CN213412069U - A split piece machine for foaming sponge - Google Patents

Abstract

The utility model belongs to the technical field of the technique of rubber processing and specifically relates to a split piece machine for foaming sponge is related to, its technical scheme main points are: the material splitting machine comprises a rack, a material guiding assembly, a splitting assembly, a material discharging assembly and a material receiving assembly, wherein one end of the rack is a feeding end for materials to enter, the other end of the rack is a material discharging end for materials to be output, the material guiding assembly is movably arranged on the rack and is positioned at the feeding end, the splitting assembly is fixedly arranged in the rack and is used for splitting the materials, the material discharging assembly and the material receiving assembly are positioned at the material discharging end and are arranged at intervals up and down, and the material guiding assembly, the splitting assembly, the material discharging assembly and the material; the splitting assembly comprises a splitting cutter fixedly connected to the rack and used for splitting materials, and the edge of the splitting cutter faces the feeding end. The application has the technical effect of splitting the foamed rubber material.

Description

A split piece machine for foaming sponge

Technical Field

The application relates to the technical field of sponge processing equipment, in particular to a splitting machine for foaming sponge.

Background

The foaming sponge is a sponge material which is prepared by taking pure natural sponge as a main body, adding a specific foaming agent together with other raw materials, foaming the sponge and performing hot press molding, and is commonly used for manufacturing flexible sponge products such as insoles, shoulder pads, patches, non-slip mats and the like.

Currently, the thickness of the foamed sponge material (hereinafter referred to as "material") required to produce different sponge products is often different. In the production and manufacturing process of the existing foaming sponge, the foaming thickness of the sponge is difficult to accurately reach the required thickness due to different dosages of the foaming agent or the plasticity of the sponge material, and further the subsequent processing treatment is required.

Therefore, a thickness splitting machine for the foamed sponge needs to be designed for performing thickness splitting on the foamed sponge.

SUMMERY OF THE UTILITY MODEL

In order to realize the technical effect to the split of foaming rubber material, this application provides a split piece machine for foaming sponge.

The application provides a split piece machine for foaming sponge adopts following technical scheme:

a splitting machine for foaming sponge comprises a rack, a material guide assembly, a splitting assembly, a material discharging assembly and a material receiving assembly, wherein one end of the rack is a feeding end for materials to enter, the other end of the rack is a material discharging end for materials to be output; the splitting assembly comprises a splitting cutter fixedly connected to the rack and used for splitting materials, and a cutter edge of the splitting cutter faces the feeding end.

By adopting the technical scheme, when the material needs to be chopped, a worker feeds the material from the feeding end to the chopping assembly by using the material guide assembly; when the materials are moved to the splitting knife, the knife edge is contacted with the materials and splits the materials, and then the materials are divided into two parts in the thickness direction of the materials, and further divided into two layers of materials; and respectively receiving the two layers of materials by using the discharging assembly and the receiving assembly.

Preferably, the material guiding assembly sequentially comprises a plurality of material supporting rollers rotatably connected to the frame and used for supporting the materials, abutting rollers rotatably connected to the frame and abutting against two opposite sides of the materials, and material guiding rollers rotatably connected to the frame and used for guiding the materials along the conveying direction of the materials; and one end of the material guide roller is provided with a driving assembly for driving the material guide roller to rotate.

Through adopting above-mentioned technical scheme, when needs are to splitting cutter transported substance material, the staff places the material in holding in the palm material roller department to the propelling movement material passes from two supporting between the tight rollers, until keeping off tightly with the guide roller, utilizes a driving motor drive guide roller to rotate, and then the guide roller drives the material and removes to splitting cutter's direction.

Preferably, the number of the guide rollers is two, and the two guide rollers are positioned on two opposite sides of the material.

Through adopting above-mentioned technical scheme, utilize two guide rollers, rotate and drive the material removal simultaneously in the relative both sides of material respectively, and then improved the guide efficiency to the material.

Preferably, the driving assembly comprises a first driving motor fixedly mounted on the frame and close to one end of the material guide roller, and a connecting rod rotatably connected between the first driving motor and the material guide roller through a coupling; one side of the material guide roller, which is far away from the material, is provided with a tightly supporting assembly for tightly supporting the material guide roller.

