CN115947100B

CN115947100B - Automobile wheel machining center feeding device

Info

Publication number: CN115947100B
Application number: CN202310229802.9A
Authority: CN
Inventors: 熊凯申; 罗守江; 景年飞; 高璐璐; 姜超
Original assignee: Shandong Xiangrui Industry And Trade Co ltd
Current assignee: Shandong Xiangrui Industry And Trade Co ltd
Priority date: 2023-03-10
Filing date: 2023-03-10
Publication date: 2023-05-26
Anticipated expiration: 2043-03-10
Also published as: CN115947100A

Abstract

The invention provides a central feeding device for automobile wheel rim processing, and mainly relates to the field of wheel rim shell processing. The utility model provides an automobile wheel limit processing center loading attachment, includes carrier, manipulator, accepts the frame and sets up the location frock on machining center workstation, have the pay-off conveyer belt on the carrier, the pay-off conveyer belt front end sets up gets the material platform, the manipulator has three degrees of freedom at least, the manipulator front end sets up the chuck, the location frock includes the frock base, frock base both sides have the frock platform, set up the elevating platform on the frock base, the elevating platform center sets up the center post, center post bottom sets up the center cylinder, a plurality of preformings are articulated at the center post top, set up the preforming cylinder in the center post. The invention has the beneficial effects that: the invention combines the processing procedures of the flange end and the bottom end hole sites of the wheel rim shell, greatly improves the processing efficiency, improves the automation degree and reduces the labor cost.

Description

Automobile wheel machining center feeding device

Technical Field

The invention mainly relates to the field of wheel rim shell processing, in particular to a feeding device for a center of automobile wheel rim processing.

Background

The wheel edge speed reducer is the last-stage speed reduction and torque increase device in the automobile transmission system, and the adoption of the wheel edge speed reducer can reduce the load of components such as a speed changer, a transmission shaft, a main speed reducer, a differential mechanism, a half shaft and the like under the condition of the same total transmission ratio, reduce the size, enable a driving axle to obtain a larger ground clearance and the like, and is widely applied to trucks, buses, off-road vehicles and other large industrial and mining vehicles.

The wheel-side speed reducer mainly comprises a wheel-side shell, an input shaft and a planetary gear system, wherein the wheel-side shell is used as a protection and installation part of each part, a plurality of installation holes, pin holes and threaded oil holes are formed in the end face flange and the bottom face of the wheel-side shell, and after rough turning and finish turning of the outer circle and the inner cavity of the wheel-side and the central hole of the bottom face are carried out, the wheel-side shell is required to be lifted and fixed on a machining center to carry out machining of each hole. At present, the wheel rim shell is fixed on a tool mainly through a driving lifting and manual adjustment mode, after the hole site machining of the flange surface is completed, a workpiece is required to be dismounted and transported to another machining center, the wheel rim shell is turned and fixed by utilizing a second set of dies, and the hole site machining of the bottom surface of the wheel rim shell is completed. The processing technology divides hole site processing into two procedures, and two sets of tools are used for twice feeding to finish the process. The whole process needs to feed and position and clamp the workpiece twice, the non-processing time is longer, the processing efficiency is lower, the manual participation degree of the processing process is high, and the labor cost is increased.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides the automobile wheel rim machining center feeding device which combines the machining procedures of the flange end and the bottom surface end hole sites of the wheel rim shell, greatly improves the machining efficiency, improves the automation degree and reduces the labor cost.

The invention aims to achieve the aim, and the aim is achieved by the following technical scheme:

