CN114289768B

CN114289768B - Carrier roller shaft clamp spring groove milling machine

Info

Publication number: CN114289768B
Application number: CN202111662142.0A
Authority: CN
Inventors: 于立阳
Original assignee: Shandong Mingyang Transportation Equipment Co ltd
Current assignee: Shandong Mingyang Transportation Equipment Co ltd
Priority date: 2021-12-30
Filing date: 2021-12-30
Publication date: 2022-12-27
Anticipated expiration: 2041-12-30
Also published as: CN115722707A; CN114289768A; CN116197439A

Abstract

The invention relates to the technical field of equipment manufacturing, in particular to a snap spring groove milling machine for a carrier roller shaft. It includes the processing body, and the processing body includes the frame, and the processing district has been seted up at the frame top, and the symmetry is equipped with a slide rail in the processing district, and a slide rail connection has the milling groove body, and the milling groove body includes at least: the workbench comprises two tables, the tables are provided with a first groove and a second slide rail, the tables are provided with bearing power bodies, each bearing power body comprises a bearing plate, the middle of the top of each bearing plate is provided with a notch, the surfaces of the bearing plates are symmetrically provided with four openings, and a first roller is rotatably connected in each four opening; the cutter feeding body comprises a cutter feeding plate, four sliding rails are symmetrically arranged on the top of the cutter feeding plate, the top of each sliding rail is connected with a disc milling cutter power body, each disc milling cutter power body comprises a third plate, a fourth motor is arranged on the top of each third plate, a groove milling cutter is connected in a transmission mode through the fourth motor, and three grooves are symmetrically formed in the bottom of each third plate. The invention mainly provides a snap spring groove milling machine for a carrier roller shaft.

Description

Carrier roller shaft clamp spring groove milling machine

Technical Field

The invention relates to the technical field of equipment manufacturing, in particular to a snap spring groove milling machine for a carrier roller shaft.

Background

The groove milling is to cut a required groove through a specific cutter, the steps are generally to directly lower the groove by a certain depth through a groove center line, mill the groove, lower the groove and mill back and forth to a specified depth, and then finish mill the groove to a size according to the width of the groove, the groove milling is generally a milling cutter in the form of a vertical milling cutter and a disc saw blade, and in the cutting process, according to different materials and processing requirements, the requirements on the whole machine tool are high, such as the number of teeth of the cutter, the rotating speed of a main shaft power head, the attribute of cutting fluid and the structural rigidity of the whole machine tool.

Need carry out the timing to the precision of milling flutes equipment during the milling flutes, and the unable regulation of notch interval of current milling flutes equipment to current milling flutes processing equipment needs the manual work to carry out the clamping, and the clamping number of times is many, and is long during the worker, and the expense is higher, is unfavorable for improving production efficiency, has certain limitation during batch production, consequently needs a bearing roller axle to mill jump ring scouring machine.

Disclosure of Invention

The invention aims to provide a snap spring slotter for milling a carrier roller shaft, which aims to solve the problems in the background technology.

In order to achieve the above object, the present invention provides a roller carrier shaft groove milling machine with a snap spring, which comprises a processing body, wherein the processing body comprises a rack, the rack is a cube, a processing area is arranged at the top of the rack, a first slide rail is symmetrically arranged in the processing area, the first slide rail is connected with a groove milling body, and the groove milling body at least comprises:

the workbench comprises two tables, a first groove is symmetrically formed in the bottom of each table, the first groove is connected with the first sliding rail in a sliding mode, a second sliding rail is symmetrically formed in the surface of one end of the top of each table, a bearing power body is arranged on the surface of one end, away from the second sliding rail, of the top of each table, the bearing power body comprises a bearing plate, the bottom of each bearing plate is connected with the top of each table, a notch is formed in the middle of the top of each bearing plate, four openings are symmetrically formed in the surface of each bearing plate, and a first roller is rotatably connected in each four openings;

the cutter feeding body comprises a cutter feeding plate, four sliding rails are symmetrically arranged on the top of the cutter feeding plate, the top of the four sliding rails is connected with a disc milling cutter power body, the disc milling cutter power body comprises a third plate, a fourth motor is arranged on the top of the third plate, a groove milling cutter is connected in transmission with the fourth motor, a third groove is symmetrically arranged on the bottom of the third plate, and the third groove is connected with the fourth sliding rails in a sliding mode.

