CN111991928A

CN111991928A - Dust removal purification device based on textile printing and dyeing

Info

Publication number: CN111991928A
Application number: CN202010803270.1A
Authority: CN
Inventors: 崔鹏
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-11
Filing date: 2020-08-11
Publication date: 2020-11-27

Abstract

The invention provides a dust removal purification device for textile printing and dyeing, relates to the technical field of textile printing and dyeing, and solves the problem that the work of a dust removal structure cannot be realized through linkage when a roller rotates for printing through structural improvement; the dust on the dust suction head and the automatic cleaning of the fiber can not be realized through the improvement of the structure. A dust removal purification device based on textile printing and dyeing comprises a roller frame; the roller frame is rotatably connected with a cloth guide roller, and the roller frame is also rotatably connected with a printing roller. Because the connecting pipe is internally provided with the one-way valve A; the exhaust pipe comprises a one-way valve B, and the one-way valve B is arranged in the exhaust pipe; when the telescopic bottle is extruded, the one-way valve A is in a closed state, and the one-way valve B is in an open state, and when the telescopic bottle is elastically reset, the one-way valve A is in an open state, and the one-way valve B is in a closed state.

Description

Dust removal purification device based on textile printing and dyeing

Technical Field

The invention belongs to the technical field of textile printing and dyeing, and particularly relates to a dust removal purification device for textile printing and dyeing.

Background

Printing and dyeing, also known as dyeing and finishing, is a processing mode and is a general name of pretreatment, dyeing, printing, after finishing, washing water and the like, a large amount of dust is generated in the printing and dyeing process, the health of operators is seriously affected by a large amount of dust in the air, and the printing and dyeing quality is also reduced.

As in application No.: CN202010196886.7, the invention discloses a dust removal device for textile printing and dyeing, which comprises a dust remover body, wherein a horn-shaped air inlet end is fixed at an air inlet of the dust remover body, a horn-shaped air outlet end is fixed at an air outlet of the dust remover body, a spray pipe is fixed outside the dust remover body through a support, a square filter shell is fixed between the dust remover body and the horn-shaped air outlet end, a filter screen plate is fixed in the square filter shell, a vertical support plate is fixed at the top of the dust remover body, a vertical sliding groove is formed in the vertical support plate, a driving motor is fixed at the top of the vertical support plate, a rib rod is fixed on a sliding block, a transverse brush plate is fixed at the bottom end of the rib rod, a brush body is fixed on the side surface of the transverse brush plate, and a drying structure is fixed at an air outlet of the horn-shaped air outlet end. The dust removal device is reasonable in structural arrangement, dust removal can be effectively and quickly achieved, foreign dust or dust can be prevented from entering the drying structure, blocking is prevented, the dust removal efficiency can be improved, and the dust removal device is high in applicability and good in practicability.

The dust removal and purification device for textile printing and dyeing similar to the above application has the following defects:

one is that the existing devices usually drive a dust collection structure arranged on a printing and dyeing device through an electrical element to realize dust collection action, but cannot realize the work of the dust collection structure through linkage when a roller rotates for printing through structural improvement; moreover, the dust suction head of the existing device is easily polluted by dust and fibers after being used for a period of time, and the automatic cleaning of the dust and the fibers on the dust suction head cannot be realized through the improvement of the structure.

In view of the above, the present invention provides a dust removal and purification device for textile printing and dyeing, which is improved in view of the conventional structure and defects, and is expected to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a dust removal and purification device for textile printing and dyeing, which aims to solve the problems that the existing device usually realizes dust removal action by driving a dust removal structure arranged on a printing and dyeing device through an electrical element, but cannot realize the work of the dust removal structure in a linkage manner while a roller rotates for printing through structural improvement; moreover, the dust suction head of the existing device is easily polluted by dust and fibers after being used for a period of time, and the automatic cleaning of the dust and the fibers on the dust suction head cannot be realized through the improvement of the structure.

The invention relates to a dust removal purification device for textile printing and dyeing, which is achieved by the following specific technical means:

a dust removal purification device based on textile printing and dyeing comprises a roller frame; the roller frame is rotatably connected with a cloth guide roller, and the roller frame is also rotatably connected with a printing roller; the roller frame is provided with a gas purification structure, and the roller frame is also provided with a cleaning structure; the cloth guide roller comprises two cams, and the two cams are arranged on a rotating shaft of the cloth guide roller; when the cloth guide roller rotates, the two cams are both contacted with the telescopic bottle, and the telescopic bottle is in an extrusion state; two the cam is crisscross form installation, and right side cam does not contact with flexible bottle when left side cam and flexible bottle contact to right side cam and flexible bottle contact when left side cam and flexible bottle contactless.

