CN219805472U - Chamfering machine for processing brake chamber push disc - Google Patents

Abstract

The utility model discloses a chamfering machine for processing a brake chamber push disc, which comprises a pair of chamfering upper rotating seats, a pair of chamfering lower rotating seats, a pair of driving idler wheels, a chamfering driving assembly and a vertical adjusting assembly, wherein the chamfering upper rotating seats are distributed front and back; the pair of upper chamfer rotating seats and the pair of lower chamfer rotating seats are arranged in the opening of the middle supporting frame; the upper chamfer rotating seats and the lower chamfer rotating seats are in one-to-one correspondence, and the upper chamfer rotating seats are positioned right above the lower chamfer rotating seats; the chamfering driving assembly drives a pair of chamfering lower rotating seats to synchronously rotate; the vertical adjusting component drives a pair of upper rotary seats of the chamfer angles to synchronously lift; the driving roller is a cylinder with a driving chamfer groove formed on the cylindrical surface; the pair of pushing disc limiting mechanisms are respectively arranged at the left side and the right side of the chamfering mechanism and used for placing the pushing disc. The utility model has the effect of chamfering pushing discs with different thicknesses.

Description

Chamfering machine for processing brake chamber push disc

Technical Field

The utility model relates to the technical field of brake chamber machining, in particular to a chamfering machine for machining a brake chamber push disc.

Background

The brake chamber is part of an automotive braking system. Is generally mounted on the drive axle of a motor vehicle and is operative to provide braking torque to the motor vehicle. The structure of the brake chamber comprises a push rod and a push disc structure, wherein the edge of the push disc is required to be subjected to chamfering processing during processing.

The utility model discloses a chamfering machine in China with the publication number of CN213887818U, which comprises a frame, a workbench, a clamping device, a forming device, an auxiliary supporting device and a cooling device. The molding device comprises a fixed molding assembly and a movable molding assembly. The fixed forming assembly comprises two driving rollers and a driving piece for driving the driving rollers to rotate, annular forming grooves coaxial with the driving rollers are formed in the side surfaces of the driving rollers, the cross section of each forming groove is semicircular, and therefore round chamfers are formed at the edges of the pushing disc after machining.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: the initiative gyro wheel is fixed connection with the driving piece, when the pushing disc of different thickness carries out the chamfer, the shaping slot of initiative gyro wheel also needs to change, needs to change different initiative gyro wheels promptly, but because initiative gyro wheel can't carry out quick replacement, leads to like this that whole beveler can't process the pushing disc of different thickness, application scope is narrow.

Disclosure of Invention

The utility model provides a chamfering machine for processing a brake chamber pushing disc, which aims to solve the technical problem that the chamfering machine cannot be used for chamfering pushing discs with different thicknesses.

The chamfering machine for processing the brake chamber push disc adopts the following technical scheme:

a chamfering machine for processing a brake chamber push disc comprises a workbench, a chamfering mechanism and a pair of push disc limiting mechanisms; a rectangular groove-shaped left and right moving groove is formed on the upper end surface of the workbench; the middle part of the lower side wall of the left-right moving groove is provided with a U-shaped middle supporting frame with a downward opening; the chamfering mechanism comprises a pair of chamfering upper rotating seats which are distributed front and back, a pair of chamfering lower rotating seats which are distributed front and back, a pair of driving idler wheels which are distributed front and back, a chamfering driving assembly and a vertical adjusting assembly; the pair of chamfer upper rotating seats and the pair of chamfer lower rotating seats are arranged in the opening of the middle supporting frame; the upper chamfering rotating seats and the lower chamfering rotating seats are in one-to-one correspondence, and the upper chamfering rotating seats are positioned right above the lower chamfering rotating seats; the chamfering driving assembly drives a pair of chamfering lower rotating seats to synchronously rotate; the vertical adjusting assembly drives a pair of upper chamfering rotating seats to synchronously lift and the upper chamfering rotating seats are rotationally arranged on the vertical adjusting assembly; the driving roller is a cylinder with a driving chamfer groove formed on the cylindrical surface; a plurality of active connecting slots with evenly distributed circumferences are respectively formed on the upper end face and the lower end face of the active roller; a plurality of active upper inserting columns matched with the active connecting slots are formed on the lower end surface of the chamfer upper rotating seat; a plurality of active lower inserting columns matched with the active connecting slots are formed on the upper end surface of the chamfer lower rotating seat; the pair of pushing disc limiting mechanisms are respectively arranged at the left side and the right side of the chamfering mechanism and used for placing pushing discs.