As a further improvement of the technical scheme, two ends of one side of the rack are symmetrically provided with side plates, the side plates are provided with a first opening penetrating through the surfaces of the side plates, the side plates are connected with an axial adjusting body, the axial adjusting body comprises a first motor located on one side of the side plates, the first motor penetrates through the side plates and is connected with a reciprocating screw rod in a transmission mode, one end of the reciprocating screw rod is located in the first opening and is connected with the first opening in a rotating mode, the surface of the reciprocating screw rod is provided with a first body and a second body, the first body is connected with the bedplate, the second body is connected with the other bedplate, the first body is provided with a second opening, the second body is provided with a third opening, the second opening and the third opening are circular penetrating openings with internal threads, and the rotating direction of the internal threads of the second opening is opposite to that of the internal threads of the third opening.

As a further improvement of the technical scheme, the first body and the second body are respectively provided with an inserting rod on one side, the surface of one side of the bedplate is provided with an inserting port, and the inserting rods are matched with the inserting ports in an inserting manner.

As a further improvement of the technical scheme, a positioning plate is arranged on one side of the third plate, a positioning body is arranged on one side of the positioning plate, a second groove is symmetrically formed in the bottom of the knife feeding plate and is an I-shaped groove, and the second groove is in sliding connection with the second sliding rail.

As a further improvement of the technical scheme, one end of the top of the feed plate is provided with a motor III, the motor III is in transmission connection with a screw, the other end of the top of the feed plate is provided with an end plate, one end of the screw is in rotation connection with the end plate, the bottom of the plate III is correspondingly provided with a bottom plate, and the screw penetrates through the bottom plate and is in threaded connection with the bottom plate.

As a further improvement of the technical scheme, the top of the platen is far away from a first plate is arranged on the surface of one end of a second sliding rail, a second plate is arranged on the top of the first plate, a movable avoiding body is arranged on the top of the second plate, the movable avoiding body comprises a avoiding plate connected with the second plate and the bottom of the avoiding plate, a top plate is arranged on the top of the avoiding plate, a pinch roller body is arranged at one end of the top plate and comprises a pinch roller plate connected with the top plate and a second hydraulic body, and the bottom of a hydraulic rod of the second hydraulic body penetrates through the pinch roller plate and is rotatably connected with a pinch roller cylinder.

As a further improvement of the technical scheme, a connecting plate is arranged at the joint of the hydraulic rod and the pinch roller cylinder, the connecting plate is a square plate, sliding rods are arranged at the tops of two ends of the connecting plate, and the tops of the sliding rods penetrate through the pinch roller plate to be in plug-in fit with the pinch roller plate.

As a further improvement of the technical scheme, no. three slide rails are symmetrically arranged at two ends of the top of the second plate, the No. three slide rails are I-shaped plates, the bottom of the avoiding plate is symmetrically provided with No. four grooves, the No. four grooves are I-shaped grooves, the No. four grooves are in sliding connection with the No. three slide rails, one end of the second plate is provided with a hydraulic body, and the hydraulic body is connected with the avoiding plate.

As a further improvement of the technical scheme, a second motor is arranged in the fourth port, one end of the second motor is in transmission connection with a second roller, and the second roller is rotatably connected with the fourth port at the other end.

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

1. in the clamp spring slot milling machine for the carrier roller shaft, the axial adjusting body is arranged, so that the first motor drives the reciprocating screw rod to rotate and further can drive the first body and the second body to move, the first body and the second body can be driven to be close to or away from each other when the reciprocating screw rod rotates, and the distance between the two platens can be adjusted conveniently.

