device for assembling the outer cylinder of the shock absorber, two sections of the outer cylinders of the shock absorber are respectively fixed through two sets of clamps, the welding position of the outer cylinders is accurately fixed, the adjusting mode of the welded workpiece after the outer cylinders are fixed is troublesome, the operation is difficult, when the welded joint is subjected to girth welding after the workpiece is fixed, the workpiece is not easy to drive to rotate at a constant speed, and the welding precision is not easy to control.

Disclosure of Invention

In view of the above, the invention provides a welding device for processing an outer cylinder of an automobile shock absorber, which is used for solving the problems that in the existing welding device for assembling the outer cylinder of the shock absorber, two sections of outer cylinders of the shock absorber are respectively fixed through two sets of clamps, the welding position of the outer cylinder is accurately fixed, the adjustment mode of a welded workpiece after the outer cylinder is fixed is troublesome, the operation is difficult, when a seam is subjected to girth welding after the workpiece is fixed, the workpiece is not easily driven to rotate at a constant speed, and the welding precision is not easily controlled.

The invention provides a welding device for processing an outer cylinder of an automobile shock absorber, which specifically comprises the following components: welding a pedestal; the right side of the welding pedestal is fixedly connected with a control panel through a screw; the automatic welding arm is fixedly connected to the rear side of the upper surface of the welding pedestal through a bolt and is connected with the control panel through an electric connecting line; the outer cylinder pushing cylinder is fixedly connected to the left side above the welding pedestal through a screw, and the right end of a push rod of the outer cylinder pushing cylinder is rotatably connected with a pushing rotary disc through a bearing; the positioning driving piece is provided with two positions, the two positions are fixedly connected inside the welding pedestal, and an output rod of the positioning driving piece is fixedly connected with a driving worm through a coupler; the middle rotating shaft is provided with two positions, and the two positions of the middle rotating shaft are both rotatably connected to the inner bottom surface of the welding pedestal; the device comprises a welding pedestal, a plurality of translation clamping tables, a plurality of welding rods and a plurality of welding rods, wherein the welding pedestal is provided with a plurality of welding holes; weld drive servo motor soon, weld drive servo motor soon and pass through bolt fixed connection on the translation of left side rear presss from both sides the platform, and weld drive servo motor's output shaft fixedly connected with initiative adjustment soon the tooth soon.

Further, the platform is placed to the upper surface left side of welding pedestal through welded connection with pushing cylinder, and the upper surface of welding pedestal has two sets of positioning guide frame through welded connection, props the platform in the middle of the fixedly connected with of the upper surface of welding pedestal, and the upper surface right side of welding pedestal has the spacing extension board in the right side through welded connection, and the spacing extension board in the right side is perpendicular to the upper surface of welding pedestal.

Furthermore, two positioning guide rods are fixedly connected to the positioning guide frame, two ends of each positioning guide rod are connected to the front surface and the rear surface of the inner portion of the positioning guide frame through welding, the two positioning guide rods are parallel to each other, and the axes of the two positioning guide rods are perpendicular to the front surface of the welding pedestal.

Furthermore, the upper surface of middle brace table is rotated through the bearing and is connected with two direction supporting wheels, and arc groove structure has been seted up on the wheel face of direction supporting wheel to the front surface of direction supporting wheel axis perpendicular to welding pedestal.

Furthermore, the left side of the upper end of the right limiting support plate is movably connected with a right limiting rotary disc, the shaft body of the right limiting rotary disc is rotatably connected onto the right limiting support plate through a bearing, and the right surface of the right limiting rotary disc is convexly processed with an outer edge.

Furthermore, the middle of the middle rotating shaft is connected with a driven worm wheel through interference fit, the upper end of the middle rotating shaft is connected with a driving gear through interference fit, the driven worm wheel is meshed with a driving worm, and the driven worm wheel and the driving worm form worm and gear transmission.

