CN112621845A

CN112621845A - Cotton processing agency of electrically conductive bubble for electromagnetic shield

Info

Publication number: CN112621845A
Application number: CN202011384197.5A
Authority: CN
Inventors: 范彬彬
Original assignee: Individual
Current assignee: Shenzhen Jintian Electron Co ltd
Priority date: 2020-12-01
Filing date: 2020-12-01
Publication date: 2021-04-09
Anticipated expiration: 2040-12-01
Also published as: CN112621845B

Abstract

The invention discloses a processing mechanism of conductive foam for electromagnetic shielding, which belongs to the field of foam processing and comprises a feeding assembly, wherein the feeding assembly comprises two seat bodies, the two seat bodies are respectively and independently and fixedly installed, one side of each seat body is provided with a rotating column, the rotating column is in rotary connection with the rotating column, the diameter of the rotating column is connected through a conveying belt, a bending rod is fixedly installed above the feeding assembly, the section of the bending rod is rectangular, a first sliding sleeve and a second sliding sleeve are sleeved on the bending rod, the first sliding sleeve and the second sliding sleeve are respectively in sliding connection with the bending rod, and the first sliding sleeve and the second sliding sleeve are connected through a connecting rod. The cutting efficiency of the foam is high.

Description

Cotton processing agency of electrically conductive bubble for electromagnetic shield

Technical Field

The invention relates to the field of foam processing, in particular to a processing mechanism of conductive foam for electromagnetic shielding.

Background

With the development of industrial technology, the development of modern industrial technology is more and more perfect, so the modern industrial technology is biased to the development of electronic technology, energy used by the electronic industry is derived from electric energy, electronic equipment needs to use electromagnetic shielding conductive foam frequently, the foam is processed in batches in engineering, then the whole piece of electromagnetic shielding conductive foam needs to be cut into small pieces to be filled into the electronic equipment, but the cutting efficiency of general equipment is low.

Disclosure of Invention

The invention aims to provide a processing mechanism of conductive foam for electromagnetic shielding, which aims at overcoming the defects of the prior art, and is characterized in that when the device is used, the processed electromagnetic shielding conductive foam is placed on a conveyor belt, then a power motor drives a driven wheel and a locking wheel to rotate through a power belt, the locking wheel can drive two sliding sleeves to slide on a bending rod when rotating, when the first sliding sleeve is pushed in a reciprocating manner, a short pipe can drive a twisting rod to rotate in a reciprocating manner, the twisting rod drives a rotary cutter to rotate through two universal joints, and at the moment, a pushing cylinder can drive a lifting plate and the rotary cutter to fall down to cut materials, so that the function of automatic hole cutting is realized.

In order to solve the above problems, the present invention provides the following technical solutions: a processing mechanism of conductive foam for electromagnetic shielding comprises a feeding assembly, wherein the feeding assembly comprises two seat bodies, the two seat bodies are respectively and independently fixedly installed, one side of each seat body is provided with a rotating column, the rotating column is rotatably connected with the corresponding seat body, the two rotating columns are connected through a conveying belt sleeve, an L-shaped bending rod is arranged above the feeding assembly, the section of the bending rod is rectangular, a first sliding sleeve and a second sliding sleeve are sleeved on the bending rod, the first sliding sleeve and the second sliding sleeve are respectively in sliding connection with the two opposite ends of the bending rod, the first sliding sleeve and the second sliding sleeve are rotatably connected through a connecting rod, one side of the first sliding sleeve and one side of the second sliding sleeve are provided with round rods, two ends of the connecting rod are respectively provided with holes matched with the round rods on one side of the first sliding sleeve and the second sliding sleeve, and the round rods are rotatably inserted in the holes, one side of buckling the pole sets up first fixed axle bed, the relative ground fixed mounting of first fixed axle bed, install from the driving wheel in one side of first fixed axle bed, the coaxial fixed mounting in one side of following the driving wheel has the locking wheel, the locking wheel with from driving wheel and first fixed axle bed swivelling joint, one side of first fixed axle bed is provided with motor power, the action wheel is installed to motor power's output, the action wheel with from establishing through the power belt cover between the driving wheel and establish and connect, the edge and the second of locking wheel slide and connect through the catch bar rotation between the cover, an end of catch bar and the side of locking wheel are articulated, another end and the second of catch bar slide the side of cover articulated.