2. In the groove milling machine for the snap spring of the carrier roller shaft, when the third motor drives the screw rod to rotate in a threaded connection mode, the third motor can drive the third plate in threaded connection with the screw rod to move at a constant speed along the fourth sliding rail, so that the groove milling of the groove milling cutter to the shaft material is facilitated.

3. In the carrier roller shaft snap spring groove milling machine, a sliding connection and a first hydraulic body are arranged, so that the first hydraulic body can drive the avoiding plate to move along a third sliding rail, the movable press wheel body is convenient to move, a second motor is arranged to drive a second roller to rotate, a shaft material is driven to rotate, the surface processing of a groove milling cutter on the shaft material is convenient, the clamping times are reduced, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the frame structure of the present invention;

FIG. 3 is a schematic view of an axial adjustment body according to the present invention;

FIG. 4 is a schematic view of the milling groove structure of the present invention;

FIG. 5 is a schematic view of the structure of the work table of the present invention;

FIG. 6 is a schematic structural diagram of a power-carrying body according to the present invention;

FIG. 7 is a schematic view of the structure of the feed body of the present invention;

FIG. 8 is a schematic cross-sectional view of the power body of the disc cutter of the present invention;

FIG. 9 is a schematic view of a mobile avoidance body of the present invention;

FIG. 10 is a schematic diagram of the puck body structure of the present invention.

The various reference numbers in the figures mean:

1. processing the body;

11. a frame; 12. a processing zone; 13. a first slide rail; 14. a side plate; 15. a first opening; 16. an axial adjustment body; 161. a first motor; 162. a reciprocating screw rod; 163. a first body; 164. body II; 165. a plug rod; 166. a second port; 167. a third opening;

2. milling a groove body;

21. a work table; 211. a platen; 212. a first groove; 213. a second sliding rail; 214. a first board; 215. a second plate; 216. an interface; 217. a third sliding rail;

22. a load bearing power body; 221. a carrier plate; 222. opening the gap; 223. a fourth port; 224. a first roller; 225. a second motor; 226. a second roller;

23. feeding a cutter body; 231. a cutter feeding plate; 232. a second groove; 233. a fourth sliding rail; 234. a third motor; 235. a screw; 236. an end plate;

24. a disc cutter power body; 241. a third plate; 242. positioning a plate; 243. a positioning body; 244. a fourth motor; 245. milling a groove cutter; 246. a third groove; 247. a base plate;

25. moving the avoidance body; 251. an avoidance plate; 252. a first hydraulic body; 253. a top plate; 254. a fourth groove;

26. a wheel pressing body; 261. a pressure wheel plate; 262. a second hydraulic body; 263. a hydraulic lever; 264. a connecting plate; 265. a slide bar; 266. pinch roller cylinder.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Example 1

Referring to fig. 1 to 8, an object of the present embodiment is to provide a snap spring slotter for milling a carrier roller shaft, which includes a processing body 1, the processing body 1 includes a rack 11, the rack 11 is a cube, a processing area 12 is provided at the top of the rack 11, the processing area 12 is a square groove, a first slide rail 13 is symmetrically provided in the processing area 12, the first slide rail 13 is an "i" shaped plate, the first slide rail 13 is connected to a milling groove body 2, and the milling groove body 2 at least includes:

the workbench 21 comprises two tables 211, the tables 211 are square plates, first grooves 212 are symmetrically arranged at the bottoms of the tables 211, the first grooves 212 are I-shaped structure grooves, the first grooves 212 are slidably connected with first sliding rails 13, second sliding rails 213 are symmetrically arranged on the surface of one end of the tops of the tables 211, the second sliding rails 213 are I-shaped plates, bearing power bodies 22 are arranged on the surfaces of the ends, far away from the second sliding rails 213, of the tops of the tables 211, the bearing power bodies 22 comprise bearing plates 221, the bottoms of which are connected with the tops of the tables 211, the bearing plates 221 are U-shaped plates, notches 222 are formed in the middles of the tops of the bearing plates 221, four openings 223 are symmetrically formed in the surfaces of the bearing plates 221, the four openings 223 are circular penetrating openings, and first rollers 224 are rotatably connected in the four openings 223;