Further, the roller frame comprises mounting seats, and two mounting seats are welded on the roller frame; the gas purification structure comprises two telescopic bottles, a filter box and a connecting pipe, wherein the two telescopic bottles are fixedly connected to the mounting seat; the filter boxes are two in number, and the two filter boxes are fixedly connected to the mounting seat; each telescopic bottle is connected with a connecting pipe.

Furthermore, the gas purification structure also comprises two exhaust pipes, wherein the two exhaust pipes are respectively connected to the two telescopic bottles and are provided with exhaust holes; the main body parts of the two exhaust pipes are located in the filter box, and the two exhaust pipes are of wavy structures.

Furthermore, the gas purification structure also comprises two gas suction pipes and two gas suction holes, and the two gas suction pipes are respectively connected to the two connecting pipes; two breathing pipes are cylindrical tubular structure, and two breathing pipe outer walls all are the annular array form and have seted up the suction opening to the suction opening that the annular array form was seted up has constituteed the expansion suction structure of breathing pipe.

Furthermore, the gas purification structure also comprises two filter screens, and the two filter screens are respectively arranged in the two filter boxes; the filter screen is not arranged in the filter liquid in the filter box, and the filter screen is arranged above the main body part of the exhaust pipe, and the two filter screens form a gas partition structure.

Further, the connecting pipe comprises a one-way valve A, and the one-way valve A is installed in the connecting pipe; the exhaust pipe comprises a one-way valve B, and the one-way valve B is arranged in the exhaust pipe; when the telescopic bottle is extruded, the one-way valve A is in a closed state, and the one-way valve B is in an open state, and when the telescopic bottle is elastically reset, the one-way valve A is in an open state, and the one-way valve B is in a closed state.

Furthermore, the cleaning structure comprises a fixed seat, sliding rods, a wiping block and an elastic piece, wherein the fixed seat is fixedly connected to the roller frame through bolts, the fixed seat is connected with the two sliding rods in a sliding manner, and the head ends of the two sliding rods are fixedly connected with the wiping block; an elastic piece is sleeved on each of the two sliding rods, and the wiping block is pushed by the elasticity of the elastic pieces to be in contact with the outer wall of the air suction pipe.

Further, the printing roller comprises a gear A, and the gear A is mounted on the printing roller; the gas purification structure comprises a gear B, the gear B is installed on the gas suction pipe and meshed with the gear A, and the gas suction pipe is in a synchronous rotating state when the printing roller rotates.

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

improved gaseous purification structure, the gaseous purification structure of this device need not electrical components for unpowered coordinated type filtration can realize that the dust absorption filters the use cost that has reduced for electrical components, and can also realize dust and spacing cleaning of cleaning on the breathing pipe in the synchronous linkage, specifically as follows: firstly, two cams are arranged, and the two cams are arranged on a rotating shaft of the cloth guide roller; when the cloth guide roller rotates, the two cams are both contacted with the telescopic bottle, and the telescopic bottle is in an extrusion state; secondly, a one-way valve A is arranged in the connecting pipe; the exhaust pipe comprises a one-way valve B, and the one-way valve B is arranged in the exhaust pipe; when the telescopic bottle is extruded, the one-way valve A is in a closed state, and the one-way valve B is in an open state; thirdly, because the cams are installed in a staggered manner, the right cams are not in contact with the telescopic bottles when the left cams are in contact with the telescopic bottles, and the right cams are in contact with the telescopic bottles when the left cams are not in contact with the telescopic bottles, the filtering efficiency is improved; fourthly, the fixed seat is fixedly connected to the roller frame through bolts, the fixed seat is connected with two sliding rods in a sliding manner, and the head ends of the two sliding rods are fixedly connected with the wiping block; the two sliding rods are sleeved with an elastic piece, and the wiping block is pushed by the elasticity of the elastic piece to be contacted with the outer wall of the air suction pipe; fifthly, because the gear B is arranged on the air suction pipe, the gear B is meshed with the gear A, and the air suction pipe is in a synchronous rotating state when the printing roller rotates, the fiber dust on the outer wall of the air suction pipe can be automatically removed under the action of the wiping block.

