阅读说明：本技术 一种用于海绵块批量成型的高效热切割设备 (Efficient hot cutting equipment for batch forming of sponge blocks ) 是由 董政琦 董成勇 于 2021-01-26 设计创作，主要内容包括：本发明涉及海绵切割领域,具体涉及一种用于海绵块批量成型的高效热切割设备,包括上料机构、推料机构、驱动机构、第一切割组件、第二切割组件和下料机构,上料机构设置于驱动机构的输出方向始端的一侧,第一切割组件包括第一热切割机构和第一贴合机构,第二切割组件包括第二热切割机构和第二贴合机构,下料机构设置于驱动机构的远离上料机构的一端,通过第一切割组件和第二切割组件的协调运作,提高了海绵切割效率,同时减少了劳动量投入,减低了企业的经济投入,通过第一贴合机构和第二贴合机构对海绵的固定,提高切割时的偏差,提高了海绵切割时的稳定性,上料机构和推料机构的设立推动海绵朝着切割出移动,提高了生产的便捷化程度。(The invention relates to the field of sponge cutting, in particular to high-efficiency thermal cutting equipment for sponge block batch forming, which comprises a feeding mechanism, a material pushing mechanism, a driving mechanism, a first cutting assembly, a second cutting assembly and a discharging mechanism, wherein the feeding mechanism is arranged on one side of the starting end of the output direction of the driving mechanism, the first cutting assembly comprises a first thermal cutting mechanism and a first laminating mechanism, the second cutting assembly comprises a second thermal cutting mechanism and a second laminating mechanism, the discharging mechanism is arranged on one end of the driving mechanism, which is far away from the feeding mechanism, the sponge cutting efficiency is improved through the coordinated operation of the first cutting assembly and the second cutting assembly, the labor input is reduced, the economic input of an enterprise is reduced, the sponge is fixed through the first laminating mechanism and the second laminating mechanism, the deviation during cutting is improved, and the stability during sponge cutting is improved, the feeding mechanism and the pushing mechanism are arranged to push the sponge to move towards the cutting, so that the convenience degree of production is improved.)

1. An efficient thermal cutting device for batch forming of sponge blocks is characterized by comprising a feeding mechanism, a pushing mechanism, a driving mechanism, a first cutting assembly, a second cutting assembly and a discharging mechanism;

the driving mechanism is vertically arranged and used for conveying the sponge to the first cutting assembly and the second cutting assembly for cutting;

the feeding mechanism is arranged on one side of the starting end of the output direction of the driving mechanism, and the output direction of the feeding mechanism is vertical to the output direction of the driving mechanism;

the pushing mechanism is arranged at one end of the feeding mechanism close to the driving mechanism and is positioned at one side of the feeding mechanism far away from the driving mechanism;

the first cutting assembly is erected at two ends of the driving mechanism and is positioned at one end, away from the feeding mechanism, of the driving mechanism, the first cutting assembly comprises a first hot cutting mechanism used for carrying out primary cutting on the sponge and a first laminating mechanism used for providing stability for the sponge during cutting, the first laminating mechanism is erected at two ends, away from the feeding mechanism, of the driving mechanism, the first hot cutting mechanisms are erected at two ends of the first laminating mechanism, and the first hot cutting mechanisms are positioned right above the first laminating mechanism;

the second cutting assembly is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, the second cutting assembly comprises a second hot cutting mechanism for performing secondary cutting on the sponge and a second laminating mechanism for providing stability for the sponge during cutting, the second laminating mechanism is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, and the second hot cutting mechanism is erected at two ends of the second laminating mechanism and is positioned right above the second laminating mechanism;

the discharging mechanism is arranged at one end, far away from the feeding mechanism, of the driving mechanism, and the output direction of the discharging mechanism is consistent with that of the driving mechanism.

2. The efficient thermal cutting equipment for sponge block batch forming according to claim 1, wherein the feeding mechanism comprises a feeding frame (1), a first motor (2), a first belt (3), a first transmission rod (4), a first connecting rod (5), a first loop bar (6), a first limiting plate (7) and a second limiting plate (8), the feeding frame (1) is vertically arranged at the output direction starting end of the driving mechanism, the length direction of the feeding mechanism is vertical to the output direction of the driving mechanism, the first transmission rod (4) and the first connecting rod (5) are horizontally arranged at two ends of the top of the feeding frame (1), the first loop bar (6) is sleeved on the first connecting rod (5), two ends of the first belt (3) are sleeved on the first transmission rod (4) and the first loop bar (6), a plurality of limiting blocks (9) for placing sponge are arranged on the surface of the first belt (3), first limiting plate (7) and second limiting plate (8) are vertical setting in the both ends at last work or material rest (1) top, and rectangle mouth (10) have been seted up to one end that second limiting plate (8) are located actuating mechanism, and first motor (2) are fixed to be set up in the lateral wall of last work or material rest (1), and the output of first motor (2) links to each other with first transfer line (4).

