CN111975686A

CN111975686A - Gearbox body machining system and method

Info

Publication number: CN111975686A
Application number: CN202010924449.2A
Authority: CN
Inventors: 刘婷婷
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-05
Filing date: 2020-09-05
Publication date: 2020-11-24

Abstract

The invention relates to the field of gearbox machining, in particular to a gearbox body machining system and method. The method comprises the following steps: the method comprises the following steps: detaching the circular shaft from the cylinder, sleeving a bearing to be installed on the front side of the circular ring, positioning the cylinder on the front side of the gearbox body, and positioning the circular ring on the rear side of the gearbox body; step two: the two door-shaped seats and the two V-shaped plates I are driven to mutually approach or separate, and then the two V-shaped plates I are driven to clamp the gearbox body; step three: and the round shaft penetrates through a bearing mounting hole in the gearbox body, and then the rear side of the round sheet is beaten, so that the round shaft and the round ring move forwards, and the round ring presses the bearing into the bearing mounting hole in the gearbox body. The rear end of the cylinder is connected with a circular shaft in a sliding mode, the middle of the circular shaft is fixedly connected with a circular ring, and the rear end of the circular shaft is fixedly connected with a wafer.

Description

Gearbox body machining system and method

Technical Field

The invention relates to the field of gearbox machining, in particular to a gearbox body machining system and method.

Background

The application number is CN201820169362.7 discloses a gearbox casing processing positioning fixture, which comprises a base, a side positioning clamping device, an adjusting device and an upper end positioning clamping device, wherein the front side in the upper end of the base is provided with a chute, a fixed plate is symmetrically arranged in an upper end mounting hole of the base, the inner side surface of the fixed plate is fixedly connected with the two sides of a leak hole support plate, a fixed bolt is arranged in an upper end threaded hole of the fixed plate, the bottom end thread of the fixed bolt is detachably connected with the threaded hole in the upper end mounting hole of the base, the gearbox casing processing positioning fixture has simple structure, convenient use and accurate positioning, brings great convenience for the use of workers, and can realize the omnibearing clamping and fixing of the gearbox casing through the side positioning clamping device and the upper end positioning clamping device according to the use requirement, is realized by an adjusting device. But this patent does not facilitate the mounting of bearings on the gearbox.

Disclosure of Invention

The invention provides a gearbox body processing system which has the beneficial effect that the bearing on a gearbox is convenient to install.

The invention relates to the field of gearbox processing, in particular to a gearbox body processing system which comprises a cylinder, a circular ring, a circular shaft and a circular sheet.

The rear end of the cylinder is connected with a circular shaft in a sliding mode, the middle of the circular shaft is fixedly connected with a circular ring, and the rear end of the circular shaft is fixedly connected with a wafer.

Gearbox box system of processing still includes hammer stem, tup, protrusion pole, driving lever, L shape arm and motor III, the upside of the lower extreme fixedly connected with drum of L shape arm, the upper portion of hammer stem articulates the upper portion rear end at L shape arm, the lower extreme fixedly connected with tup of hammer stem, the upper portion fixedly connected with protrusion pole of hammer stem, the upper portion of L shape arm is provided with motor III, fixedly connected with driving lever on motor III's the output shaft, the driving lever rotates the anterior once that the round pushed down protrusion pole.

Gearbox box processing system still includes the motor cabinet, and the vertical sliding connection of motor cabinet is on L shape arm, and motor III fixed connection is on the motor cabinet, and the motor cabinet is fixed through the mode that the screw compressed tightly with L shape arm.

The gearbox box processing system further comprises a vertical sliding column and a base, the vertical sliding column is vertically connected to the base in a sliding mode, the vertical sliding column and the base are fixed in a screw pressing mode, and the upper end of the vertical sliding column is fixedly connected to the lower side of the cylinder.

The gearbox box processing system further comprises a flat strip plate and a support, the support is fixedly connected to the left end and the right end of the lower side of the flat strip plate, and the cylinder is located on the upper side of the flat strip plate.

