CN112575569A

CN112575569A - Textile machine for cutting gauze

Info

Publication number: CN112575569A
Application number: CN202011371628.4A
Authority: CN
Inventors: 袁正中
Original assignee: Muye Wenzhou Shoes Co ltd
Current assignee: Huaibei minnong Biotechnology Co., Ltd
Priority date: 2020-11-30
Filing date: 2020-11-30
Publication date: 2021-03-30
Anticipated expiration: 2040-11-30
Also published as: CN112575569B

Abstract

The invention provides a textile machine for cutting gauze, relates to the technical field of textile machines, and solves the problem that other auxiliary functions cannot be realized by linkage when a cutter is driven to realize cloth cutting through structural improvement; the absorption of the flying flocks cannot be realized; the problem of the supplementary cooling of roller can not be realized in the linkage in the cutting. A textile machine for cutting gauze comprises a flow line frame body; and the assembly line frame body is provided with a cloth driving structure. The outer wall of the air suction head is provided with air suction holes in an annular array shape, the air suction holes are in a circular hole-shaped structure, and the air suction holes in the annular array shape jointly form an air suction head diffusion type air suction structure, so that the absorption effect of fluff is improved; because of the connection pipe tail end and roller B sealed rotation are connected, and roller B is hollow column structure to can enter into roller B through the connecting pipe tail end combustion gas and realize the cooling to roller B.

Description

Textile machine for cutting gauze

Technical Field

The invention belongs to the technical field of textile machinery, and particularly relates to a textile machinery for cutting gauze.

Background

The textile machines are also called textile machines, weaving machines, cotton spinning machines and the like, and the ancient textile machines are weaving machines driven by manpower. The textile machine is a full name of a tool for processing raw materials such as threads, silks, hemp and the like into silk threads and then weaving the silk threads into cloth; such as spinning pendants, spinning wheels, spindles, pedal looms, modern mechanical looms, modern numerical control automatic looms and the like.

As in application No.: CN201810079634.9, the invention discloses a textile machine for cutting gauze, which comprises a base, wherein the top of the base is respectively connected with a first baffle and a second baffle, one side of the first baffle, which is close to the center of the base, is connected with a conical surface top shaft, the conical surface top shaft is connected with a pressing conical surface top shaft between the first baffle and the second baffle through a rolling shaft, one side of the pressing conical surface top shaft is connected with a shaft sleeve connected with the second baffle, one end, which is close to the pressing conical surface top shaft, of the shaft sleeve is connected with a pressing spring arranged outside the shaft sleeve, a knife rest connected with the first baffle and the second baffle is arranged below the pressing spring, the top of the knife rest is provided with a knife matched with the knife rest, a winding wheel arranged between the knife and the base is provided with a winding wheel arranged between the first baffle and the second baffle, one end of the winding. Has the advantages that: the invention has convenient operation, is beneficial to disassembly, can cut gauzes with different lengths and sizes, and has high working efficiency of textile equipment.

Textile cutting machines similar to the above-mentioned applications currently suffer from the following drawbacks:

one is that the existing device usually realizes independent cutting through an electric element when cutting the cloth, but cannot realize other auxiliary functions through linkage when driving a cutter to realize cloth cutting through structural improvement; moreover, the prior device is easy to scatter into the air when the cloth is conveyed and cut, and the scattered lint cannot be absorbed; finally, the roller of the existing device is easy to scald when the cloth is conveyed, and the auxiliary cooling of the roller can not be realized in a linkage manner when the cloth is cut.

Therefore, in view of the above, research and improvement are made for the existing structure and defects, and a textile machine for cutting gauze is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a textile machine for cutting gauze, which aims to solve the problem that the existing device realizes independent cutting through an electric element when cutting cloth, but cannot realize other auxiliary functions through linkage when driving a cutter to realize cloth cutting through structural improvement; moreover, the prior device is easy to scatter into the air when the cloth is conveyed and cut, and the scattered lint cannot be absorbed; finally, the roller of the existing device is easy to scald when the cloth is conveyed, and the problem of auxiliary cooling of the roller cannot be realized in a linkage manner when the cloth is cut.