In one of them embodiment, one side of buckling the pole is provided with the locking axle bed, the twist rod is installed to one side of locking axle bed, the end of twist rod is provided with the interlude pole, the interlude pole passes from the inboard of locking axle bed, and interlude pole and locking axle bed sliding connection, the twist rod extends along vertical direction, the cover is equipped with the nozzle stub on the twist rod, the outside of twist rod is provided with the spiral line, and the inboard of nozzle stub is provided with spiral line assorted helicla flute, one side of nozzle stub is provided with the extension board, the centre of extension board is provided with the connecting hole, first sliding is sheathe in and is provided with the inserted bar of interlude in the.

In one embodiment, two vertical guide rails are fixedly mounted below the locking shaft seat, a vertical slider is sleeved on each vertical guide rail, the vertical sliders are connected with the vertical guide rails in a sliding mode, a lifting table is fixedly mounted on one side of each of the two vertical sliders, a transverse plate is arranged on one side of the lifting table, the transverse plate is perpendicular to the lifting table, a bearing is fixedly mounted on the transverse plate, a rotary cutting saw is fixedly mounted in an inner ring of the bearing, the end of the rotary cutting saw penetrates through the transverse plate, a propelling cylinder is fixedly mounted on one side of one of the vertical guide rails, and the output end of the propelling cylinder is fixedly connected with the lifting table.

In one embodiment, a first universal joint is arranged below the locking shaft seat and fixedly connected with the end of the inserting rod, a second universal joint is installed on one side of the transverse plate and connected with the end of the rotary cutting saw, a square sleeve is installed on one side, away from the locking shaft seat, of the first universal joint, a square inserting rod is installed on one side, away from the rotary cutting saw, of the second universal joint, the end of the square inserting rod is inserted into the inner side of the square sleeve, and the square inserting rod is in sliding connection with the square sleeve.

In one embodiment, a second fixed shaft seat is arranged below the locking wheel, a linkage wheel disc is installed on one side of the second fixed shaft seat, the linkage wheel disc is connected with the second fixed shaft seat in a rotating mode, the linkage wheel disc is connected with the locking wheel through a linkage belt sleeve, a semi-ring gear is coaxially and fixedly installed on one side of the linkage wheel disc, a gear disc is installed on one side of the semi-ring gear, the gear disc is meshed with the semi-ring gear, a third fixed shaft seat is fixedly arranged on one side of the gear disc, the third fixed shaft seat is connected with the gear disc in a rotating mode, the third fixed shaft seat is fixedly installed, the gear disc is fixedly connected with one of the rotating columns through a round rod, and the round rod between the gear disc and the rotating column penetrates through the seat body.

In one of them embodiment, the one end that the toothed disc was kept away from to the material loading subassembly is provided with cutting assembly, and cutting assembly includes two guide rails, and guide rail is independent fixed mounting respectively, and the cover is equipped with the hoist and mount slider on every guide rail, hoist and mount slider and guide rail sliding connection, and the common fixed mounting in bottom of two hoist and mount sliders has the objective table, and the bottom fixed mounting of objective table has the electric saw, and guide rail is perpendicular with the direction of transfer of conveyer belt.

In one embodiment, a nut block is fixedly installed in the middle of the top surface of the object stage, a lead screw is inserted into the inner side of the nut block, the lead screw is installed on the output end of a servo motor, and the servo motor is fixedly installed.

In one embodiment, a blanking assembly is installed below the cutting assembly, the blanking assembly comprises a charging box, a base platform is installed at the bottom end of the charging box, the base platform is fixedly installed, two flanges extend out of the top end of the base platform, the side walls on the two opposite sides of the charging box are rotatably connected with the two flanges extending out of the base platform, a torsion motor is installed on one side of the base platform, an output end of the torsion motor penetrates through the base platform to be fixedly connected with the charging box, four ground feet are arranged at the bottom end of the base platform, and the ground feet are uniformly arranged on the bottom surface of the.

The invention has the beneficial effects that:

one of them, the device is when using, put the conveyer belt to the electromagnetic shield conducting bubble cotton of handling on, then power motor passes through power belt and drives and follow the driving wheel and the locking wheel is rotatory, the locking wheel can drive two when rotatory to slide the cover and slide at the pole of buckling, the nozzle stub can drive the reciprocal rotation of torsion bar when first sliding the cover reciprocal propulsion, the torsion bar drives the rotary-cut according to the rotation through two universal joints, the propulsion cylinder at this moment can drive the lifter plate and the rotary-cut according to falling and go to cut the material, the function of automatic hole cutting has been realized, and cutting efficiency is higher.

