CN112621248A

CN112621248A - Batch milling and polishing equipment for surfaces of cylindrical parts

Info

Publication number: CN112621248A
Application number: CN202011615327.1A
Authority: CN
Inventors: 张琦
Original assignee: Shijiazhuang Ganzhi Technology Co ltd
Current assignee: Jiangmen Xianbo Technology Co ltd
Priority date: 2020-12-30
Filing date: 2020-12-30
Publication date: 2021-04-09
Anticipated expiration: 2040-12-30
Also published as: CN112621248B

Abstract

The invention discloses a batch milling and polishing device for the surface of a cylindrical piece, which comprises a machine body, wherein a power cavity is arranged in the machine body, an annular rotating cavity is arranged on the upper side of the machine body, a support ring is fixedly arranged on the upper side of the machine body, a cavity is arranged in the support ring, a top plate is arranged on the upper side of the support ring, a support column is fixedly arranged on the upper side of the machine body, a processing cavity is arranged on the lower side of the support column, an ascending cavity is arranged on the upper side of the processing cavity, a descending cavity is arranged on the upper side of the ascending cavity, a sealed cavity is formed in the machine body and the top plate, a control device for controlling rotation is arranged in the machine body, a milling device for milling a cylindrical plane groove is arranged on the upper side of a movable spring, and a polishing device for polishing the plane groove is arranged on the lower side of the movable spring, the device can automatically realize, the safety risk of workers is reduced.

Description

Batch milling and polishing equipment for surfaces of cylindrical parts

Technical Field

The invention relates to the relevant field of machine polishing devices, in particular to batch milling and polishing equipment for surfaces of cylindrical parts.

Background

The surface of a cylindrical workpiece needs to be milled frequently in machining to form a flat surface, the planar machining of the cylindrical workpiece can be generally formed by milling by a milling machine, the machining efficiency of the machining mode is low, only one cylindrical workpiece can be machined at a time, the purpose of rapid machining cannot be achieved for machining a large number of cylindrical workpieces, the integral yield cannot be improved, the machining time can be prolonged by frequently loading and unloading the workpiece, the operation of workers is increased, and the safety risk is increased.

Disclosure of Invention

In order to solve the problems, the invention provides a batch milling and grinding device for the surface of a cylindrical part.

The invention is realized by the following technical scheme.

The invention relates to a batch milling and polishing device for the surface of a cylindrical part, which comprises a machine body, wherein a power cavity is arranged in the machine body, an annular rotating cavity is arranged on the upper side of the machine body, a support ring is fixedly arranged on the upper side of the machine body, a cavity is arranged in the support ring, a top plate is arranged on the upper side of the support ring, a support column is fixedly arranged on the upper side of the machine body, a processing cavity is arranged on the lower side of the support column, an ascending cavity is arranged on the upper side of the processing cavity, a descending cavity is arranged on the upper side of the ascending cavity, a sealed cavity is formed in the machine body and the top plate, a polishing body is fixedly arranged on the right side of the support column, a belt wheel;

the control device comprises a main motor fixedly arranged on the lower side wall of the power cavity, the main motor is in power connection with a motor shaft, a first belt wheel and a second belt wheel are fixedly arranged on the main motor, a supporting block is fixedly arranged on the lower side wall of the rotating cavity, a rotating ring is connected on the supporting block in a sliding manner, the side wall of the rotating cavity is in rotating connection with two first rotating shafts, a first belt wheel and a first belt wheel are respectively connected between the first belt wheel and the second belt wheel and the two first rotating shafts, a third belt wheel and a first gear are fixedly arranged on each first rotating shaft, the first gear is respectively meshed with the left side and the right side of the rotating ring, four rotating rods distributed circumferentially are fixedly arranged on the rotating ring and slide in the cavity, a rotating plate is arranged on the upper side of each rotating rod, four falling grooves distributed circumferentially are arranged in the rotating plate, a rotating sliding, an upper rotating rod, a lower rotating rod and two fixed blocks are fixedly arranged on each rotating rod, a milling body and an upper supporting plate are fixedly arranged on the left side of the supporting column, a lower supporting plate is fixedly arranged on the right side of the supporting ring in the movable spring, an upper side baffle is fixedly arranged on the upper supporting plate, the left side of the upper side baffle is a plane, a lower side baffle is fixedly arranged on the lower supporting plate, the right side of the lower side baffle is a plane, an upper material box is fixedly arranged on the upper side of the top plate, and the upper material box is communicated with the movable spring;

the upper side of the movable spring is provided with a milling device for milling a cylindrical plane groove, and the lower side of the movable spring is provided with a polishing device for polishing the plane groove.

