1. A cutter vacuum ion plating processing device convenient for multi-surface plating comprises a shell body (1), an operation box (2), a shell door (3) and a processing cylinder (4); an operation box (2) is arranged on one side of the shell body (1), a shell door (3) is arranged on the front side of the shell body (1), and a processing cylinder (4) is fixed on the inner bottom surface of the shell body (1);

it is characterized in that it also comprises:

the rotating motor (5), the rotating motor (5) is arranged in the middle of the upper side of the shell body (1), an output shaft of the rotating motor (5) penetrates through a top plate of the shell body (1) and is arranged in the shell body (1), and the rotating motor (5) is connected with an external power supply;

the upper supporting column (6) is arranged in the shell body (1), and the top end of the upper supporting column (6) is fixedly connected with an output shaft of the rotating motor (5);

the first electric push rod (7), the first electric push rod (7) is arranged in a groove (6-1) formed in the bottom of the upper support column (6), and the first electric push rod (7) is connected with an external power supply;

the connecting rod (8) is movably arranged in a groove (6-1) at the bottom of the upper supporting column (6), and the top end of the connecting rod (8) is fixedly connected with the pushing end of the first electric push rod (7);

the lower supporting column (9) is arranged in the processing cylinder (4), and the lower supporting column (9) is arranged on the lower side of the connecting rod (8) and is fixedly connected with the bottom of the connecting rod (8);

the number of the sleeves (10) is two, and the sleeves (10) are respectively sleeved and fixed on the lower supporting column (9);

the net placing frames (11) are multiple, the net placing frames (11) are arranged on the periphery of the sleeve (10), the multiple net placing frames (11) are distributed in a circumferential equiangular mode, and one side, close to the sleeve (10), of each net placing frame (11) is fixedly connected with the sleeve (10);

the device comprises a plurality of supports (12), wherein the supports (12) are distributed in a plurality of placing net racks (11) in an equal distribution manner, and the bottoms of the supports (12) are fixed on the inner bottom surfaces of the placing net racks (11);

the supporting blocks (13) are a plurality of supporting blocks (13), are distributed in the plurality of placing net racks (11) in an equal amount, and are symmetrically arranged on two sides of the support (12) in pairs;

the operating seats (14) are multiple and are arranged corresponding to the supporting blocks (13), and the operating seats (14) are fixed on the supporting blocks (13);

the operating motors (15) are multiple, the operating motors (15) are respectively fixed on the outer side wall of the operating seat (14), the output shafts of the operating motors (15) penetrate through the side wall of the operating seat (14) and then are arranged in the operating seat (14), and the operating motors (15) are connected with an external power supply;

the rotary gears (16) are provided in a plurality, the rotary gears (16) are respectively arranged in the operating seat (14), and the rotary gears (16) are respectively sleeved and fixed on an output shaft of the operating motor (15);

the driving gear blocks (17) are multiple, the driving gear blocks (17) are respectively arranged in the operating seat (14), and the driving gear blocks (17) are arranged on the upper side of the rotating gear (16) and meshed with the rotating gear (16);

the driving guide blocks (18) are arranged in the operating seat (14), the driving guide blocks (18) are fixed on the driving tooth block (17), and the driving guide blocks (18) are arranged on a driving rail arranged on the inner top surface of the operating seat (14) in a sliding mode;

the supporting frames (19) are arranged in the plurality of placing net racks (11) in an equivalent distribution manner, and are symmetrically arranged on two sides of the support (12), the supporting frames (19) are arranged in an L-shaped structure, and the horizontal end in the supporting frames (19) penetrates through the side wall, close to the support (12), of the operation seat (14), is arranged in the operation seat (14) and is fixedly connected with the driving tooth block (17);

bottom support (20), bottom support (20) are the several, and the equal quantity distributes and sets up in the several places rack (11), and two bisymmetry sets up in the both sides of support (12), and bottom support (20) are "L" shape structure setting, and the horizontal end in bottom support (20) is fixed in on the vertical end in support frame (19).