Through adopting above-mentioned technical scheme, when needs drive guide roller, the staff starts a driving motor, and a driving motor's output shaft rotates and then drives the head rod and rotate, and the head rod rotates and drives guide roller and rotate, and then realizes the guide to the material.

Preferably, the abutting assembly comprises a first fixing rod fixedly connected to the frame, an abutting shaft with a side wall abutting against the side wall of the material guide roller and rotating relatively, and a mounting block with one side fixedly connected to the first fixing rod and the other side rotatably connected to the abutting shaft.

Through adopting above-mentioned technical scheme, utilize to support the axle lateral wall and guide roller lateral wall to support tightly and rotate and install in the installation piece, when the guide roller rotates, the guide roller drives to support the axle rotation and support tightly the axle simultaneously and support tightly in the guide roller, and then reduce the condition emergence that the guide roller takes place the skew because of the shaft coupling transmission.

Preferably, the discharging assembly comprises a material rolling roller rotatably connected to the frame for rolling the material and a first conveying belt communicated between the material rolling roller and the splitting assembly and used for conveying the material to the material rolling roller.

Through adopting above-mentioned technical scheme, when the material was accomplished to split and is cut, divide into two-layer material, wherein the length direction ejection of compact of one deck material along first conveyer belt and export to windup roller department, the staff takes the material to put at the lateral wall of windup roller, along with the output rolling material of material.

Preferably, the number of the winding rollers is two, and the two winding rollers are parallel to each other.

Through adopting above-mentioned technical scheme, utilize two winding up rollers, when needs coil stock, the staff with the material butt between the lateral wall of two winding up rollers, the staff rolling material of being convenient for.

Preferably, the material receiving assembly comprises a second conveyor belt which is communicated with the chopping assembly and is arranged at an upper and lower interval with the first conveyor belt.

Through adopting above-mentioned technical scheme, the second conveyer belt drives another layer of material and exports along the direction of delivery of second conveyer belt, and then reduces and take place to interfere at the in-process of the ejection of compact between the two-layer material.

Preferably, still including install in the guide subassembly deviates from the pay-off subassembly of cleaving subassembly one side, the pay-off subassembly includes fixed mounting in the support frame of frame, movable mounting in the support frame and for the lifter of support frame oscilaltion and rotate connect in the feed roll that the lifter supplied the material to take, the lifter with install between the support frame and be used for the drive actuating cylinder of lifter oscilaltion.

Through adopting above-mentioned technical scheme, the staff closes the surface at the feed roll with the material lid, when needs are to the pay-off of guide subassembly, drives actuating cylinder drive lifter oscilaltion, and then the lifter drives the feed roll oscilaltion for the feed roll drives the material and can take place the luffing motion at the in-process of pay-off, and then has reduced the material and has produced the condition emergence of irreversible deformation because of too compact and leading to splitting at the in-process of splitting.

In summary, the present application includes at least one of the following beneficial technical effects:

1. feeding the material from the feeding end to the chopping assembly through the material guide assembly; when the material moves to the splitting knife, the material is contacted with the knife edge, so that the splitting knife splits the material, and the material is divided into two parts in the thickness direction and then divided into two layers; respectively receiving the two layers of materials by using a discharging assembly and a receiving assembly;

2. the material is placed at the material supporting roller, and is pushed to pass through the two abutting rollers until the material is abutted against one side, facing the abutting rollers, of the material guiding roller, the driving assembly is utilized to drive the material guiding roller to rotate, and then the material guiding roller rotates to drive the material to move towards the direction of the splitting cutter;

3. through supporting tightly and rotate with the guide roller lateral wall and install in the mounting groove, when the guide roller rotated, the guide roller drove to support the axle and rotate and support the axle simultaneously and support tightly in the guide roller, and then reduce the guide roller and take place not influence the rotation of guide roller simultaneously because of the condition emergence of shaft coupling transmission skew.