Preferably, every sliding connection has telescopic fixture in the fixed block, telescopic fixture with be connected with expanding spring between the fixed block, two fixed grip blocks have set firmly in the telescopic fixture, every it has two removal pivots to slide in the fixed grip block, the removal is changeed and has been set firmly the centre gripping gyro wheel in the pivot, the centre gripping gyro wheel is the line that is equipped with the increase friction, use in the removal pivot gliding removal slider in the fixed grip block, remove the slider with be connected with the removal spring between the fixed grip block, upward the rotating rod downside has set firmly the circular arc sloping block, the rotating rod upside has set firmly down circular arc sloping block down, go up the circular arc sloping block with the circular arc sloping block is the circular arc sloping block down.

Preferably, a processing motor is fixedly arranged on the lower side wall of the processing cavity, the processing motor is in power connection with a processing rotating shaft, a second gear is fixedly arranged on the processing rotating shaft, a second rotating shaft is rotatably connected between the processing cavity and the ascending cavity, the second rotating shaft extends into the descending cavity, spring plates are fixedly arranged on the lower side and the upper side of the second rotating shaft respectively, a lifting spring is respectively connected between the spring plate and the upper side wall of the descending cavity and the lower side wall of the processing cavity, a gear III is fixedly arranged in the rotating shaft II, a first fixing sleeve and a second fixing sleeve are respectively and rotatably connected to the rotating shaft II, a descending rod is fixedly arranged on the first fixing sleeve, an ascending rod is fixedly arranged in the second fixing sleeve, a gear four meshed with the gear two is connected to the lower middle spline of the rotating shaft two in the machining cavity, and a rotating shaft three is rotatably connected between the gear four and the machining cavity.

Preferably, the milling device comprises a rotating shaft four which is rotatably installed on the upper side wall and the lower side wall of the descending cavity, a gear five and a bevel gear one are arranged on the rotating shaft four at high pressure, the left side wall of the descending cavity and the milling body are rotatably connected with a milling rotating shaft, a bevel gear two meshed with the bevel gear one is fixedly arranged on the right side of the milling rotating shaft, a milling cutter clamp is fixedly arranged on the left side of the milling rotating shaft, and a milling cutter is arranged in the milling cutter clamp.

Preferably, grinding device installs including rotating the pivot five of lateral wall about the chamber that rises, set firmly gear six and band pulley four in the pivot five, lateral wall rotates about the band pulley chamber and is connected with pivot six, set firmly band pulley five in the pivot six, set firmly two band pulleys six on the pivot six, band pulley four with be connected with belt two between the band pulley five, the lateral wall rotates about the chamber that polishes is connected with pivot seven, set firmly two band pulley seven in the pivot seven, every band pulley seven with be connected with belt three between the band pulley six, set firmly the wheel of polishing in the pivot seven.

The beneficial effects are that: the utility model provides an equipment of polishing mills in batches on cylinder surface, wherein controlling means can rotate and realize the automatic whereabouts of work piece, and accomplish in proper order and mill and polish back unloading, milling unit can carry out the plane milling to the cylinder work piece of pairing rotation, mill out the plane at the face of cylinder, grinding device can polish the cylinder plane, increase the precision, this equipment can realize automatically that planar batch mills and polishes in the cylinder, make it accomplish processing fast, the time of cylinder planar processing has significantly reduced, its process velocity and machining efficiency have been improved, and automatic processing has reduced the manual operation volume, workman's safety risk has been reduced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic top view of an embodiment of the present invention;

FIG. 2 is a cross-sectional view taken along the line A-A of FIG. 1 in accordance with an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 2 in accordance with an embodiment of the present invention;

FIG. 4 is a cross-sectional view taken along the line C-C of FIG. 2 in accordance with an embodiment of the present invention;

FIG. 5 is a cross-sectional view taken in the direction D-D of FIG. 2 in accordance with an embodiment of the present invention;

FIG. 6 is a cross-sectional view taken in the direction E-E of FIG. 2 in accordance with an embodiment of the present invention;

FIG. 7 is a cross-sectional view taken in the direction F-F of FIG. 2 in accordance with an embodiment of the present invention;

fig. 8 is an enlarged schematic view at G in fig. 5 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-8, wherein for ease of description the orientations described below are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 2 itself.