2. The vacuum ion plating processing apparatus for a tool facilitating multi-sided plating according to claim 1, wherein: it also includes:

the electric push rods (21) are multiple, the electric push rods (21) are respectively fixed in a placing groove formed in the upper side of the support (12), and the electric push rods (21) are connected with an external power supply;

the connecting ejector blocks (22) are provided in a plurality, and are respectively connected and fixed with the top pushing ends of the second electric push rods (21);

the reinforcing clamping blocks (23) are distributed in the plurality of placing net racks (11) in an equal distribution manner and are arranged on the upper side of the bottom support (20), and the reinforcing clamping blocks (23) are flush with the vertical end in the bottom support (20);

the upper connecting frames (24) are multiple, the upper connecting frames (24) are arranged in an inverted L-shaped structure, and the horizontal ends of the upper connecting frames (24) are respectively fixed on the outer sides of the reinforcing clamping blocks (23);

the lower connecting frames (25) are multiple, the lower connecting frames (25) are arranged in an L-shaped structure, the horizontal ends of the lower connecting frames (25) are respectively fixed on the outer sides of the vertical ends of the bottom support (20), and the vertical ends of the lower connecting frames (25) penetrate through sliding grooves (24-1) formed in the vertical ends of the upper connecting frames (24) on the upper sides of the lower connecting frames;

the guide support rods (26) are arranged in the upper ends of the vertical ends of the lower connecting frames (25) in a penetrating manner and are fixed in the upper ends of the vertical ends of the lower connecting frames (26), the guide support rods (26) are arranged in guide support grooves (24-2) formed in the vertical ends of the upper connecting frames (24) in a vertically sliding manner, and the guide support grooves (24-2) are communicated with the sliding grooves (24-1);

the second electric push rod (21) is started, the connecting top block (22) and the horizontal end in the bottom support (20) are arranged in a flush mode, the cutter is arranged at the horizontal end in the bottom support (20) and is connected to the top block (22), and when the cutter moves, the reinforcing clamping blocks (23) on two sides and the upper connecting frame (24) are driven to move along with the cutter, the cutter is moved and guided through the lower connecting frame (25), and the cutter is clamped through the reinforcing clamping blocks (23) when moving.

3. The vacuum ion plating processing apparatus for a tool facilitating multi-sided plating according to claim 1, wherein: the connecting device further comprises a plurality of connecting blocks (27), the connecting blocks (27) are arranged in an arc-shaped structure, the connecting blocks (27) are arranged between two adjacent net racks (11), and the connecting blocks (27) are fixedly connected with the side walls of the net racks (11); the connecting blocks (27) reinforce the stability between two adjacent net racks (11).

4. The vacuum ion plating processing apparatus for a tool facilitating multi-sided plating according to claim 1, wherein: the processing device also comprises two clamping rings (28), wherein the two clamping rings (28) are arranged in the processing cylinder (4), the clamping rings (28) are arranged on the outer side of the net rack (11), and the inner annular wall of each clamping ring (28) is fixedly connected with the outer annular wall of the net rack (11); the clamping rings (28) enable the plurality of net racks (11) to be placed more stably.

5. The vacuum ion plating processing apparatus for a tool facilitating multi-sided plating according to claim 1, wherein: it also includes:

the baffle frame (29) is arranged in an arc-shaped structure, the baffle frame (29) is inserted into a slot (4-1) formed in the front side of the processing barrel (4), and the inner annular wall of the baffle frame (29) is flush with the inner annular wall of the processing barrel (4);

the limiting arc block (30), the limiting arc block (30) is fixed on the inner ring wall of the blocking frame (29), the left side and the right side of the limiting arc block (30) are exposed on the blocking frame (29), and the exposed ends are in contact with the inner ring wall of the processing barrel (4);

the two insertion rails (31) are respectively fixed on the left side and the right side of the blocking frame (29), the insertion rails (31) are arranged in insertion rail grooves (4-2) formed in the processing barrel (4) in a vertically sliding mode, and the two insertion rail grooves (4-2) are respectively arranged on the left side and the right side of the insertion groove (4-1) and are communicated with the insertion groove (4-1);

the blocking frame (29) is driven to move through the insertion and matching of the insertion rail (31) and the insertion rail groove (4-2).