the utility model provides a car rim processing center loading attachment, includes carrier, manipulator, accepting frame and the location frock of setting on machining center workstation, it has the pay-off conveyer belt to bear on the frame, the pay-off conveyer belt front end sets up and gets the material platform, it sets up liftable location arc board to get the material platform bottom, location arc board suits with the wheel rim shell inner wall; the mechanical arm is at least provided with three degrees of freedom, the front end of the mechanical arm is provided with a chuck, the bottom of the chuck is hinged with a plurality of claws, the hinged positions of the tail ends of the claws are arc-shaped and are provided with ring teeth, the center of the chuck is provided with a chuck motor, and a motor shaft of the chuck motor is provided with a driving gear meshed with the ring teeth; the bearing frame is arranged on the opposite side of the bearing frame, the positioning tool comprises a tool base, tool tables are arranged on two sides of the tool base, the tool tables and the tool base are combined into a U-shaped structure, two tool tables are respectively provided with an inner rail, pushing seats are arranged in the inner rails in a sliding mode, pushing cylinders are arranged at the tail ends of the pushing seats, two pushing seats are rotatably provided with a turnover shaft, the turnover shaft is provided with a turnover motor, the bottom of the front end of the turnover shaft is fixedly provided with a bearing plate, the top of the front end of the turnover shaft is provided with a clamping seat, the clamping seat is provided with a clamping cylinder, a clamping piece is arranged on a piston rod of the clamping cylinder, a lifting table is arranged on the tool base, at least one positioning pin is arranged on the lifting table, the center of the lifting table is provided with a center column, the bottom of the center column is provided with a plurality of pressing pieces in a hinged mode, and the top of the piston rod of the pressing piece cylinder is hinged with the pressing pieces.

The material taking platform is provided with a groove, the positioning arc plate is slidably arranged in the groove, the bottom of the positioning arc plate is provided with a positioning cylinder, and the top of the positioning arc plate is provided with a taper.

When the clamping jaw is in an initial state, the clamping jaw is retracted inside the chuck.

The side of the tool table is provided with a limiting groove, and the bearing plate is in sliding connection with the limiting groove.

The pushing air cylinder is a two-stage air cylinder, the front end of the bearing plate slides out of the limit groove while the rear end of the bearing plate is still in the limit groove due to the primary extension of the pushing air cylinder, and the bearing plate completely slides out of the limit groove due to the secondary extension of the pushing air cylinder.

The lifting platform is in sliding connection with the tool platform, and a lifting cylinder is arranged between the lifting platform and the tool base.

The middle part of the tool table is provided with a limiting table, and the limiting table is adaptive to the top surface of the lifting table.

The preforms are located in the central column when the preforms are in an initial state.

The clamping seat is rotatably provided with a swinging seat, the swinging seat is provided with a swinging motor, and the clamping cylinder is arranged on the swinging seat.

The side surface of the tool table is inclined and provided with a high-pressure nozzle.

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

the invention completes the combination processing of the bottom hole site of the wheel rim shell and the hole site of the flange end, can complete the processing of the hole sites of the two ends through one-time feeding, reduces the feeding and discharging operation of one-time workpieces, reduces the transferring process of one-time workpieces through the combination procedure, and improves the processing efficiency.

The automatic feeding and discharging of the wheel rim shell is completed through the manipulator, the automation degree of machining of the hole site of the wheel rim shell is improved, the manual participation degree is reduced, an operator can look at more machining centers, and therefore the labor cost is reduced.

The device improves the electrification degree of the processing tool, and can drive the wheel rim shell to turn over through automatic driving of the processing tool, so that the conversion of the processing position of the wheel rim shell is completed, and the processing efficiency is greatly improved.

Drawings

FIG. 1 is a reference diagram of the use of the present invention;

FIG. 2 is a schematic diagram of a positioning tool for machining the bottom surface of a wheel rim shell;

FIG. 3 is a left-hand structural schematic diagram of a positioning tool for machining the bottom surface of a wheel rim shell;

FIG. 4 is a schematic structural diagram of a positioning tool for machining flange faces of wheel side shells;

FIG. 5 is a schematic top view of the positioning tool for machining the flange surface of the wheel rim shell;

FIG. 6 is a schematic diagram of the positioning tool structure of the invention;

FIG. 7 is a schematic view of the structure of the pushing base part of the present invention;

FIG. 8 is a schematic view of a partial cross-sectional structure of a center post of the present invention;

FIG. 9 is a schematic top view of the chuck of the present invention;

FIG. 10 is a schematic view of the structure of the take-off platform of the present invention;

FIG. 11 is a schematic view of the partial enlarged construction of the A part of the present invention;

FIG. 12 is a schematic view of the present invention showing the partial enlarged structure of the portion B.