Gearbox box system of processing still includes the spout, double thread screw rod I, motor I, door shape seat and V-arrangement board I, be provided with the spout on the flat slat, equal sliding connection in both ends has the door shape seat about the spout, the upper portion of two door shape seats all is provided with V-arrangement board I, the right side fixedly connected with motor I of flat slat, fixedly connected with double thread screw rod I on motor I's the output shaft, double thread screw rod I is located the spout, the thread of both ends is opposite about double thread screw rod I, both ends are passed through the screw thread and are cooperated with two door shape seats respectively about double thread screw rod I.

The gearbox body processing system also comprises a sliding cylinder, an upright post, a sliding rail and a double-thread screw II, motor II, the cross axle, the lug, spout I and spout pole I, two V-arrangement board I's lower part all is provided with the lug, equal fixedly connected with cross axle on two lugs, two cross axles rotate the upper end of connecting at two door shape seats respectively, equal fixedly connected with spout pole I on two lugs, all be provided with spout I on two spout poles I, the front side fixedly connected with slide rail of flat board, the equal sliding connection in both ends has the stand about the slide rail, the equal fixedly connected with slide cylinder in upper portion of two stands, two slide cylinder difference sliding connection are on two spout I, the right side fixedly connected with motor II of flat board, fixedly connected with double thread screw rod II on motor II's the output shaft, the screw thread direction at both ends is opposite about double thread screw rod II, both ends cooperate with two stands respectively through the screw thread about double thread screw rod I.

Gearbox box system of processing still includes electric putter I, articulated convex seat, V shaped plate II, slide hole pole II, slide hole II and sliding pin, the articulated convex seat of the equal fixedly connected with in upper portion of two V shaped plate I, the articulated connection is on two articulated convex seats respectively in the lower part of two V shaped plate II, the equal fixedly connected with slide hole pole II in front of two V shaped plate II, all be provided with slide hole II on two slide hole pole II, the equal fixedly connected with electric putter I in front of two V shaped plate I, the equal fixedly connected with sliding pin in upper portion of two electric putter I, two sliding pin difference sliding connection are on two slide hole II.

The gearbox box processing system further comprises a front moving column, a rear moving column and a reinforcing rod, wherein the front moving column and the rear moving column are connected to the vertical sliding column in a sliding mode in the front-rear direction, the reinforcing rod is fixedly connected to the rear ends of the front moving column and the rear moving column, the reinforcing rod is attached to the front sides of the two V-shaped plates I, and the vertical sliding column and the front moving column and the rear moving column are fixed in a screw pressing mode.

A method for processing a gearbox body by a gearbox body processing system comprises the following steps:

the method comprises the following steps: detaching the circular shaft from the cylinder, sleeving a bearing to be installed on the front side of the circular ring, positioning the cylinder on the front side of the gearbox body, and positioning the circular ring on the rear side of the gearbox body;

step two: the two door-shaped seats and the two V-shaped plates I are driven to mutually approach or separate, and then the two V-shaped plates I are driven to clamp the gearbox body;

step three: and the round shaft penetrates through a bearing mounting hole in the gearbox body, and then the rear side of the round sheet is beaten, so that the round shaft and the round ring move forwards, and the round ring presses the bearing into the bearing mounting hole in the gearbox body.

The gearbox body processing system has the beneficial effects that:

the invention relates to a gearbox body processing system which is convenient for installing a bearing on a gearbox. Pull down the circle axle from the drum to the bearing housing that will need the installation is in the front side of ring, and make the drum be located the front side of gearbox box, make the ring be located the rear side of gearbox box, pass the bearing mounting hole on the gearbox box with the circle axle, then beat the rear side of disk, make circle axle and ring move forward, and then make on the ring pressed the bearing into the bearing mounting hole on the gearbox box, at this moment drum and ring push up both sides around the gearbox box respectively, make the bearing stable installation go into the bearing mounting hole.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an overall structure of a gearbox housing processing system according to the present invention;

FIG. 2 is a schematic diagram of an overall structure of a transmission housing processing system according to the present invention;

FIG. 3 is a schematic structural view of a flat plate;

FIG. 4 is a first structural schematic diagram of the door-shaped seat and the V-shaped plate II;

FIG. 5 is a schematic view of the structure of the cylinder and the hammer rod;

fig. 6 is a second structural schematic diagram of the door-shaped seat and the V-shaped plate II.