The invention relates to a device for milling and grinding surfaces of cylindrical parts in batches, which comprises a machine body 10, wherein a power cavity 85 is arranged in the machine body 10, an annular rotating cavity 86 is arranged on the upper side of the machine body 10, a support ring 22 is fixedly arranged on the upper side of the machine body 10, a cavity 92 is arranged in the support ring 22, a top plate 24 is arranged on the upper side of the support ring 22, a support pillar 23 is fixedly arranged on the upper side of the machine body 10, a processing cavity 87 is arranged on the lower side of the support pillar 23, an ascending cavity 88 is arranged on the upper side of the processing cavity 87, a descending cavity 89 is arranged on the upper side of the ascending cavity 88, a sealed cavity 93 is formed in the machine body 10 and the top plate 24, a grinding body 58 is fixedly arranged on the right side of the support pillar 23, a belt wheel cavity 90 and a grinding cavity 91 are arranged in the grinding body 58, a control device 94 for controlling rotation is arranged in, the main motor 11 is in power connection with a motor shaft 12, a first belt wheel 13 and a second belt wheel 14 are fixedly arranged on the main motor 2, a support block 19 is fixedly arranged on the lower side wall of the rotating cavity 86, a rotating ring 20 is slidably connected onto the support block 19, two first rotating shafts 16 are rotatably connected onto the side wall of the rotating cavity 86, a first belt 15 is respectively connected between the first belt wheel 13 and the second belt wheel 14 and the two first rotating shafts 16, a third belt wheel 17 and a first gear 18 are fixedly arranged on each first rotating shaft 16, the first gear 18 is respectively engaged with the left side and the right side of the rotating ring 20, four rotating rods 21 distributed circumferentially are fixedly arranged on the rotating ring 20, the rotating rods 21 slide in the cavity 92, a rotating plate 27 is arranged on the upper side of the rotating rods 21, four falling grooves 28 distributed circumferentially are arranged in the rotating plate 27, and a rotating sliding ring 26, the rotating plate 27 is fixedly connected with the rotating sliding ring 26, an upper rotating rod 29, a lower rotating rod 69 and two fixing blocks 68 are fixedly arranged on each rotating rod 21, a milling body 31 and an upper supporting plate 78 are fixedly arranged on the left side of the supporting column 23, a lower supporting plate 64 is fixedly arranged on the right side of the supporting ring 22 in the moving spring 73, an upper baffle 77 is fixedly arranged on the upper supporting plate 78, the left side of the upper baffle 77 is a plane, a lower baffle 65 is fixedly arranged on the lower supporting plate 64, the right side of the lower baffle 65 is a plane, an upper material box 25 is fixedly arranged on the upper side of the top plate 24, the upper material box 25 is communicated with the moving spring 73, a milling device 95 for milling a cylindrical plane groove is arranged on the upper side of the moving spring 73, and a polishing device 96 for polishing the plane groove is arranged on the.

Beneficially, a telescopic clamp 66 is slidably connected in each fixed block 68, a telescopic spring 67 is connected between the telescopic clamp 66 and the fixed block 68, two fixed clamping blocks 72 are fixedly arranged in the telescopic clamp 66, two movable rotating shafts 75 are slidably arranged in each fixed clamping block 72, a clamping roller 76 is fixedly arranged on each movable rotating shaft 75, the clamping roller 76 is provided with lines for increasing friction, a movable slider 74 sliding in the fixed clamping block 72 is used on each movable rotating shaft 75, a movable spring 73 is connected between each movable slider 74 and the fixed clamping block 72, an upper arc inclined block 30 is fixedly arranged on the lower side of the upper rotating rod 29, a lower arc inclined block 70 is fixedly arranged on the upper side of the lower rotating rod 69, both the upper arc inclined block 30 and the lower arc inclined block 70 are arc inclined blocks, so as to start the main motor 11, and the motor shaft 12 rotates, the first belt wheel 13 and the second belt wheel 14 are driven to rotate, the first belt wheel 15 drives the third belt wheel 17 and the first gear 18 to rotate respectively, the rotating ring 20 is driven to rotate, the rotating rod 21 is driven to slide in the cavity 92, the rotating rod 21 drives the rotating plate 27, the upper rotating rod 29, the lower rotating rod 69 and the two fixing blocks 68 to rotate, a cylindrical member is placed in the upper material box 25, when the upper material box 25 is aligned with the lower dropping groove 28, the cylindrical member falls into the lower dropping groove 28 and then continues to fall into the telescopic fixture 66 on the upper side, the upper support plate 78 supports the cylindrical member, when the cylindrical member enters the telescopic fixture 66, the clamping roller 76 is pushed open, the moving spring 73 is compressed, the moving slider 74 slides in the fixed clamping block 72, and the moving spring 73 pushes the clamping roller 76 to clamp the cylindrical member, the cylinder is prevented from rotating, when the fixing block 68 on the upper side rotates to the left, the telescopic clamp 66 therein contacts the upper baffle 77 and is stopped by the upper baffle 77, the telescopic clamp 66 moves in the fixing block 68 and enters the fixing block 68 to compress the telescopic spring 67, the telescopic clamp 66 on the upper side drives the cylinder to move horizontally, when the fixing block 68 on the upper side rotates to be separated from the upper support plate 78, the cylinder falls down into the telescopic clamp 66 on the lower side and drives the clamping roller 76 to rotate, the cylinder enters the telescopic clamp 66 on the lower side and is held by the lower support plate 64, when the fixing block 68 on the lower side rotates to the right, the telescopic clamp 66 therein is stopped by the lower baffle 65, the telescopic clamp 66 on the lower side drives the cylinder to move horizontally, when the fixing block 68 on the lower side rotates to the front side, the cylindrical member breaks away from the lower support plate 64 and falls down, thereby realizing blanking.