Drawings

FIG. 1 is a schematic view of the overall structure of a foam sponge splitting machine according to the present embodiment;

FIG. 2 is a schematic view of the structure of FIG. 1 from another perspective;

FIG. 3 is a schematic structural view of the feeding assembly in the present embodiment;

FIG. 4 is a schematic structural view of the material guiding assembly and the fastening assembly in the present embodiment;

FIG. 5 is a schematic structural diagram of the material guiding assembly, the tightening assembly, the driving assembly and the cleaving assembly in the present embodiment;

FIG. 6 is a schematic diagram of a part of the structure of the material cleaved by the cleaving assembly of the present embodiment;

FIG. 7 is a schematic structural view of the discharging assembly and the receiving assembly in this embodiment.

In the figure, 1, a frame; 11. a side plate; 111. a through hole; 12. a support block; 2. a feeding end; 3. a discharge end; 4. a feeding assembly; 41. a support frame; 411. a support bar; 412. an extension rod; 413. a fixed block; 42. a lifting rod; 43. a push block; 44. a feed roller; 45. a driving cylinder; 5. a material guiding assembly; 51. a material supporting roller; 52. a tightening roller; 53. a material guide roller; 54. a drive assembly; 541. a first drive motor; 542. a first connecting rod; 543. a coupling; 55. a propping component; 551. a first fixing lever; 552. the shaft is abutted; 553. mounting blocks; 554. mounting grooves; 555. a second connecting rod; 6. a cleaving assembly; 61. a second fixing bar; 62. a splitting knife; 621. a knife edge; 7. a discharge assembly; 71. a first conveyor belt; 72. a material rolling roller; 8. a material receiving assembly; 81. a second conveyor belt; 82. a third conveyor belt.

Detailed Description

The present application is described in further detail below with reference to figures 1-7.

The embodiment of the application discloses a split piece machine for foaming sponge. Referring to fig. 1 and 2, the splitting machine comprises a frame 1, wherein one end of the frame 1 is a feeding end 2, and the other end of the frame 1 is a discharging end 3. Frame 1 includes two blocks of curb plates 11 that set up along vertical direction relatively, and two curb plates 11 all are provided with a plurality of along the horizontal direction and run through the through-hole 111 of the 11 relative both sides of curb plate, and the staff of being convenient for is adjusted and is corrected the transport position of material at pan feeding end 2 and discharge end 3.

Meanwhile, the sheet splitting machine further comprises a feeding component 4, a material guide component 5, a splitting component 6, a material receiving component 8 and a material discharging component 7, wherein the feeding component 4 is located at the feeding end 2 of the rack and drives the material to ascend and descend vertically, the material guide component 5 is located at the feeding end 2 and is installed in the rack 1 and used for pulling the material along the conveying direction, the splitting component 6 is installed in the rack 1 and used for splitting the material from the thickness direction of the material, and the material receiving component 8 and the material discharging component 7. Receive and set up along vertical direction interval from top to bottom between material subassembly 8 and the ejection of compact subassembly 7, receive material subassembly 8 and ejection of compact subassembly 7 and withdraw the material that has accomplished the cleaving respectively along two kinds of different directions. The feeding component 4, the material guiding component 5, the chopping component 6, the discharging component 7 and the material receiving component 8 are sequentially communicated along the conveying direction of the materials.

Referring to fig. 2 and 3, specifically, the feeding assembly 4 includes a support frame 41 fixedly installed on the top of the two side plates 11, the support frame 41 includes two support rods 411 respectively welded on the top of the two side plates 11 along the vertical direction, one end of each support rod is welded on one side of the support rod 411 away from the material guiding assembly 5, the other end of each support rod extends to the outside of the machine frame 1 along the horizontal direction, and a fixing block 413 welded on one end of the extension rod 412 away from the machine frame 1 along the horizontal direction. In this embodiment, the number of the extension rods 412 may be four, the four extension rods 412 are parallel to each other, and two corresponding extension rods 412 are respectively located at the top end and the bottom end of each support rod 411 away from the material guiding assembly 5. In this embodiment, the number of the fixing blocks 413 may be two, two fixing blocks 413 are parallel to each other, and each fixing block 413 is welded between the ends of the two extending rods 412 away from the supporting rod 411 in the horizontal direction.