In the figure: a flat plate 1; a sliding cylinder 101; a chute 102; a double-thread screw I103; a column 104; a slide rail 105; a double-threaded screw II 106; a motor II 107; a bracket 108; a motor I109; a door-shaped seat 2; a horizontal axis 201; a bump 202; a V-shaped plate I203; an electric push rod I204; a hinge boss 205; a slide hole I206; a slide hole rod I207; v-shaped plate II 3; a slide hole rod II 301; a slide hole II 302; a slide pin 303; a cylinder 4; a vertical strut 401; a base 402; a front and rear moving column 403; a reinforcing rod 404; a circular ring 405; a circular shaft 406; a wafer 407; a hammer lever 5; a hammer head 501; a projecting rod 502; a deflector rod 503; an L-shaped arm 504; motor III 505; a motor mount 506.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 6, and the invention relates to the field of gearbox processing, in particular to a gearbox housing processing system, which comprises a cylinder 4, a circular ring 405, a circular shaft 406 and a circular sheet 407, and is convenient for mounting a bearing on a gearbox.

The rear end of the cylinder 4 is slidably connected with a round shaft 406, the middle part of the round shaft 406 is fixedly connected with a round ring 405, and the rear end of the round shaft 406 is fixedly connected with a round piece 407. During the use, pull down circle axle 406 from drum 4 to the bearing cover that will install is in the front side of ring 405, and make drum 4 be located the front side of gearbox box, make circle 405 be located the rear side of gearbox box, pass the bearing mounting hole on the gearbox box with circle axle 406, then beat the rear side of disk 407, make circle axle 406 and ring 405 move forward, and then make circle 405 press the bearing into on the bearing mounting hole on the gearbox box, at this moment drum 4 and ring 405 push up in the front and back both sides of gearbox box respectively, make the bearing stable installation go into the bearing mounting hole.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes a hammer rod 5, a hammer head 501, a protruding rod 502, a shift lever 503, an L-shaped arm 504 and a motor III505, the lower end of the L-shaped arm 504 is fixedly connected with the upper side of the cylinder 4, the upper portion of the hammer rod 5 is hinged to the rear end of the upper portion of the L-shaped arm 504, the lower end of the hammer rod 5 is fixedly connected with the hammer head 501, the upper portion of the hammer rod 5 is fixedly connected with the protruding rod 502, the upper portion of the L-shaped arm 504 is provided with the motor III505, the shift lever 503 is fixedly connected to the output shaft of the motor III505, and the shift lever 503 pushes down the. When the motor III505 rotates, the driving lever 503 is driven to rotate, the driving lever 503 presses down the front part of the protruding rod 502 once per rotation, and then the hammer rod 5 and the hammer head 501 are lifted up once, and after the driving lever 503 is separated from the protruding rod 502, the hammer rod 5 and the hammer head 501 hammer down, and then the wafer 407 and the circular shaft 406 are hammered forwards, and then the bearing is driven to be hammered into the bearing mounting hole.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 6, and the gearbox housing processing system further includes a motor base 506, the motor base 506 is vertically slidably connected to the L-shaped arm 504, the motor III505 is fixedly connected to the motor base 506, and the motor base 506 and the L-shaped arm 504 are fixed by means of screw compression. The motor base 506 can slide up and down on the L-shaped arm 504, so as to adjust the up-down position of the shifting lever 503, and further adjust the amplitude of the shifting lever 503 pressing the protruding rod 502 when rotating, and further adjust the lifting height of the hammer head 501, and further adjust the hammering force.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes a vertical sliding column 401 and a base 402, the vertical sliding column 401 is vertically slidably connected to the base 402, the vertical sliding column 401 and the base 402 are fixed by a screw compression method, and the upper end of the vertical sliding column 401 is fixedly connected to the lower side of the cylinder 4. The vertical sliding column 401 can vertically slide on the base 402, so that the height of the cylinder 4 can be adjusted, and bearings with different heights on the gearbox body can be conveniently installed.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes a flat plate 1 and a bracket 108, the bracket 108 is fixedly connected to both the left and right ends of the lower side of the flat plate 1, and the cylinder 4 is located on the upper side of the flat plate 1. Two brackets 108 are used for supporting the flat strip plate 1, and the flat strip plate 1 is used for placing a gearbox casing needing to be provided with a bearing.