Through adopting above-mentioned technical scheme, go up the roating seat through vertical adjusting component drive a pair of chamfer and rise for the initiative of roating seat is gone up to the chamfer goes up the spliced pole and breaks away from the initiative gyro wheel, then can be vertically upwards take down the initiative gyro wheel and change, and the chamfering machine can carry out the chamfer processing to the pushing disc of different thickness like this.

Optionally, four supporting feet which are distributed in a rectangular shape are formed on the lower end surface of the workbench; a horizontal supporting plate is formed among the four supporting legs; the chamfering driving assembly comprises a reduction gearbox fixed on the lower end face of the horizontal supporting plate; the input shaft of the reduction gearbox is connected with a chamfering motor, and the output shaft is fixed with a driving gear; a driving cylinder coaxially arranged is fixed on the lower end surface of the chamfering lower rotating seat; the driving column vertically penetrates through and is rotatably arranged on the lower side wall of the left-right moving groove and the horizontal supporting plate; a driven gear is fixed at the lower end of the driving cylinder; the driven gears are meshed with the driving gears respectively.

By adopting the technical scheme, the chamfering motor drives the driving gear to rotate through the reduction gearbox, and the driving gear simultaneously drives a pair of driven gears meshed with the driving gear to rotate; the driven gears drive the pair of chamfering lower rotating seats to rotate through the driving cylinder, and the pair of chamfering lower rotating seats respectively drive the pair of driving rollers to rotate so as to carry out chamfering processing.

Optionally, the vertical adjustment assembly comprises a vertical adjustment plate; a pair of adjusting guide posts are formed on the upper end surface of the vertical adjusting plate; the pair of adjusting guide posts vertically penetrate through the horizontal part of the middle supporting frame; the horizontal part of the middle support frame is in threaded connection with a vertical adjusting bolt; the bottom of the vertical adjusting bolt is pivoted on the upper end surface of the vertical adjusting plate; the pair of upper chamfer rotating seats are rotatably arranged on the lower end face of the vertical adjusting plate.

Through adopting above-mentioned technical scheme, make vertical adjusting plate rise or descend under the guide effect of a pair of adjusting guide pillar through rotating vertical adjusting bolt for the roating seat is kept away from or is close to the initiative gyro wheel on a pair of chamfer.

Optionally, the pushing disc limiting mechanism comprises a moving support frame and a left-right driving assembly which are arranged in the left-right moving groove in a left-right moving way; the left-right driving assembly is used for driving the movable supporting frame to move left and right; the movable supporting frame is provided with a pushing disc limiting assembly, an auxiliary roller and an auxiliary roller mounting assembly; the auxiliary roller mounting assembly is used for connecting the auxiliary roller to the movable supporting frame; the pushing disc limiting assembly is positioned between the chamfering mechanism and the auxiliary roller and used for limiting the front and rear positions of the pushing disc; the auxiliary roller is a cylinder with an auxiliary chamfer groove formed on the cylindrical surface; the auxiliary roller and the driving roller are positioned on the same horizontal plane.

Through adopting above-mentioned technical scheme, push away the dish and place on pushing away the spacing subassembly of dish, then supplementary gyro wheel supports and lean on pushing away the dish, moves the support frame and is close to chamfering mechanism next, until the other end of pushing away the dish supports a pair of initiative gyro wheel, then a pair of initiative gyro wheel synchronous revolution carries out the chamfer processing to pushing away the dish.