Referring to fig. 2 and 3, in particular, the feeding assembly 4 further includes a lifting rod 42 vertically penetrating the upper and lower surfaces of the two fixing blocks 413 and capable of moving up and down, a pushing block 43 fixedly connected to the lifting rod 42, and a feeding roller 44 rotatably supported on the lifting rod 42. In the present embodiment, the number of the lift pins 42 may be set to two. The two ends of the pushing block 43 are respectively welded between the top ends of the two lifting rods 42, the pushing block 43 can be abutted against the top surface of the fixed block 413, and the two ends of the feeding roller 44 are respectively connected between the bottom ends of the two lifting rods 42 in a rotating manner. In addition, a driving cylinder 45 for driving the lifting rod 42 to move up and down is fixedly installed between the two fixing blocks 413 along the vertical direction, the driving cylinder 45 is fixedly installed on the top surface of the fixing block 413, and a piston rod of the driving cylinder 45 penetrates through the other fixing block 413 and is welded to the bottom of the push block 43.

When feeding is needed, a worker puts one side of the material on the side wall of the feeding roller 44; when guide subassembly 5 along direction of delivery pulling material, the staff starts to drive actuating cylinder 45, drive actuating cylinder 45's piston rod oscilaltion, and then piston rod drive ejector pad 43 oscilaltion, and then ejector pad 43 drives lifter 42 along vertical direction oscilaltion, and then lifter 42 drives feed roll 44 oscilaltion, make the material along with feed roll 44 can take place the luffing motion, and then reduced the material and taken place because of the condition that too compact leads to producing irreversible deformation after cleaving at the in-process of cleaving.

Referring to fig. 4 and 5, the material guiding assembly 5 is used for pulling the material to the chopping assembly 6 along the conveying direction, so as to guide the material. Specifically, the material guiding assembly 5 sequentially includes a plurality of material supporting rollers 51, a pressing roller 52 and a material guiding roller 53, which are rotatably connected between the two side plates 11 along the horizontal direction, along the material conveying direction. In this embodiment, the number of the material supporting rollers 51 can be set to five, and the five material supporting rollers 51 are arranged in an inclined manner upwards at intervals in sequence along the conveying direction of the material. In this embodiment, the number of the resisting rollers 52 can be set to two, and the two resisting rollers 52 respectively resist the material along the two opposite sides of the material, thereby reducing the occurrence of uneven chopping caused by too low compactness during chopping of the material. In this embodiment, the number of the material guiding rollers 53 may be two, and the two material guiding rollers 53 correspondingly abut against two opposite sides of the material.

Referring to fig. 4 and 5, the end portions of the two material guiding rollers 53 in the same direction are respectively provided with a driving assembly 54 for driving the material guiding assembly 5 to rotate, and specifically, the driving assembly 54 includes a first driving motor 541 fixedly mounted on one side wall of one of the side plates 11, which is away from the material guiding rollers 53, and a first connecting rod 542, two ends of which are correspondingly and rotatably connected to the first driving motor 541 and the material guiding rollers 53. One side that curb plate 11 deviates from guide roll 53 has supporting shoe 12 along the welding of horizontal direction, supporting shoe 12 extends in the one side direction of keeping away from guide roll 53, in this embodiment, the quantity of supporting shoe 12 can set up to two, two supporting shoes 12 set up relatively along vertical direction, two first driving motor 541 correspond fixed connection respectively in two relative both sides of supporting shoe 12, and two first driving motor 541's output shaft all faces head rod 542, and rotate with head rod 542 towards the one end of first driving motor 541 through shaft coupling 543, the other end of head rod 542 passes through shaft coupling 543 and guide roll 53's tip fixed connection, in this embodiment, the shaft coupling 543 can set up to universal joint 543.