3. The efficient thermal cutting equipment for batch forming of the sponge blocks as claimed in claim 1, wherein the material pushing mechanism comprises a cylinder (11), a first supporting column (12) and a pushing plate (13), the first supporting column (12) is vertically arranged on the outer side of one end, close to the driving mechanism, of the material feeding mechanism, the air rod is horizontally arranged at the top of one side, away from the driving mechanism, of the first supporting column (12), the pushing plate (13) is sleeved on the output end of the cylinder (11), and the pushing plate (13) is flush with the rectangular opening (10) of the second limiting plate (8).

4. The efficient thermal cutting equipment for sponge block batch forming according to claim 1, wherein the driving mechanism comprises a conveying frame (14), a second motor (15), a second transmission rod (16), a second connecting rod (17), a second loop bar (18) and a second belt (19), the conveying frame (14) is vertically arranged at the tail end of the output direction of the feeding mechanism, the conveying frame (14) is positioned at one side of the feeding frame (1) far away from the pushing mechanism, openings (20) are respectively arranged at two ends of the conveying frame (14) close to the second thermal cutting, the second transmission rod (16) and the second connecting rod (17) are horizontally arranged at the tops of two ends of the conveying frame (14), the second loop bar (18) is sleeved on the second connecting rod (17), the second motor (15) is fixedly arranged at the outer side of the conveying frame (14), and the output end of the second motor (15) is connected with the second transmission rod (16), two ends of a second belt (19) are respectively sleeved on the second transmission rod (16) and the second sleeve rod (18), and the second belt (19) is flush with the joint of the limiting block (9) on the surface of the first belt (3) and the sponge.

5. The efficient thermal cutting equipment for batch forming of sponge blocks as claimed in claim 1, wherein the first applying mechanism comprises a third motor (21), a sliding table (22), a bidirectional screw rod (23), two sliding blocks (24), a first inductor (25) and two applying plates (26), the sliding table (22) is horizontal, two ends of the bottom of the sliding table are arranged at the bottom of the driving frame through two second supporting columns (27), the bidirectional screw rod (23) is horizontally arranged in the sliding table (22), the two sliding blocks (24) are sleeved on threads at two ends of the bidirectional screw rod (23), the third motor (21) is fixedly arranged at the outer side of the sliding table (22), an output end of the third motor (21) is connected with one end of the bidirectional screw rod (23), the two applying plates (26) are vertically arranged on the two sliding blocks (24), the first inductor (25) is arranged at one side of the sliding table (22) far away from the feeding mechanism through a supporting plate, the height of the first inductor (25) is consistent with the top of the driving frame.

6. The efficient thermal cutting equipment for sponge block batch forming according to claim 1, wherein the first thermal cutting mechanism comprises two sets of first lead screw sliding tables (28), a first cross beam (29), two first C-shaped brackets (30), two first connecting plates (31), a plurality of first thermal cutting knives (32) and a plurality of first fixing blocks (33), the two sets of first lead screw sliding tables (28) are vertically erected at two ends of the sliding table (22), the first cross beam (29) is horizontal, two ends of the first lead screw sliding tables are connected with output ends of the two sets of first lead screw sliding tables (28), the two first C-shaped brackets (30) are vertically arranged at two ends of the bottom of the first cross beam (29), the two first connecting plates (31) are horizontal, two ends of the first connecting plates are respectively connected with two ends of the two first C-shaped brackets (30), the plurality of first fixing blocks (33) are arranged at a fixed interval at the inner side of one connecting plate far away from the feeding mechanism, a plurality of first hot cutting knife (32) are level and one end sets up in the interval that is close to a feed mechanism's a connection board's the outside other end and links to each other with a plurality of fixed block with the interval that the fixed block distributes.

7. The efficient thermal cutting equipment for batch forming of sponge blocks as claimed in claim 1, wherein the second attaching mechanism comprises two sets of transmission mechanisms, the two sets of transmission mechanisms are symmetrically distributed through the central line of the driving frame, each set of transmission mechanism comprises a fourth motor (34), a third connecting rod (35), a second inductor (36), two shaft seats (37), two turning rods (38) and a third supporting column (39), the third supporting column (39) is arranged at the tail end of the output direction of the driving mechanism, the third supporting column (39) is arranged at one side of the first attaching mechanism away from the feeding mechanism, the two shaft seats (37) are arranged at the top of the third supporting column (39) in a spaced and mutually parallel manner, the third connecting rod (35) is horizontal and two ends are connected with the two shaft seats (37), the two turning rods (38) are sleeved at two ends of the third connecting rod (35), the distance between the two turning rods (38) is the same as the diameter of the sponge, the second inductor (36) is arranged at one end, far away from the feeding mechanism, of the top of the third supporting column (39), the fourth motor (34) is fixedly arranged on the outer side of one shaft seat, and the output end of the fourth motor (34) is connected with one end of the third connecting rod (35).