Beneficially, a processing motor 59 is fixedly arranged on the lower side wall of the processing cavity 87, the processing motor 59 is in power connection with a processing rotating shaft 60, a second gear 61 is fixedly arranged on the processing rotating shaft 60, a second rotating shaft 38 is rotatably connected between the processing cavity 87 and the ascending cavity 88, the second rotating shaft 38 extends into the descending cavity 89, spring plates 39 are fixedly arranged on the lower side and the upper side of the second rotating shaft 38 respectively, a lifting spring 40 is connected between each spring plate 39 and the upper side wall of the descending cavity 89 and the lower side wall of the processing cavity 87 respectively, a third gear 45 is fixedly arranged in the second rotating shaft 38, a first fixed sleeve 37 and a second fixed sleeve 46 are rotatably connected on the second rotating shaft 38 respectively, a descending rod 35 is fixedly arranged on the first fixed sleeve 37, an ascending rod 47 is fixedly arranged in the second fixed sleeve 46, a fourth gear 63 meshed with the second gear 61 is in spline connection under the second rotating shaft 38 in the processing cavity 87, a third rotating shaft 62 is rotatably connected between the fourth gear 63 and the processing cavity 87, so that the processing motor 59 is started, the processing rotating shaft 60 rotates to drive the second gear 61 to rotate, the second gear 61 drives the fourth gear 63 and the second rotating shaft 38 to rotate to drive the third gear 45 to rotate, when the lower arc inclined block 70 rotates to the left side of the moving spring 73, the lower arc inclined block 70 pushes the lifting rod 47 to ascend, drives the second rotating shaft 38 to ascend, makes the third gear 45 ascend, stretches and compresses the lifting spring 40, at this time, the upper arc inclined block 30 does not contact the lowering rod 35, when the lower circular arc inclined block 70 continues to rotate, the upper circular arc inclined block 30 contacts and pushes the descending rod 35 to descend, the lower arc inclined block 70 is separated from the lifting rod 47, so that the second rotating shaft 38 and the third gear 45 are lowered.

Advantageously, the milling device 95 comprises a rotating shaft four 42 rotatably mounted on the upper and lower side walls of the descending cavity 89, a gear five 44 and a bevel gear one 43 are mounted on the rotating shaft four 42 under high pressure, a milling rotating shaft 32 is rotatably connected in the left side wall of the descending cavity 89 and the milling body 31, a bevel gear two 41 meshed with the bevel gear one 43 is fixedly mounted on the right side of the milling rotating shaft 32, a milling cutter holder 33 is fixedly mounted on the left side of the milling rotating shaft 32, a milling cutter 34 is arranged in the milling cutter holder 33, so that when the gear three 45 ascends, the gear three 45 is meshed with the gear five 44, the gear three 45 drives the gear five 44 and the bevel gear one 43 to rotate, the bevel gear one 43 drives the bevel gear two 41 and the milling rotating shaft 32 to rotate the holder milling cutter 33 and the milling cutter 34, and the milling cutter 34 mills the moving cylindrical member, and milling a plane.