The invention relates to a textile machine for cutting gauze, which is realized by the following specific technical means:

a textile machine for cutting gauze comprises a flow line frame body; the assembly line frame body is provided with a cloth driving structure, and a cutting structure is welded on the assembly line frame body; the cutting structure is provided with a shifting structure, and the cutting structure is also provided with an auxiliary structure; the cutting structure comprises a cylindrical rod, a cutting seat and an auxiliary block, the cylindrical rod is welded on the assembly line frame body, the cutting seat is welded on the cylindrical rod, and cloth passes through the cutting seat; the left end face and the right end face of the cutting seat are respectively welded with an auxiliary block, the two auxiliary blocks are of triangular cylindrical rod-shaped structures, and the two auxiliary blocks are arranged in a mirror image shape; the auxiliary structure comprises a connecting pipe, the head end of the connecting pipe is connected with the water storage box, and the height of the head end of the connecting pipe is higher than the liquid level; the tail end of the connecting pipe is connected with the roller B in a sealing and rotating mode, and the roller B is of a hollow structure.

Further, the cloth driving structure comprises a roller A, a driving motor A and a roller B, wherein the roller A is rotatably connected to the assembly line frame body, the assembly line frame body is fixedly connected with the driving motor A through bolts, and a rotating shaft of the driving motor A is connected with the roller A; roller B rotates to be connected on the assembly line support body, and roller B and roller A all contact with the cloth to roller A, driving motor A and roller B have constituteed cloth transport structure jointly.

Furthermore, the cutting structure also comprises four sliding rods, stop blocks, a mounting seat A, a cutter and elastic pieces, wherein the four sliding rods are welded on the top end face of the cutting seat, and the stop blocks are welded on the four sliding rods; the mounting seat A is connected to the four sliding rods in a sliding manner, and a cutter is mounted on the mounting seat A; an elastic piece is sleeved on each sliding rod, and the four elastic pieces jointly form an elastic reset structure of the mounting seat A and the cutter.

Furthermore, the cutting structure also comprises a mounting seat B, the mounting seat B is welded on the four sliding rods, and the mounting seat B is of a concave structure; the poking structure comprises a rotating shaft, a poking block and a driving motor B, wherein the rotating shaft is rotatably connected to the mounting base B, the mounting base B is fixedly connected with the driving motor B through a bolt, and the rotating shaft of the driving motor B is connected with the rotating shaft; the rotating shaft is provided with a poking block, and the poking block is in elastic contact with the mounting seat A.

Furthermore, the auxiliary structure comprises an elastic telescopic gas cylinder, a water storage box, an exhaust pipe and an air suction pipe, wherein the elastic telescopic gas cylinder is fixedly connected to the bottom end face of the mounting seat B through a bolt; the water storage box is welded on the top end surface of the mounting seat B; the elastic telescopic gas cylinder is connected with an exhaust pipe and an air suction pipe, the exhaust pipe is connected with the water storage box, and the exhaust pipe and the air suction pipe are internally provided with one-way valves.

Furthermore, the head end of the elastic telescopic gas cylinder is welded with a stress plate, the stress plate is of a rectangular plate-shaped structure, and the stress plate is in elastic contact with the poking block.

Furthermore, the auxiliary structure also comprises an air suction head and an air suction hole, the air suction head is connected to the air suction pipe, and the air suction head is of a cylindrical tubular structure; the outer wall of the air suction head is provided with air suction holes in an annular array shape, the air suction holes are in a circular hole structure, and the air suction holes in the annular array shape jointly form an air suction head diffusion type air suction structure.

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

through the cooperation setting of tailorring structure, stirring structure and auxiliary structure, can realize the continuous cutting of cloth, and can also link the absorption that realizes the air in the batting dust to can also realize roller B's cooling, specifically as follows: firstly, the installation seat A is connected to the four sliding rods in a sliding manner, and a cutter is installed on the installation seat A; each sliding rod is sleeved with an elastic piece, and the four elastic pieces jointly form an elastic reset structure of the mounting seat A and the cutter; secondly, the rotating shaft is rotatably connected to the mounting seat B, the mounting seat B is fixedly connected with a driving motor B through a bolt, and the rotating shaft of the driving motor B is connected with the rotating shaft; the rotating shaft is provided with the poking block, and the poking block is in elastic contact with the mounting seat A, so that when the poking block rotates along with the rotating shaft, the mounting seat A can be continuously poked, and further, the cloth can be continuously cut; thirdly, an exhaust pipe and an air suction pipe are connected to the elastic telescopic gas cylinder, the exhaust pipe is connected with the water storage box, and one-way valves are arranged in the exhaust pipe and the air suction pipe; fourthly, a stress plate is welded at the head end of the elastic telescopic gas cylinder and is in a rectangular plate structure, and the stress plate is in elastic contact with the shifting block, so that the continuous extrusion of the elastic telescopic gas cylinder can be realized when the shifting block rotates along with the rotating shaft, and further, the continuous gas suction can be realized; fifthly, because the outer wall of the air suction head is provided with air suction holes in an annular array shape, the air suction holes are in a circular hole-shaped structure, and the air suction holes in the annular array shape jointly form a diffusion type air suction structure of the air suction head, the absorption effect of the fluff is improved; sixthly, the tail end of the connecting pipe is connected with the roller B in a sealing and rotating mode, and the roller B is of a hollow structure, so that discharged gas at the tail end of the connecting pipe can enter the roller B to cool the roller B.

