CN113771449A

CN113771449A - Efficient antibacterial textile material and preparation treatment method

Info

Publication number: CN113771449A
Application number: CN202111145848.XA
Authority: CN
Inventors: 颜丽菊
Original assignee: Individual
Current assignee: Sanmen Jiman Technology Co ltd
Priority date: 2021-09-28
Filing date: 2021-09-28
Publication date: 2021-12-10
Anticipated expiration: 2041-09-28
Also published as: CN113771449B

Abstract

The invention provides a high-efficiency antibacterial textile material and a preparation and treatment method thereof, relating to the technical field of textile materials, wherein the preparation and treatment method of the high-efficiency antibacterial textile material comprises the following steps: s1, winding the textile material: rewinding the plurality of layers of textile cloth to ensure that the textile cloth made of different materials wound into a cylindrical shape extends towards one direction simultaneously; s2, bonding textile cloth: bonding and adhering the multiple layers of textile materials in the step S1, extending the textile cloth which is formed by winding different materials into a cylindrical shape outwards, and gluing and adhering the bonding surfaces of the multiple layers of textile materials in the extending process to ensure that the multiple layers of textile materials are bonded and fixed in a sandwich mode; according to the invention, the fixed limiting plate is arranged at the top end of the fixed supporting rod, and the elastic swing rod is limited by the fixed limiting plate, so that the phenomenon that the elastic swing rod swings excessively due to the fact that the limiting swing rod is pushed upwards by woven cloth is effectively avoided.

Description

Efficient antibacterial textile material and preparation treatment method

Technical Field

The invention relates to the technical field of textile materials, in particular to a high-efficiency antibacterial textile material and a preparation and treatment method thereof.

Background

The textile material refers to fiber and fiber products, and is specifically represented as fiber, yarn, fabric and composites thereof, and currently, a sandwich type textile material which is made of various different materials is used for splicing, stacking and bonding, and along with the demand of social development, the demand of people on the textile material begins to be improved, for example, the textile material which needs high elasticity and high air permeability is needed.

Conventionally, patent No. CN201811523324.8 discloses a bacteriostatic textile material formed by immersing Chinese herbal medicines into cloth and a method for preparing the same. The components in the antibacterial textile material have a synergistic effect, can effectively inhibit and kill bacteria, and has a wide application prospect. The antibacterial textile material is applied to inhibiting and killing escherichia coli, or bacillus subtilis, or staphylococcus aureus, or staphylococcus albus, or yeast. The patent No. CN201811523324.8 discloses an antibacterial textile material, which comprises radix angelicae, pepper, dandelion, asarum and scutellaria baicalensis, and all components in the antibacterial textile material have synergistic effects, so that the antibacterial textile material can effectively inhibit and sterilize bacteria, and has a wide application prospect.

The preparation method of the high-elastic antibacterial textile material disclosed by the patent still has some defects in the actual production process, and the specific defects are as follows:

at present, when high-elastic antibacterial textile material is produced and prepared, a plurality of layers of textile materials need to be bonded in a sandwich mode to form textile cloth with special performance, when the textile cloth is actually bonded, manual bonding is mostly carried out, a large amount of manpower is consumed for manual bonding, the workload of each worker is large, the bonding is not firm due to uneven gluing, the process flow of the existing textile material is complex, the textile material is immersed into Chinese herbal medicines through manpower, medicine scraps are remained on the surfaces of the Chinese herbal medicines, the medicine content on the surfaces of the easy-to-use textile cloth is uneven, and the attractiveness is influenced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a high-efficiency antibacterial textile material and a preparation treatment method thereof, and solves the technical problems that when the existing high-elasticity antibacterial textile material is produced and prepared, multiple layers of textile materials need to be bonded in a sandwich mode to form textile cloth with special performance, when the textile cloth is actually bonded, manual bonding is mostly performed, a large amount of manpower is consumed for manual bonding, the workload of each worker is large, the bonding is not firm due to uneven gluing, the process flow of the existing textile material is complex, and the appearance is affected due to uneven medicine content on the surface of the textile cloth easy to use and the medicine residues left on the surface of the Chinese herbal medicine in the process of manually soaking the textile material into the Chinese herbal medicine.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