And secondly, when the power motor drives the rotary cutting saw to rotate, the linkage wheel disc also rotates through the linkage belt, the semi-ring gear on one side of the linkage wheel disc also continuously rotates, the semi-ring gear can intermittently drive the gear disc to rotate, the gear disc can drive the conveying belt to advance step by step, the automatic feeding function is realized, then the cutting assembly can cut the perforated material into strips and fall into the charging box, and the torsion motor can drive the charging box to overturn and unload.

Drawings

Fig. 1 is a schematic front view of a processing mechanism of conductive foam for electromagnetic shielding.

Fig. 2 is a schematic diagram of a side view of a processing mechanism of the conductive foam for electromagnetic shielding.

Fig. 3 is a schematic view of a bending rod of a processing mechanism of the conductive foam for electromagnetic shielding.

Fig. 4 is a schematic diagram of a twisting rod of a processing mechanism of the conductive foam for electromagnetic shielding.

Fig. 5 is a schematic sectional view of a processing mechanism of the conductive foam for electromagnetic shielding.

Fig. 6 is a schematic sectional view of a second perspective of the mechanism for processing the electromagnetic shielding conductive foam.

Fig. 7 is a schematic diagram of a cutting assembly of a processing mechanism of the conductive foam for electromagnetic shielding.

Fig. 8 is a schematic view of a blanking assembly of a processing mechanism of the conductive foam for electromagnetic shielding.

Description of reference numerals:

1-feeding component, 101-conveyor belt, 102-rotating column, base body 103-conveyor shaft seat, 2-bending rod, 201-first sliding sleeve, 202-second sliding sleeve, 203-connecting rod, 3-twisting rod, 301-inserting rod, 302-spiral thread, 4-short tube, 401-spiral groove, 402-extending plate, 403-connecting hole, 5-locking shaft seat, 501-first universal joint, 502-second universal joint, 503-square sleeve, 504-square inserting rod, 6-vertical guide rail, 601-lifting platform, 602-transverse plate, 603-rotary cutting saw, 604-bearing, 605-pushing cylinder, 606-vertical slide block, 7-first fixed shaft seat, 8-locking wheel, 801-driven wheel and 802-pushing rod, 9-power motor, 10-driving wheel, 11-power belt, 12-linkage belt, 13-second fixed shaft seat, 14-linkage wheel disc, 15-semi-ring gear, 16-gear disc, 1601-third fixed shaft seat, 17-cutting assembly, 1701-guide rail, 1702-hoisting slider, 1703-objective table, 1704-nut block, 1705-electric saw, 1706-screw rod, 1707-servo motor, 18-blanking assembly, 1801-charging box, 1802-abutment, 1803-torsion motor and 1804-anchor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description of the present invention, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