The reference numbers shown in the drawings: 1. a carrier; 2. a manipulator; 3. a bearing frame; 4. positioning a tool; 5. a lifting table; 11. a feeding conveyor belt; 12. a material taking platform; 13. positioning an arc plate; 14. positioning a cylinder; 21. a chuck; 22. a claw; 23. a chuck motor; 41. a tooling base; 42. a tooling table; 43. an inner rail; 44. a pushing seat; 45. a pushing cylinder; 46. a turnover shaft; 47. a turnover motor; 48. a carrying plate; 49. clamping base; 50. clamping an air cylinder; 51. clamping pieces are arranged; 52. a positioning pin; 53. a center column; 54. a central cylinder; 55. tabletting; 56. a tabletting cylinder; 57. a limit groove; 58. a lifting cylinder; 59. a limiting table; 491. a swinging seat; 492. and (5) swinging the motor.

Detailed Description

The invention will be further described with reference to the accompanying drawings and specific embodiments. It is to be understood that these examples are illustrative of the present invention and are not intended to limit the scope of the present invention. Further, it will be understood that various changes or modifications may be made by those skilled in the art after reading the teachings of the invention, and such equivalents are intended to fall within the scope of the invention as defined herein.

As shown in fig. 1-12, the loading device for the automobile wheel rim machining center comprises a bearing frame 1, a manipulator 2, a bearing frame 3 and a positioning tool 4 arranged on a workbench of the machining center. Each action part of the device is controlled by a controller. The bearing frame 1 is used as a storage frame of the automobile wheel rim shell and is used as a positioning position for grabbing by the manipulator 2. The positioning tool 4 is used as a positioning tool for processing hole sites of a processing center and is used for positioning the wheel rim shell and finishing the hole site processing operation of the flange end and the bottom surface end of the wheel rim shell. The positioning tool 4 is an important component for combining hole site machining procedures. The carrying frame 3 is used as a temporary storage frame for workpieces for finishing hole site machining, and the carrying operation of workpiece feeding and discharging is finished through a manipulator.

The bearing frame 1 is provided with a feeding conveyer belt 11, the front end of the feeding conveyer belt 11 is provided with a material taking platform 12, the bottom of the material taking platform 12 is provided with a liftable positioning arc plate 13, and the diameter of the positioning arc plate 13 is consistent with that of the inner wall of the wheel rim shell. The feeding conveyor belt 11 is used as a conveying mechanism of the wheel rim shell after turning, can be connected to a turning process, can be independently arranged, and places the wheel rim shell in a hoisting mode. The flange end of the wheel rim shell on the feeding conveyor belt 11 is downward and contacts with the surface of the conveyor belt 11. The feeding conveyer belt 11 drives the wheel-side shell to move downwards through the driving of the feeding motor, and the feeding conveyer belt reaches the material taking platform 12 and then is positioned by the material taking platform 12. The material taking platform 12 is also a position where the manipulator 2 clamps the wheel rim shell. Positioning sensors connected with the controller in a signal manner are arranged on the material taking platform 12 and at the tail end of the material feeding conveyor belt 11. Specifically, the material taking platform 12 is provided with a groove, the positioning arc plate 13 is slidably mounted in the groove, the bottom of the positioning arc plate 13 is provided with a positioning cylinder 14, and the top of the positioning arc plate 13 is provided with a taper. The top of the positioning arc plate 13 is excessively directed towards the center of the circle, so that a certain taper is formed. When the wheel rim shell is conveyed to the material taking platform 12, a sensor on the material taking platform 12 detects a signal, the controller controls the conveying belt 11 to stop running, meanwhile, the positioning air cylinder 14 jacks up the positioning arc plate 13, the taper at the top of the positioning arc plate 13 guides the inner wall of the wheel rim shell to a certain extent, and finally, the wheel rim shell is positioned to a position to be grabbed by utilizing the diameter of the positioning arc plate 13, and at the moment, the outer wall of the positioning arc plate 13 is attached to the inner wall of the wheel rim shell. When the feed conveyor 11 is started and the end position sensor fails to detect the wheel rim housing for a long period of time, a signal is sent to the controller reporting that the work piece is empty, which is replenished by the operator.