Furthermore, two lower guide holes are formed in the lower end of the translation clamping table, a synchronous rack is fixedly connected to the inner surface of the translation clamping table, the synchronous rack is perpendicular to the inner surface of the translation clamping table, the lower guide holes are connected to the positioning guide rods in a sliding mode, the synchronous rack is meshed with the driving gear, and the synchronous rack and the driving gear form gear-rack transmission.

Furthermore, the upper surface of the translation clamping table is connected with a longitudinal connecting column through welding, and the longitudinal connecting column is perpendicular to the upper surface of the translation clamping table.

Furthermore, the upper part of the inner surface of the longitudinal connecting column is connected with a synchronous clamping plate through welding, and the synchronous clamping plate is of an arc-shaped bent plate body structure.

Furthermore, the inner surface of the synchronous clamping plate is rotatably connected with four positioning clamping wheels through bearings, the axes of the positioning clamping wheels face to the transverse direction, the right end of the upper positioning clamping wheel shaft body of the left rear synchronous clamping plate is fixedly connected with a driven adjusting rotary tooth through interference fit, the driven adjusting rotary tooth is meshed with a driving adjusting rotary tooth, and the driven adjusting rotary tooth and the driving adjusting rotary tooth form gear transmission.

Advantageous effects

1. The welding fixture comprises a cylindrical outer cylinder of the shock absorber, a driving worm and a driven worm, wherein the driving worm and the driven worm are in transmission with a middle rotating shaft, the driving gear is in transmission with two groups of synchronous racks, the two translation clamping tables on the same side are driven to move inwards together, two synchronous clamping plates synchronously move towards the middle, the positioning clamping wheels are in surface contact with the shock absorber, the shock absorber outer cylinder is in synchronous contact with four positioning clamping wheels at the moment, the shock absorber outer cylinder is clamped with the shock absorber outer cylinder, the shock absorber outer cylinder is in contact with the shock absorber outer cylinder in four directions, the axis of the shock absorber outer cylinder is kept in the middle of the four positioning clamping wheels, and when the shock absorber outer cylinder with different outer diameters is fixed, the axis of the shock absorber outer cylinder can be kept not to deviate all the time, and the welding fixture of the two sections of the shock absorber outer cylinders with different outer diameters can not cause deviation because the two sections of the outer cylinders are coaxially welded on the same assembly table.

2. According to the invention, after a workpiece is radially fixed through a synchronous clamping plate and a positioning clamping wheel, the positioning clamping wheel is in rolling connection with an outer cylinder of a cylindrical workpiece, the positioning clamping wheel on the upper side of the left rear part is fixed by a spin welding driving servo motor, and the positioning clamping wheel is limited from freely rotating, so that the circumferential fixation of a left cylinder is realized, two workpieces to be welded are placed on positioning mechanisms on two sides for clamping before the workpiece is welded, the action of an outer cylinder pushing cylinder is controlled, a pushing rotary disc is pushed to move rightwards, the left workpiece is pushed rightwards, after the two workpieces are contacted, the workpiece is limited through a right limiting rotary disc on the right side, the axial fixation of the workpiece is realized through pushing the pushing rotary disc and the right limiting rotary disc, the position adjustment mode of the workpiece is simple and convenient, the workpiece butting precision is high, and the welding precision is favorably improved; after the butt joint is finished, controlling the spin welding to drive a servo motor to rotate, driving a positioning clamping wheel on the upper left rear side to rotate through gear transmission of a driving adjusting rotary tooth and a driven adjusting rotary tooth, driving the positioning clamping wheel to rotate through rolling connection of the positioning clamping wheel and a workpiece, driving the workpiece to rotate circumferentially, enabling the two workpieces to rotate synchronously through friction force between contact surfaces of the two workpieces, and operating an automatic welding arm to be close to a joint of the two workpieces to perform girth welding on the joint while the two outer cylinders rotate; the two workpieces are driven to synchronously rotate at a constant speed, the position precision between the two workpieces is ensured, the welding seam structure is uniform in the girth welding process, and the welding high precision is ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to some embodiments of the invention only and are not intended to limit the invention.