Referring to fig. 1 to 8, the processing mechanism of the conductive foam for electromagnetic shielding includes a feeding assembly 1, the feeding assembly 1 includes two base bodies 103, the two base bodies 103 are respectively and independently and fixedly mounted, for example, fixedly mounted with respect to the ground, one side of each base body 103 is mounted with a rotating column 102, the rotating column 102 is rotatably connected with the corresponding base body 103, the two rotating columns 102 are sleeved and connected by a conveyor belt 101, an L-shaped bent rod 2 is disposed above the feeding assembly 1, the bent rod is fixedly mounted with respect to the ground, the cross section of the bent rod 2 is rectangular, the bent rod 2 is sleeved with a first sliding sleeve 201 and a second sliding sleeve 202, the first sliding sleeve 201 and the second sliding sleeve 202 are respectively slidably connected with the opposite ends of the bent rod 2, the first sliding sleeve 201 and the second sliding sleeve 202 are rotatably connected by a connecting rod 203, one side of the first sliding sleeve 201 and the second sliding sleeve 202 is provided with a round rod, two ends of the connecting rod 203 are respectively provided with a hole matched with a round rod at one side of the first sliding sleeve 201 and the second sliding sleeve 202, the round rods are rotatably inserted in the holes, one side of the bending rod 2 is fixedly provided with a first fixed shaft seat 7, the first fixed shaft seat is fixedly arranged relative to the ground, one side of the first fixed shaft seat 7 is provided with a driven wheel 801, one side of the driven wheel 801 is coaxially and fixedly provided with a locking wheel 8, the locking wheel 8 and the driven wheel 801 are rotatably connected with the first fixed shaft seat 7, one side of the first fixed shaft seat 7 is provided with a power motor 9, the power motor is fixedly arranged relative to the ground, the output end of the power motor 9 is provided with a driving wheel 10, the driving wheel 10 is sleeved and connected with the driven wheel 801 through a power belt 11, the edge of the locking wheel 8 is rotatably connected with the second sliding sleeve 202 through a push rod 802, one end of the push rod, the other end of the push rod 802 is hinged to the side face of the second sliding sleeve 202, the first sliding sleeve 201 and the second sliding sleeve 202 can slide along the bending rod 2 respectively, synchronous operation is achieved between the first sliding sleeve 201 and the second sliding sleeve 202 through the connecting rod 203, the power motor 9 drives the locking wheel 8 to rotate through the power belt 11, meanwhile, the locking wheel 8 drives the second sliding sleeve 202 to move through the push rod 802, then, the power motor 9 indirectly provides sliding power for the first sliding sleeve 201 and the second sliding sleeve 202, foam materials to be processed are placed on the conveyor belt 101, and the conveyor belt 101 can drive the foam materials to be pushed forwards step by step.

One side of the bending rod 2 is provided with a locking shaft seat 5 which is fixedly arranged relative to the ground. Twist pole 3 is installed to one side of locking axle bed 5, the end of twist pole 3 is provided with interlude pole 301, interlude pole 301 passes from the inboard of locking axle bed 5, the twist pole extends along vertical direction, and interlude pole 301 and locking axle bed 5 sliding connection, the cover is equipped with nozzle stub 4 on the twist pole 3, the outside of twist pole 3 is provided with spiral line 302, and nozzle stub 4's inboard be provided with spiral line 302 assorted helicla flute 401, one side of nozzle stub 4 is provided with extension board 402, the centre of extension board 402 is provided with connecting hole 403, first sliding is sheathe in and is provided with the inserted bar of interlude in connecting hole 403 inboard, nozzle stub 4 can slide cover 201 synchronous operation with first, so nozzle stub 4 can drive twist pole 3 reciprocating rotation through driving helicla flute 401 and spiral line 302.

Two vertical guide rails 6 are fixedly mounted below the locking shaft seat 5, a vertical sliding block 606 is sleeved on each vertical guide rail 6, the vertical sliding blocks 606 are connected with the vertical guide rails 6 in a sliding mode, a lifting table 601 is fixedly mounted on the two vertical sliding blocks 606 together, a transverse plate 602 is arranged on one side of the lifting table 601, the transverse plate 602 is perpendicular to the lifting table 601, a bearing 604 is fixedly mounted on the transverse plate 602, a rotary cutting saw 603 is fixedly mounted in an inner ring of the bearing 604, the end of the rotary cutting saw 603 penetrates through the transverse plate 602, a pushing cylinder 605 is fixedly mounted on one side of one of the vertical guide rails 6, the output end of the pushing cylinder 605 is fixedly connected with the lifting table 601, the pushing cylinder 605 drives the lifting table 601 to slide up and down, the lifting table 601 at the moment slides along the vertical guide rails 6 through the vertical sliding blocks 606, and the pushing cylinder 605 provides sliding power for. The rotary cutting saw is used for performing rotary cutting operation on the foam on the conveying belt, and the conveying belt is static during the rotary cutting operation.

A first universal joint 501 is arranged below the locking shaft seat 5, the first universal joint 501 is fixedly connected with the end of the inserting rod 301, a second universal joint 502 is installed on one side of the transverse plate 602, the second universal joint 502 is connected with the end of the rotary cutting saw 603, a square sleeve 503 is installed on one side of the first universal joint 501, which is far away from the locking shaft seat, a square inserting rod 504 is installed on one side of the second universal joint 502, which is far away from the rotary cutting saw, the end of the square inserting rod 504 is inserted into the inner side of the square sleeve 503, the square inserting rod 504 is slidably connected with the square sleeve 503, the first universal joint 501 and the twisting rod 3 synchronously rotate, the second universal joint 502 and the first universal joint 501 also rotate together, and when the lifting platform 601 falls down, the square inserting rod 504 is inserted into the inner side of the square sleeve 503.