8. The efficient thermal cutting equipment for sponge block batch forming according to claim 1, wherein the second thermal cutting mechanism comprises two groups of second lead screw sliding tables (40), a second cross beam (41), two second C-shaped supports (42), two second connecting plates (43) and a plurality of second thermal cutting knives (44), the two groups of second lead screw sliding tables (40) are vertically arranged at two ends of two third supporting columns (39), the second cross beam (41) is horizontal, two ends of the second cross beam are connected with output ends of the two groups of second lead screw sliding tables (40), the two second C-shaped supports (42) are vertically arranged at two ends of the bottom of the cross beam, the two second connecting plates (43) are horizontal, two ends of the second connecting plates are respectively connected with two ends of the two second C-shaped supports (42), a U-shaped groove (45) with a fixed interval is arranged at the inner side of one connecting plate close to the first motor (2), one end of the second heat cutting knives is arranged on the other connecting plate at a distance distributed by the U-shaped grooves (45), and the other ends of the second heat cutting knives (44) are embedded in the U-shaped grooves (45).

9. The efficient thermal cutting equipment for sponge block batch forming according to claim 1, wherein the blanking mechanism comprises a conveying conveyor belt (46), a collecting box (47) and two limiting frames (48), the conveying conveyor belt (46) is arranged at one end of the driving mechanism far away from the feeding mechanism through two fourth supporting columns (49), the two limiting frames (48) are arranged at the top of two ends of the conveying conveyor belt (46) at intervals and in parallel with each other, and the collecting box (47) is vertically arranged at the tail end of the output direction of the conveying conveyor belt (46).

Technical Field

The invention relates to the field of sponge cutting, in particular to high-efficiency hot cutting equipment for batch forming of sponge blocks.

Background

The sponge has the characteristics of good flexibility, water absorption and the like, so the sponge is often used in the transportation of articles or the storage of the articles to protect the articles, the sponge has a wide application range, and the production requirement is large.

The electric heat cutting device on market is when using, and cutting process poor stability, cutting inefficiency, the rejection rate is high, and the urgent need is improved, at the in-process of normal processing, can not play the function of protection, in the time of the unexpected condition of taking place moreover, has the problem that its device can not be timely conveniently handled to it. Therefore, an electric cutting device for sponge production is provided.

Disclosure of Invention

In order to solve the technical problem, the high-efficiency thermal cutting equipment for batch forming of the sponge blocks is provided, and the technical scheme solves the problems of automatic thermal cutting, convenience and high stability.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows: a high-efficiency thermal cutting device for sponge block batch forming comprises a feeding mechanism, a pushing mechanism, a driving mechanism, a first cutting assembly, a second cutting assembly and a discharging mechanism;

the driving mechanism is vertically arranged and used for conveying the sponge to the first cutting assembly and the second cutting assembly for cutting;

the feeding mechanism is arranged on one side of the starting end of the output direction of the driving mechanism, and the output direction of the feeding mechanism is vertical to the output direction of the driving mechanism;

the pushing mechanism is arranged at one end of the feeding mechanism close to the driving mechanism and is positioned at one side of the feeding mechanism far away from the driving mechanism;

the first cutting assembly is erected at two ends of the driving mechanism and is positioned at one end, away from the feeding mechanism, of the driving mechanism, the first cutting assembly comprises a first hot cutting mechanism used for carrying out primary cutting on the sponge and a first laminating mechanism used for providing stability for the sponge during cutting, the first laminating mechanism is erected at two ends, away from the feeding mechanism, of the driving mechanism, the first hot cutting mechanisms are erected at two ends of the first laminating mechanism, and the first hot cutting mechanisms are positioned right above the first laminating mechanism;

the second cutting assembly is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, the second cutting assembly comprises a second hot cutting mechanism for performing secondary cutting on the sponge and a second laminating mechanism for providing stability for the sponge during cutting, the second laminating mechanism is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, and the second hot cutting mechanism is erected at two ends of the second laminating mechanism and is positioned right above the second laminating mechanism;

the discharging mechanism is arranged at one end, far away from the feeding mechanism, of the driving mechanism, and the output direction of the discharging mechanism is consistent with that of the driving mechanism.