a preparation and treatment method of a high-efficiency antibacterial textile material comprises the following steps:

s1, winding the textile material: rewinding the plurality of layers of textile cloth to ensure that the textile cloth made of different materials wound into a cylindrical shape extends towards one direction simultaneously;

s2, bonding textile cloth: bonding and adhering the multiple layers of textile materials in the step S1, extending the textile cloth which is formed by winding different materials into a cylindrical shape outwards, and gluing and adhering the bonding surfaces of the multiple layers of textile materials in the extending process to ensure that the multiple layers of textile materials are bonded and fixed in a sandwich mode;

s3, pressing after bonding: in the step S2, the multiple layers of textile cloth are pressed and fixed after being adhered and fixed in an interlayer manner, and the two pressing rollers roll and press the textile cloth from the middle of the upper direction and the lower direction, so that the adhered multiple layers of textile cloth are adhered more firmly;

s4, adsorbing the antibacterial preparation: in the step S3, the bonded textile cloth droops by gravity to enable the textile cloth to be vertically placed in a bacteriostatic preparation box, bacteriostatic preparations are stored in the bacteriostatic preparation box, and the textile cloth swings in the bacteriostatic preparation box, so that the bacteriostatic preparations are uniformly adsorbed on the surface of the textile cloth in the bacteriostatic preparation box;

s5, reciprocating shaking and draining: reciprocating swing is carried out on the woven cloth adsorbed with the bacteriostatic agent in the step S5, when the woven cloth is lifted from the bacteriostatic agent box, the bacteriostatic agent adsorbed on the surface of the woven cloth adsorbed with the bacteriostatic agent is shaken and drained, air is blown downwards in the shaking process, and redundant bacteriostatic agent on the surface of the woven cloth is blown downwards by air flow and falls into the bacteriostatic agent box for recycling;

s6, scraping and pressing the medicine scraps on the textile cloth: scraping the fragments of the textile fabric surface after adsorbing the antibacterial agent in the step S5, scraping the textile fabric surface through a third scraping blade, and scraping the fragments of the textile fabric surface after adsorbing the antibacterial agent;

s7, opening holes in the textile cloth: the textile cloth which adsorbs the antibacterial agent and is drained in the step S6 is perforated, so that a plurality of air holes are uniformly formed on the surface of the textile cloth;

s8, rewinding of textile cloth: and (4) winding the textile fabric with the holes in the step (S8), and winding the textile fabric through a rewinding mechanism.

As a preferred technical solution of the present invention, the method for preparing and processing a high-efficiency antibacterial textile material described in the above steps S1-S8 is specifically completed by matching a high-efficiency antibacterial textile material preparation and processing device, which includes a bottom workbench and a glue spreader frame disposed at the top end of the bottom workbench, wherein the bottom workbench is horizontally disposed, a plurality of glue spreading legs are fixedly disposed on the left side of the top end of the bottom workbench, the middle part of the top end of each glue spreading leg is rotatably connected with a plurality of bobbins, a first adhesive cloth is wound on the bobbin at the topmost end, a textile cloth is wound on the bobbin at the middle part, and a second adhesive cloth is wound on the bobbin at the bottommost end;

a gluing supporting leg is fixedly mounted at the top end of the bottom workbench, a gluing roller frame is fixedly mounted at the top end of the gluing supporting leg, and two gluing rollers are rotatably connected to the gluing roller frame;

the top end of the bottom workbench is fixedly provided with a pressing mechanism, and the middle part of the pressing mechanism is rotatably connected with two pressing rollers;

a glue solution drying box is fixedly arranged at the top end of the bottom workbench, and an antibacterial agent box (16) is fixedly arranged at the right end of the glue solution drying box; a cloth shaking mechanism is fixedly installed above the bacteriostatic preparation box, supporting rollers are respectively arranged on the left side and the right side of the bacteriostatic preparation box, a hole opening mechanism is fixedly arranged on the right side of each supporting roller, and a rewinding mechanism is arranged on the right side of each hole opening mechanism;