In the drawings:

fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic structural view of the left side of the embodiment of the present invention.

Fig. 3 is a schematic structural diagram of the rear of the embodiment of the present invention.

FIG. 4 is a schematic structural diagram of a translation stage according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an intermediate rotating shaft in an embodiment of the invention.

Fig. 6 is a schematic structural view of a synchronous splint according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a positioning mechanism according to an embodiment of the present invention.

Fig. 8 is a partially enlarged structural schematic diagram at a in fig. 1 according to an embodiment of the present invention.

Fig. 9 is a partially enlarged structural schematic diagram at B of fig. 4 according to an embodiment of the present invention.

Fig. 10 is a partially enlarged structural view at C of fig. 7 according to an embodiment of the present invention.

List of reference numerals

1. Welding a pedestal; 101. a cylinder pushing placing table; 102. positioning a guide frame; 1021. positioning the guide rod; 103. a middle support table; 1031. a guide supporting wheel; 104. a right limiting support plate; 1041. a right limiting rotary disc; 2. a control panel; 3. automatically welding the arm; 4. the outer cylinder pushes the cylinder; 401. a propelling rotating disc; 5. positioning a driving piece; 501. a driving worm; 6. an intermediate rotating shaft; 601. a driven worm gear; 602. a driving gear; 7. a translation clamping table; 701. a lower guide hole; 702. a synchronous rack; 703. connecting columns longitudinally; 704. synchronous clamping plates; 7041. positioning a pinch roller; 7042. the driven adjusting rotary teeth; 8. driving a servo motor by spin welding; 801. the rotary teeth are actively adjusted.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

Example (b): please refer to fig. 1 to 10:

the invention provides a welding device for processing an outer cylinder of an automobile shock absorber, which comprises: welding the pedestal 1; the right side of the welding pedestal 1 is fixedly connected with a control panel 2 through a screw; the automatic welding arm 3 is fixedly connected to the rear side of the upper surface of the welding pedestal 1 through bolts, and the automatic welding arm 3 is connected with the control panel 2 through an electric connecting line; the outer cylinder pushing cylinder 4 is fixedly connected to the left side above the welding pedestal 1 through a screw, the right end of a pushing rod of the outer cylinder pushing cylinder 4 is rotatably connected with a pushing rotary disc 401 through a bearing, the right side of the upper surface of the welding pedestal 1 is connected with a right limiting support plate 104 through welding, the right limiting support plate 104 is perpendicular to the upper surface of the welding pedestal 1, the left side of the upper end of the right limiting support plate 104 is movably connected with a right limiting rotary disc 1041, a shaft body of the right limiting rotary disc 1041 is rotatably connected to the right limiting support plate 104 through a bearing, an outer edge is formed in the right surface of the right limiting rotary disc 1041 in a protruding mode, the right end of a workpiece is limited through the right limiting rotary disc 1041, the radial positioning of the workpiece is realized, two workpieces to be welded are placed on positioning mechanisms on two sides to be clamped before the workpiece is welded, the outer cylinder pushing cylinder 4 is controlled to move rightwards, the pushing rotary disc 401 pushes the left workpiece, the two workpieces are contacted, the workpiece is limited through the right limiting rotary disc 1041 on the right side, the workpiece, the axial fixing of the workpiece is realized through the pushing rotary disc 401 and the right limiting rotary disc 1041, the workpiece is conveniently adjusted, the position of the workpiece, the workpiece is convenient position adjustment mode, and the high butt joint precision of the workpiece is favorable for improving the welding precision; the welding bench is characterized by comprising a positioning driving piece 5, wherein the positioning driving piece 5 is provided with two positions, the two positioning driving pieces 5 are fixedly connected inside the welding bench 1, and an output rod of the positioning driving piece 5 is fixedly connected with a driving worm 501 through a coupler; the middle rotating shaft 6 is provided with two positions, and the two positions of the middle rotating shaft 6 are both rotatably connected to the inner bottom surface of the welding pedestal 1; the welding bench is characterized by comprising four translation clamping tables 7, wherein every two translation clamping tables 7 form a group, and the two translation clamping tables 7 are movably connected inside the welding bench 1; spin welding drive servo motor 8, spin welding drive servo motor 8 passes through bolt fixed connection on the translation clamp 7 at left side rear, and spin welding drive servo motor 8's output shaft fixedly connected with initiative adjustment revolves tooth 801.