the cutter feeding body 23 comprises a cutter feeding plate 231, the top of the cutter feeding plate 231 is symmetrically provided with four sliding rails 233, the four sliding rails 233 are I-shaped plates, the top of the four sliding rails 233 is connected with a disc milling cutter power body 24, the disc milling cutter power body 24 comprises a three plate 241, the three plate 241 is a square plate, the top of the three plate 241 is provided with a four motor 244, the four motor 244 is in transmission connection with a milling groove cutter 245, the bottom of the three plate 241 is symmetrically provided with a three groove 246, the three groove 246 is an I-shaped groove, and the three groove 246 is in sliding connection with the four sliding rails 233.

In the embodiment, when the shaft material to be milled is placed in the notch 222, after the surface of the shaft material is contacted with the first roller 224, the first motor 161 drives the reciprocating screw rod 162 to rotate in the first opening 15, the first body 163 and the second body 164 which are in threaded connection with the reciprocating screw rod 162 are driven when the reciprocating screw rod 162 rotates, that is, the two platens 211 move along the first sliding rail 13 to adjust the distance between the two platens 211, when the platens 211 move, the two ends of the shaft material are contacted with the positioning body 243, the feed plate 231 moves on the surface of the second sliding rail 213, the third plate 241 moves on the surface of the fourth sliding rail 233, the two ends of the shaft material are respectively aligned and positioned with the surface of the positioning body 243, the fourth motor 244 drives the milling cutter 245 to rotate at a high speed, the third motor 234 drives the screw rod 235 to rotate in the end plate 236, so that the bottom plate 247 which is in threaded connection with the screw rod 235 drives the third plate 241 to move along the fourth sliding rail 233, until the milling cutter 245 is close to the surface of the shaft material and mill the groove.

Further, in order to adjust the distance between the two platens 211 conveniently, two ends of one side of the frame 11 are symmetrically provided with side plates 14, each side plate 14 is a square plate, each side plate 14 is provided with a first opening 15 penetrating through the surface of each side plate, each first opening 15 is a circular through opening, each side plate 14 is connected with an axial adjusting body 16, each axial adjusting body 16 comprises a first motor 161 located on one side of each side plate 14, each first motor 161 penetrates through the corresponding side plate 14 to be connected with a reciprocating screw rod 162 in a transmission mode, one end of each reciprocating screw rod 162 is located in the corresponding first opening 15 to be connected with the corresponding first opening 15 in a rotating mode, the surface of each reciprocating screw rod 162 is provided with a first body 163 and a second body 164, each first body 163 is connected with one platen 211, each second body 164 is connected with another platen 211, each first body 163 is provided with a second opening 166, each second body 164 is provided with a third opening 167, each second opening 166 and each third opening 167 are both internally threaded, the rotating direction of the internal threads of each second opening 166 is opposite to the rotating direction of the internal threads of the third opening 167, each second body 161 is opposite to the rotating direction of the internal threads, each other, the first motor 161, the axial adjusting body 161 drives the screw rod 161 to rotate so as to drive the first screw rod 162 and the second body 164 to move away from the first opening, and the second opening 164, and the reciprocating screw rod 162, and the second body 164, and the reciprocating screw rod 162, and the reciprocating screw rod 164 are opposite directions of the reciprocating screw rod 162 are opposite to drive the reciprocating screw rod 162, and the reciprocating screw rod 162 to be away from the reciprocating body, and the reciprocating direction of the reciprocating body 162, and the reciprocating body 162, so that the reciprocating body can be away from the reciprocating body.

Further, in order to be convenient for being connected with the bedplate 211, the first body 163 and the second body 164 are respectively provided with the plug rod 165 on one side, the surface of one side of the bedplate 211 is provided with the plug port 216, the plug rod 165 is in plug fit with the plug port 216, and the axial adjusting body 16 can be connected with the workbench 21 by adopting a plug fit mode, so that the distance between the notches is adjustable.