the textile fabric, the second adhesive cloth and the right end of the first adhesive cloth penetrate through the glue spreader rack, one glue spreader extends between the first adhesive cloth and the textile fabric, and the other glue spreader extends between the textile fabric and the second adhesive cloth;

the textile material, the second is pasted cloth and first is pasted cloth and is stretched into in hold-down mechanism after passing in the glue spreader frame, compress tightly textile material, the second is pasted cloth and first and is pasted cloth through two hold-down rollers and compress tightly the laminating and form textile material, textile material passes through glue solution stoving case and dries and enter bacteriostatic agent case, support the textile material through the backing roll at both ends about the bacteriostatic agent case, and carry out the trompil with textile material through trompil mechanism, then through rolling back the mechanism and convolute textile material into the tube-shape.

As a preferred technical scheme of the invention, the cloth shaking mechanism comprises a third support rod vertically fixed at the top end of the bacteriostatic preparation box, a second electric push rod is fixedly installed in the middle of the third support rod, a push rod extends leftwards from the second electric push rod, and the top end of the push rod of the second electric push rod is rotatably connected with a second pasting roller;

a fixed sliding block is fixedly installed on the left side of the top end of the bacteriostatic preparation box, a spring hole is formed in the right end of the fixed sliding block, a compression spring is installed in the spring hole, a lifting sliding rod is connected in the spring hole in a sliding mode, and a first pasting roller is connected to the right end of the lifting sliding rod in a rotating mode;

as a preferred technical scheme of the invention, a row of first air nozzles are fixedly mounted at the bottom end of the fixed sliding block, a second air nozzle is fixedly mounted at the left side of the third supporting rod, a second air pump is arranged on the second air nozzle to provide an air source, and the second air pump is fixedly mounted on the third supporting rod;

and a third air pump is fixedly mounted at the top end of the fixed sliding block and connected with the first air nozzle and provides an air source for the first air nozzle.

As a preferred technical scheme of the present invention, fixed support rods are fixedly mounted at the bottom ends of the first pasting roller and the second pasting roller, the bottom ends of the fixed support rods are hinged with elastic swing rods, a fixed limiting plate is disposed at the bottom end of the fixed support rod at each side, a first balance spring is fixedly mounted on the fixed limiting plate of the elastic swing rod, and a second balance spring is fixedly mounted at the other side of the elastic swing rod and the middle portion of the fixed support rod.

As a preferable technical scheme of the invention, a V-shaped third scrap shoveling blade is fixed at the bottom end of the elastic swing rod positioned on each side of the textile material.

A high-efficiency antibacterial textile material comprises a textile fabric, a first adhesive cloth and a second adhesive cloth, wherein the textile fabric is arranged in a middle layer, the first adhesive cloth is adhered to the top layer of the textile fabric, the second adhesive cloth is adhered to the top layer of the textile fabric, and the textile fabric is made of cotton cloth; the first adhesive cloth and the second adhesive cloth are non-woven fabrics with diamond net surfaces, wherein a bacteriostatic agent is doped in glue for adhesion, and the bonded textile cloth is immersed in the bacteriostatic agent box and drained to realize a bacteriostatic function.

Compared with the prior art, the invention at least comprises the following beneficial effects:

the production and preparation process of the high-elasticity breathable textile material carries out whole-process unattended automatic production and processing on multiple layers of textile cloth through whole-process automatic production and processing, and carries out the process steps of automatic uniform gluing and bonding, uniform adsorption of antibacterial agents, rapid shaking and draining, automatic hole opening and the like.