Advantageously, the grinding device 96 comprises a rotating shaft five 48 rotatably mounted on the upper and lower side walls of the ascending cavity 88, a gear six 49 and a pulley four 50 are fixedly arranged on the rotating shaft five 48, a rotating shaft six 52 is rotatably connected to the upper and lower side walls of the pulley cavity 90, a pulley five 53 is fixedly arranged in the rotating shaft six 52, two pulleys six 71 are fixedly arranged on the rotating shaft six 52, a belt two 51 is connected between the pulley four 50 and the pulley five 53, a rotating shaft seven 54 is rotatably connected to the upper and lower side walls of the grinding cavity 91, two pulleys seven 55 are fixedly arranged in the rotating shaft seven 54, a belt three 56 is connected between each pulley seven 55 and the pulley six 71, a grinding wheel 57 is fixedly arranged in the rotating shaft seven 54, so that when the gear three 45 descends, the gear three 45 is engaged with the gear six 49, the gear three 45 drives the gear six 49 and the pulley four 50 to rotate, the belt II 51 drives the belt wheel V53 and the belt wheel V71 to rotate, the belt III 56 drives the belt wheel V55 and the grinding wheel 57 to rotate, and the grinding wheel 57 grinds the milling plane of the cylindrical part, so that the plane precision is increased.

In the initial state, the main motor 11 is not started, and the third gear 45 is separated from the fifth gear 44 and the sixth gear 49.

When the work is started, the main motor 11 is started, the motor shaft 12 rotates to drive the belt wheel I13 and the belt wheel II 14 to rotate, the belt I15 respectively drives the two belt wheel III 17 and the gear I18 to rotate, the rotating ring 20 is driven to rotate, the rotating rod 21 is driven to slide in the cavity 92, the rotating rod 21 drives the rotating plate 27, the upper rotating rod 29, the lower rotating rod 69 and the two fixing blocks 68 to rotate, a cylindrical member is placed in the upper material box 25, when the upper material box 25 is aligned with the lower falling groove 28, the cylindrical member falls into the lower falling groove 28 and then continuously falls into the upper telescopic clamp 66, the upper support plate 78 supports the cylindrical member, when the cylindrical member enters the telescopic clamp 66, the clamping roller 76 is pushed open, the moving spring 73 is compressed, the moving slider 74 slides in the fixed clamping block 72, the moving spring 73 pushes the clamping roller 76 to clamp the cylindrical member, so that the cylindrical member cannot rotate, and when the upper fixing block 68 rotates to the left, wherein the telescopic clamp 66 contacts the upper baffle 77 and is blocked by the upper baffle 77, the telescopic clamp 66 moves in the fixed block 68 and enters the fixed block 68, the telescopic spring 67 is compressed, the upper telescopic clamp 66 drives the cylindrical part to move horizontally, when the upper fixed block 68 rotates to separate from the upper support plate 78, the cylindrical part falls down into the lower telescopic clamp 66 and drives the clamping roller 76 to rotate, the cylindrical part enters into the lower telescopic clamp 66 and is supported by the lower support plate 64, when the lower fixed block 68 rotates to the right side, the telescopic clamp 66 therein is blocked by the lower baffle 65, the lower telescopic clamp 66 drives the cylindrical part to move horizontally, when the lower fixed block 68 rotates to the front side, the cylindrical part separates from the lower support plate 64, the cylindrical part falls down to realize blanking, the processing motor 59 is started, the processing rotating shaft 60 rotates to drive the second gear 61 to rotate, the second gear 61 drives the fourth gear 63 and the second rotating shaft 38 to rotate, the third gear 45 is driven to rotate, when the lower arc-shaped inclined block 70 rotates to the left side of the moving spring 73, the lower arc-shaped inclined block 70 pushes the lifting rod 47 to lift, the second rotating shaft 38 is driven to lift, the third gear 45 is lifted, the lifting spring 40 is stretched and compressed, at the moment, the upper arc-shaped inclined block 30 does not contact with the lifting rod 35, when the lower arc-shaped inclined block 70 continues to rotate, the upper arc-shaped inclined block 30 contacts and pushes the lifting rod 35 to descend, the lower arc-shaped inclined block 70 is separated from the lifting rod 47, the second rotating shaft 38 and the third gear 45 descend, when the third gear 45 rises, the third gear 45 is meshed with the fifth gear 44, the third gear 45 drives the fifth gear 44 and the first bevel gear 43 to rotate, the first bevel gear 43 drives the second bevel gear 41 and the milling rotating shaft 32 to rotate, the milling cutter 33 and the milling cutter 34 are driven to mill a cylindrical part in motion, a plane, when the third gear 45 descends, the third, the gear III 45 drives the gear VI 49 and the belt wheel IV 50 to rotate, the belt II 51 drives the belt wheel V53 and the belt wheel VI 71 to rotate, the belt III 56 drives the belt wheel V55 and the grinding wheel 57 to rotate, and the grinding wheel 57 grinds the milling plane of the cylindrical part to increase the plane precision.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a cylinder surface mills equipment of polishing in batches, includes the organism, its characterized in that: the machine body is internally provided with a power cavity, an annular rotating cavity is arranged on the upper side of the machine body, a support ring is fixedly arranged on the upper side of the machine body, a cavity is arranged in the support ring, a top plate is arranged on the upper side of the support ring, a support column is fixedly arranged on the upper side of the machine body, a processing cavity is arranged on the lower side of the support column, an ascending cavity is arranged on the upper side of the processing cavity, a descending cavity is arranged on the upper side of the ascending cavity, a sealing cavity is formed in the machine body and the top plate, a grinding body is fixedly arranged on the right side of the support column, a belt wheel cavity and a grinding cavity are arranged in;