Preferably, the feeding mechanism comprises a feeding frame, a first motor, a first belt and a first transmission rod, the automatic feeding device comprises a first connecting rod, a first loop bar, a first limiting plate and a second limiting plate, wherein the feeding frame is vertically arranged at the output direction starting end of the driving mechanism, the length direction of the feeding mechanism is perpendicular to the output direction of the driving mechanism, the first driving rod and the first connecting rod are horizontally arranged at the two ends of the top of the feeding frame, the first loop bar is sleeved on the first connecting rod, the two ends of a first belt are sleeved on the first driving rod and the first loop bar, a plurality of limiting blocks for placing sponge are arranged on the surface of the first belt, the first limiting plate and the second limiting plate are vertically arranged at the two ends of the top of the feeding frame, a rectangular opening is formed in one end, located on the driving mechanism, of the second limiting plate, a first motor is fixedly arranged on the side wall of the feeding frame, and the output end of the.

Preferably, pushing equipment includes cylinder, first support post and push pedal, and first support post is vertical to be set up in the outside that feed mechanism is close to actuating mechanism one end, and the gas pole is the level and sets up in one side top that actuating mechanism was kept away from to first support post, and the output of cylinder is located to the push pedal cover, and the push pedal flushes with the rectangle mouth of second limiting plate.

Preferably, actuating mechanism includes the transfer frame, the second motor, the second transfer line, the second connecting rod, second loop bar and second belt, the transfer frame is vertical the tail end that sets up in feed mechanism output direction, the transfer frame is located the one side that pushing equipment was kept away from to the work or material rest, the both ends that the transfer frame is close to the second hot cutting all are equipped with the opening, second transfer line and second connecting rod are the level and set up in the both ends top of transfer frame, the second connecting rod is located to the second loop bar cover, the second motor is fixed to be set up in the outside of transfer frame, the output of second motor links to each other with the second transfer line, the both ends of second belt overlap respectively on locating second transfer line and second loop bar, the stopper on second belt and the first belt surface flushes with the laminating department of sponge.

Preferably, first laminating mechanism includes the third motor, the slip table, two-way lead screw, two sliders, first inductor and two rigging boards, the slip table is the level and sets up in the bottom of carriage through two second support columns in bottom both ends, two-way lead screw is the level and sets up in the slip table, two slider covers are located on the both ends screw thread of two-way lead screw, the fixed outside that sets up in the slip table of third motor, the output of third motor links to each other with two-way lead screw one end, two rigging boards are vertical the setting on two sliders, first inductor sets up in one side that the feed mechanism was kept away from to the slip table through the backup pad, the height of first inductor keeps unanimous with the top of carriage.

Preferably, the first hot cutting mechanism comprises two sets of first lead screw sliding tables, a first cross beam, two first C-shaped supports, two first connecting plates, a plurality of first hot cutting knives and a plurality of first fixing blocks, the two sets of first lead screw sliding tables are vertically erected at two ends of the sliding tables, the first cross beam is horizontal, two ends of the first cross beam are connected with output ends of the two sets of first lead screw sliding tables, the two first C-shaped supports are vertically arranged at two ends of the bottom of the first cross beam, the two first connecting plates are horizontal, two ends of the first connecting plates are respectively connected with two ends of the two first C-shaped supports, a fixed distance between the first fixing blocks of the plurality of first connecting plates is arranged on the inner side of one connecting plate far away from the feeding mechanism, the first hot cutting knives of the plurality of first hot cutting knives are horizontal, and one end of each hot cutting knife is arranged at the outer side of one connecting plate.

Preferably, the second attaching mechanism comprises two groups of transmission mechanisms which are symmetrically distributed through the central line of the driving frame, the two groups of transmission mechanisms comprise a fourth motor, a third connecting rod and a second inductor, two axle beds, two upset poles and third support column, the third support column sets up in one side that feed mechanism was kept away from to drive mechanism output direction's tail end and third support column are located first laminating mechanism, two axle beds are the interval and parallel arrangement of each other in the top of third support column, the third connecting rod is level and both ends and links to each other with two axle beds, the both ends of third connecting rod are located to two upset pole covers, the interval of two upset poles is the same with the diameter of sponge, the second inductor sets up in the one end that feed mechanism was kept away from at the top of third support column, the fixed outside that sets up in an axle bed of fourth motor, the output of fourth motor links to each other with the one end of third connecting rod.