The cloth shaking mechanism is arranged above the bacteriostatic agent box, the woven cloth adsorbed with the bacteriostatic agent is shaken in a reciprocating manner by utilizing the reciprocating pushing of the second electric push rod, the first pasting roller utilizes the internal compression spring to enable the first pasting roller to realize reciprocating sliding along with the reciprocating movement of the second pasting roller by matching with the pressing of the first pasting roller on the woven cloth, the woven cloth cannot float indefinitely when shaking, so that the effective shaking control on the woven cloth adsorbed with the bacteriostatic agent is improved, the woven cloth is prevented from floating randomly, the redundant bacteriostatic agent attached to the surface of the woven cloth adsorbed with the bacteriostatic agent is quickly shaken off by pushing the woven cloth adsorbed with the bacteriostatic agent in a reciprocating manner, the surface of the woven cloth adsorbed with the bacteriostatic agent is uniformly adsorbed, and the second air nozzle and the first air nozzle below are matched to blow air downwards, accelerate weaving cloth surface adhesion unnecessary antibacterial agent and drip downwards, utilize wind-force can accelerate the stoving speed that adsorbs the weaving cloth that has antibacterial agent, wherein, through second air nozzle and first air nozzle to the nozzle gas downwards, the reciprocal slip of cylinder and second paste is pasted to the cooperation first, make second air nozzle and first air nozzle at nozzle gas in-process downwards, weaving cloth is reciprocal to be trembled, the simulation air current is at weaving cloth surface reciprocating swing, thereby improve weaving cloth's installation fastness effectively.

In the process of reciprocating shaking of the textile cloth by the first pasting roller and the second pasting roller, the redundant and solidified solid bacteriostatic agent on the surface of the textile cloth with the bacteriostatic agent is scraped by the lower third scrap shoveling blade, so that the redundant bacteriostatic agent on the surface of the textile cloth is not solidified into a cause state when the second air nozzle and the first air nozzle blow down, and the third scrap shoveling blade can effectively improve the removal of the redundant bacteriostatic agent on the surface of the textile cloth, thereby effectively improving the uniformity of the bacteriostatic agent adsorbed by the textile cloth.

The elastic swing rod and the fixing support rod are elastically supported through the second balance spring and the first balance spring, so that the elastic support of the second balance spring and the first balance spring is realized, the elastic swing rod is tightly attached to the surface of woven cloth, the top end of the fixing support rod is provided with the fixing limiting plate, the fixing limiting plate is used for limiting the elastic swing rod, and the situation that the limiting swing rod is pushed upwards by the woven cloth to cause excessive swing of the elastic swing rod is effectively avoided.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a flow chart of the process steps of the process for producing a highly elastic breathable textile material of the present invention;

FIG. 2 is a schematic front view of the apparatus for producing highly elastic and breathable textile material of the present invention;

FIG. 3 is a front view of the hole opening mechanism of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 in accordance with the teachings of the present invention;

FIG. 5 is an enlarged partial cross-sectional view taken at D of FIG. 3 in accordance with the teachings of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 2 taken at B in the present specification;

FIG. 7 is an enlarged view of a portion of FIG. 6 taken at C in the present specification;

FIG. 8 is an enlarged, fragmentary, schematic view of the applicator roll of FIG. 2 of the present specification;

FIG. 9 is a schematic cross-sectional front view of a glue roll according to the present invention for applying glue between a textile fabric and a woven fabric;