2. The batch milling and grinding device for the surfaces of cylindrical parts according to claim 1, wherein: every sliding connection has telescopic fixture in the fixed block, telescopic fixture with be connected with expanding spring between the fixed block, two fixed grip blocks have set firmly in the telescopic fixture, every it has two removal pivots to slide in the fixed grip block, the removal has set firmly the centre gripping gyro wheel in the pivot, the centre gripping gyro wheel is the line that is equipped with the increase friction, use in the removal pivot gliding removal slider in the fixed grip block, remove the slider with be connected with the removal spring between the fixed grip block, upward the bull stick downside has set firmly circular arc sloping block, the bull stick upside has set firmly down circular arc sloping block down, go up the circular arc sloping block with the circular arc sloping block is the circular arc sloping block down.

3. The batch milling and grinding device for the surfaces of cylindrical parts according to claim 1, wherein: a processing motor is fixedly arranged on the lower side wall of the processing cavity, the processing motor is in power connection with a processing rotating shaft, a second gear is fixedly arranged on the processing rotating shaft, a second rotating shaft is rotatably connected between the processing cavity and the ascending cavity, the second rotating shaft extends into the descending cavity, spring plates are fixedly arranged on the lower side and the upper side of the second rotating shaft respectively, a lifting spring is respectively connected between the spring plate and the upper side wall of the descending cavity and the lower side wall of the processing cavity, a gear III is fixedly arranged in the rotating shaft II, a first fixing sleeve and a second fixing sleeve are respectively and rotatably connected to the rotating shaft II, a descending rod is fixedly arranged on the first fixing sleeve, an ascending rod is fixedly arranged in the second fixing sleeve, a gear four meshed with the gear two is connected to the lower middle spline of the rotating shaft two in the machining cavity, and a rotating shaft three is rotatably connected between the gear four and the machining cavity.

4. The batch milling and grinding device for the surfaces of cylindrical parts according to claim 1, wherein: the milling device comprises a rotating shaft four which is rotatably arranged on the upper side wall and the lower side wall of the descending cavity, a gear five and a bevel gear one are arranged on the rotating shaft four during high pressure, the left side wall of the descending cavity and the milling body are rotatably connected with a milling rotating shaft, a bevel gear two meshed with the bevel gear one is fixedly arranged on the right side of the milling rotating shaft, a milling cutter clamp is fixedly arranged on the left side of the milling rotating shaft, and a milling cutter is arranged in the milling cutter clamp.

5. The batch milling and grinding device for the surfaces of cylindrical parts according to claim 1, wherein: grinding device installs including rotating the pivot five of lateral wall about the chamber that rises, set firmly gear six and band pulley four in the pivot five, lateral wall rotates about the band pulley chamber and is connected with pivot six, band pulley five has set firmly in the pivot six, two band pulleys six have set firmly in the pivot six, band pulley four with be connected with belt two between the band pulley five, the lateral wall rotates about the chamber that polishes and is connected with pivot seven, two band pulley seven have set firmly in the pivot seven, every band pulley seven with be connected with belt three between the band pulley six, set firmly the wheel of polishing in the pivot seven.