A second fixed shaft seat 13 is arranged below the locking wheel 8, the second fixed shaft seat is fixedly installed relative to the ground, a linkage wheel disc 14 is installed on one side of the second fixed shaft seat 13, the linkage wheel disc 14 is rotatably connected with the second fixed shaft seat 13, the linkage wheel disc 14 and the locking wheel 8 are connected in a sleeved mode through a linkage belt 12, a half-ring gear 15 is fixedly installed on one side of the linkage wheel disc 14, a gear disc 16 is coaxially and fixedly installed on one side of the half-ring gear 15, the gear disc 16 and the half-ring gear 15 are meshed with each other, a third fixed shaft seat 1601 is arranged on one side of the gear disc 16, the third fixed shaft seat 1601 is rotatably connected with the gear disc 16, the third fixed shaft seat 1601 is fixedly installed relative to the ground, for example, the gear disc 16 and one of the rotating columns 102 are fixedly connected through a round rod, the round rod between the gear disc 16 and the rotating column 102 passes through the seat 103, and the power motor 9 drives the twisting, the locking wheel drives the linkage wheel disc 14 to rotate through the linkage belt 12, the linkage wheel disc 14 drives the gear disc 16 to rotate through the half-ring gear 15, the rotation of the gear disc 16 is intermittent, the gear disc 16 can drive the rotating column 102 to advance step by step, and the conveying belt is driven to achieve the function of automatic feeding. For example, the entirety of the interlocking belt extends in the vertical direction.

The end of the feeding assembly 1, which is far away from the gear plate, is provided with a cutting assembly 17, the cutting assembly 17 includes two guide rails 1701, the guide rails 1701 are respectively and independently and fixedly mounted, for example, fixed and mounted relative to the ground, each guide rail 1701 is sleeved with a hoisting slider 1702, the hoisting sliders 1702 are slidably connected with the guide rails 1701, the bottom ends of the two hoisting sliders 1702 are jointly and fixedly mounted with an object stage 1703, the bottom end of the object stage 1703 is fixedly mounted with an electric saw 1705, after the foam is rotationally cut by the rotary cutting saw 603, the end of the foam can extend out from the end of the feeding assembly 1, then the electric saw 1705 slides on the guide rails 1701 through the object stage 1703, and the electric saw 1705 can cut the foam into one strip. The guide rail is perpendicular to the conveying direction of the conveyor belt.

A nut block 1704 is fixedly installed in the middle of the top surface of the object stage 1703, a lead screw 1706 is inserted into the inner side of the nut block 1704, the lead screw 1706 is installed on the output end of the servo motor 1707, and the servo motor 1707 is fixedly installed, for example, fixed relative to the guide rail. The servo motor 1707 drives the object stage 1703 to move through the screw 1706, and the servo motor 1707 indirectly provides power for operation through the electric saw 1705.

The unloading subassembly 18 is installed to cutting subassembly 17's below, unloading subassembly 18 is including charging box 1801, base station 1802 is installed to charging box 1801's bottom, base station 1802 fixed mounting, for example, relative ground fixed mounting, two turn-ups extend out on base station 1802's top, charging box 1801's relative both sides lateral wall respectively with base station 1802 two turn-ups swivelling joint that extend, torsion motor 1803 is installed to one side of base station 1802, torsion motor 1803's output passes base station 1802, in order to with charging box 1801 fixed connection, the bottom of base station is provided with four lower margin 1804, lower margin 1804 evenly arranged is in the bottom surface of base station 1802, the bubble cotton after being cut into the strip by the electric saw can fall into charging box 1801, then after charging box 1801 filled up, torsion motor 1803 drives charging box 1801 and overturns the unloading.