in the figure: 1. a bottom support leg; 2. a bottom work table; 3. a bobbin; 4. weaving cloth; 5. gluing supporting legs; 6. a glue spreading roller frame; 7. glue spreading roller; 701. a third crank; 702. a third servo motor; 703. a lifting cross frame; 704. a lifting slideway; 705. an oil supply pump; 706. an oil delivery pipe; 707. a sponge sleeve; 708. a steel wire sleeve; 709. an oil storage chamber; 710. an oil storage partition plate; 711. an oil jet; 712. an oil sleeve; 713. an oil injection cavity; 714. an oil inlet cavity channel; 8. a hold-down mechanism; 801. a support frame; 802. a compression spring; 803. a spring slot; 804. an elastic slider; 9. a pressure roller; 10. a glue solution drying box; 11. weaving cloth; 12. a cloth shaking mechanism; 1201. a second servo motor; 1202. fixing the sliding block; 1203. a spring hole; 1204. a compression spring; 1205. lifting the sliding rod; 1206. a first pasting roller; 1207. a first air nozzle; 1208. a second pasting roller; 1209. a second air nozzle; 1210. a second electric push rod; 1211. a third support bar; 1212. a second air pump; 1213. a second balance spring; 1214. an elastic swing link; 1215. a first balance spring; 1216. fixing a limit plate; 1217. fixing the supporting rod; 1218. a third scrap shoveling edge; 14. a hole opening mechanism; 1401. a first electric push rod; 1402. a support frame; 1403. a push rod frame; 1404. a lifting base; 1405. a return tension spring; 1406. lifting the sliding rod; 1407. sliding the clamping block; 1408. a compression plate; 1409. grasping the teeth; 1411. a cloth bottom plate; 1412. floor legs, 1413, support shaft; 1414. rotating the shaft cylinder in a reciprocating manner; 1415. a pin rod; 1416. an S-shaped slideway; 1417. cutting teeth; 1418. a lifting groove; 1419. a yielding chip storage groove; 1420. a second vent hole; 1421. a support roller; 15. a rewinding mechanism; 16. a bacteriostatic agent box; 17. a first adhesive patch; 18. and a second adhesive cloth.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further described below by combining with the specific drawings, and it is to be noted that the embodiments and the features in the embodiments can be combined with each other in the application without conflict.

Example 1

Please refer to fig. 1-9, which are schematic structural diagrams of a high-efficiency antibacterial textile material and a preparation and treatment method thereof;

The preparation and treatment method of the efficient antibacterial textile material comprises the steps of S1-S8, and is specifically completed by matching an efficient antibacterial textile material preparation and treatment device, wherein the efficient antibacterial textile material preparation and treatment device comprises a bottom workbench 2 and a glue spreader frame 6 arranged at the top end of the bottom workbench 2, the bottom workbench 2 is horizontally arranged, a plurality of bottom supporting legs 1 are fixedly arranged at the bottom end of the bottom workbench 2 at equal intervals, a plurality of glue spreading supporting legs 5 are fixedly arranged on the left side of the top end of the bottom workbench 2, the middle part of the top end of each glue spreading supporting leg 5 is rotatably connected with a plurality of winding frames 3, a first adhesive cloth 17 is wound on the winding frame 3 at the topmost end, a textile cloth 4 is wound on the winding frame 3 at the middle part, and a second adhesive cloth 18 is wound on the winding frame 3 at the bottommost end;

a gluing leg 5 is fixedly arranged at the top end of the bottom workbench 2, a gluing roller frame 6 is fixedly arranged at the top end of the gluing leg 5, and two gluing rollers 7 are rotatably connected to the gluing roller frame 6;

a pressing mechanism 8 is fixedly arranged at the top end of the bottom workbench 2, and the middle part of the pressing mechanism 8 is rotatably connected with two pressing rollers 9;

a glue solution drying box 10 is fixedly arranged at the top end of the bottom workbench 2, and an antibacterial preparation box 16 is fixedly arranged at the right end of the glue solution drying box 10; a cloth shaking mechanism 12 is fixedly installed above the bacteriostatic preparation box 16, supporting rollers 13 are respectively arranged on the left side and the right side of the bacteriostatic preparation box 16, a hole opening mechanism 14 is fixedly arranged on the right side of each supporting roller 13, and a rewinding mechanism 15 is arranged on the right side of each hole opening mechanism 14;

wherein the textile fabric 4, the second adhesive fabric 18 and the right end of the first adhesive fabric 17 all penetrate through the glue spreader frame 6, one glue spreader 7 extends between the first adhesive fabric 17 and the textile fabric 4, and the other glue spreader 7 extends between the textile fabric 4 and the second adhesive fabric 18;

the textile material 4, the second adhesive cloth 18 and the first adhesive cloth 17 penetrate through the glue spreader frame 6 and then extend into the pressing mechanism 8, the textile material 4, the second adhesive cloth 18 and the first adhesive cloth 17 are pressed and attached through the two pressing rollers 9 to form a textile material, the textile material is dried through the glue solution drying box 10 and enters the bacteriostatic preparation box 16, the textile material is supported through the supporting rollers 13 at the left end and the right end of the bacteriostatic preparation box 16, the textile material is perforated through the perforating mechanism 14, and then the textile material is wound into a cylindrical shape through the rewinding mechanism 15.