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes a sliding groove 102, a double-threaded screw I103, a motor I109, a door-shaped seat 2 and a V-shaped plate I203, the sliding groove 102 is provided on the flat plate 1, both ends of the sliding groove 102 are all slidably connected to the door-shaped seat 2, the upper portions of the two door-shaped seats 2 are all provided with the V-shaped plate I203, the right side of the flat plate 1 is fixedly connected to the motor I109, the double-threaded screw I103 is fixedly connected to an output shaft of the motor I109, the double-threaded screw I103 is located in the sliding groove 102, the thread directions of the left and right ends of the double-threaded screw I103 are opposite, and the left and right ends of the double-threaded screw I103. The motor I109 drives the double-thread screw I103 to rotate by taking the axis of the motor I as the axis, and then drives the two door-shaped seats 2 and the two V-shaped plates I203 to be close to or far away from each other, and then drives the two V-shaped plates I203 to clamp the gearbox body, and the V-shaped design of the V-shaped plates I203 is convenient for clamping the gearbox in the middle.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes a sliding cylinder 101, a vertical column 104, a sliding rail 105, a double-threaded screw II106, a motor II107, a horizontal shaft 201, a projection 202, a sliding hole I206, and a sliding hole rod I207, the lower portions of the two V-shaped plates I203 are each provided with a projection 202, the two projections 202 are each fixedly connected with a horizontal shaft 201, the two horizontal shafts 201 are respectively rotatably connected to the upper ends of the two door-shaped seats 2, the two projections 202 are each fixedly connected with a sliding hole rod I207, the two sliding hole rods I207 are each provided with a sliding hole I206, the front side of the flat plate 1 is fixedly connected with a sliding rail 105, the left and right ends of the sliding rail 105 are each slidably connected with a vertical column 104, the upper portions of the two vertical columns 104 are each fixedly connected with a sliding cylinder 101, the two sliding cylinders 101 are each slidably connected to the two sliding holes I206, the right side of the flat plate 1 is, the left and right ends of the double-thread screw II106 have opposite thread directions, and the left and right ends of the double-thread screw I103 are respectively matched with the two upright posts 104 through threads. When the motor II107 rotates, the double-thread screw II106 can be driven to rotate by taking the axis of the double-thread screw II as a shaft, so that the two upright posts 104 are driven to be close to or away from each other, and then the two sliding cylinders 101 are driven to be close to or away from each other, and when the two sliding cylinders 101 are driven to be close to or away from each other, the two sliding hole rods I207 are driven to rotate by taking the axes of the two transverse shafts 201 as shafts respectively, so that the two V-shaped plates I203 are driven to rotate by taking the axes of the two transverse shafts 201 as shafts respectively, and further the angle of the two V-shaped plates I203 is adjusted.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 6, the gearbox housing processing system further includes an electric push rod I204, an articulated boss 205, a V-shaped plate II3, a sliding hole rod II301, a sliding hole II302 and a sliding pin 303, the upper portions of the two V-shaped plates I203 are fixedly connected with the articulated boss 205, the lower portions of the two V-shaped plates II3 are respectively and hingedly connected to the two articulated boss 205, the front sides of the two V-shaped plates II3 are respectively and fixedly connected with the sliding hole rod II301, the two sliding hole rods II301 are respectively provided with the sliding hole II302, the front sides of the two V-shaped plates I203 are respectively and fixedly connected with the electric push rod I204, the upper portions of the two electric push rods I204 are respectively and fixedly connected with the sliding pin 303, and the two sliding pins 303 are respectively and slidably connected to. Two electric putter I204 can drive two sliding pin 303 and slide from top to bottom respectively when flexible, and then drive two slide hole pole II301 rotations, and then drive two V-arrangement board II3 and rotate on two articulated convex seats 205, angle between adjustment V-arrangement board II3 and the V-arrangement board I203, and then make two V-arrangement board II3 of upside can detain the upper portion at both ends about the gearbox, with the more firm fixed of gearbox box, prevent that the hammering from causing the displacement to the gearbox box.