The manipulator 2 has three degrees of freedom at least, the manipulator 2 can adopt a frame type manipulator structure driven by a screw transmission or synchronous belt mechanism, and also can adopt a numerical control robot with high degree of freedom, the manipulator structure driven by the screw transmission or synchronous belt mechanism is suitable for workpieces with larger weight, and the numerical control robot is suitable for workpieces with lighter weight and narrower processing position. Since the robot arm 2 itself is not the end point of the present invention, the present embodiment will be described by way of example only with respect to a numerical control robot.

The front end of the manipulator 2 is provided with a chuck 21, the bottom of the chuck 21 is hinged with a plurality of claws 22, the hinged positions of the tail ends of the claws 22 are arc-shaped and are provided with ring teeth, the center of the chuck 21 is provided with a chuck motor 23, and a motor shaft of the chuck motor 23 is provided with a driving gear meshed with the ring teeth. The chuck 21 at the front end of the manipulator 2 is used as an action part for clamping the central hole of the bottom surface of the wheel rim shell. The diameter of the clamping head 21 is slightly smaller than that of the central hole of the bottom surface of the wheel rim shell. When the jaws 22 are in the initial state, the jaws 22 are retracted inside the collet 21. When the wheel rim shell needs to be grabbed, the mechanical arm 2 drives the chuck 21 to be inserted into the center hole of the wheel rim shell, the chuck motor 23 drives the ring gear to rotate through the driving gear, so that the claw 22 is screwed out of the chuck 21, the claw 22 is contacted with the inner bottom surface of the wheel rim shell, and the wheel rim shell is lifted and transported. When the transfer is completed, the chuck motor 23 is controlled to rotate reversely, and the clamping jaws 22 are retracted into the chucks 21 again.

The bearing frame 3 is arranged on the opposite side of the bearing frame 1, the bearing frame 3 bears the wheel side shells with the hole site machined, the bearing frame 1 can be a frame body with a transferable wheel set, and a belt conveyor can be installed for transferring.

The positioning tool 4 comprises a tool base 41, tool tables 42 are arranged on two sides of the tool base 41, and the tool tables 42 and the tool base 41 are combined to form a U-shaped structure. The tooling base 41 is mounted on a workbench of a machining center through a T-shaped pressing block. The two tooling tables 42 are provided with inner rails 43, and the two inner rails 43 are on the same straight line. The pushing seat 44 is slidably mounted in the inner rail 43, and the pushing seat 44 is tightly attached to the inner rail 43 without gaps. The pushing cylinder 45 is arranged at the tail end of the pushing seat 44, and the pushing cylinder 45 is used as a power source for the pushing seat 44 to slide along the inner rail 43. The pushing cylinder 45 in this embodiment adopts a two-stage stretching cylinder, so as to push the subsequent carrying plate 48 in two stages.

The two pushing seats 44 are rotatably provided with a turnover shaft 46, the turnover shaft 46 is provided with a turnover motor 47, the bottom of the front end of the turnover shaft 46 is fixedly provided with a bearing plate 48, the top of the front end of the turnover shaft 46 is provided with a clamping seat 49, the clamping seat 49 is provided with a clamping cylinder 50, and a piston rod of the clamping cylinder 50 is provided with a clamping piece 51. The bearing plate 48 is pushed by the pushing cylinder 45 to extend to the outer side of the pushing seat 44, so as to bear the flange end of the wheel rim shell. The flange end of the wheel rim shell is pressed by the clamping seat 49 on the clamping cylinder 50, so that the wheel rim shell is fixed. The side of the tooling table 42 is provided with a limiting groove 57, and the bearing plate 48 is slidably connected with the limiting groove 57. The first stage of the pushing cylinder 45 extends to enable the front end of the bearing plate 48 to slide out of the limit groove 57 but the rear end of the bearing plate is still in the limit groove 57, so that the bearing plate 48 is kept horizontal under the limit of the limit groove 57, and the flatness of machining of the wheel rim shell hole site is ensured. The second stage of the pushing cylinder 45 extends to enable the bearing plate 48 to completely slide out of the limit groove 57, and at this time, the action of the turning shaft 46 is released, so that the clamping piece 51 and the clamping of the bearing plate 48 can drive the wheel rim shell to turn over, and the bottom surface of the wheel rim shell faces downwards to finish the machining of the hole site of the flange end.