The connecting pipeline of the gas purification structure is improved, firstly, two exhaust pipes are arranged, the two exhaust pipes are respectively connected to the two telescopic bottles, and exhaust holes are formed in the two exhaust pipes; the main body parts of the two exhaust pipes are positioned in the filter box, and the two exhaust pipes are both of a wavy structure, so that the diffusion range during exhaust can be enlarged, and the filtering effect is improved; secondly, two air suction pipes are arranged, and the two air suction pipes are respectively connected to the two connecting pipes; the two air suction pipes are of cylindrical tubular structures, the outer walls of the two air suction pipes are provided with air suction holes in an annular array shape, and the air suction holes in the annular array shape form an expansion air suction structure of the air suction pipes, so that the air suction efficiency and the range of the air suction pipes are improved; thirdly, two filter screens are arranged, and the two filter screens are respectively arranged in the two filter boxes; the filter screen is not inside the filtering liquid in the filter cartridge, and the filter screen is located the top position of blast pipe main part to two filter screens have constituteed gaseous structure of cutting apart, thereby have further improved blast pipe exhaust gas's purification efficiency.

Drawings

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

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

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

Fig. 4 is a schematic top view of the present invention.

Fig. 5 is an enlarged view of the structure of fig. 4B according to the present invention.

Fig. 6 is an enlarged schematic view of the gas purification structure of the present invention.

FIG. 7 is a schematic view of the gas purification structure according to the present invention.

Fig. 8 is an enlarged view of the structure of fig. 7 at C according to the present invention.

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

1. a roll stand; 101. a mounting seat; 2. a cloth guide roller; 201. a cam; 3. a printing roller; 301. a gear A; 4. a gas purification structure; 401. a telescopic bottle; 402. a filter cartridge; 403. a connecting pipe; 40301. a one-way valve A; 404. an air intake duct; 405. a suction hole; 406. an exhaust pipe; 40601. a one-way valve B; 407. a filter screen; 408. a gear B; 5. cleaning the structure; 501. a fixed seat; 502. a slide bar; 503. a wiping block; 504. an elastic member.

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 8:

the invention provides a dust removal purification device based on textile printing and dyeing, which comprises a roller frame 1; the roller frame 1 is rotatably connected with a cloth guide roller 2, and the roller frame 1 is also rotatably connected with a printing roller 3; the roller frame 1 is provided with a gas purification structure 4, and the roller frame 1 is also provided with a cleaning structure 5; referring to fig. 2, the cloth guide roller 2 includes two cams 201, and the two cams 201 are installed on the rotating shaft of the cloth guide roller 2; when the cloth guide roller 2 rotates, the two cams 201 are both contacted with the telescopic bottle 401, and the telescopic bottle 401 is in an extrusion state; referring to fig. 2 and 4, the two cams 201 are installed in a staggered manner, and the right cam 201 does not contact the telescopic bottle 401 when the left cam 201 contacts the telescopic bottle 401, and the right cam 201 contacts the telescopic bottle 401 when the left cam 201 does not contact the telescopic bottle 401, thereby improving the filtering efficiency.

Referring to fig. 2, the roller frame 1 includes two mounting seats 101, and the two mounting seats 101 are welded on the roller frame 1; the gas purification structure 4 comprises two telescopic bottles 401, two filter boxes 402 and a connecting pipe 403, wherein the two telescopic bottles 401 are fixedly connected to the mounting seat 101; the number of the filter boxes 402 is two, and the two filter boxes 402 are both fixedly connected to the mounting base 101; a connecting tube 403 is connected to each telescopic bottle 401.

Referring to fig. 4 and 5, the gas purification structure 4 further includes two exhaust pipes 406, the two exhaust pipes 406 are respectively connected to the two telescopic bottles 401, and the two exhaust pipes 406 are both provided with an exhaust hole; the main body parts of the two exhaust pipes 406 are both located in the filter box 402, and the two exhaust pipes 406 are both in a wavy structure, so that the diffusion range during exhaust can be increased, and the filtering effect is improved.

Referring to fig. 2, the gas purifying structure 4 further includes two gas suction pipes 404 and two gas suction holes 405, the two gas suction pipes 404 are provided, and the two gas suction pipes 404 are respectively connected to the two connecting pipes 403; the two air suction pipes 404 are of cylindrical tubular structures, the outer walls of the two air suction pipes 404 are provided with air suction holes 405 in an annular array shape, and the air suction holes 405 in the annular array shape form an expansion air suction structure of the air suction pipes 404, so that the air suction efficiency and range of the air suction pipes 404 are improved.