6. The operating principle of the vacuum ion plating processing device for tools to facilitate multi-surface plating according to claim 1, wherein: when the device is used, a cutter is placed between two opposite bottom supports (20) in a placing net rack (11), the bottom supports (20) are driven to correspondingly adjust, so that the bottom supports (20) clamp the bottom of the cutter, firstly, an operation motor (15) is started to rotate a rotating gear (16), and then, the rotating gear is meshed to move a driving tooth block (17), so that a support frame (19) is moved, and the bottom supports (20) are driven to move until the bottom of the cutter is clamped; treat the cutter and press from both sides tightly in proper order after, promote downwards through an electric putter (7), make bottom suspension dagger (9) downstream, thereby drive sleeve (10) and support rack and move downwards, until supporting in the rack arranges a processing section of thick bamboo (4), rotate motor (5) through the start-up, make and go up support column (6) and drive bottom suspension dagger (9) and rotate, then drive the support rack and rotate in a processing section of thick bamboo (4), thereby make the cutter rotate in a processing section of thick bamboo (4), make the different face homoenergetic of cutter process.

Background

Vacuum ion plating, also called vacuum coating, is a popular method at present, and the prepared product has strong metal feeling and high brightness, and compared with other coating methods, the method has lower cost and less pollution to the environment, and is widely adopted by various industries at present; with the development of manufacturing industry, the demand on the cutter is higher and higher, a thin layer needs to be coated on the outer surface of the cutter, and the coating material has high hardness, wear resistance and high temperature resistance, so that the coated cutter allows a higher cutting speed to be adopted compared with an uncoated cutter, thereby improving the cutting efficiency or prolonging the service life of the cutter at the same cutting speed; however, in the coating process of the existing cutting tool, only one surface of the cutting tool can be processed independently, and a plurality of surfaces of the cutting tool cannot be processed in a conversion mode, so that the processing efficiency is low.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings of the prior art, and provides a vacuum ion plating processing device for a cutter, which is simple in structure, reasonable in design, convenient to use and convenient to perform multi-surface plating, and can drive the cutter to rotate, so that the cutter can be uniformly plated in a film plating machine, the phenomenon of non-uniform film plating is avoided, and the working efficiency of film plating is improved.

In order to achieve the purpose, the invention adopts the technical scheme that: the device comprises a shell body, an operation box, a shell door and a processing barrel; an operation box is arranged on one side of the shell body, a shell door is arranged on the front side of the shell body, and a processing barrel is fixed on the inner bottom surface of the shell body;

it also includes:

the rotating motor is arranged in the middle of the upper side of the shell body, an output shaft of the rotating motor penetrates through a top plate of the shell body and is arranged in the shell body, and the rotating motor is connected with an external power supply;

the upper support column is arranged in the shell body, and the top end of the upper support column is fixedly connected with an output shaft of the rotating motor;

the first electric push rod is arranged in a groove formed in the bottom of the upper support column and is connected with an external power supply;

the connecting rod is movably arranged in a groove at the bottom of the upper supporting column, and the top end of the connecting rod is fixedly connected with the pushing end of the first electric push rod;

the lower support column is arranged in the processing cylinder, arranged on the lower side of the connecting rod and fixedly connected with the bottom of the connecting rod;

the number of the sleeves is two, and the sleeves are respectively sleeved and fixed on the lower support columns;

the placing net racks are arranged on the periphery of the sleeve, the placing net racks are distributed in a circumferential equiangular mode, and one side, close to the sleeve, of each placing net rack is fixedly connected with the sleeve;

the device comprises a plurality of supports, a plurality of positioning net racks and a plurality of positioning net racks, wherein the supports are distributed in the plurality of positioning net racks in an equivalent manner, and the bottoms of the supports are fixed on the inner bottom surfaces of the positioning net racks;

the support blocks are distributed in the plurality of placing net racks in an equivalent manner, and are symmetrically arranged on two sides of the support in pairs;

the operating seats are arranged corresponding to the support blocks and are fixed on the support blocks;

the operating motors are a plurality of and are respectively fixed on the outer side wall of the operating seat, the output shafts of the operating motors penetrate through the side wall of the operating seat and then are arranged in the operating seat, and the operating motors are connected with an external power supply;

the rotating gears are arranged in the operating seat respectively, and are sleeved and fixed on an output shaft of the operating motor respectively;

the driving gear blocks are arranged in the operating seat respectively, arranged on the upper side of the rotating gear and meshed with the rotating gear;

the driving guide blocks are arranged in the operating seat respectively, fixed on the driving gear block and arranged on the driving rail arranged on the inner top surface of the operating seat in a sliding manner respectively;

the supporting frames are arranged in the plurality of placing net racks in an equivalent distribution mode, are symmetrically arranged on two sides of the support in pairs, are arranged in an L-shaped structure, and are arranged in the operating seat after the horizontal end of each supporting frame penetrates through one side wall, close to the support, of the operating seat and connected and fixed with the driving tooth block;

the bottom support, the bottom support is the several, and the equivalent distribution sets up in the rack is placed to the several, and two bisymmetry sets up in the both sides of support, and the bottom support is "L" shape structure setting, and the horizontal end in the bottom support is fixed in on the vertical end in the support frame.