More specifically, the lower portion of the tool table 42 located below the inner rail 43 is a hollow structure, and the hollow structure is communicated with the bottom of the inner rail 43, so that after the turnover shaft 46 drives the clamping seat 49 to turn over, the clamping seat 49, the clamping cylinder 50 and the clamping piece 51 on the clamping seat 49 can enter the hollow structure along with the recovery of the pushing seat 44, thereby preventing the interference between the part of the structure and the tool table 42.

More specifically, the clamping seat 49 is rotatably provided with a swinging seat 491, the swinging seat 491 is provided with a swinging motor 492, and the clamping cylinder 50 is provided on the swinging seat 491. The swing motor 492 may drive the swing seat 491 to rotate 180 degrees, so that the clamping piece 51 does not interfere with the placement of the wheel rim shell in the initial state.

The lifting table 5 is arranged on the tooling base 41, at least one positioning pin 52 is arranged on the lifting table 5, and the positioning pin 52 is used for positioning a machining hole on the bottom surface of the wheel rim shell, so that the position of a hole on the flange is determined. The center of the lifting platform 5 is provided with a center column 53, and the center column 53 is used as a component for compacting and positioning wheel side shells. The center post 53 includes a fixed cylinder fixedly connected to the elevating table 5 and a slide cylinder slidably connected to the fixed cylinder. A central cylinder 54 is arranged in a fixed cylinder at the bottom of the central column 53, a piston rod of the central cylinder 54 is fixedly arranged at the bottom of the sliding cylinder, and the sliding cylinder can ascend and descend through the expansion and the contraction of the central cylinder 54. The top of the sliding cylinder of the central column 53 is hinged with a plurality of pressing sheets 55, a pressing sheet cylinder 56 is arranged in the sliding cylinder of the central column 53, and the top end of a piston rod of the pressing sheet cylinder 56 is hinged with the pressing sheets 55. Specifically, the tail end of the pressing piece 55 is a long hole, and the front end of the pressing piece cylinder 56 is provided with a connecting column, and the connecting column slides in the long hole. By pressing down the pressing cylinder 56, the pressing sheet 55 can be pushed to rotate so as to expand the pressing sheet 55, and then the central cylinder 54 is contracted, so that the pressing sheet 55 presses the bottom of the wheel rim shell, and the wheel rim shell is fixed. Further, when the pressing piece 55 is in the initial state, the pressing piece 55 is located in the center post 53. The top of the center post 53 is provided with a limiting block, when the pressing piece 55 is unfolded from bottom to top by 90 degrees, the pressing piece can be contacted with the limiting block at the top of the center post 53, so that the displacement of the pressing piece 55 is limited, and the wheel rim shell is well fixed.

Specifically, the lifting platform 5 is slidably connected with the tooling platform 42, and a lifting cylinder 58 is installed between the lifting platform 5 and the tooling base 41. The side of the tooling table 42 is provided with a sliding groove, and the lifting table 5 is provided with a sliding block matched with the sliding groove. The lifting platform 5 can be lifted up by the lifting action of the lifting cylinder 58 so as to be in contact with the bottom surface of the turned wheel rim. The middle part of the tooling table 42 is provided with a limiting table 59, and the limiting table 59 is contacted with the top surface of the lifting table 5, so that the levelness of the lifting table 5 is ensured, the horizontal state of the wheel rim shell is ensured, and the hole site machining accuracy of the bottom surface of the wheel rim shell is ensured.