When the device is used, the first sliding sleeve 201 and the second sliding sleeve 202 can respectively slide along the bending rod 2, the first sliding sleeve 201 and the second sliding sleeve 202 synchronously operate through the connecting rod 203, the power motor 9 drives the locking wheel 8 to rotate through the power belt 11, the locking wheel 8 drives the second sliding sleeve 202 to move through the pushing rod 802, then the power motor 9 indirectly provides sliding power for the first sliding sleeve 201 and the second sliding sleeve 202, foam materials to be processed are placed on the conveyor belt 101, the conveyor belt 101 can drive the foam materials to be pushed forward step by step, the short pipe 4 and the first sliding sleeve 201 synchronously operate, then the short pipe 4 drives the torsion rod 3 to rotate back and forth through driving the spiral groove 401 and the spiral thread 302, the pushing cylinder 605 drives the lifting platform 601 to slide up and down, then the lifting platform 601 at the moment slides along the vertical guide rail 6 through the vertical sliding block 606, the pushing cylinder 605 provides sliding power for the lifting platform 601, the first universal joint 501 and the twisting rod 3 rotate synchronously, the second universal joint 502 and the first universal joint 501 rotate together, when the lifting platform 601 falls down, the square insertion rod 504 penetrates inside the square sleeve 503, the power motor 9 drives the twisting rod 3 to rotate, the twisting rod 3 drives the linkage wheel disc 14 to rotate through the linkage belt 12, the linkage wheel disc 14 drives the gear disc 16 to rotate through the half-ring gear 15, the rotation of the gear disc 16 is intermittent, the gear disc 16 drives the rotating column 102 to advance step by step, the automatic feeding function is realized, after the foam is cut, the end of the foam extends out from the end of the feeding assembly 1, the electric saw 1705 slides on the guide rail 1701 through the objective table 1703, the electric saw 1705 cuts the foam into strips, the servo motor drives the objective table 1703 to move through the screw rod 1706, the servo motor 1707 indirectly provides running power for the electric saw 1705, the cut foam can fall into the charging box 1801, and then after the charging box 1801 is filled, the torsion motor 1803 drives the charging box 1801 to overturn and unload.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any minor modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the technical scope of the present invention.

Claims

1. The utility model provides a cotton processing agency of electrically conductive bubble for electromagnetic shield which characterized in that: comprises a feeding assembly (1), wherein the feeding assembly (1) comprises two base bodies (103), the two base bodies (103) are respectively and independently fixedly installed, a rotating column (102) is installed on one side of each base body (103), the rotating column (102) is rotatably connected with the corresponding base body (103), the two rotating columns (102) are sleeved and connected through a conveyor belt (101), an L-shaped bending rod (2) is arranged above the feeding assembly (1), the section of the bending rod (2) is rectangular, a first sliding sleeve (201) and a second sliding sleeve (202) are sleeved on the bending rod (2), the first sliding sleeve (201) and the second sliding sleeve (202) are respectively in sliding connection with two opposite ends of the bending rod (2), the first sliding sleeve (201) is rotatably connected with the second sliding sleeve (202) through a connecting rod (203), a round rod is arranged on one side of the first sliding sleeve (201) and one side of the second sliding sleeve (202), two ends of the connecting rod (203) are respectively provided with a hole matched with a round rod on one side of the first sliding sleeve (201) and the second sliding sleeve (202), the round rod is rotatably inserted into the hole, one side of the bending rod (2) is provided with a first fixed shaft seat (7), the first fixed shaft seat is fixedly installed relative to the ground, one side of the first fixed shaft seat (7) is provided with a driven wheel (801), one side of the driven wheel (801) is coaxially and fixedly provided with a locking wheel (8), the locking wheel (8) and the driven wheel (801) are rotatably connected with the first fixed shaft seat (7), one side of the first fixed shaft seat (7) is provided with a power motor (9), the output end of the power motor (9) is provided with a driving wheel (10), the driving wheel (10) and the driven wheel (801) are sleeved and connected through a power belt (11), the edge of the locking wheel (8) and the second sliding sleeve (202) are rotatably connected through a pushing rod (802, one end of the push rod (802) is hinged with the side surface of the locking wheel (8), and the other end of the push rod (802) is hinged with the side surface of the second sliding sleeve (202).

2. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 1, wherein: one side of buckling rod (2) is provided with locking axle bed (5), twist rod (3) is installed to one side of locking axle bed (5), the end of twist rod (3) is provided with interlude pole (301), interlude pole (301) are passed from the inboard of locking axle bed (5), and interlude pole (301) and locking axle bed (5) sliding connection, twist rod extends along vertical direction, the cover is equipped with nozzle stub (4) on twist rod (3), the outside of twist rod (3) is provided with spiral line (302), and the inboard of nozzle stub (4) be provided with spiral groove (401) with spiral line (302) assorted, one side of nozzle stub (4) is provided with extension board (402), the centre of extension board (402) is provided with connecting hole (403), be provided with the inserted bar of interlude in connecting hole (403) inboard on the first sliding sleeve.

3. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 2, wherein: two vertical guide rails (6) are fixedly mounted below the locking shaft seat (5), each vertical guide rail (6) is sleeved with a vertical slider (606), the vertical sliders (606) are connected with the vertical guide rails (6) in a sliding mode, one side of each vertical slider (606) is fixedly provided with a lifting platform (601) together, one side of each lifting platform (601) is provided with a transverse plate (602), the transverse plates (602) are perpendicular to the lifting platforms (601), a bearing (604) is fixedly mounted on each transverse plate (602), a rotary cutting saw (603) is fixedly mounted in an inner ring of the bearing (604), the end of each rotary cutting saw (603) penetrates through each transverse plate (602), a propelling cylinder (605) is fixedly mounted on one side of one vertical guide rail (6), and the output end of each propelling cylinder (605) is fixedly connected with each lifting platform (601).

4. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 3, wherein: the lower part of the locking shaft seat (5) is provided with a first universal joint (501), the first universal joint (501) is fixedly connected with the end of the inserting rod (301), one side of the transverse plate (602) is provided with a second universal joint (502), the second universal joint (502) is connected with the end of the rotary cutting saw (603), one side of the first universal joint (501), which is far away from the locking shaft seat, is provided with a square sleeve (503), one side of the second universal joint (502), which is far away from the rotary cutting saw, is provided with a square inserting rod (504), the end of the square inserting rod (504) is inserted into the inner side of the square sleeve (503), and the square inserting rod (504) is connected with the square sleeve (503) in a sliding manner.

5. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 4, wherein: a second fixed shaft seat (13) is arranged below the locking wheel (8), a linkage wheel disc (14) is arranged on one side of the second fixed shaft seat (13), the linkage wheel disc (14) is rotationally connected with the second fixed shaft seat (13), the linkage wheel disc (14) is sleeved and connected with the locking wheel (8) through a linkage belt (12), a semi-ring gear (15) is coaxially and fixedly arranged on one side of the linkage wheel disc (14), and one side of the semi-ring gear (15) is provided with a gear disc (16), the gear disc (16) and the semi-ring gear (15) are meshed with each other, one side of the gear disc (16) is fixedly provided with a third fixed shaft seat (1601), the third fixed shaft seat (1601) is in rotary connection with the gear disc (16), the third fixed shaft seat (1601) is fixedly arranged, the gear disc (16) is fixedly connected with one of the rotating columns (102) through a round rod, and the round rod between the gear disc (16) and the rotating column (102) penetrates through the seat body (103).

6. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 5, wherein: one end that the toothed disc was kept away from in material loading subassembly (1) is provided with cutting assembly (17), cutting assembly (17) include two guide rail (1701), guide rail (1701) independent fixed mounting respectively, the cover is equipped with hoist and mount slider (1702) on every guide rail (1701), hoist and mount slider (1702) and guide rail (1701) sliding connection, the common fixed mounting in bottom of two hoist and mount sliders (1702) has objective table (1703), the bottom fixed mounting of objective table (1703) has electric saw (1705), the direction of transfer of guide rail and conveyer belt is perpendicular.

7. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 6, wherein: the middle of the top surface of the object stage (1703) is fixedly provided with a nut block (1704), a screw rod (1706) is inserted into the inner side of the nut block (1704), the screw rod (1706) is arranged at the output end of a servo motor (1707), and the servo motor (1707) is fixedly arranged.

8. The processing mechanism of the conductive foam for electromagnetic shielding according to claim 7, wherein: unloading subassembly (18) are installed to the below of cutting subassembly (17), unloading subassembly (18) are including charging box (1801), base station (1802) is installed to the bottom of charging box (1801), base station (1802) fixed mounting, two turn-ups are extended to the top of base station (1802), charging box's (1801) relative both sides lateral wall and two turn-ups swivelling joint that base station (1802) extend, torsion motor (1803) are installed to one side of base station (1802), base station (1802) are passed to the output of torsion motor (1803), with and charging box (1801) fixed connection, the bottom of base station (1802) is provided with four lower margin (1804), lower margin (1804) align to grid is in the bottom surface of base station (1802).