Preferably, it further comprises:

the electric push rods are a plurality of and are respectively fixed in the placing grooves formed in the upper side of the support, and the electric push rods are connected with an external power supply;

the connecting ejector blocks are multiple and are respectively connected and fixed with the top pushing ends of the second electric push rods;

the reinforcing clamping blocks are distributed in the plurality of placing net racks in an equal distribution mode and arranged on the upper side of the bottom support, and the reinforcing clamping blocks are flush with the vertical end in the bottom support;

the upper connecting frames are arranged in an inverted L-shaped structure, and the horizontal ends of the upper connecting frames are respectively fixed on the outer sides of the reinforcing clamping blocks;

the lower connecting frames are arranged in an L-shaped structure, the horizontal ends of the lower connecting frames are respectively fixed at the outer sides of the vertical ends in the bottom bracket, and the vertical ends of the lower connecting frames penetrate through sliding grooves formed in the vertical ends of the upper connecting frames at the upper sides of the lower connecting frames;

the guide support rods are arranged in the upper ends of the vertical ends in the lower connecting frame in a penetrating way and are fixed in the upper ends of the vertical ends in the lower connecting frame respectively, the guide support rods are arranged in guide support grooves formed in the vertical ends in the upper connecting frame in a vertically sliding way respectively, and the guide support grooves are communicated with the sliding grooves;

starting No. two electric putter, making the horizontal end of connecting in kicking block and the bottom support flush the setting, on the horizontal end of bottom support and the connection kicking block were arranged in to the cutter, and when the cutter removed, drive the reinforcement clamp splice of both sides and go up the link and follow the removal to remove the direction through lower link, the cutter presss from both sides tightly through the reinforcement clamp splice when removing.

Preferably, the device also comprises a plurality of connecting blocks, the connecting blocks are arranged in an arc-shaped structure, the connecting blocks are arranged between two adjacent placing net racks, and the connecting blocks are fixedly connected with the side walls of the placing net racks; the connecting block reinforces the steadiness between two adjacent rack of placing.

Preferably, the processing device also comprises two clamping rings, the two clamping rings are arranged in the processing cylinder, the clamping rings are arranged on the outer side of the net rack, and the inner ring wall of each clamping ring is fixedly connected with the outer ring wall of the net rack; the clamping rings enable the plurality of net racks to be placed more stably.

Preferably, it further comprises:

the baffle frame is of an arc-shaped structure and is inserted into a slot formed in the front side of the processing cylinder, and the inner annular wall of the baffle frame is flush with the inner annular wall of the processing cylinder;

the limiting arc block is fixed on the inner annular wall of the blocking frame, the left side and the right side of the limiting arc block are exposed on the blocking frame, and the exposed ends of the limiting arc block are in contact with the inner annular wall of the processing barrel;

the two insertion rails are respectively fixed on the left side and the right side of the blocking frame, are arranged in insertion rail grooves formed in the processing cylinder in a vertically sliding mode, are respectively arranged on the left side and the right side of the inserting groove and are communicated with the inserting groove;

through inserting the rail and inserting establishing the cooperation with inserting the rail groove, drive and keep off the frame and remove.

The working principle of the invention is as follows: when the device is used, a cutter is placed between two opposite bottom supports in a placing net rack, the bottom supports are driven to correspondingly adjust to clamp the bottom of the cutter, firstly, an operation motor is started to rotate a rotating gear, then, the rotating gear is meshed to move a driving tooth block, so that a support frame is moved to drive the bottom supports to move until the bottom of the cutter is clamped; treat that the cutter presss from both sides tightly in proper order after, promote downwards through an electric putter, make the bottom suspension dagger downstream to drive sleeve and support rack and move downwards, in the section of thick bamboo of processing is arranged in to the support rack, rotate the motor through the start-up, make and go up the support column and drive the bottom suspension dagger and rotate, drive the support rack then and rotate in the section of thick bamboo of processing, thereby make the cutter rotate in the section of thick bamboo of processing, make the different face homoenergetic of cutter process.