The specific implementation method nine:

the present embodiment is described below with reference to fig. 1 to 6, the transmission case machining system further includes a front-rear moving column 403 and a reinforcing rod 404, the front-rear moving column 403 is slidably connected to the vertical sliding column 401 in the front-rear direction, the reinforcing rod 404 is fixedly connected to the rear end of the front-rear moving column 403, the reinforcing rod 404 is attached to the front sides of the two V-shaped plates I203, and the vertical sliding column 401 and the front-rear moving column 403 are fixed by means of screw compression. The front and rear moving columns 403 can move forward and backward, and then the front and rear positions of the reinforcing rod 404 are adjusted, so that the reinforcing rod 404 is attached to the front sides of the two V-shaped plates I203, and further the two V-shaped plates I203 are not stable enough when hammering.

the method comprises the following steps: detaching the circular shaft 406 from the cylinder 4, sleeving a bearing to be installed on the front side of the circular ring 405, positioning the cylinder 4 on the front side of the gearbox body, and positioning the circular ring 405 on the rear side of the gearbox body;

step two: the two door-shaped seats 2 and the two V-shaped plates I203 are driven to mutually approach or separate, and then the two V-shaped plates I203 are driven to clamp the gearbox body;

step three: the round shaft 406 is passed through the bearing mounting hole in the gearbox housing and then the rear side of the disc 407 is hammered so that the round shaft 406 and the ring 405 move forward so that the ring 405 presses the bearing into the bearing mounting hole in the gearbox housing.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. A gearbox housing system of processing, includes drum (4), ring (405), circle axle (406) and disk (407), its characterized in that: the rear end of the cylinder (4) is connected with a circular shaft (406) in a sliding mode, the middle of the circular shaft (406) is fixedly connected with a circular ring (405), and the rear end of the circular shaft (406) is fixedly connected with a circular sheet (407).

2. The gearbox housing machining system of claim 1, wherein: the gearbox box processing system further comprises a hammer rod (5), a hammer head (501), a protruding rod (502), a shifting lever (503), an L-shaped arm (504) and a motor III (505), the lower end of the L-shaped arm (504) is fixedly connected with the upper side of a cylinder (4), the upper portion of the hammer rod (5) is hinged to the rear end of the upper portion of the L-shaped arm (504), the lower end of the hammer rod (5) is fixedly connected with the hammer head (501), the upper portion of the hammer rod (5) is fixedly connected with the protruding rod (502), the upper portion of the L-shaped arm (504) is provided with the motor III (505), the shifting lever (503) is fixedly connected to an output shaft of the motor III (505), and the shifting lever (503) pushes down the front portion of the protruding rod (.

3. The gearbox housing machining system of claim 2, wherein: gearbox box processing system still includes motor cabinet (506), and vertical sliding connection of motor cabinet (506) is on L shape arm (504), and motor III (505) fixed connection is on motor cabinet (506), and motor cabinet (506) are fixed through the mode that the screw compressed tightly with L shape arm (504).

4. A transmission housing machining system according to claim 3 wherein: the gearbox box processing system further comprises a vertical sliding column (401) and a base (402), wherein the vertical sliding column (401) is vertically connected to the base (402) in a sliding mode, the vertical sliding column (401) and the base (402) are fixed in a screw pressing mode, and the upper end of the vertical sliding column (401) is fixedly connected to the lower side of the cylinder (4).

5. The gearbox housing machining system of claim 4, wherein: the gearbox box body processing system further comprises a flat strip plate (1) and a support (108), the left end and the right end of the lower side of the flat strip plate (1) are fixedly connected with the support (108), and the cylinder (4) is located on the upper side of the flat strip plate (1).