Preferably, the second thermal cutting mechanism comprises two sets of second lead screw sliding tables, a second cross beam, two second C-shaped supports, two second connecting plates and a plurality of second thermal cutting knives, the two sets of second lead screw sliding tables are vertically arranged at two ends of two third supporting columns, the second cross beam is horizontal, two ends of the second cross beam are connected with output ends of the two sets of second lead screw sliding tables, the two second C-shaped supports are vertically arranged at two ends of the bottom of the cross beam, the two second connecting plates are horizontal, two ends of the second connecting plates are respectively connected with two ends of the two second C-shaped supports, a U-shaped groove with a fixed interval is arranged on the inner side of one connecting plate close to the first motor, one ends of the plurality of second thermal cutting knives are arranged on the other connecting plate at intervals distributed in the U-shaped groove, and the other ends of the plurality of second thermal cutting knives are.

Preferably, unloading mechanism includes transport transmission band, collecting box and two spacing, and the transport transmission band sets up in actuating mechanism keeps away from the one end of feed mechanism through two fourth support columns, and two spacing are the interval and parallel arrangement each other in the both ends top of transport transmission band, and the collecting box is vertical the end that sets up in transport transmission band output direction.

Compared with the prior art, the invention has the beneficial effects that: through the coordinated operation of first cutting subassembly and second cutting subassembly, improved the cutting efficiency of sponge, reduced the input of amount of labour simultaneously, reduceed the economic input of enterprise, through the fixed of first laminating mechanism and second laminating mechanism to the sponge, deviation when improving the cutting has improved the stability when sponge cutting, and the establishment of feed mechanism and pushing equipment promotes the sponge and removes towards cutting out, has improved the convenient degree of production.

Drawings

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

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

FIG. 3 is a schematic view of a feeding mechanism of the present invention;

FIG. 4 is a schematic view of the pushing mechanism of the present invention;

FIG. 5 is a schematic view of the drive mechanism of the present invention;

FIG. 6 is a schematic view of a first attachment mechanism of the present invention;

FIG. 7 is a schematic view of a first thermal cutting mechanism of the present invention;

FIG. 8 is a schematic view of a second attachment mechanism of the present invention;

FIG. 9 is a schematic view of a second thermal cutting mechanism of the present invention;

fig. 10 is a schematic view of the blanking mechanism of the present invention.

The reference numbers in the figures are: a feeding frame 1, a first motor 2, a first belt 3, a first transmission rod 4, a first connecting rod 5, a first sleeve rod 6, a first limit plate 7, a second limit plate 8, a limit block 9, a rectangular opening 10, a cylinder 11, a first support 12, a push plate 13, a conveying frame 14, a second motor 15, a second transmission rod 16, a second connecting rod 17, a second sleeve rod 18, a second belt 19, an opening 20, a third motor 21, a sliding table 22, a bidirectional screw 23, two sliders 24, a first inductor 25, two joint plates 26, two second support columns 27, two groups of first screw sliding tables 28, a first beam 29, two first C-shaped supports 30, two first connecting plates 31, a plurality of first hot cutting knives 32, a plurality of first fixing blocks 33, a fourth motor 34, a third connecting rod 35, a second inductor 36, two shaft seats 37, two turnover rods 38 and a third support column 39, two sets of second lead screw slip tables 40, second crossbeam 41, two second C type supports 42, two second link up board 43, a plurality of second hot cutting sword 44, U type groove 45, carry transmission band 46, collecting box 47, two spacing 48, two fourth support columns 49.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

Referring to fig. 1 to 10, a high-efficiency thermal cutting device for sponge block batch forming comprises a feeding mechanism, a pushing mechanism, a driving mechanism, a first cutting assembly, a second cutting assembly and a blanking mechanism; the sponge to be cut is firstly placed on the feeding mechanism and transported to the position of the material pushing assembly, then the material pushing mechanism pushes the sponge to the driving mechanism, the driving mechanism transports the sponge to the first cutting assembly for primary cutting, the first cutting assembly is moved to the position of the second cutting assembly for secondary cutting after cutting is completed, and the sponge is moved to the blanking mechanism through the driving mechanism after cutting is completed for blanking.

The driving mechanism is vertically arranged and used for conveying the sponge to the first cutting assembly and the second cutting assembly for cutting; the driving mechanism transports the sponge to the first cutting assembly and the second cutting assembly for cutting.

The feeding mechanism is arranged on one side of the starting end of the output direction of the driving mechanism, and the output direction of the feeding mechanism is vertical to the output direction of the driving mechanism; the sponge is transported to the pushing mechanism by the feeding mechanism.

The pushing mechanism is arranged at one end of the feeding mechanism close to the driving mechanism and is positioned at one side of the feeding mechanism far away from the driving mechanism; the pushing mechanism pushes the sponge transported by the feeding mechanism to the driving mechanism.