Optionally, the movable supporting frame comprises a vertical connecting plate; an upper supporting plate is formed at the upper end of the end surface of the vertical connecting plate, which is close to the middle supporting frame, and a lower supporting plate is formed at the lower end of the vertical connecting plate; the left-right length of the upper supporting plate is smaller than the left-right width of the lower supporting plate; the auxiliary roller is positioned between the upper supporting plate and the lower supporting plate; the pushing disc limiting assembly is located on the portion, exceeding the upper supporting plate, of the lower supporting plate.

Through adopting above-mentioned technical scheme, auxiliary roller installs go up the backup pad with between the backup pad down, push away a limit assembly and be located down the backup pad surpasses go up the backup pad on the part of backup pad, push away like this and take out and put the convenience.

Optionally, the pushing disc limiting assembly comprises a U-shaped vertical adjusting frame; a pair of vertical inserted bars which are distributed front and back are formed on the lower end surface of the vertical adjusting frame; a pair of vertical inserting rods vertically penetrate through the lower supporting plate; a pushing disc adjusting bolt vertically penetrates through the lower supporting plate and is connected with the lower supporting plate in a threaded manner; the upper end of the push disc adjusting bolt is pivoted on the lower end face of the vertical adjusting frame; front and rear blocking components are respectively arranged in the opening of the vertical adjusting frame.

By adopting the technical scheme, the vertical adjusting frame can be driven to vertically move along the pair of vertical inserting rods by screwing the pushing disc adjusting bolts, so that the pushing disc is opposite to the driving roller; the front and back blocking components are used for limiting the push disc in the front and back direction.

Optionally, the front-rear blocking assembly comprises front-rear baffles; a pair of left and right front and rear guide posts are respectively formed on the end surfaces of the front and rear baffles, which are far away from each other; a pair of front and rear guide posts penetrate through the vertical parts of the corresponding sides of the vertical adjusting frame in the front-rear direction; front and rear adjusting bolts penetrate through a pair of vertical parts of the vertical adjusting frame in a front-rear penetrating way and are screwed with the pair of vertical parts of the vertical adjusting frame; the inner side ends of the front and rear adjusting bolts are pivoted on the front and rear baffles at the corresponding sides.

Through adopting above-mentioned technical scheme, can drive the front and back baffle and be close to or keep away from the pushing disc along a pair of front and back guide pillar direction through twisting front and back adjusting bolt.

Optionally, the auxiliary roller mounting assembly includes a vertical moving seat and a pair of auxiliary roller connecting seats distributed up and down; a plurality of movable guide posts are formed on the upper end surface of the vertical movable seat; the movable guide post vertically penetrates through the upper supporting plate; the upper supporting plate vertically penetrates through the upper supporting plate and is in threaded connection with a movable bolt; the lower end of the movable bolt is pivoted on the upper end surface of the vertical movable seat; the auxiliary roller connecting seat on the upper side is rotatably arranged on the upper end surface of the lower supporting plate, and the auxiliary roller connecting seat on the lower side is rotatably arranged on the upper end surface of the lower supporting plate; a plurality of auxiliary connecting slots with evenly distributed circumferences are respectively formed on the upper end face and the lower end face of the auxiliary roller; a plurality of auxiliary connecting inserting posts matched with the auxiliary connecting slots are respectively formed on the end surfaces of the pair of auxiliary roller connecting seats, which are close to each other.

Through adopting above-mentioned technical scheme, can make vertical removal seat keep away from auxiliary roller or be close to through rotatory removal bolt, auxiliary roller changes conveniently like this to adapt to the push away of different thickness dish.

In summary, the beneficial effects of the utility model are as follows:

1. the pushing discs with different thicknesses can be subjected to chamfering processing.

Drawings

Fig. 1 is a schematic top view of the present utility model.

Fig. 2 is a schematic view of the structure of the section A-A of fig. 1 according to the present utility model.

Fig. 3 is a partially enlarged schematic view of the push plate limiting mechanism 20 of fig. 2 according to the present utility model.

Fig. 4 is a schematic structural view of a cross section of the installation connection of a pair of driving rollers 37 of the present utility model.