When the material needs to be pulled along the conveying direction, the worker starts the first driving motor 541, the output shaft of the first driving motor 541 rotates, the first connecting rod 542 is utilized, the output shaft of the first driving motor 541 drives the material guiding roller 53 to rotate, the material guiding roller 53 rotates to drive the material to move, and the material starts from the feeding assembly 4, sequentially passes through the material supporting roller 51, the abutting roller 52 and the material guiding roller 53 and moves towards the splitting assembly 6.

Referring to fig. 4 and 5, the two guide rollers 53 are provided with a tightly-supporting assembly 55 for tightly supporting the guide rollers 53 on the side away from the material, and specifically, the tightly-supporting assembly 55 includes a first fixing rod 551 welded to the two opposite sides of the two side plates 11 in the horizontal direction, a tightly-supporting shaft 552 for tightly supporting the guide rollers 53, and a mounting block 553 installed between the first fixing rod 551 and the tightly-supporting shaft 552. The mounting block 553 is fixedly connected to the first fixing rod 551 along one side in the vertical direction, and rotatably connected to the abutting shaft 552 at the other side, and a side wall of the abutting shaft 552 abuts against a side wall of the material guiding roller 53 along the horizontal direction and relatively rotates with the material guiding roller 53. The welding of installation piece 553 has second connecting rod 555 along vertical direction towards one side of first dead lever 551, and the one end that second connecting rod 555 deviates from installation piece 553 runs through first dead lever 551 along vertical direction, and second connecting rod 555 passes through bolt fixed connection in first dead lever 551. In this embodiment, the number of the second connecting rods 555 may be two, and the two second connecting rods are respectively located at two opposite ends of the side surface of the mounting block 553 in the length direction. Meanwhile, one side of the mounting block 553 facing the resisting shaft 552 is provided with a mounting groove 554 for the resisting shaft 552 to be mounted, and the resisting shaft 552 is rotatably connected to groove walls at both ends of the mounting groove 554 in the length direction. In this embodiment, the number of the two abutting shafts 552 in the same mounting block 553 is set to be two, the two abutting shafts 552 are parallel to each other, and the side walls of the two abutting shafts 552 abut against two opposite sides of the same guide roller 53 respectively.

When the first driving motor 541 of drive starts, first driving motor 541 drives guide roller 53 to rotate through second connecting rod 555 and universal coupling 543, the condition of luffing motion can appear when guide roller 53 rotates takes place, guide roller 53 rotates simultaneously and drives the rotation of supporting shaft 552, utilize supporting shaft 552 to support tightly in guide roller 53, and then reduced the condition that luffing motion appears in guide roller 53 and taken place, do not influence the rotation of guide roller 53 simultaneously.

Referring to fig. 5 and 6, the splitting assembly 6 is located on a side of the guide roll 53 facing away from the abutting roll 52, and specifically, the splitting assembly 6 includes a second fixing rod 61 welded between the two side plates 11 in the horizontal direction and a splitting blade 62 welded to the second fixing rod 61 in the horizontal direction on a side facing the guide roll 53. The cutting edge 621 of the cleaving knife 62 faces the material guiding rollers 53 and is disposed between the two material guiding rollers 53. The top surface of the splitting knife 62 is set to be an arc curved surface, so that the material output after splitting is finished at the later stage. When the guide roller 53 rotates, the guide roller 53 drives the material to move towards the cleaving assembly 6, and then the port of the material abuts against the knife edge 621 of the cleaving knife 62, the guide roller 53 continuously rotates and drives the material to continuously move towards the cleaving knife 62, and then the cleaving knife 62 cleaves the material from the thickness direction of the material, so that two layers of materials are cleaved by one layer of material. One layer of material is at the top and exits along the top surface of the cleaver 62 and the other layer of material is at the bottom and exits along the bottom surface of the cleaver 62.