Referring to fig. 6, the gas purification structure 4 further includes two filter screens 407, the two filter screens 407 are provided in total, and the two filter screens 407 are respectively installed in the two filter cartridges 402; the filter net 407 is not located inside the filter liquid in the filter box 402, and the filter net 407 is located above the main body of the exhaust pipe 406, and the two filter nets 407 form a gas dividing structure, thereby further improving the purification efficiency of the exhaust gas from the exhaust pipe 406.

Referring to fig. 7 and 8, the connection pipe 403 includes a check shutter a40301, and one check shutter a40301 is installed in the connection pipe 403; the exhaust pipe 406 comprises a check valve B40601, and the check valve B40601 is installed in the exhaust pipe 406; check valve a40301 assumes a closed state when telescopic bottle 401 is squeezed and check valve B40601 assumes an open state, and check valve a40301 assumes an open state when telescopic bottle 401 is elastically restored and check valve B40601 assumes a closed state.

Referring to fig. 2, the cleaning structure 5 includes a fixed seat 501, a sliding rod 502, a wiping block 503 and an elastic member 504, the fixed seat 501 is fixedly connected to the roller frame 1 by bolts, two sliding rods 502 are slidably connected to the fixed seat 501, and the head ends of the two sliding rods 502 are fixedly connected to the wiping block 503; an elastic member 504 is sleeved on each of the two sliding rods 502, and the wiping block 503 is pushed by the elastic force of the elastic member 504 to contact with the outer wall of the air suction pipe 404.

Referring to fig. 2, the printing roller 3 includes a gear a301, and the printing roller 3 is mounted with the gear a 301; the gas purification structure 4 comprises a gear B408, the gear B408 is installed on the gas suction pipe 404, the gear B408 is meshed with the gear A301, and the gas suction pipe 404 is in a synchronous rotation state when the printing roller 3 rotates, so that the fiber dust on the outer wall of the gas suction pipe 404 can be automatically removed under the action of the wiping block 503.

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

when the cloth guide roller 2 and the printing roller 3 rotate in use, firstly, two cams 201 are arranged, and the two cams 201 are both arranged on a rotating shaft of the cloth guide roller 2; when the cloth guide roller 2 rotates, the two cams 201 are both contacted with the telescopic bottle 401, and the telescopic bottle 401 is in an extrusion state; secondly, a one-way valve A40301 is installed in the connecting pipe 403; the exhaust pipe 406 comprises a check valve B40601, and the check valve B40601 is installed in the exhaust pipe 406; when telescopic bottle 401 is squeezed, one-way valve A40301 is in a closed state, and one-way valve B40601 is in an open state, and when telescopic bottle 401 is elastically reset, one-way valve A40301 is in an open state, and one-way valve B40601 is in a closed state; thirdly, since the cams 201 are installed in a staggered manner, and the right cam 201 does not contact the telescopic bottle 401 when the left cam 201 contacts the telescopic bottle 401, and the right cam 201 contacts the telescopic bottle 401 when the left cam 201 does not contact the telescopic bottle 401, the filtering efficiency is improved; fourthly, the fixed seat 501 is fixedly connected to the roller frame 1 through bolts, two sliding rods 502 are connected to the fixed seat 501 in a sliding manner, and the head ends of the two sliding rods 502 are fixedly connected with the wiping block 503; an elastic piece 504 is sleeved on each of the two sliding rods 502, and the elastic force of the elastic piece 504 pushes the lower wiping block 503 to contact with the outer wall of the air suction pipe 404; fifthly, because the gear B408 is installed on the air suction pipe 404, the gear B408 is meshed with the gear A301, and the air suction pipe 404 is in a synchronous rotation state when the printing roller 3 rotates, the fiber dust on the outer wall of the air suction pipe 404 can be automatically removed under the action of the wiping block 503;

in the use process, firstly, two exhaust pipes 406 are arranged, the two exhaust pipes 406 are respectively connected to the two telescopic bottles 401, and the two exhaust pipes 406 are provided with exhaust holes; the main body parts of the two exhaust pipes 406 are both positioned in the filter box 402, and the two exhaust pipes 406 are both in a wavy structure, so that the diffusion range during exhaust can be enlarged, and the filtering effect is improved; secondly, two air suction pipes 404 are arranged, and the two air suction pipes 404 are respectively connected to the two connecting pipes 403; the two air suction pipes 404 are of cylindrical tubular structures, the outer walls of the two air suction pipes 404 are provided with air suction holes 405 in an annular array shape, and the air suction holes 405 in the annular array shape form an expansion air suction structure of the air suction pipes 404, so that the air suction efficiency and range of the air suction pipes 404 are improved; thirdly, two filter screens 407 are arranged, and the two filter screens 407 are respectively arranged in the two filter boxes 402; the filter net 407 is not located inside the filter liquid in the filter box 402, and the filter net 407 is located above the main body of the exhaust pipe 406, and the two filter nets 407 form a gas dividing structure, thereby further improving the purification efficiency of the exhaust gas from the exhaust pipe 406.