Drawings

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

Fig. 2 is a schematic axial view of the present invention in another direction of fig. 1.

Fig. 3 is an enlarged schematic view of fig. 2 at a.

Fig. 4 is an enlarged schematic view of fig. 2B according to the present invention.

FIG. 5 is a schematic view of the present invention with the frame removed.

Fig. 6 is a schematic view of a main view enlarging structure of the auxiliary structure of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a production line frame body; 2. a cloth driving structure; 201. a roller A; 202. driving a motor A; 203. a roller B; 3. cutting the structure; 301. a cylindrical rod; 302. a cutting seat; 303. an auxiliary block; 304. a slide bar; 305. a stopper; 306. a mounting seat A; 307. a cutter; 308. an elastic member; 309. a mounting seat B; 4. a toggle structure; 401. a rotating shaft; 402. a shifting block; 403. driving a motor B; 5. an auxiliary structure; 501. an elastic telescopic gas cylinder; 502. a water storage box; 503. an exhaust pipe; 504. an air intake duct; 505. an air suction head; 506. a suction hole; 507. and (4) connecting the pipes.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 6:

the invention provides a textile machine for cutting gauze, which comprises a flow line frame body 1; the assembly line frame body 1 is provided with a cloth driving structure 2, and the assembly line frame body 1 is welded with a cutting structure 3; the cutting structure 3 is provided with a shifting structure 4, and the cutting structure 3 is also provided with an auxiliary structure 5; referring to fig. 2 and 3, the cutting structure 3 comprises a cylindrical rod 301, a cutting seat 302 and an auxiliary block 303, the cylindrical rod 301 is welded on the assembly line frame body 1, the cutting seat 302 is welded on the cylindrical rod 301, and the cloth passes through the cutting seat 302; the left end face and the right end face of the cutting seat 302 are both welded with one auxiliary block 303, the two auxiliary blocks 303 are both in triangular cylindrical rod-shaped structures, and the two auxiliary blocks 303 are arranged in a mirror image shape, so that the smoothness of cloth when the cloth is in contact with the cutting seat 302 can be improved; referring to fig. 2 and 5, the auxiliary structure 5 includes a connection pipe 507, a head end of the connection pipe 507 is connected with the water storage box 502, and a height of the head end of the connection pipe 507 is higher than a liquid level; the tail end of the connecting pipe 507 is in sealed rotary connection with the roller B203, and the roller B203 is in a hollow structure, so that gas discharged from the tail end of the connecting pipe 507 can enter the roller B203 to cool the roller B203.

Referring to fig. 2, the cloth driving structure 2 includes a roller a201, a driving motor a202 and a roller B203, the roller a201 is rotatably connected to the assembly line frame body 1, the assembly line frame body 1 is fixedly connected with the driving motor a202 through a bolt, and a rotating shaft of the driving motor a202 is connected with the roller a 201; roller B203 rotates to be connected on assembly line support body 1, and roller B203 and roller A201 all contact with the cloth to roller A201, driving motor A202 and roller B203 have constituteed cloth transport structure jointly.

Referring to fig. 2 and 4, the cutting structure 3 further includes four sliding rods 304, a stopper 305, a mounting seat a306, a cutter 307 and an elastic member 308, the number of the sliding rods 304 is four, and the four sliding rods 304 are welded on the top end surface of the cutting seat 302, and one stopper 305 is welded on each of the four sliding rods 304; the mounting seat A306 is connected to the four sliding rods 304 in a sliding manner, and a cutter 307 is arranged on the mounting seat A306; each sliding rod 304 is sleeved with an elastic member 308, and the four elastic members 308 form an elastic reset structure of the mounting seat a306 and the cutter 307.