Referring to fig. 6 and 7, the discharging assembly 7 is used for outputting the material which is located at the bottom and is output along the bottom surface of the cleaving knife 62, and specifically, the discharging assembly 7 includes a first conveying belt 71 with one end inclined downward toward the other end, and a material rolling roller 72 which is rotatably connected between the two side plates 11 along the horizontal direction and is communicated with the first conveying belt 71. The first conveyor belt 71 is communicated with the splitting knife 62, one end, facing the splitting knife 62, of the first conveyor belt 71 is a high-position end, the high-position end is close to the bottom of the splitting knife 62, and one end, facing away from the splitting knife 62, of the first conveyor belt 71 is a low-position end. In this embodiment, the number of the winding rollers 72 may be two, and the two winding rollers 72 are parallel to each other and at the same height. One side of the frame 1 is provided with a second driving motor (not shown in the figure) which is coaxially and fixedly connected with one rotating shaft of the first conveyor belt 71 and is used for driving the first conveyor belt 71 to drive, and a third driving motor (not shown in the figure) which is coaxially and fixedly connected with the material rolling roller 72 and is used for driving the material rolling roller 72 to rotate.

When the materials are split, the worker drives the second driving motor and the third driving motor, the second driving motor drives the first conveyor belt 71 to transmit, and then the first conveyor belt 71 drives the materials at the bottom to be output in the top-down inclined direction; the staff takes the lateral wall of material to put at the top of two coiling material roller 72 lateral walls, and third driving motor drives coiling material roller 72 and rotates, and then coiling material roller 72 drives the material and removes staff's rolling material simultaneously, and then realizes the coil stock to being located the bottom material.

Referring to fig. 6 and 7, the material receiving assembly 8 is used for outputting the material which is located at the top and is output along the top surface of the cleaving knife 62, and specifically, the material receiving assembly 8 includes a second conveyor belt 81 with one end inclined and upward arranged toward the other end, and a third conveyor belt 82 with one end communicated with the second conveyor belt 81 and the other end extending toward one side departing from the second conveyor belt 81 along the horizontal direction. The second conveyor belt 81 and the third conveyor belt 82 are both disposed between the two side plates 11. The second conveyor belt 81 is communicated with the splitting blade 62, and one end of the second conveyor belt 81 facing the splitting blade 62 is a low end, and one end facing the third conveyor belt 82 is a high end. A fourth driving motor (not shown) for driving the second conveyor belt 81 and the third conveyor belt 82 to transmit power is arranged on one side of the frame 1. The first conveyor belt 71, the second conveyor belt 81 and the third conveyor belt 82 are all prior art conveyor belts, and will not be described in detail here.

When the material is cleaved, the worker starts the second driving motor, the second driving motor drives the second conveyor belt 81 to transmit, and then the second conveyor belt 81 drives the material to move along the direction of the third conveyor belt 82; when the material moves to the third conveyor belt 82, the third conveyor belt 82 drives the material to move in the direction away from the second conveyor belt 81 at the same time, and then the material positioned at the top is output.

The implementation principle of the splitting machine for the foaming sponge in the embodiment of the application is as follows:

when the material needs to be split into pieces, a worker pulls out one end of the material placed at the feeding end 2, the material passes through the two lifting rods 42 and is placed at the top of the side wall of the feeding roller 44, then the material is placed at the top of the side wall of the material supporting roller 51, and the port for pulling the material sequentially passes through the two abutting rollers 52 and the two material guiding rollers 53, so that the abutting rollers 52 and the material guiding rollers 53 are abutted against the material.

When the material needs to be cleaved in the thickness direction of the material, a worker simultaneously starts the driving cylinder 45 and the first driving motor 541, then the driving cylinder 45 drives the piston rod to stretch, then the piston rod drives the lifting rod 42 to move up and down by utilizing the push block 43, and then the lifting rod 42 drives the feeding roller 44 and the material to move up and down, so that the phenomenon that the material subjected to cleaving is irreversibly deformed due to over-compactness in the cleaving process is reduced; meanwhile, the first driving motor 541 drives the material guiding roller 53 to rotate, so that the material guiding roller 53 rotates to drive the material to move towards the splitting knife 62, the port of the material is abutted to the knife edge 621 of the splitting knife 62, the material guiding roller 53 continues to rotate, the splitting knife 62 splits the material, and a layer of material is split into two layers of material.