Still further, in order to avoid the occurrence of groove milling skew, the shaft material to be processed needs to be positioned, a positioning plate 242 is arranged on one side of a third plate 241, the positioning plate 242 is a square plate, a positioning body 243 is arranged on one side of the positioning plate 242, the positioning body 243 is of a partial conical structure, a second groove 232 is symmetrically formed in the bottom of the feed plate 231, the second groove 232 is an 'I' shaped groove, the second groove 232 is slidably connected with a second sliding rail 213, two ends of the shaft material are clamped through the positioning body 243, when the two table plates 211 are close to each other, the shaft material is extruded, and the shaft material can be positioned and aligned just opposite to the positioning body 243 by moving the disc milling cutter power body 24 through the second sliding rail 213 and the second groove 232 which are slidably connected.

Further, in order to facilitate the groove milling of the shaft material, one end of the top of the cutter feeding plate 231 is provided with the third motor 234, the third motor 234 is in transmission connection with the screw 235, the other end of the top of the cutter feeding plate 231 is provided with the end plate 236, the end plate 236 is a square plate provided with a circular through hole, one end of the screw 235 is in rotation connection with the end plate 236, the bottom of the third plate 241 is correspondingly provided with the bottom plate 247, the bottom plate 247 is a square plate provided with a circular through hole, the screw 235 passes through the bottom plate 247 and is in threaded connection with the bottom plate 247, when the third motor 234 drives the screw 235 to rotate through the mode of threaded connection, the third plate 241 in threaded connection with the screw 235 can be driven to move along the fourth sliding rail 233 at a constant speed, and therefore the groove milling of the groove cutter 245 to the shaft material is facilitated.

Example 2

Referring to fig. 9-10, in order to avoid vibration of the shaft material during groove milling, the following modifications are made in this embodiment based on embodiment 1:

wherein, when considering to carry out the milling flutes to the axle material, thereby the axle material can shake influences the milling flutes effect, in order to fix the axle material, platen 211 top is kept away from No. two slide rail 213 one end surfaces and is equipped with a board 214, a board 214 top is equipped with No. two boards 215, a board 214 and No. two boards 215 are the square plate, no. two board 215 tops are equipped with the removal and dodge body 25, the removal is dodged body 25 and is included the bottom and dodge board 251 that No. two boards 215 are connected, it is equipped with roof 253 to dodge board 251 top, roof 253 is "L" template, roof 253 top one end is equipped with pinch roller 26, pinch roller 26 includes pinch roller 261 that bottom and roof 253 are connected, pinch roller board is the square plate, pinch roller 261 middle part is equipped with No. two hydraulic pressure body 262, pinch roller 261 passes pinch roller 261 rotation and is connected with pinch roller 266, through being equipped with pinch roller 266 and cylinder 224 cooperation multiple spot contact, can stabilize the connection to the axle material, thereby avoid the vibrations of axle material.

Further, in order to ensure the vertical removal of pinch roller 266, thereby ensure the fixed effect to the axle material, hydraulic stem 263 is equipped with connecting plate 264 with pinch roller 266 junction, connecting plate 264 is the square plate, connecting plate 264 both ends top is equipped with slide bar 265, press wheel plate 261 and pinch roller plate 261 grafting cooperation are passed at the slide bar 265 top, through adopting grafting complex mode, make hydraulic stem 263 can drive pinch roller 266 and carry out the ascending removal of vertical side, avoid pinch roller 266 to take place the ascending rotation of horizontal direction, thereby ensure the fixed effect to the axle material.

Further, in order to facilitate the placement of the shaft material, the pressure wheel body 26 needs to be moved, a third slide rail 217 is symmetrically arranged at two ends of the top of the second plate 215, the third slide rail 217 is an 'I' shaped plate, a fourth groove 254 is symmetrically arranged at the bottom of the avoidance plate 251, the fourth groove 254 is an 'I' shaped groove, the fourth groove 254 is in sliding connection with the third slide rail 217, one end of the second plate 215 is provided with a first hydraulic body 252, the first hydraulic body 252 is connected with the avoidance plate 251, and the first hydraulic body 252 can drive the avoidance plate 251 to move along the third slide rail 217 through the mode of being provided with the sliding connection and the first hydraulic body 252, so that the purpose of moving the pressure wheel body 26 is facilitated.