Referring to fig. 5, the cutting structure 3 further includes a mounting seat B309, the mounting seat B309 is welded on the four sliding rods 304, and the mounting seat B309 is a concave structure; the toggle structure 4 comprises a rotating shaft 401, a toggle block 402 and a driving motor B403, the rotating shaft 401 is rotatably connected to an installation base B309, the installation base B309 is fixedly connected with the driving motor B403 through a bolt, and a rotating shaft of the driving motor B403 is connected with the rotating shaft 401; the rotating shaft 401 is provided with the toggle block 402, and the toggle block 402 is in elastic contact with the mounting seat A306, so that continuous toggling of the mounting seat A306 can be realized when the toggle block 402 rotates along with the rotating shaft 401, and further continuous cutting of cloth is realized.

Referring to fig. 5 and 6, the auxiliary structure 5 comprises an elastic telescopic gas cylinder 501, a water storage box 502, an exhaust pipe 503 and an air suction pipe 504, wherein the elastic telescopic gas cylinder 501 is fixedly connected to the bottom end face of the mounting seat B309 through bolts; the water storage box 502 is welded on the top end face of the mounting seat B309; an exhaust pipe 503 and an air suction pipe 504 are connected to the elastic telescopic air cylinder 501, the exhaust pipe 503 is connected with the water storage box 502, and one-way valves are installed in the exhaust pipe 503 and the air suction pipe 504.

Referring to fig. 6, a stress plate is welded at the head end of the elastic telescopic gas cylinder 501, and the stress plate is in a rectangular plate-shaped structure and is in elastic contact with the toggle block 402, so that when the toggle block 402 rotates along with the rotating shaft 401, continuous extrusion of the elastic telescopic gas cylinder 501 can be realized, and continuous suction can be realized.

Referring to fig. 2 and 4, the auxiliary structure 5 further includes a suction head 505 and a suction hole 506, the suction head 505 is connected to the suction pipe 504, and the suction head 505 is a cylindrical tubular structure; the outer wall of the air suction head 505 is provided with air suction holes 506 in an annular array shape, the air suction holes 506 are in a circular hole-shaped structure, and the air suction holes 506 in the annular array shape jointly form a diffusion type air suction structure of the air suction head 505, so that the absorption effect of the fluff is improved.

The specific use mode and function of the embodiment are as follows:

during cutting, firstly, the installation seat A306 is connected to the four sliding rods 304 in a sliding manner, and the installation seat A306 is provided with a cutter 307; each sliding rod 304 is sleeved with an elastic piece 308, and the four elastic pieces 308 jointly form an elastic reset structure of the mounting seat A306 and the cutter 307; secondly, the rotating shaft 401 is rotatably connected to the mounting seat B309, the mounting seat B309 is fixedly connected with a driving motor B403 through a bolt, and the rotating shaft of the driving motor B403 is connected with the rotating shaft 401; the rotating shaft 401 is provided with the toggle block 402, and the toggle block 402 is in elastic contact with the mounting seat A306, so that when the toggle block 402 rotates along with the rotating shaft 401, the mounting seat A306 can be continuously toggled, and further, the cloth can be continuously cut;

when the air purifying device purifies the wool and dust in the air and cools the roller B203, firstly, an exhaust pipe 503 and an air suction pipe 504 are connected to the elastic telescopic air cylinder 501, the exhaust pipe 503 is connected with the water storage box 502, and one-way valves are arranged in the exhaust pipe 503 and the air suction pipe 504; secondly, a stress plate is welded at the head end of the elastic telescopic gas cylinder 501, the stress plate is of a rectangular plate-shaped structure and is in elastic contact with the toggle block 402, so that when the toggle block 402 rotates along with the rotating shaft 401, continuous extrusion of the elastic telescopic gas cylinder 501 can be realized, and further continuous gas suction can be realized; thirdly, the outer wall of the air suction head 505 is provided with air suction holes 506 in an annular array shape, the air suction holes 506 are in a circular hole-shaped structure, and the air suction holes 506 in the annular array shape jointly form a diffusion type air suction structure of the air suction head 505, so that the absorption effect of the fluff is improved; fourthly, the tail end of the connecting pipe 507 is in sealed rotary connection with the roller B203, and the roller B203 is in a hollow structure, so that gas exhausted from the tail end of the connecting pipe 507 can enter the roller B203 to cool the roller B203.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. A textile machine for cutting gauze, characterized in that: comprises a production line frame body (1); the cloth driving structure (2) is installed on the assembly line frame body (1), and the cutting structure (3) is welded on the assembly line frame body (1); the cutting structure (3) is provided with a shifting structure (4), and the cutting structure (3) is also provided with an auxiliary structure (5); the cutting structure (3) comprises a cylindrical rod (301), a cutting seat (302) and an auxiliary block (303), the cylindrical rod (301) is welded on the assembly line frame body (1), the cutting seat (302) is welded on the cylindrical rod (301), and cloth passes through the cutting seat (302); the left end face and the right end face of the cutting seat (302) are both welded with an auxiliary block (303), the two auxiliary blocks (303) are of triangular column rod-shaped structures, and the two auxiliary blocks (303) are arranged in a mirror image shape; the auxiliary structure (5) comprises a connecting pipe (507), the head end of the connecting pipe (507) is connected with the water storage box (502), and the height of the head end of the connecting pipe (507) is higher than the liquid level; the tail end of the connecting pipe (507) is in sealed rotary connection with the roller B (203), and the roller B (203) is of a hollow structure.