After adopting the structure, the invention has the beneficial effects that:

1. the height of the sleeve is changed by driving the lower support column to move in height, so that the support net rack moves in height, and the cutter is placed in the processing cylinder;

2. the cutter is relatively clamped by the left and right bottom supports, so that the cutter is in a stable state in the supporting net rack.

Drawings

In order to more clearly illustrate the embodiments of the present 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, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a top view of fig. 1.

Fig. 3 is a sectional view taken along line a-a in fig. 1.

Fig. 4 is a sectional view taken along line B-B in fig. 2.

Fig. 5 is an enlarged view of the portion C in fig. 3.

Fig. 6 is an enlarged view of a portion D in fig. 3.

Fig. 7 is an enlarged view of a portion E in fig. 4.

Fig. 8 is an enlarged view of a portion F in fig. 4.

Description of reference numerals:

the device comprises a shell body 1, an operation box 2, a shell door 3, a processing barrel 4, a slot 4-1, a rail insertion groove 4-2, a rotating motor 5, an upper support column 6, a groove 6-1, a first electric push rod 7, a connecting rod 8, a lower support column 9, a sleeve 10, a placing net rack 11, a support 12, a support block 13, an operation seat 14, an operation motor 15, a rotating gear 16, a driving tooth block 17, a driving guide block 18, a support frame 19, a bottom support 20, a second electric push rod 21, a connecting top block 22, a reinforcing clamping block 23, an upper connecting frame 24, a sliding groove 24-1, a guiding support groove 24-2, a lower connecting frame 25, a guiding support rod 26, a connecting block 27, a clamping ring 28, a blocking frame 29, a limiting arc block 30 and a rail insertion 31.

Detailed Description

The invention will be further described with reference to the accompanying drawings.

Referring to fig. 1 to 8, the technical solution adopted by the present embodiment is: the device comprises a shell body 1, an operation box 2, a shell door 3 and a processing cylinder 4; an operation box 2 is arranged on one side of a shell body 1, a shell door 3 is arranged on the front side of the shell body 1, one side of the shell door 3 is hinged to the shell body 1 through a hinge, the other side of the shell door 3 is connected with the shell body 1 through a hasp, and a processing barrel 4 is fixed on the inner bottom surface of the shell body 1 through a bolt;

it also includes:

the rotating motor 5 is arranged in the middle of the upper side of the shell body 1 through bolts, an output shaft of the rotating motor 5 penetrates through a top plate of the shell body 1 and is arranged in the shell body 1, the rotating motor 5 is connected with an external power supply, and the specific use model of the rotating motor 5 is directly purchased, installed and used from the market according to actual use requirements;

the upper support column 6 is arranged in the shell body 1, and the top end of the upper support column 6 is fixed with an output shaft of the rotating motor 5 by a bolt;

the first electric push rod 7 is arranged in a groove 6-1 formed in the bottom of the upper support column 6, the first electric push rod 7 is connected with an external power supply, and the first electric push rod 7 is directly purchased, installed and used from the market according to actual use requirements in specific use models;

the connecting rod 8 is movably arranged in a groove 6-1 at the bottom of the upper supporting column 6, and the top end of the connecting rod 8 is fixed with the pushing end of the first electric push rod 7 through a bolt;

the lower support column 9 is arranged in the processing cylinder 4, and the lower support column 9 is arranged on the lower side of the connecting rod 8 and fixed with the bottom of the connecting rod 8 by using a bolt;

the number of the sleeves 10 is two, and the sleeves 10 are respectively sleeved and fixed on the lower support pillar 9 by bolts;

the device comprises a plurality of placing net racks 11, wherein the placing net racks 11 are arranged on the periphery of a sleeve 10, the placing net racks 11 are distributed in a circumferential equiangular manner, and one side, close to the sleeve 10, of each placing net rack 11 is fixed with the sleeve 10 through bolts;

the device comprises a plurality of supports 12, wherein the supports 12 are distributed in a plurality of placing net racks 11 in an equal amount, and the bottoms of the supports 12 are fixed on the inner bottom surfaces of the placing net racks 11 by bolts;

the supporting blocks 13 are a plurality of supporting blocks 13, are distributed in the plurality of placing net racks 11 in an equal amount, and are symmetrically arranged on two sides of the support 12 in pairs;