6. The gearbox housing machining system of claim 5, wherein: gearbox box system of processing still includes spout (102), double thread screw rod I (103), motor I (109), door shape seat (2) and V-arrangement board I (203), be provided with spout (102) on flat slat (1), both ends equal sliding connection has door shape seat (2) about spout (102), the upper portion of two door shape seats (2) all is provided with V-arrangement board I (203), the right side fixedly connected with motor I (109) of flat slat (1), fixedly connected with double thread screw rod I (103) on the output shaft of motor I (109), double thread screw rod I (103) are located spout (102), the screw thread direction of both ends is opposite about double thread screw rod I (103), both ends cooperate with two door shape seats (2) respectively through the screw thread about double thread screw rod I (103).

7. The gearbox housing machining system of claim 6, wherein: the gearbox body processing system further comprises sliding cylinders (101), upright posts (104), sliding rails (105), double-thread screw rods II (106), motors II (107), transverse shafts (201), lugs (202), sliding holes I (206) and sliding hole rods I (207), wherein the lugs (202) are arranged at the lower parts of the two V-shaped plates I (203), the transverse shafts (201) are fixedly connected to the two lugs (202), the two transverse shafts (201) are respectively and rotatably connected to the upper ends of the two door-shaped seats (2), the sliding hole rods I (207) are respectively and fixedly connected to the two lugs (202), the sliding holes I (206) are respectively arranged on the two sliding hole rods I (207), the sliding rails (105) are fixedly connected to the front side of the flat plate (1), the upright posts (104) are respectively and slidably connected to the left end and the right end of the sliding rails (105), the sliding cylinders (101) are respectively and fixedly connected to the upper parts of the two upright posts (104), and the two sliding cylinders (101) are respectively and slidably connected, the right side of the flat slat (1) is fixedly connected with a motor II (107), an output shaft of the motor II (107) is fixedly connected with a double-thread screw II (106), the thread directions of the left end and the right end of the double-thread screw II (106) are opposite, and the left end and the right end of the double-thread screw I (103) are respectively matched with the two upright posts (104) through threads.

8. The gearbox housing machining system of claim 7, wherein: gearbox box system of processing still includes electric putter I (204), articulated convex seat (205), V shaped plate II (3), slide opening pole II (301), slide opening II (302) and sliding pin (303), the equal fixedly connected with articulated convex seat (205) in upper portion of two V shaped plate I (203), the lower part of two V shaped plate II (3) articulates respectively and connects on two articulated convex seats (205), the equal fixedly connected with slide opening pole II (301) in front side of two V shaped plate II (3), all be provided with slide opening II (302) on two slide opening poles II (301), the equal fixedly connected with electric putter I (204) in front side of two V shaped plate I (203), the equal fixedly connected with sliding pin (303) in upper portion of two electric putter I (204), two sliding pin (303) are sliding connection respectively on two slide opening II (302).

9. The gearbox housing machining system of claim 8, wherein: the gearbox box processing system further comprises a front and rear moving column (403) and a reinforcing rod (404), the front and rear moving column (403) is connected to the vertical sliding column (401) in a sliding mode in the front and rear direction, the reinforcing rod (404) is fixedly connected to the rear ends of the front and rear moving column (403), the reinforcing rod (404) is attached to the front sides of the two V-shaped plates I (203), and the vertical sliding column (401) and the front and rear moving column (403) are fixed in a screw pressing mode.

10. The method of claim 8 for machining a transmission case with a transmission case machining system comprising the steps of:

the method comprises the following steps: detaching the circular shaft (406) from the cylinder (4), sleeving a bearing to be installed on the front side of the circular ring (405), positioning the cylinder (4) on the front side of the gearbox body, and positioning the circular ring (405) on the rear side of the gearbox body;

step two: the two door-shaped seats (2) and the two V-shaped plates I (203) are driven to mutually approach or separate, and then the two V-shaped plates I (203) are driven to clamp the gearbox body;

step three: the round shaft (406) penetrates through a bearing mounting hole in the gearbox body, then the rear side of the round plate (407) is beaten, so that the round shaft (406) and the round ring (405) move forwards, and the round ring (405) presses the bearing into the bearing mounting hole in the gearbox body.