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. The utility model provides a dust purification device based on weaving printing and dyeing usefulness which characterized in that: comprises a roller frame (1); the roller frame (1) is rotatably connected with a cloth guide roller (2), and the roller frame (1) is also rotatably connected with a printing roller (3); the roller frame (1) is provided with a gas purification structure (4), and the roller frame (1) is also provided with a cleaning structure (5); the cloth guide roller (2) comprises two cams (201), and the two cams (201) are arranged on a rotating shaft of the cloth guide roller (2); when the cloth guide roller (2) rotates, the two cams (201) are both contacted with the telescopic bottle (401), and the telescopic bottle (401) is in an extrusion state; the two cams (201) are installed in a staggered mode, when the left cam (201) is in contact with the telescopic bottle (401), the right cam (201) is not in contact with the telescopic bottle (401), and when the left cam (201) is not in contact with the telescopic bottle (401), the right cam (201) is in contact with the telescopic bottle (401).

2. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the roller frame (1) comprises mounting seats (101), and the two mounting seats (101) are welded on the roller frame (1); the gas purification structure (4) comprises two telescopic bottles (401), two filter boxes (402) and two connecting pipes (403), wherein the two telescopic bottles (401) are fixedly connected to the mounting seat (101); the number of the filter boxes (402) is two, and the two filter boxes (402) are fixedly connected to the mounting base (101); each telescopic bottle (401) is connected with a connecting pipe (403).

3. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the gas purification structure (4) further comprises two exhaust pipes (406), the two exhaust pipes (406) are arranged, the two exhaust pipes (406) are respectively connected to the two telescopic bottles (401), and exhaust holes are formed in the two exhaust pipes (406); the main body parts of the two exhaust pipes (406) are both positioned in the filter box (402), and the two exhaust pipes (406) are both of a wavy structure.

4. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the gas purification structure (4) further comprises two gas suction pipes (404) and two gas suction holes (405), wherein the two gas suction pipes (404) are respectively connected to the two connecting pipes (403); two breathing pipes (404) are cylindrical tubular structure, and two breathing pipe (404) outer walls all are the annular array form and have seted up suction opening (405), and suction opening (405) that the annular array form was seted up have constituteed the expansion suction structure of breathing pipe (404).

5. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the gas purification structure (4) further comprises two filter screens (407), wherein the two filter screens (407) are arranged, and the two filter screens (407) are respectively arranged in the two filter boxes (402); the filter screen (407) is not arranged inside the filtered liquid in the filter box (402), the filter screen (407) is arranged above the main body part of the exhaust pipe (406), and the two filter screens (407) form a gas dividing structure.

6. The dust removal and purification device based on textile printing and dyeing as claimed in claim 2, characterized in that: the connecting pipe (403) comprises a one-way valve A (40301), and the one-way valve A (40301) is installed in the connecting pipe (403); the exhaust pipe (406) comprises a check valve B (40601), and the check valve B (40601) is installed in the exhaust pipe (406); when the telescopic bottle (401) is squeezed, the one-way valve A (40301) is in a closed state, the one-way valve B (40601) is in an open state, and when the telescopic bottle (401) elastically resets, the one-way valve A (40301) is in an open state, and the one-way valve B (40601) is in a closed state.

7. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the cleaning structure (5) comprises a fixed seat (501), sliding rods (502), a wiping block (503) and an elastic piece (504), wherein the fixed seat (501) is fixedly connected to the roller frame (1) through bolts, the fixed seat (501) is connected with the two sliding rods (502) in a sliding mode, and the head ends of the two sliding rods (502) are fixedly connected with the wiping block (503); an elastic piece (504) is sleeved on each of the two sliding rods (502), and the elastic force of the elastic piece (504) pushes the wiping block (503) to be in contact with the outer wall of the air suction pipe (404).

8. The dust removal and purification device based on textile printing and dyeing as claimed in claim 1, wherein: the printing roller (3) comprises a gear A (301), and the gear A (301) is mounted on the printing roller (3); the gas purification structure (4) comprises a gear B (408), the gear B (408) is installed on the gas suction pipe (404), the gear B (408) is meshed with the gear A (301), and the gas suction pipe (404) is in a synchronous rotating state when the printing roller (3) rotates.