The first cutting assembly is erected at two ends of the driving mechanism and is positioned at one end, away from the feeding mechanism, of the driving mechanism, the first cutting assembly comprises a first hot cutting mechanism used for carrying out primary cutting on the sponge and a first laminating mechanism used for providing stability for the sponge during cutting, the first laminating mechanism is erected at two ends, away from the feeding mechanism, of the driving mechanism, the first hot cutting mechanisms are erected at two ends of the first laminating mechanism, and the first hot cutting mechanisms are positioned right above the first laminating mechanism; the first laminating mechanism is attached to the sponge to prevent the sponge from shaking during cutting, and the first thermal cutting mechanism is used for transversely cutting the sponge.

The second cutting assembly is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, the second cutting assembly comprises a second hot cutting mechanism for performing secondary cutting on the sponge and a second laminating mechanism for providing stability for the sponge during cutting, the second laminating mechanism is erected at two ends of the driving mechanism and is positioned at one side, away from the feeding mechanism, of the first cutting assembly, and the second hot cutting mechanism is erected at two ends of the second laminating mechanism and is positioned right above the second laminating mechanism; the first laminating mechanism laminates the sponge and prevents the sponge from shaking during cutting, and the second thermal cutting mechanism vertically cuts the sponge.

The discharging mechanism is arranged at one end, far away from the feeding mechanism, of the driving mechanism, and the output direction of the discharging mechanism is consistent with that of the driving mechanism. The cut sponge is collected by the blanking mechanism.

The feeding mechanism comprises a feeding frame 1, a first motor 2, a first belt 3, a first transmission rod 4, a first connecting rod 5, a first sleeve rod 6, a first limiting plate 7 and a second limiting plate 8, the feeding frame 1 is vertically arranged at the initial end of the output direction of the driving mechanism, the length direction of the feeding mechanism is vertical to the output direction of the driving mechanism, the first transmission rod 4 and the first connecting rod 5 are horizontally arranged at two ends of the top of the feeding frame 1, the first sleeve rod 6 is sleeved on the first connecting rod 5, two ends of the first belt 3 are sleeved on the first transmission rod 4 and the first sleeve rod 6, a plurality of limiting blocks 9 for placing sponge are arranged on the surface of the first belt 3, the first limiting plate 7 and the second limiting plate 8 are vertically arranged at two ends of the top of the feeding frame 1, one end of the second limiting plate 8, which is positioned at the driving mechanism, is provided with a rectangular opening 10, the first motor 2 is fixedly arranged on the side wall of, the output end of the first motor 2 is connected with a first transmission rod 4. The output end of the first motor 2 drives the first transmission rod 4 connected with the first motor to rotate, the first belt 3 sleeved on the first transmission rod is driven to rotate on the first transmission rod 4 and the first connecting rod 5 through the rotation of the first transmission, the first belt 3 rotates to drive the limiting block 9 to rotate, the sponge placed on the limiting block 9 moves towards the pushing mechanism through the rotation of the limiting block 9, and the first limiting plate 7 and the second limiting plate 8 are used for controlling the advancing direction of the sponge.

The pushing mechanism comprises an air cylinder 11, a first supporting column 12 and a pushing plate 13, the first supporting column 12 is vertically arranged on the outer side of one end, close to the driving mechanism, of the feeding mechanism, the air rod is horizontally arranged at the top of one side, far away from the driving mechanism, of the first supporting column 12, the pushing plate 13 is sleeved on the output end of the air cylinder 11, and the pushing plate 13 is flush with a rectangular opening 10 of the second limiting plate 8. The output end of the air cylinder 11 extends outwards to push the push plate 13 connected with the air cylinder to move towards the feeding frame 1 until the rectangular opening 10 of the second limiting plate 8 pushes the sponge to move to the driving mechanism.

The driving mechanism comprises a conveying frame 14, a second motor 15, a second transmission rod 16, a second connecting rod 17, a second sleeve rod 18 and a second belt 19, the conveying frame 14 is vertically arranged at the tail end of the output direction of the feeding mechanism, the conveying frame 14 is positioned on one side, away from the pushing mechanism, of the feeding frame 1, openings 20 are formed in two ends, close to second thermal cutting, of the conveying frame 14, the second transmission rod 16 and the second connecting rod 17 are horizontally arranged at the tops of two ends of the conveying frame 14, the second sleeve rod 18 is sleeved on the second connecting rod 17, the second motor 15 is fixedly arranged on the outer side of the conveying frame 14, the output end of the second motor 15 is connected with the second transmission rod 16, two ends of the second belt 19 are respectively sleeved on the second transmission rod 16 and the second sleeve rod 18, and the second belt 19 is flush with a joint of a limiting block 9 on the surface of the first belt 3 and the sponge. The output end of the second motor 15 drives the second transmission rod 16 connected with the second motor to rotate, the rotation of the second transmission rod 16 drives the second belt 19 sleeved on the second transmission rod 16 to rotate on the second transmission rod 16 and the second sleeve rod 18, and the rotation of the second belt 19 moves the sponge towards the first cutting assembly.