The pressing mechanism 8 comprises two supporting frames 801, compression springs 802, spring grooves 803 and elastic sliding blocks 804, the two supporting frames 801 are vertically fixed at the top end of the bottom workbench 2, the two supporting frames 801 are arranged at the top end of the workbench 2 and located at the front side and the rear side of the textile material, the middle of each supporting frame 801 is provided with two spring grooves 803, each spring groove 803 is in sliding connection with the elastic sliding block 804, and each pressing roller 9 is rotatably connected in the corresponding elastic sliding block 804;

the pressing rollers 9 of the invention are elastically supported by the compression springs 802, so that the two pressing rollers 9 clamp the textile fabric towards the middle.

The rewinding mechanism 15 includes a rewinding drum 1502, a cloth blocking frame 1503, a supporting frame 1504, a transmission chain 1505, a transmission chain wheel 1506, a first servo motor 1507, a first shifting wheel 1508 and a first grooved wheel 1509, the supporting frame 1504 is vertically fixed at the top end of the bottom workbench 2, the top end of the supporting frame 1504 is rotatably connected with the rewinding drum 1502, the cloth blocking frame 1503 is fixedly installed at two ends of the rewinding drum 1502, the transmission chain 1505 is arranged at one end of the rewinding drum 1502, the transmission chain wheel 1506 is arranged at one end of the inner ring of the transmission chain 1505, the first grooved wheel 1509 is fixedly installed at one end of the transmission chain wheel 1506, the first shifting wheel 1508 is engaged and connected with the first shifting wheel 1508, the first shifting wheel 1508 is fixed at the top end of the output shaft of the first servo motor 1507, and the first servo motor 1507 is fixedly installed at the top end of the bottom workbench 2.

In the invention, the rewinding roller 1502 is driven to rotate by the engagement of the first dial wheel 1508 and the first sheave 1509, so that the rewinding roller 1502 is driven to rotate intermittently.

The glue spreader frame 6 comprises a third crank 701, a third servo motor 702, a lifting cross frame 703 and a lifting slideway 704, the third servo motor 702 is fixedly installed at the top end of the glue spreader frame 6, the third servo motor 702 extends forwards out of an output shaft, and the third crank 701 is fixedly installed at the top end of the output shaft of the third servo motor 702;

two through lifting slide ways 704 are arranged in the middle of the glue spreader frame 6, each glue spreader 7 is connected in the corresponding lifting slide way 704 through rotation, the front side and the rear side of the glue spreader frame 6 are symmetrically and slidably connected with lifting transverse frames 703, and the top ends of the lifting transverse frames 703 on each side are connected on corresponding third cranks 701 through sliding. The glue spreader 7 is driven to reciprocate up and down and shake by reciprocating up and down of the up-down cross frame 703.

Each glue spreader 7 comprises an oil storage cavity 709, oil storage partition plates 710, an oil nozzle 711, an oil sleeve 712, an oil injection cavity 713 and an oil inlet cavity channel 714, the oil sleeve 712 is of a cylindrical structure, the middle part of the oil sleeve 712 is provided with the oil inlet cavity channel 714 of a round hole structure, the outer ring of the oil sleeve 712 is fixedly provided with the steel wire sleeve 708 of the cylindrical structure, a plurality of oil storage partition plates 710 are fixedly arranged between the steel wire sleeve 708 and the oil sleeve 712 at equal intervals, the oil storage cavity 709 is isolated between every two adjacent oil storage partition plates 710, the outer circular surface of the oil sleeve 712 is fixedly provided with the oil nozzle 711 extending into each oil storage cavity 709, and the inner wall of the oil inlet cavity channel 714 is fixedly provided with a plurality of oil injection cavities 713 communicated with the oil nozzle 711 at equal intervals;