Fig. 5 is a schematic left-hand view of the vertical adjustment frame 26 of the present utility model.

Fig. 6 is a schematic top view of a pair of driven gears 38 and a driving gear 33 according to the present utility model.

Reference numerals illustrate:

10. a work table; 100. a left-right moving groove; 101. a moving avoidance groove; 11. supporting feet; 12. a horizontal support plate; 13. a middle support frame;

20. a pushing disc limiting mechanism; 21. left and right driving components; 22. moving the support frame; 221. a vertical connecting plate; 222. an upper support plate; 223. a lower support plate; 23. an auxiliary roller connecting seat; 231. auxiliary connecting plug posts; 24. an auxiliary roller; 240. an auxiliary chamfer groove; 241. an auxiliary connection slot; 25. a vertical moving seat; 251. moving the guide post; 252. moving the bolt; 26. a vertical adjusting frame; 261. a vertical insert rod; 262. pushing a disc adjusting bolt; 27. front and rear baffles; 271. front and rear guide posts; 272. a front-rear adjusting bolt;

30. chamfering mechanism; 31. chamfering motor; 32. a reduction gearbox; 33. a drive gear; 34. a vertical adjustment plate; 341. adjusting the guide post; 342. a vertical adjusting bolt; 35. chamfering the upper rotating seat; 351. actively inserting a column; 36. chamfering the lower rotating seat; 361. actively inserting a column; 37. a driving roller; 370. an active chamfer groove; 371. actively connecting the slots; 38. a driven gear;

40. pushing the tray.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-6.

The utility model discloses a chamfering machine for processing a brake chamber push disc, referring to fig. 1 and 2, comprising a workbench 10, a chamfering mechanism 30 and a pair of push disc limiting mechanisms 20; the upper end surface of the workbench 10 is provided with a rectangular groove-shaped left and right moving groove 100, and the lower end surface is provided with four rectangular supporting legs 11; a horizontal supporting plate 12 is formed among the four supporting legs 11; the chamfering mechanism 30 is provided in the middle of the left-right movement groove 100 and is used for chamfering the push plate 40; a pair of push plate stopper mechanisms 20 are provided at left and right portions of the left and right movement groove 100, respectively, and serve to place and restrict the push plate 40.

Referring to fig. 1 to 3, the push plate stopper mechanism 20 includes a moving support frame 22 provided in the left-right moving groove 100 to move left-right and a left-right driving assembly 21; the left-right driving component 21 is used for driving the movable supporting frame 22 to move left and right and is arranged in the left-right movable groove 100; the left and right driving components 21 may be linear driving components such as an electric cylinder, an air cylinder or a hydraulic cylinder and are respectively fixed on the left and right end surfaces of the workbench 10; a pushing disc limiting assembly, an auxiliary roller 24 and an auxiliary roller mounting assembly are arranged on the movable supporting frame 22; the auxiliary roller 24 is a cylinder with an auxiliary chamfer groove 240 formed on the cylindrical surface; when machining a push plate 40 of a different thickness, a different auxiliary roller 24 may be replaced, such that the auxiliary chamfer 240 on the auxiliary roller 24 is compatible with the push plate 40.

Referring to fig. 2 and 3, the moving support 22 includes a vertical connection plate 221; an upper support plate 222 is formed at the upper end of the end surfaces of the pair of vertical connection plates 221, which are close to each other, and a lower support plate 223 is formed at the lower end of the pair of vertical connection plates; the left-right length of the upper support plate 222 is smaller than the left-right width of the lower support plate 223;