Still further, in order to reduce the clamping number of times, improve machining efficiency, be equipped with No. two motors 225 in No. four mouths 223, no. two motor 225 one end transmission is connected with No. two cylinders 226, no. two cylinders 226 rotates with No. four mouths 223 of the other end and is connected, it is rotatory to drive No. two cylinders 226 through being equipped with No. two motors 225, thereby make the axle material with a cylinder 224 and No. two cylinder 226 contact driven rotatoryly, thereby be convenient for facing (operation) of slot milling cutter 245 to the axle material, reduce the clamping number of times, and the production efficiency is improved.

Example 3

Considering that the milling cutter 245 has a wear problem in use, in order to ensure that the depth of the clamp spring groove of the same batch of products is the same and improve the machining precision, the embodiment is provided with the grating ruler, and by using the signal feedback of the grating ruler through the PLC programming technology, the cutter compensation is performed according to the wear condition of the milling cutter 245, x is x _q ＝x _p -x _pq ，z _q ＝z _p -z _pq The method comprises the steps of actually milling grooves by using a tool tip for contact, compensating the length of the tool for realizing the conversion between a tool tip track and a reference point, wherein p is the tool tip, q is the reference point, and if the circular arc radius of the tool tip is zero, the coordinate x of the tool tip point relative to the reference point is measured by using a tool length measuring device according to the signal feedback of a grating ruler _pq ，z _pq Storing the profile path of the shaft material into a tool complement memory table, wherein the profile path of the shaft material is cut out by a tool nose, a tool nose point p is programmed during programming, and the coordinate of the tool nose point p is set as x _p ，z _p The reference point coordinate is q (x) _q ，z _q ) Can be according to the formula x _q ＝x _p -x _pq ，z _q ＝z _p -z _pq And (4) calculating, and realizing compensation of the cutter by controlling the reference point q, thereby ensuring that the depth of the clamp spring grooves of the same batch of products is the same and improving the machining precision.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The bearing roller shaft mills jump ring scouring machine, its characterized in that: including the processing body (1), the processing body (1) includes frame (11), frame (11) are the cube, processing district (12) have been seted up at frame (11) top, processing district (12) interior symmetry is equipped with slide rail (13) No. one, slide rail (13) are connected with and mill cell body (2), mill cell body (2) and include at least:

the workbench (21) comprises two tables (211), a first groove (212) is symmetrically formed in the bottom of each table (211), the first groove (212) is connected with the first sliding rail (13) in a sliding mode, a second sliding rail (213) is symmetrically formed in the surface of one end of the top of each table (211), a bearing power body (22) is arranged on the surface of one end, away from the second sliding rail (213), of the top of each table (211), the bearing power body (22) comprises a bearing plate (221) with the bottom connected with the top of each table (211), a notch (222) is formed in the middle of the top of each bearing plate (221), a fourth opening (223) is symmetrically formed in the surface of each bearing plate (221), and a first roller (224) is connected in a rotating mode through the fourth opening (223);

the cutter feeding body (23) comprises a cutter feeding plate (231), the top of the cutter feeding plate (231) is symmetrically provided with a fourth sliding rail (233), the top of the fourth sliding rail (233) is connected with a disc milling cutter power body (24), the disc milling cutter power body (24) comprises a third plate (241), the top of the third plate (241) is provided with a fourth motor (244), the fourth motor (244) is in transmission connection with a slot milling cutter (245), the bottom of the third plate (241) is symmetrically provided with a third slot (246), and the third slot (246) is in sliding connection with the fourth sliding rail (233);