The left side of the upper surface of the welding pedestal 1 is connected with a push cylinder placing table 101 through welding, the outer cylinder push cylinder 4 is installed through the push cylinder placing table 101, the upper surface of the welding pedestal 1 is connected with two groups of positioning guide frames 102 through welding, two positioning guide rods 1021 are fixedly connected to the positioning guide frames 102, two ends of each positioning guide rod 1021 are connected to the front surface and the rear surface inside the positioning guide frame 102 through welding, the two positioning guide rods 1021 are parallel to each other, the axes of the two positioning guide rods 1021 are perpendicular to the front surface of the welding pedestal 1, the positioning guide rods 1021 are slidably connected with a lower guide hole 701 and play a role in guiding, an intermediate supporting table 103 is fixedly connected to the middle of the upper surface of the welding pedestal 1, the upper surface of the intermediate supporting table 103 is rotatably connected with two guide supporting wheels 1031 through bearings, the axes of the guide supporting wheels 1031 are perpendicular to the front surface of the welding pedestal 1, arc-shaped groove structures are formed in the wheel surfaces of the guide supporting wheels 1031, and play a role in supporting workpieces on the left side.

The middle of the middle rotating shaft 6 is connected with a driven worm wheel 601 in an interference fit manner, the upper end of the middle rotating shaft 6 is connected with a driving gear 602 in an interference fit manner, the driven worm wheel 601 is meshed with a driving worm 501, the driven worm wheel 601 and the driving worm 501 form worm and gear transmission, the lower end of the translation clamping table 7 is provided with two lower guide holes 701, the inner surface of the translation clamping table 7 is fixedly connected with a synchronous rack 702, the synchronous rack 702 is perpendicular to the inner surface of the translation clamping table 7, the lower guide holes 701 are connected to a positioning guide rod 1021 in a sliding manner, the synchronous rack 702 is meshed with the driving gear 602, and the synchronous rack 702 and the driving gear 602 form gear and rack transmission; the driving worm 501 and the worm gear of the driven worm gear 601 drive the middle rotating shaft 6 to rotate, and the driving gear 602 and the synchronous gear rack of the two groups of synchronous racks 702 drive the two translation clamping tables 7 on the same side to move inwards together.

The upper surface of the translation clamping table 7 is connected with a longitudinal connecting column 703 through welding, the longitudinal connecting column 703 is perpendicular to the upper surface of the translation clamping table 7, a synchronous clamping plate 704 is connected above the inner surface of the longitudinal connecting column 703 through welding, and the synchronous clamping plate 704 is of an arc-shaped bent plate body structure; the inner surface of the synchronous clamping plate 704 is rotatably connected with four positioning clamping wheels 7041 through bearings, the axes of the positioning clamping wheels 7041 face the transverse direction, the right end of the shaft body of the positioning clamping wheel 7041 positioned above the left rear synchronous clamping plate 704 is fixedly connected with driven adjusting rotary teeth 7042 in an interference fit mode, the driven adjusting rotary teeth 7042 are meshed with driving adjusting rotary teeth 801, and the driven adjusting rotary teeth 7042 and the driving adjusting rotary teeth 801 form gear transmission; when the two translation clamping tables 7 move inwards together, the two synchronous clamping plates 704 move towards the middle synchronously, so that the positioning clamping wheel 7041 is in surface contact with the outer cylinder of the shock absorber, at the moment, the outer cylinder of the shock absorber is in synchronous contact with the positioning clamping wheels 7041 at four positions, the outer cylinder of the shock absorber is clamped, the outer cylinder of the shock absorber is in contact with the outer cylinder of the shock absorber in four directions, the axis of the outer cylinder of the shock absorber is kept in the middle of the positioning clamping wheels 7041 at four positions, and when the outer cylinders of the shock absorbers with different outer diameters are fixed, the axis of the outer cylinder of the shock absorber can be kept from shifting all the time.