referring to fig. 2 and 3, the auxiliary roller mounting assembly includes a vertical moving seat 25 and a pair of auxiliary roller connecting seats 23 distributed up and down; the vertical movement seat 25 is vertically movably provided on the lower end surface of the upper support plate 222; one auxiliary roller connecting seat 23 is rotatably provided on the lower end surface of the vertically movable seat 25, and the other auxiliary roller connecting seat 23 is rotatably provided on the upper end surface of the lower support plate 223; a plurality of movable guide posts 251 are formed on the upper end surface of the vertical movable seat 25; the moving guide post 251 vertically passes through the upper support plate 222; a moving bolt 252 vertically penetrates through and is screwed with the upper support plate 222; the lower end of the moving bolt 252 is pivoted on the upper end surface of the vertical moving seat 25; a plurality of auxiliary connecting slots 241 with evenly distributed circumferences are respectively formed on the upper end face and the lower end face of the auxiliary roller 24; a plurality of auxiliary connecting inserting posts 231 matched with the auxiliary connecting slots 241 are respectively formed on the end surfaces of the pair of auxiliary roller connecting seats 23, which are close to each other; when the auxiliary roller 24 is dismounted, only the moving bolt 252 is required to be screwed to drive the vertical moving seat 25 to vertically move, so that the auxiliary roller 24 can be dismounted and replaced.

Referring to fig. 3, the push plate limiting assembly includes a vertical adjusting frame 26 vertically moving in a "U" shape provided on an upper end surface of the lower support plate 223; the vertical adjusting frame 26 is positioned between the auxiliary roller 24 and the chamfering mechanism 30; a pair of vertical inserted bars 261 which are distributed front and back are formed on the lower end surface of the vertical adjusting frame 26; a pair of vertical insertion bars 261 vertically penetrate through the lower support plate 223; a push plate adjusting bolt 262 vertically penetrates through the lower support plate 223 and is screwed with the lower support plate; the upper end of the push plate adjusting bolt 262 is pivoted on the lower end surface of the vertical adjusting frame 26; a moving avoidance groove 101 with an upper opening and a lower opening for the left and right movement of the screw rod of the push plate adjusting bolt 262 and the vertical inserted link 261 is formed on the lower side wall of the left and right moving groove 100; front and rear blocking assemblies are provided in the opening of the vertical adjustment frame 26 at the front and rear, respectively. In this way, the pushing plate 40 can be adjusted in vertical position along with the vertical movement of the vertical adjusting frame 26, so that the pushing plate 40 is at a proper height when being processed.

Referring to fig. 3 and 5, the front-rear blocking assembly includes front and rear baffles 27; a pair of left and right guide posts 271 are formed on the end surfaces of the pair of front and rear baffles 27 which are spaced apart from each other; a pair of front and rear guide posts 271 penetrating through the vertical portions of the respective sides of the vertical adjustment frame 26 in the front-rear direction; a pair of vertical portions of the vertical adjustment frame 26 are passed through front and rear and are screwed with front and rear adjustment bolts 272; the inner ends of the front and rear adjusting bolts 272 are pivotally connected to the front and rear shutters 27 on the respective sides. The pair of front and rear shutters 27 contact the front and rear ends of the push plate 40, respectively, such that the cooperation of the pair of front and rear shutters 27 and the auxiliary roller 24 limits the push plate 40.

Referring to fig. 1, 2 and 4, a middle support frame 13 of a U shape with a downward opening is formed at the middle of the lower sidewall of the left and right moving groove 100; the chamfering mechanism 30 comprises a pair of chamfer upper rotating seats 35 which are distributed front and back, a pair of chamfer lower rotating seats 36 which are distributed front and back, a pair of driving rollers 37 which are distributed front and back, a chamfer driving assembly and a vertical adjusting assembly; the driving roller 37 is a cylinder with a driving chamfer groove 370 formed on the cylindrical surface; a plurality of active connecting slots 371 which are uniformly distributed on the circumference are respectively formed on the upper and lower end surfaces of the active roller 37; a plurality of active upper plug posts 351 matched with the active connecting plug 371 are formed on the lower end surface of the chamfer upper rotating seat 35; a plurality of active lower plug posts 361 matched with the active connecting plug slots 371 are formed on the upper end surface of the chamfer lower rotating seat 36; a pair of upper chamfer rotating seats 35 and a pair of lower chamfer rotating seats 36 are arranged in the opening of the middle supporting frame 13; the upper chamfering rotating seats 35 and the lower chamfering rotating seats 36 are in one-to-one correspondence, and the upper chamfering rotating seats 35 are positioned right above the lower chamfering rotating seats 36; the chamfer driving assembly drives a pair of chamfer lower rotating seats 36 to synchronously rotate; the vertical adjusting assembly drives a pair of upper chamfer rotating seats 35 to synchronously lift; a pair of upper chamfer rotating seats 35 and a pair of lower chamfer rotating seats 36 are respectively used for connecting a pair of driving rollers 37; when the driving roller 37 is dismounted, the vertical adjusting assembly drives the pair of upper chamfering rotating seats 35 to ascend, so that the driving roller 37 can be conveniently dismounted and replaced, and the driving roller 37 with different driving chamfer grooves 370 can be replaced according to pushing discs 40 with different thicknesses, so that the chamfering machine can process the pushing discs 40 with different thicknesses.