2. A textile machine for cutting gauze as claimed in claim 1, characterized in that: the cloth driving structure (2) comprises a roller A (201), a driving motor A (202) and a roller B (203), the roller A (201) is rotatably connected to the assembly line frame body (1), the assembly line frame body (1) is fixedly connected with the driving motor A (202) through bolts, and a rotating shaft of the driving motor A (202) is connected with the roller A (201); roller B (203) rotate to be connected on assembly line support body (1), and roller B (203) and roller A (201) all contact with the cloth to roller A (201), driving motor A (202) and roller B (203) have constituteed cloth transport structure jointly.

3. A textile machine for cutting gauze as claimed in claim 1, characterized in that: the cutting structure (3) further comprises four sliding rods (304), a stop block (305), a mounting seat A (306), a cutter (307) and an elastic piece (308), wherein the number of the sliding rods (304) is four, the four sliding rods (304) are all welded on the top end face of the cutting seat (302), and the stop block (305) is welded on each of the four sliding rods (304); the mounting seat A (306) is connected to the four sliding rods (304) in a sliding manner, and a cutter (307) is arranged on the mounting seat A (306); each sliding rod (304) is sleeved with an elastic piece (308), and the four elastic pieces (308) jointly form an elastic reset structure of the mounting seat A (306) and the cutter (307).

4. A textile machine for cutting gauze as claimed in claim 1, characterized in that: the cutting structure (3) further comprises a mounting seat B (309), the mounting seat B (309) is welded on the four sliding rods (304), and the mounting seat B (309) is of a concave structure; the toggle structure (4) comprises a rotating shaft (401), a toggle block (402) and a driving motor B (403), the rotating shaft (401) is rotatably connected to an installation base B (309), the installation base B (309) is fixedly connected with the driving motor B (403) through a bolt, and a rotating shaft of the driving motor B (403) is connected with the rotating shaft (401); the rotating shaft (401) is provided with a toggle block (402), and the toggle block (402) is in elastic contact with the mounting seat A (306).

5. A textile machine for cutting gauze as claimed in claim 1, characterized in that: the auxiliary structure (5) comprises an elastic telescopic gas cylinder (501), a water storage box (502), an exhaust pipe (503) and an air suction pipe (504), and the elastic telescopic gas cylinder (501) is fixedly connected to the bottom end face of the mounting seat B (309) through a bolt; the water storage box (502) is welded on the top end surface of the mounting seat B (309); the elastic telescopic gas cylinder (501) is connected with an exhaust pipe (503) and an air suction pipe (504), the exhaust pipe (503) is connected with the water storage box (502), and one-way valves are arranged in the exhaust pipe (503) and the air suction pipe (504).

6. A textile machine for cutting gauze as claimed in claim 5, characterized in that: the head end of the elastic telescopic gas cylinder (501) is welded with a stress plate, the stress plate is of a rectangular plate-shaped structure, and the stress plate is in elastic contact with the poking block (402).

7. A textile machine for cutting gauze as claimed in claim 1, characterized in that: the auxiliary structure (5) further comprises a suction head (505) and a suction hole (506), the suction head (505) is connected to the suction pipe (504), and the suction head (505) is of a cylindrical tubular structure; the outer wall of the air suction head (505) is provided with air suction holes (506) in an annular array shape, the air suction holes (506) are in a circular hole-shaped structure, and the air suction holes (506) in the annular array shape jointly form a diffusion type air suction structure of the air suction head (505).