The specific use mode and function of the embodiment are as follows: in the invention, firstly, two workpieces to be welded are placed on positioning mechanisms at two sides, the positioning driving part 5 is controlled to act, the middle rotating shaft 6 is driven to rotate through the transmission of the driving worm 501 and the worm gear of the driven worm gear 601, the two translation clamping platforms 7 at the same side are driven to move inwards together through the transmission of the driving gear 602 and the synchronous gear racks of the two groups of synchronous racks 702, the two synchronous clamping plates 704 synchronously move towards the middle, the positioning clamping wheel 7041 is contacted with the outer cylinder surface of the shock absorber, at the moment, the outer cylinder of the shock absorber is synchronously contacted with the positioning clamping wheels 7041 at four positions to clamp the outer cylinder of the shock absorber, the axis of the outer cylinder of the shock absorber is kept at the middle of the positioning clamping wheel 7041 at four positions through the contact of the outer cylinder of the shock absorber in four directions, and the outer cylinder pushing cylinder 4 is controlled to act, promote to impel capstan 401 and move right, promote the left side work piece right, after two work pieces contact, carry on spacingly through right spacing capstan 1041 on right side to the work piece, realize the axial fixity of work piece through impel capstan 401 and right spacing capstan 1041, after the butt joint is accomplished, control welds the rotation of drive servo motor 8 soon, gear drive through initiative regulation spiral tooth 801 and driven regulation spiral tooth 7042 drives the location clamp wheel 7041 rotation of left rear upside, through the roll connection of here location clamp wheel 7041 and work piece, it can drive the work piece and carry out the circumference and rotate to drive the work piece, and through the frictional force between two work piece contact surfaces, make two work piece synchronous rotations, when two urceolus are rotatory, control automatic weld arm 3 and be close to two work piece joints, carry out the girth joint.

Finally, it should be noted that, when describing the positions of the components and the matching relationship therebetween, the present invention is usually illustrated by one/a pair of components, however, it should be understood by those skilled in the art that such positions, matching relationship, etc. are also applicable to other/other pairs of components.

The above description is intended to be illustrative of the present invention and not to limit the scope of the invention, which is defined by the claims appended hereto.

Claims (10)

1. The utility model provides an automobile shock absorber ware urceolus welding set for processing which characterized in that includes: a welding pedestal (1); the right side of the welding pedestal (1) is fixedly connected with a control panel (2) through a screw; the automatic welding arm (3) is fixedly connected to the rear side of the upper surface of the welding pedestal (1) through a bolt, and the automatic welding arm (3) is connected with the control panel (2) through an electric connecting line; the outer cylinder pushing cylinder (4) is fixedly connected to the left side above the welding pedestal (1) through screws, and the right end of a push rod of the outer cylinder pushing cylinder (4) is rotatably connected with a pushing rotary disc (401) through a bearing; the welding bench is characterized by comprising a positioning driving piece (5), wherein the positioning driving piece (5) is provided with two positions, the two positioning driving pieces (5) are fixedly connected inside the welding bench (1), and an output rod of the positioning driving piece (5) is fixedly connected with a driving worm (501) through a coupler; the middle rotating shaft (6) is provided with two positions, and the two positions of the middle rotating shaft (6) are rotatably connected to the inner bottom surface of the welding pedestal (1); the welding bench is characterized by comprising four translation clamping tables (7), wherein every two translation clamping tables (7) form a group, and the two groups of translation clamping tables (7) are movably connected inside the welding bench (1); spin welding drive servo motor (8), spin welding drive servo motor (8) pass through bolt fixed connection on the translation of left side rear presss from both sides platform (7), and spin welding drive servo motor (8) output shaft fixedly connected with initiative adjustment revolves tooth (801).

2. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 1, wherein: the upper surface left side of welding pedestal (1) has the jar that pushes away through welded connection and places platform (101), and the upper surface of welding pedestal (1) has two sets of positioning guide frame (102) through welded connection, props platform (103) in the middle of the fixedly connected with of the upper surface of welding pedestal (1), and the upper surface right side of welding pedestal (1) has right spacing extension board (104) through welded connection, and right spacing extension board (104) is perpendicular to the upper surface of welding pedestal (1).

3. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 2, wherein: two positioning guide rods (1021) are fixedly connected to the positioning guide frame (102), two ends of each positioning guide rod (1021) are connected to the front surface and the rear surface of the inside of the positioning guide frame (102) in a welding mode, the two positioning guide rods (1021) are parallel to each other, and the axes of the two positioning guide rods (1021) are perpendicular to the front surface of the welding pedestal (1).

4. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 2, wherein: the upper surface of the middle supporting table (103) is rotatably connected with two guide supporting wheels (1031) through bearings, the axis of each guide supporting wheel (1031) is perpendicular to the front surface of the welding pedestal (1), and an arc-shaped groove structure is formed in the wheel surface of each guide supporting wheel (1031).

5. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 1, wherein: the left side of the upper end of the right limiting support plate (104) is movably connected with a right limiting rotary disc (1041), the shaft body of the right limiting rotary disc (1041) is rotatably connected to the right limiting support plate (104) through a bearing, and the right surface of the right limiting rotary disc (1041) is convexly processed with an outer edge.

6. The welding device for processing the outer cylinder of the automobile shock absorber as set forth in claim 3, wherein: the middle of the middle rotating shaft (6) is connected with a driven worm wheel (601) through interference fit, the upper end of the middle rotating shaft (6) is connected with a driving gear (602) through interference fit, the driven worm wheel (601) is meshed with a driving worm (501), and the driven worm wheel (601) and the driving worm (501) form worm and gear transmission.

7. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 6, wherein: two lower guide holes (701) are formed in the lower end of the translation clamping table (7), a synchronous rack (702) is fixedly connected to the inner surface of the translation clamping table (7), the synchronous rack (702) is perpendicular to the inner surface of the translation clamping table (7), the lower guide holes (701) are connected to a positioning guide rod (1021) in a sliding mode, the synchronous rack (702) is meshed with a driving gear (602), and the synchronous rack (702) and the driving gear (602) form gear-rack transmission.

8. The welding device for processing the outer cylinder of the automobile shock absorber according to claim 7, wherein: the upper surface of the translation clamping table (7) is connected with a longitudinal connecting column (703) through welding, and the longitudinal connecting column (703) is perpendicular to the upper surface of the translation clamping table (7).

9. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 8, wherein: the upper part of the inner surface of the longitudinal connecting column (703) is connected with a synchronous clamping plate (704) through welding, and the synchronous clamping plate (704) is of an arc-shaped bent plate body structure.

10. The welding device for processing the outer cylinder of the automobile shock absorber as claimed in claim 9, wherein: the interior surface of synchronous splint (704) rotates through the bearing and is connected with four places location and presss from both sides wheel (7041), and location presss from both sides wheel (7041) axis towards transverse direction, and the top location that is located synchronous splint (704) in left rear presss from both sides wheel (7041) axis right-hand member and revolves tooth (7042) through interference fit fixedly connected with driven regulation, and driven regulation revolves tooth (7042) meshing connection initiative regulation and revolves tooth (801), and driven regulation revolves tooth (7042) and initiative regulation and revolves tooth (801) and form gear drive.

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