Referring to fig. 1, 2, 4 and 6, the chamfer driving assembly includes a reduction gearbox 32 fixed on the lower end surface of the horizontal support plate 12; the input shaft of the reduction gearbox 32 is connected with a chamfering motor 31, and the output shaft is fixed with a driving gear 33; a coaxially arranged driving column 362 is fixed on the lower end surface of the chamfering lower rotating seat 36; the driving column 362 vertically passes through and is rotatably provided on the lower sidewall of the left and right moving groove 100 and the horizontal support plate 12; a driven gear 38 is fixed at the lower end of the driving cylinder 362; a pair of driven gears 38 are respectively engaged with the driving gear 33. The chamfering motor 31 drives the driving gear 33 to rotate through the reduction gearbox 32, the driving gear 33 drives the chamfering lower rotating seat 36 to rotate through the pair of driven gears 38 and the pair of driving cylinders 362, and the chamfering lower rotating seat 36 drives the driving roller 37 to rotate.

Referring to fig. 1, 2 and 4, the vertical adjustment assembly includes a vertical adjustment plate 34; a pair of adjusting guide columns 341 are formed on the upper end surface of the vertical adjusting plate 34; a pair of adjusting guide posts 341 vertically pass through the horizontal portion of the middle supporting frame 13; the horizontal part of the middle supporting frame 13 is in threaded connection with a vertical adjusting bolt 342; the bottom of the vertical adjusting bolt 342 is pivoted on the upper end surface of the vertical adjusting plate 34; a pair of chamfer upper swivel seats 35 are rotatably provided on the lower end face of the vertical adjustment plate 34. The vertical adjusting plate 34 and the pair of upper chamfer rotating seats 35 thereon are driven to vertically move along the pair of adjusting guide columns 341 by screwing the vertical adjusting bolts 342, so that the pair of upper chamfer rotating seats 35 are separated from the pair of driving rollers 37.

The utility model relates to a working principle of a chamfering machine for processing a brake chamber push disc, which comprises the following steps:

according to the thickness of the push plate 40, a pair of driving rollers 37 and auxiliary rollers 24 which are matched with each other are replaced, (the auxiliary rollers 24 are replaced specifically by rotating the moving bolt 252 to drive the vertical moving seat 25 and the upper auxiliary roller connecting seat 23 on the vertical moving seat to ascend so as to replace the auxiliary rollers 24; the pair of driving rollers 37 are replaced specifically by rotating the vertical adjusting bolt 342 to drive the vertical adjusting plate 34 and the pair of chamfer upper rotating seats 35 on the vertical adjusting plate to ascend so as to replace the driving rollers 37); then, putting a push plate 40 into an opening of the vertical adjusting frame 26 at one side, driving a pair of front and rear baffles 27 to approach each other until the front and rear baffles 27 are respectively contacted with the front end and the rear end of the front and rear baffles 27, then moving the support frame 22 to the chamfering mechanism 30 until one end of the push plate 40 is contacted with a pair of driving rollers 37 and the other end is contacted with an auxiliary roller 24, and then synchronously rotating the pair of driving rollers 37 to chamfer the push plate 40; at this time, the next pushing disc 40 is placed in the opening of the vertical adjusting frame 26 at the other side according to the above principle, so that the chamfering processing of the subsequent pushing disc 40 is convenient, the chamfering processing of the pushing discs 40 with different thicknesses is adapted, and meanwhile, when one pushing disc 40 performs the chamfering processing, the other pushing disc 40 finishes feeding, so that the chamfering processing efficiency is high.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (8)