More specifically, in order to ensure smooth discharge of the iron chips during machining of the machining center hole site, the side surface of the tooling table 42 is provided with a high-pressure nozzle in an inclined state. The high-pressure nozzle is connected with high-pressure air flow, and the iron pin is purged and removed after the processing is completed, so that the iron pin is prevented from interfering with subsequent processing.

The processing method for completing the wheel rim shell by using the device comprises the following steps:

s1: firstly, a controller controls a feeding conveyer belt 11 on a bearing frame 1 to convey wheel side shells which are prevented from being inverted to a material taking platform 12, then a positioning air cylinder 14 drives a positioning arc plate 13 to lift, and the wheel side shells are driven along with the contact of the positioning arc plate 13 and the inner cavity of the wheel side shells, so that the wheel side shells are moved to a position to be grabbed of the material taking platform 12.

S2: then the controller controls the manipulator 2 to grab the wheel rim shell, the manipulator 2 drives the chuck 21 to be inserted into the central hole of the bottom surface of the wheel rim shell, the chuck motor 23 in the chuck 21 drives the claw 22 to unscrew from the chuck 21, then the manipulator 2 lifts the wheel rim shell and then transfers the wheel rim shell to the positioning tool 4 in the machining center, the positioning cylinder 14 drives the positioning arc plate 13 to shrink, and the feeding conveyor belt 11 conveys the next wheel rim shell to the material taking platform 12.

S3: the pushing cylinder 45 drives the pushing seat 44 to extend at one stage, the manipulator 2 places the wheel rim shell to the bearing position of the bearing plate 48 for bearing, then the controller controls the swinging seat 491 to rotate 180 degrees and then face the direction of the wheel rim shell, the clamping cylinder 50 controls the clamping piece 51 to press down and fix the wheel rim shell, then the controller controls the clamping jaw 22 in the clamping head 21 to retract, the manipulator 2 breaks away from clamping the wheel rim shell, and then the machining center processes the bottom hole position of the wheel rim shell.

S4, after finishing the hole site processing of the bottom surface of the wheel rim shell, the clamping cylinder 50 temporarily controls the clamping piece 51 to loosen the clamping, then the pushing cylinder 45 drives the pushing seat 44 to extend secondarily, the bearing plate 48 is separated from contact with the limiting groove 57, meanwhile, the clamping cylinder 50 controls the clamping piece 51 to continuously clamp the wheel rim shell, then the overturning motor 47 drives the overturning shaft 46 to overturn for 180 degrees, and the clamping cylinder 50 controls the clamping piece 51 to loosen the clamping of the wheel rim shell again. Meanwhile, the lifting cylinder 58 drives the lifting table 5 to be lifted to a position contacting with the bottom surface of the wheel rim shell, wherein the center column 53 is inserted into a machining hole of the bottom surface of the wheel rim shell, the center column 53 is inserted into the center hole of the bottom surface and is lowered by the pressing cylinder 56 to drive the pressing sheet 55 to be unfolded, the center cylinder 54 is pressed down to drive the pressing sheet 55 to clamp and fix the inner bottom surface of the wheel rim shell, then the pushing cylinder 45 drives the pushing seat 44 to be completely contracted and separated from contact with the flange end of the wheel rim shell, and the machining center completes hole site machining of the flange surface of the wheel rim shell.

S5: after the hole site of the flange surface of the wheel rim shell is machined, the pushing cylinder 45 drives the pushing seat 44 to extend secondarily, the bearing plate 48 is continuously contacted with the flange end, the clamping cylinder 50 controls the clamping piece 51 to clamp the wheel rim shell, and then the overturning motor 47 drives the overturning shaft 46 to overturn 180 degrees, so that the bottom surface of the wheel rim shell faces upwards. The wheel rim shells are then gripped by the robot arm 2 and placed on the carrier 3.

S6: the pushing cylinder 45 drives the pushing seat 44 to shrink one stage to be in a one-stage telescopic state, the swinging seat 491 swings 180 degrees to the rear side, and the next wheel rim shell is waited for processing.