First laminating mechanism includes third motor 21, slip table 22, two-way lead screw 23, two sliders 24, first inductor 25 and two rigging boards 26, slip table 22 is the level and the bottom both ends set up in the bottom of drive yoke through two second support columns 27, two-way lead screw 23 is the level and sets up in slip table 22, two 24 covers of slider locate two-way lead screw 23's both ends screw thread, third motor 21 is fixed to be set up in the outside of slip table 22, third motor 21's output links to each other with two-way lead screw 23 one end, two rigging boards 26 are vertical setting up on two sliders 24, first inductor 25 sets up in one side that feed mechanism was kept away from to slip table 22 through the backup pad, the height of first inductor 25 keeps unanimous with the top of drive yoke. When the first sensor 25 senses the sponge, the second motor 15 stops rotating, then the output end of the third motor 21 drives the two-way screw rod 23 connected with the third motor to rotate, the two-way screw rod 23 rotates to drive the two sliding blocks 24 sleeved on the two-way screw rod to move oppositely, and the two sliding blocks 24 move to drive the two attaching plates 26 to move towards the sponge direction until the sponge surface is attached.

The first thermal cutting mechanism comprises two groups of first screw rod sliding tables 28, a first cross beam 29, two first C-shaped brackets 30, two first connecting plates 31, a plurality of first thermal cutting knives 32 and a plurality of first fixing blocks 33, two sets of first lead screw slip tables 28 are the both ends of vertical erectting in slip table 22, first crossbeam 29 is the level and both ends link to each other with the output of two sets of first lead screw slip tables 28, two first C type supports 30 are vertical setting in the bottom both ends of first crossbeam 29, two first linking plate 31 are the level and both ends link to each other with the both ends of two first C type supports 30 respectively, a fixed interval of a plurality of first fixed block 33 sets up in the inboard of a linking plate of keeping away from feed mechanism, a plurality of first hot cutting knife 32 is the level and one end links to each other with a plurality of fixed block with the interval that the fixed block distributes in the outside other end that is close to a linking plate of feed mechanism. The output end of the two groups of first screw rod sliding tables 28 drives the first cross beam 29 to move towards the sponge direction, the first cross beam 29 drives the two first C-shaped supports 30 connected with the first cross beam and the two first connecting plates 31 connected with the two first C-shaped supports 30 to move downwards, the first hot cutters move downwards through the two first connecting plates 31 until the first hot cutters are in contact with the sponge quickly, and the first hot cutters start to generate heat and cut the sponge along with descending.

The second attaching mechanism comprises two groups of transmission mechanisms which are symmetrically distributed through the central line of the driving frame, each group of transmission mechanisms comprises a fourth motor 34, a third connecting rod 35, a second inductor 36, two shaft seats 37, two turning rods 38 and a third supporting column 39, the third supporting column 39 is arranged at the tail end of the output direction of the driving mechanism, the third supporting column 39 is positioned at one side of the first attaching mechanism away from the feeding mechanism, the two shaft seats 37 are arranged at intervals and in parallel at the top of the third supporting column 39, the third connecting rod 35 is horizontal, the two ends of the third connecting rod are connected with the two shaft seats 37, the two turning rods 38 are sleeved at the two ends of the third connecting rod 35, the distance between the two turning rods 38 is the same as the diameter of the sponge, the second inductor 36 is arranged at one end of the top of the third supporting column 39 away from the feeding mechanism, the fourth motor 34 is fixedly arranged at the outer side of one, the output of the fourth motor 34 is connected to one end of a third connecting rod 35. When the sponge is sensed by the second sensor 36, the second motor 15 stops rotating, and at the same time, the output end of the fourth motor 34 drives the third connecting rod 35 connected therewith to rotate, and the rotation of the third connecting rod 35 drives the two turning rods 38 sleeved thereon to rotate.