1. A beveler for processing brake chamber pushes away dish which characterized in that: comprises a workbench (10), a chamfering mechanism (30) and a pair of pushing disc limiting mechanisms (20); a rectangular groove-shaped left and right moving groove (100) is formed on the upper end surface of the workbench (10); the middle part of the lower side wall of the left-right moving groove (100) is provided with a U-shaped middle supporting frame (13) with a downward opening; the chamfering mechanism (30) comprises a pair of chamfering upper rotating seats (35) which are distributed front and back, a pair of chamfering lower rotating seats (36) which are distributed front and back, a pair of driving rollers (37) which are distributed front and back, a chamfering driving assembly and a vertical adjusting assembly; a pair of the chamfer upper rotating seats (35) and a pair of the chamfer lower rotating seats (36) are arranged in the opening of the middle supporting frame (13); the upper chamfering rotating seats (35) and the lower chamfering rotating seats (36) are in one-to-one correspondence, and the upper chamfering rotating seats (35) are positioned right above the lower chamfering rotating seats (36); the chamfer driving assembly drives a pair of chamfer lower rotating seats (36) to synchronously rotate; the vertical adjusting assembly drives a pair of upper chamfer rotating seats (35) to synchronously lift; the driving roller (37) is a cylinder with a driving chamfer groove (370) formed on the cylindrical surface; a plurality of active connecting slots (371) with evenly distributed circumferences are respectively formed on the upper end face and the lower end face of the active roller (37); a plurality of active upper plug posts (351) matched with the active connecting slots (371) are formed on the lower end surface of the chamfer upper rotating seat (35); a plurality of active lower plug posts (361) matched with the active connecting slots (371) are formed on the upper end surface of the chamfer lower rotating seat (36); the pair of pushing disc limiting mechanisms (20) are respectively arranged at the left side and the right side of the chamfering mechanism (30) and used for placing pushing discs (40).

2. A chamfering machine for machining brake chamber push disks as claimed in claim 1, characterized in that: four supporting feet (11) which are distributed in a rectangular shape are formed on the lower end surface of the workbench (10); a horizontal supporting plate (12) is formed among the four supporting legs (11); the chamfer driving assembly comprises a reduction gearbox (32) fixed on the lower end surface of the horizontal supporting plate (12); an input shaft of the reduction gearbox (32) is connected with a chamfering motor (31), and an output shaft is fixed with a driving gear (33); a driving cylinder (362) which is coaxially arranged is fixed on the lower end surface of the chamfering lower rotating seat (36); the driving column (362) vertically passes through and is rotatably arranged on the lower side wall of the left-right moving groove (100) and the horizontal supporting plate (12); a driven gear (38) is fixed at the lower end of the driving cylinder (362); a pair of the driven gears (38) are respectively engaged with the driving gears (33).

3. A chamfering machine for machining brake chamber push disks as claimed in claim 1, characterized in that: the vertical adjustment assembly includes a vertical adjustment plate (34); a pair of adjusting guide posts (341) are formed on the upper end surface of the vertical adjusting plate (34); a pair of adjusting guide posts (341) vertically penetrate through the horizontal part of the middle supporting frame (13); the horizontal part of the middle supporting frame (13) is in threaded connection with a vertical adjusting bolt (342); the bottom of the vertical adjusting bolt (342) is pivoted on the upper end surface of the vertical adjusting plate (34); the pair of chamfering upper rotating seats (35) are rotatably arranged on the lower end face of the vertical adjusting plate (34).