each glue spreader 7 rotatably connected to the middle of the glue spreader frame 6 is connected with an oil delivery pipe 706 at one end thereof, the top ends of the two oil delivery pipes 706 are connected with an oil supply pump 705 together, and the oil supply pump 705 is fixedly installed at the top end of the glue spreader frame 6, so that glue can be supplied to each oil nozzle 711 through the oil supply pump 705.

The steel wire sleeve 708 is a cylinder structure woven by a plurality of steel wires in a rhombic net shape, and a cylindrical sponge sleeve 707 is sleeved on the outer circular surface of the steel wire sleeve 708.

The glue spreader 7 frame is arranged at the position of the binding surfaces of the two adjacent layers of textile cloth through the glue spreader 7, the textile cloth can drag the glue spreader 7 to rotate in the forward moving process, the binding surfaces of the adjacent textile cloth are coated with glue by rolling the glue spreader 7 on the textile cloth, so that the bonding firmness of the textile cloth is improved, each glue spreader 7 sprays glue in the oil storage cavity 709 through the oil nozzle 711, glue solution remains in the oil storage cavity 709, the glue solution penetrates through the steel wire sleeve 708 into the sponge sleeve 707 on the surface of the steel wire sleeve 708 through the rotation of the glue spreader 7 by utilizing the gravity, the glue solution in the oil storage cavity 709 is uniformly adsorbed by utilizing the siphon characteristic of the sponge sleeve 707, and the glue spreader 7 uniformly coats the surface of the textile cloth.

According to the invention, the oil spray nozzle 711 is arranged in the sponge sleeve by utilizing the adsorption of the sponge sleeve 707, so that glue solution sprayed by the oil spray nozzle 711 cannot uniformly drip in the textile fabric, and the effectiveness of the glue spray nozzle in adhering to the surface of the textile fabric can be effectively realized.

According to the invention, the glue spreader 7 is reciprocated, lifted and shaken by the lifting cross frame 703, so that when the glue spreader 7 is lifted upwards, the outer circular surface of the glue spreader 7 is in rolling contact with the surface of the topmost first adhesive cloth 17, the glue spreader 7 is rotated along one direction, when the glue spreader 7 is lowered downwards and reciprocally, the outer circular surface of the glue spreader 7 is in rolling contact with the surface of the bottommost second adhesive cloth 18, the glue spreader 7 is rotated along the other direction, and the glue solution is swung reciprocally in the oil storage cavity 709 by the reciprocating lifting of the glue spreader 7 in cooperation with the reciprocating rotation of the glue spreader 7, so that the precipitation of the glue solution in the oil storage cavity 709 can be effectively reduced, the glue solution can be kept in a certain activity in the oil storage cavity 709 all the time, the adsorption uniformity of the sponge sleeve 707 is effectively improved, and the gluing uniformity of the bonding surface of the sponge cloth is effectively improved.

The perforating mechanism 14 comprises a cloth bottom plate 1411 arranged below the textile material, the top surface of the cloth bottom plate 1411 is a plane, bottom plate legs 1412 are fixedly arranged at the bottom end of the cloth bottom plate 1411, and the bottom plate legs 1412 are vertically and fixedly arranged in the bacteriostatic agent box 16;

a support frame 1402 is fixedly installed on the right side of the top end of the cloth bottom plate 1411, a push rod frame 1403 is fixedly installed on the top end of the support frame 1402, a first electric push rod 1401 is fixedly installed on the top end of the push rod frame 1403, a push rod extends downwards from the first electric push rod 1401, the bottom end of the push rod of the first electric push rod 1401 is fixedly installed on a lifting base 1404, and a plurality of hole drilling drills 1410 which are vertically arranged on the lifting base 1404 are fixedly installed at equal intervals at the bottom end of the lifting base 1404;