The staff starts second driving motor and third driving motor, and then first conveyer belt 71 and windup roller 72 rotate, and first conveyer belt 71 drives the material and exports along top-to-bottom incline direction to carry out the coil stock in windup roller 72 department. Meanwhile, the worker starts a fourth driving motor, the fourth driving motor drives the second conveyor belt 81 and the third conveyor belt 82 to rotate, the second conveyor belt 81 drives the materials on the top to incline towards the third conveyor belt 82 to move along the direction from bottom to top, and the third conveyor belt 82 drives the materials to move towards the direction departing from the second conveyor belt 81, so that the materials on the top are output.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a split piece machine for foaming sponge, includes frame (1), the pan feeding end (2) of one end for supplying the material to get into of frame (1), discharge end (3) of the other end for supplying the material output, its characterized in that: the material splitting device is characterized by further comprising a material guide assembly (5) movably arranged on the rack (1) and positioned at the feeding end (2), a splitting assembly (6) fixedly arranged in the rack (1) and used for splitting materials, and a material discharging assembly (7) and a material receiving assembly (8) which are positioned at the material discharging end (3) and arranged at intervals up and down, wherein the material guide assembly (5), the splitting assembly (6), the material discharging assembly (7) and the material receiving assembly (8) are sequentially communicated along the conveying direction of the materials; the splitting assembly (6) comprises a splitting knife (62) fixedly connected to the rack (1) and used for splitting materials, and a knife edge (621) of the splitting knife (62) faces the feeding end (2).

2. The splitting machine for foaming sponges according to claim 1, characterized in that: the material guide assembly (5) sequentially comprises a plurality of material supporting rollers (51) which are rotatably connected to the rack (1) and used for supporting materials, abutting rollers (52) which are rotatably connected to the rack (1) and abut against two opposite sides of the materials, and material guide rollers (53) which are rotatably connected to the rack (1) and used for guiding materials along the conveying direction of the materials; one end of the guide roller (53) is provided with a driving component (54) for driving the guide roller (53) to rotate.

3. The splitting machine for foaming sponges according to claim 2, characterized in that: the number of the guide rollers (53) is two, and the two guide rollers (53) are positioned on two opposite sides of the material.

4. The splitting machine for foaming sponges according to claim 2, characterized in that: the driving assembly (54) comprises a first driving motor (541) fixedly installed on the frame (1) and close to one end of the material guide roller (53), and a connecting rod rotatably connected between the first driving motor (541) and the material guide roller (53) through a coupler (543); and one side of the guide roller (53) departing from the material is provided with a tight abutting component (55) for abutting against the guide roller (53).

5. The splitting machine for foaming sponges according to claim 4, characterized in that: the abutting assembly (55) comprises a first fixing rod (551) fixedly connected to the rack (1), an abutting shaft (552) with a side wall abutting against the side wall of the guide roller (53) and capable of rotating relatively, and a mounting block (553) with one side fixedly connected to the first fixing rod (551) and the other side rotatably connected with the abutting shaft (552).

6. The splitting machine for foaming sponges according to claim 1, characterized in that: the discharging assembly (7) comprises a coiling roller (72) which is rotatably connected to the rack (1) and used for coiling materials and a first conveying belt (71) which is communicated between the coiling roller (72) and the chopping assembly (6) and used for conveying the materials to the coiling roller (72).

7. The splitting machine for foaming sponges according to claim 6, characterized in that: the number of the coiling rollers (72) is two, and the two coiling rollers (72) are parallel to each other.

8. The splitting machine for foaming sponges according to claim 6, characterized in that: the material receiving assembly (8) comprises a second conveying belt (81) which is communicated with the chopping assembly (6) and is arranged at an upper and lower interval with the first conveying belt (71).

9. The splitting machine for foaming sponges according to claim 1, characterized in that: still including install in guide subassembly (5) deviate from pay-off subassembly (4) of cleaving subassembly (6) one side, pay-off subassembly (4) including fixed mounting in support frame (41) of frame (1), movable mounting in support frame (41) and for lifter (42) of support frame (41) oscilaltion and rotate connect in lifter (42) supply the material to take up feed roll (44) of putting, lifter (42) with install between support frame (41) and be used for the drive actuating cylinder (45) of lifter (42) oscilaltion.

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