4. A chamfering machine for machining brake chamber push disks as claimed in claim 1, characterized in that: the pushing disc limiting mechanism (20) comprises a movable supporting frame (22) and a left-right driving assembly (21) which are arranged in the left-right movable groove (100) in a left-right movable mode; the left-right driving assembly (21) is used for driving the movable supporting frame (22) to move left and right; a pushing disc limiting assembly, an auxiliary roller (24) and an auxiliary roller mounting assembly are arranged on the movable supporting frame (22); the auxiliary roller mounting assembly is used for connecting the auxiliary roller (24) to the movable supporting frame (22); the pushing disc limiting assembly is positioned between the chamfering mechanism (30) and the auxiliary roller (24) and used for limiting the front-back position of the pushing disc (40); the auxiliary roller (24) is a cylinder with an auxiliary chamfer groove (240) formed on the cylindrical surface; the auxiliary roller (24) and the driving roller (37) are positioned on the same horizontal plane.

5. A chamfering machine for machining brake chamber push disks as defined in claim 4, wherein: the movable supporting frame (22) comprises a vertical connecting plate (221); an upper supporting plate (222) is formed at the upper end of the end surface of the vertical connecting plate (221) close to the middle supporting frame (13), and a lower supporting plate (223) is formed at the lower end of the vertical connecting plate; the left-right length of the upper support plate (222) is smaller than the left-right width of the lower support plate (223); the auxiliary roller (24) is positioned between the upper support plate (222) and the lower support plate (223); the push plate limiting assembly is located on a portion of the lower support plate (223) beyond the upper support plate (222).

6. A chamfering machine for machining brake chamber push disks as defined in claim 5, wherein: the pushing disc limiting assembly comprises a U-shaped vertical adjusting frame (26); a pair of vertical inserted bars (261) which are distributed front and back are formed on the lower end surface of the vertical adjusting frame (26); a pair of vertical insertion rods (261) vertically penetrating through the lower support plate (223); a push disc adjusting bolt (262) vertically penetrates through the lower supporting plate (223) and is screwed with the lower supporting plate; the upper end of the pushing disc adjusting bolt (262) is pivoted on the lower end surface of the vertical adjusting frame (26); front and rear blocking assemblies are respectively arranged in the opening of the vertical adjusting frame (26).

7. A chamfering machine for machining brake chamber push disks as defined in claim 6, wherein: the front and rear blocking assembly comprises a front and rear baffle (27); a pair of left and right distributed front and rear guide posts (271) are respectively formed on the end surfaces of the front and rear baffle plates (27) which are far away from each other; a pair of front and rear guide posts (271) passing through the vertical portions of the respective sides of the vertical adjustment frame (26) in the front-rear direction; front and rear adjusting bolts (272) penetrate through a pair of vertical parts of the vertical adjusting frame (26) in the front-rear mode and are connected with the vertical adjusting frames in a threaded mode; the inner ends of the front and rear adjusting bolts (272) are pivoted on the front and rear baffles (27) on the corresponding sides.

8. A chamfering machine for machining brake chamber push disks as defined in claim 5, wherein: the auxiliary roller mounting assembly comprises a vertical moving seat (25) and a pair of auxiliary roller connecting seats (23) which are distributed up and down; a plurality of movable guide posts (251) are formed on the upper end surface of the vertical movable seat (25); the movable guide post (251) vertically passes through the upper support plate (222); the upper supporting plate (222) vertically passes through and is screwed with a movable bolt (252); the lower end of the movable bolt (252) is pivoted on the upper end surface of the vertical movable seat (25); the auxiliary roller connecting seat (23) on the upper side is rotatably arranged on the upper end surface of the lower supporting plate (223), and the auxiliary roller connecting seat (23) on the lower side is rotatably arranged on the lower end surface of the vertical moving seat (25); a plurality of auxiliary connecting slots (241) with evenly distributed circumferences are respectively formed on the upper end face and the lower end face of the auxiliary roller (24); a plurality of auxiliary connecting inserting posts (231) matched with the auxiliary connecting slots (241) are respectively formed on the end surfaces of the pair of auxiliary roller connecting seats (23) which are close to each other.