the two ends of one side of the rack (11) are symmetrically provided with side plates (14), the side plates (14) are provided with a first opening (15) penetrating through the surface of the side plates, the side plates (14) are connected with axial adjusting bodies (16), each axial adjusting body (16) comprises a first motor (161) located on one side of the side plate (14), each first motor (161) penetrates through the corresponding side plate (14) to be connected with a reciprocating screw rod (162) in a transmission mode, one end of each reciprocating screw rod (162) is located in the corresponding first opening (15) and is connected with the corresponding first opening (15) in a rotating mode, a first body (163) and a second body (164) are arranged on the surface of each reciprocating screw rod (162), the first body (163) is connected with the bedplate (211), the second body (164) is connected with the other bedplate (211), the first body (163) is provided with a second opening (166), the second body (164) is provided with a third opening (167), the second opening (166) and the third opening (166) are internally threaded, and the inner threaded openings in the opposite directions to the third internal thread opening (166);

a first plate (214) is arranged on the surface of one end, away from the second sliding rail (213), of the top of the bedplate (211), a second plate (215) is arranged on the top of the first plate (214), a movable avoiding body (25) is arranged on the top of the second plate (215), the movable avoiding body (25) comprises an avoiding plate (251) with the bottom connected with the second plate (215), a top plate (253) is arranged on the top of the avoiding plate (251), a pressure wheel body (26) is arranged at one end of the top plate (253), the pressure wheel body (26) comprises a pressure wheel plate (261) with the bottom connected with the top plate (253), a second hydraulic body (262) is arranged in the middle of the top of the pressure wheel plate (261), and the bottom of a hydraulic rod (263) of the second hydraulic body (262) penetrates through the pressure wheel plate (261) to be rotatably connected with a pressure wheel roller (266);

a connecting plate (264) is arranged at the joint of the hydraulic rod (263) and the pinch roller (266), the connecting plate (264) is a square plate, sliding rods (265) are arranged at the tops of two ends of the connecting plate (264), and the tops of the sliding rods (265) penetrate through the pinch roller plate (261) to be in inserted fit with the pinch roller plate (261);

no. three slide rails (217) are symmetrically arranged at two ends of the top of the second plate (215), the No. three slide rails (217) are I-shaped plates, a No. four groove (254) is symmetrically arranged at the bottom of the avoidance plate (251), the No. four groove (254) is an I-shaped groove, the No. four groove (254) is in sliding connection with the No. three slide rails (217), a No. one hydraulic body (252) is arranged at one end of the second plate (215), and the No. one hydraulic body (252) is connected with the avoidance plate (251).

2. The carrier roller shaft circlip groove milling machine as claimed in claim 1, which is characterized in that: the first body (163) and the second body (164) are respectively provided with an insertion rod (165), the surface of one side of the bedplate (211) is provided with an insertion port (216), and the insertion rods (165) are in insertion fit with the insertion ports (216).

3. The carrier roller shaft circlip groove milling machine as claimed in claim 1, which is characterized in that: no. three board (241) one side is equipped with locating plate (242), locating plate (242) one side is equipped with location body (243), no. two grooves (232) have been seted up to cutting feed plate (231) bottom symmetry, no. two grooves (232) are "worker" type groove, no. two grooves (232) with No. two slide rail (213) sliding connection.

4. The carrier roller shaft circlip groove milling machine as claimed in claim 1, which is characterized in that: advance cutting board (231) top one end and be equipped with No. three motor (234), no. three motor (234) transmission is connected with screw rod (235), the cutting board (231) top other end is equipped with end plate (236), screw rod (235) one end with end plate (236) rotate and are connected, no. three board (241) bottom correspondence is equipped with bottom plate (247), screw rod (235) pass bottom plate (247) with bottom plate (247) threaded connection.

5. The carrier roller shaft circlip groove milling machine as claimed in claim 1, which is characterized in that: be equipped with No. two motor (225) in No. four mouthful (223), no. two motor (225) one end transmission is connected with No. two cylinder (226), no. two cylinder (226) and the other end No. four mouthful (223) rotate and are connected.