Claims

1. The utility model provides an automobile wheel limit processing center loading attachment, includes carrier (1), manipulator (2), holds frame (3) and sets up location frock (4) on machining center workstation, its characterized in that: the lifting type wheel rim shell is characterized in that a feeding conveyor belt (11) is arranged on the bearing frame (1), a material taking platform (12) is arranged at the front end of the feeding conveyor belt (11), a lifting positioning arc plate (13) is arranged at the bottom of the material taking platform (12), and the positioning arc plate (13) is adapted to the inner wall of the wheel rim shell; the mechanical arm (2) is at least provided with three degrees of freedom, the front end of the mechanical arm (2) is provided with a chuck (21), the bottom of the chuck (21) is hinged with a plurality of claws (22), the hinged position of the tail ends of the claws (22) is arc-shaped and provided with ring teeth, the center of the chuck (21) is provided with a chuck motor (23), and a motor shaft of the chuck motor (23) is provided with a driving gear meshed with the ring teeth; the bearing frame (3) is arranged on one side opposite to the bearing frame (1), the positioning tool (4) comprises a tool base (41), two sides of the tool base (41) are provided with tool tables (42), the tool tables (42) and the tool base (41) are combined into a U-shaped structure, two inner rails (43) are arranged on the tool tables (42), a pushing seat (44) is arranged in the inner rails (43) in a sliding manner, pushing cylinders (45) are arranged at the tail ends of the pushing seats (44), a turnover shaft (46) is arranged on the pushing seats (44) in a rotating manner, a turnover motor (47) is arranged on the turnover shaft (46), a bearing plate (48) is fixedly arranged at the bottom of the front end of the turnover shaft (46), a limiting groove (57) is formed in the side of the tool table (42), the bearing plate (48) is in sliding connection with the limiting groove (57), the pushing cylinders (45) are two-stage cylinders, one-stage extension of the pushing cylinders (45) enables the front end of the bearing plate (48) to slide out of the limiting groove (57), and the two-stage extension cylinders (45) enable the front end of the bearing plate (48) to slide out of the limiting groove (57) and keep the limiting groove (57) to be completely extended in the lower-stage (57), make clamping piece (51) and loading board (48) clamping can drive wheel limit shell upset, tilting axis (46) front end top sets up clamping seat (49), set up clamping cylinder (50) on clamping seat (49), rotate on clamping seat (49) and set up swing seat (491), set up swing motor (492) on swing seat (491), clamping cylinder (50) set up on swing seat (491), set up clamping piece (51) on clamping cylinder (50)'s the piston rod, set up elevating platform (5) on frock base (41), set up at least one locating pin (52) on elevating platform (5), elevating platform (5) center sets up center post (53), center post (53) bottom sets up center cylinder (54), center post (53) top articulates a plurality of preforming (55), set up preforming cylinder (56) in center post (53), the piston rod top of preforming cylinder (56) articulates with preforming (55).

2. The automobile wheel rim machining center feeding device according to claim 1, wherein: the material taking platform (12) is provided with a groove, the positioning arc plate (13) is slidably arranged in the groove, the bottom of the positioning arc plate (13) is provided with a positioning cylinder (14), and the top of the positioning arc plate (13) is provided with a taper.

3. The automobile wheel rim machining center feeding device according to claim 1, wherein: when the clamping jaw (22) is in an initial state, the clamping jaw (22) is retracted inside the clamping head (21).

4. The automobile wheel rim machining center feeding device according to claim 1, wherein: the lifting table (5) is in sliding connection with the tooling table (42), and a lifting cylinder (58) is arranged between the lifting table (5) and the tooling base (41).

5. The automobile wheel rim machining center feeding device according to claim 4, wherein: and a limiting table (59) is arranged in the middle of the tool table (42), and the limiting table (59) is matched with the top surface of the lifting table (5).

6. The automobile wheel rim machining center feeding device according to claim 1, wherein: when the press sheet (55) is in an initial state, the press sheet (55) is positioned in the center column (53).

7. The automobile wheel rim machining center feeding device according to any one of claims 1-6, wherein: the side face of the tooling table (42) is provided with a high-pressure nozzle in an inclined state.