The second hot cutting mechanism comprises two sets of second lead screw sliding tables 40, a second cross beam 41, two second C-shaped supports 42, two second connecting plates 43 and a plurality of second hot cutting knives 44, the two sets of second lead screw sliding tables 40 are vertically arranged at two ends of two third supporting columns 39, the second cross beam 41 is horizontal, two ends of the second cross beam are connected with output ends of the two sets of second lead screw sliding tables 40, the two second C-shaped supports 42 are vertically arranged at two ends of the bottom of the cross beam, the two second connecting plates 43 are horizontal, two ends of the second connecting plates are respectively connected with two ends of the two second C-shaped supports 42, a U-shaped groove 45 with a fixed interval is arranged on the inner side of one connecting plate close to the first motor 2, one ends of the plurality of second hot cutting knives are arranged on another connecting plate at intervals distributed by the U-shaped grooves 45, and the other ends of the plurality of second hot cutting knives 44 are embedded in. The output ends of the two groups of second screw rod sliding tables 40 drive the second cross beams 41 to move towards the sponge direction, the second cross beams 41 drive the two second C-shaped supports 42 connected with the second cross beams and the two second connecting plates 43 connected with the two second C-shaped supports 42 to move downwards, the plurality of second hot cutters move downwards through the two first connecting plates 31 until the second hot cutters are in contact with the sponge quickly, and the plurality of second hot cutters start to generate heat and cut the sponge along with descending.

The blanking mechanism comprises a conveying belt 46, a collecting box 47 and two limiting frames 48, the conveying belt 46 is arranged at one end, away from the feeding mechanism, of the driving mechanism through two fourth supporting columns 49, the two limiting frames 48 are arranged at the tops of two ends of the conveying belt 46 at intervals in parallel, and the collecting box 47 is vertically arranged at the tail end of the output direction of the conveying belt 46. When the cut sponge is moved to the conveying belt 46 by the driving mechanism, the sponge is moved to the collecting box 47 by the conveying belt 46, and the sponge is prevented from falling off when the conveying belt 46 moves by the two limiting frames 48.

Firstly, placing sponge to be cut into a feeding mechanism, wherein the feeding mechanism drives a first transmission rod 4 connected with the feeding mechanism to rotate through an output end of a first motor 2, a first belt 3 sleeved on the feeding mechanism is driven to rotate on the first transmission rod 4 and a first connecting rod 5 through the first transmission rotation, the first belt 3 further drives a limiting block 9 to rotate, the sponge placed on the limiting block 9 moves towards a material pushing mechanism through the rotation of the limiting block 9, when the sponge is located at the material pushing mechanism, an output end of an air cylinder 11 on the material pushing mechanism extends outwards so as to push a push plate 13 connected with the air cylinder to move towards the material rack 1 until the rectangular opening 10 penetrating through a second limiting plate 8 pushes the sponge to move onto a driving mechanism.

And step two, the driving mechanism drives the second transmission rod 16 connected with the driving mechanism to rotate through the output end of the second motor 15, the second transmission rod 16 drives the second belt 19 sleeved on the second transmission rod 16 to rotate on the second transmission rod 16 and the second sleeve rod 18, and the sponge is moved towards the first cutting assembly through the rotation of the second belt 19.

Step three, when the first sensor 25 senses the sponge, the second motor 15 stops rotating, then the output end of the third motor 21 drives the two-way screw rod 23 connected with the third motor to rotate, the rotation of the two-way screw rod 23 further drives the two sliding blocks 24 sleeved on the two-way screw rod to move oppositely, the movement of the two sliding blocks 24 drives the two attaching plates 26 to move towards the sponge direction until the sponge surface is attached, then the first thermal cutting mechanism drives the first cross beam 29 to move towards the sponge direction through the output ends of the two groups of first screw rod sliding tables 28, the first cross beam 29 drives the two first C-shaped supports 30 connected with the first cross beam and the two first connecting plates 31 connected with the two first C-shaped supports 30 to move downwards, and the plurality of first thermal cutters move downwards through the two first connecting plates 31 until the sponge is quickly contacted, and the plurality of first thermal cutters start to generate heat and cut the sponge along with descending.

Step four, after the sponge is cut by the first cutting mechanism, the sponge moves towards the second cutting component through the driving mechanism, when the sponge is sensed by the second sensor 36, the second motor 15 stops rotating, and at the same time, the output end of the fourth motor 34 drives the third connecting rod 35 connected therewith to rotate, the rotation of the third connecting rod 35 drives the two turning rods 38 sleeved thereon to rotate to joint the sponge, then the output end of the two groups of second screw rod sliding tables 40 drives the second cross beam 41 to move towards the sponge direction, the second cross beam 41 drives the two second C-shaped supports 42 connected with the second cross beam and the two second connecting plates 43 connected with the two second C-shaped supports 42 to move downwards, the plurality of second hot cutters move downwards through the two first connecting plates 31 until the second hot cutters are in contact with the sponge quickly, and the plurality of second hot cutters start to generate heat and cut the sponge along with descending.

Step five, when the cut sponge is moved to the conveying conveyor belt 46 through the driving mechanism, the conveying conveyor belt 46 moves the sponge to the collecting box 47, and the two limiting frames 48 prevent the sponge from falling off when the conveying conveyor belt 46 moves.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.