a plurality of operating seats 14, wherein the operating seats 14 are arranged corresponding to the support blocks 13, and the operating seats 14 are fixed on the support blocks 13 by bolts;

the operating motors 15 are provided in a plurality of numbers and are respectively fixed on the outer side wall of the operating seat 14, the output shafts of the operating motors 15 penetrate through the side wall of the operating seat 14 and are arranged in the operating seat 14, the operating motors 15 are connected with an external power supply, and the specific use models of the operating motors 15 are directly purchased, installed and used from the market according to actual use requirements;

the rotating gears 16 are provided in a plurality of numbers, the rotating gears 16 are respectively arranged in the operating seat 14, and the rotating gears 16 are respectively sleeved and fixed on the output shaft of the operating motor 15 by bolts;

the driving gear blocks 17 are arranged in the operating seat 14, the driving gear blocks 17 are arranged on the upper side of the rotating gear 16, and the driving gear blocks 17 are meshed with the rotating gear 16;

the driving guide blocks 18 are a plurality of driving guide blocks 18, the driving guide blocks 18 are respectively arranged in the operation seat 14, the driving guide blocks 18 are fixed on the driving gear block 17 by bolts, and the driving guide blocks 18 are respectively arranged on driving rails arranged on the inner top surface of the operation seat 14 in a sliding manner;

the supporting frames 19 are arranged in the plurality of placing net racks 11 in an equivalent distribution manner, and are symmetrically arranged on two sides of the support 12 in pairs, the supporting frames 19 are arranged in an L-shaped structure, and the horizontal ends of the supporting frames 19 penetrate through one side wall of the operation seat 14 close to the support 12, are arranged in the operation seat 14, and are fixed with the driving tooth blocks 17 by bolts;

bottom support 20, bottom support 20 is the several, and the equal quantity distributes and sets up in the several places rack 11, and two bisymmetry settings in the both sides of support 12, and bottom support 20 is "L" shape structure setting, and the horizontal end in bottom support 20 utilizes the bolt fastening to be in the support frame 19 on the vertical end.

Preferably, the method further comprises the following steps:

the second electric push rods 21 are provided with a plurality of numbers, and are respectively fixed in the placing grooves formed in the upper side of the support 12, the second electric push rods 21 are connected with an external power supply, and the specific use model of the second electric push rods 21 is directly purchased, installed and used from the market according to the actual use requirement;

the connecting ejector blocks 22 are multiple, and are respectively fixed with the top pushing ends of the second electric push rods 21 by bolts;

the reinforcing clamping blocks 23 are a plurality of reinforcing clamping blocks 23, are distributed in the plurality of placing net racks 11 in an equal amount and are arranged on the upper side of the bottom bracket 20, and the reinforcing clamping blocks 23 are arranged in a flush manner with the vertical ends in the bottom bracket 20;

the upper connecting frames 24 are multiple, the upper connecting frames 24 are arranged in an inverted L-shaped structure, and the horizontal ends of the upper connecting frames 24 are respectively fixed on the outer sides of the reinforcing clamping blocks 23 by bolts;

the lower connecting frames 25 are provided in a plurality of numbers, the lower connecting frames 25 are arranged in an L-shaped structure, the horizontal ends of the lower connecting frames 25 are respectively fixed at the outer sides of the vertical ends of the bottom bracket 20 by bolts, and the vertical ends of the lower connecting frames 25 penetrate through sliding grooves 24-1 formed in the vertical ends of the upper connecting frames 24 at the upper sides of the lower connecting frames 25;

the guide support rods 26 are a plurality of guide support rods 26, the guide support rods 26 are respectively arranged in the upper ends of the vertical ends of the lower connecting frame 25 in a penetrating manner and are fixed in the upper ends of the vertical ends of the lower connecting frame 25 by bolts, the guide support rods 26 are respectively arranged in guide support grooves 24-2 formed in the vertical ends of the upper connecting frame 24 in a vertically sliding manner, and the guide support grooves 24-2 are communicated with the sliding grooves 24-1;

the tool is pushed by the second electric push rod 21, so that the connecting jacking block 22 supports the tool, and when the tool moves, the reinforcing clamping blocks 23 on two sides and the upper connecting frame 24 are driven to move along with the tool, and the tool is guided to move through the lower connecting frame 25, so that the tool is more stable when moving.

As a preferable scheme, further, the utility model further comprises a plurality of connecting blocks 27, the connecting blocks 27 are arranged in an arc structure, the connecting blocks 27 are arranged between two adjacent net racks 11, and the connecting blocks 27 are fixed with the side walls of the net racks 11 by bolts; the adjacent two rack 11 are more stable through the connecting block 27.

Preferably, the processing machine further comprises two clamping rings 28, the two clamping rings 28 are arranged in the processing cylinder 4, the clamping ring 28 is arranged on the outer side of the rack 11, and the inner annular wall of the clamping ring 28 is connected with the outer annular wall of the rack 11 through bolts; the clamping ring 28 improves the stability of the rack 11.

Preferably, the method further comprises the following steps:

the baffle frame 29 is of an arc-shaped structure, the baffle frame 29 is inserted into a slot 4-1 formed in the front side of the processing cylinder 4, and the inner annular wall of the baffle frame 29 is flush with the inner annular wall of the processing cylinder 4;

the limiting arc block 30 is fixed on the inner annular wall of the blocking frame 29 by bolts, the left side and the right side of the limiting arc block 30 are exposed on the blocking frame 29, and the exposed ends are in contact with the inner annular wall of the processing barrel 4;

two insertion rails 31, wherein the two insertion rails 31 are respectively fixed on the left side and the right side of the baffle frame 29 by bolts, the insertion rails 31 are arranged in insertion rail grooves 4-2 formed in the processing cylinder 4 in a vertically sliding manner, and the two insertion rail grooves 4-2 are respectively arranged on the left side and the right side of the slot 4-1 and are communicated with the slot 4-1;

the blocking frame 29 is driven by hand to move, and the moving guide is carried out through the insertion matching of the insertion rail 31 and the insertion rail groove 4-2.

The working principle of the specific embodiment is as follows: when the device is used, a cutter is placed between two opposite bottom supports 20 in a placing net rack 11, the bottom supports 20 are driven to correspondingly adjust to enable the bottom supports 20 to clamp the bottom of the cutter, firstly, an operating motor 15 is started to enable a rotating gear 16 to rotate and then to be meshed to enable a driving tooth block 17 to move, so that a supporting frame 19 moves to drive the bottom supports 20 to move until the bottom of the cutter is clamped, the bottom supports 20 drive a reinforcing clamping block 23 to move along with the cooperation of a lower connecting frame 25 and an upper connecting frame 24 in the moving process, so that the reinforcing clamping block 23 clamps the side wall of the cutter, and a second electric push rod 21 pushes to enable a connecting top block 22 to move to support the bottom of the cutter, and the second electric push rod 21 pushes to drive the cutter to push, the height of the cutter is changed, and when the cutter moves in height, the reinforcing clamping block 23 and the upper connecting frame 24 are driven to move along with the cutter, so that the stability of the cutter during moving is reinforced; treat the cutter after pressing from both sides tightly in proper order, promote downwards through an electric putter 7, make bottom suspension dagger 9 downstream, thereby drive sleeve 10 and support rack and move downwards, arrange the processing section of thick bamboo 4 in until the support rack, rotate motor 5 through the start-up, make and go up support 6 and drive bottom suspension dagger 9 and rotate, drive the support rack then and rotate in the processing section of thick bamboo 4, thereby make the cutter rotate in the processing section of thick bamboo 4, make the different face homoenergetic of cutter process.

After adopting above-mentioned structure, this embodiment beneficial effect does:

1. the height of the sleeve 10 is changed by driving the lower support column 9 to move in height, so that the support net rack moves in height, and the cutter is placed in the processing cylinder 4;

2. the cutter is relatively clamped by the left bottom bracket 20 and the right bottom bracket 20, so that the cutter is in a stable state in the supporting net rack;

3. when the bottom bracket 20 moves, the reinforcing clamping block 23 on the upper side is driven to carry out clamping operation, so that the stability of the cutter is improved;

4. the adjacent supporting net frames are more stable through the matching of the connecting blocks 27 and the clamping rings 28.

The above description is only for the purpose of illustrating the technical solutions of the present invention and not for the purpose of limiting the same, and other modifications or equivalent substitutions made by those skilled in the art to the technical solutions of the present invention should be covered within the scope of the claims of the present invention without departing from the spirit and scope of the technical solutions of the present invention.