the left side and the right side of the push rod frame 1403 are symmetrically provided with sliding fixture blocks 1407, the sliding fixture blocks 1407 on each side are obliquely fixed, the sliding fixture blocks 1407 obliquely fixed on each side are connected with the lifting slide rod 1406 in a sliding mode, the top end of each sliding fixture block 1407 and the side wall of the lifting slide rod 1406 are fixedly provided with return tension springs 1405, the bottom end of the lifting slide rod 1406 is fixedly provided with a pressing plate 1408, the pressing plate 1408 is a plane, and the bottom end of each grasping tooth 1409 is fixedly provided with a plurality of grasping teeth 1409 with diamond structures.

The trepanning drill 1410 comprises a supporting shaft 1413 vertically fixed at the bottom end of the lifting base 1404, each supporting shaft 1413 is arranged to be a cylindrical rod, the outer circular surface of each supporting shaft 1413 is rotatably connected with a reciprocating rotary shaft cylinder 1414, the reciprocating rotary shaft cylinder 1414 is of a cylindrical structure, a lifting groove 1418 of a circular hole structure is formed in the top end of the reciprocating rotary shaft cylinder 1414, the lifting groove 1418 of the reciprocating rotary shaft cylinder 1414 is connected to the outer circular surface of the supporting shaft 1413 through sliding, a sunken S-shaped slideway 1416 is formed in the inner wall of the reciprocating rotary shaft cylinder 1414, a convex pin 1415 is fixedly arranged on the outer circular surface of the supporting shaft 1413, the pin 1415 is connected to the S-shaped slideway 1416 through sliding, and a circular chopping tooth 1417 is formed on the bottom end surface of the reciprocating rotary shaft cylinder 1414 and close to the outer circular surface of the reciprocating rotary shaft cylinder 1414.

Reciprocating rotation axle section of thick bamboo 1414 bottom middle part has been seted up and has been stepped down and store up chip groove 1419, and exhaust hole 1420 has been seted up in the middle part of the chip groove 1419 that steps down, and second exhaust hole 1421 that link up is seted up in the middle part of supporting shaft 1413, and lifting pedestal 1404 top fixed mounting has fourth air pump 1422, and fourth air pump 1422 is for providing the air supply for each second exhaust hole 1421 through oil pipeline.

The punching mechanism 14 of the invention is lifted and lowered downwards in a reciprocating manner through the lifting base 1404, a plurality of punching drills are controlled to fall downwards in a reciprocating manner at the same time, each time the punching drill falls downwards, punching is carried out on the woven cloth on the top surface of the cloth base plate 1411 below, wherein the woven cloth intermittently moves on the top surface of the cloth base plate 1411 through intermittent rewinding of the rewinding mechanism 15, when the woven cloth stops intermittently on the top surface of the cloth base plate 1411, the lifting base 1404 falls downwards, the woven cloth on two sides of the punching drill is pressed and fixed by the pressing plates 1408 on two sides, so that the punching drill is more accurate and stable when punching is carried out on the surface of the woven cloth, and the woven cloth is prevented from sliding on the top surface of the cloth base plate 1411 in the punching process.

In the reciprocating lifting process of the lifting base 1404, the sliding fixture blocks 1407 obliquely fixed on two sides are in sliding connection with the lifting slide rod 1406, so that the pressing plates 1408 on two sides compress textile cloth in the downward falling process of the lifting base 1404, and the sliding fixture blocks 1407 obliquely fixed with the lifting slide rod 1406 enable the pressing plates 1408 to gradually pull the textile cloth towards two sides along with the downward movement of the lifting base 1404 in the pressing process of the textile cloth, so that the top surface of the textile cloth is pulled flatly, accurate tapping of the tapping drill is facilitated, the pulling flatness of the textile cloth is effectively improved, and the pulling flatness of the tapping drill on the textile cloth in the tapping process is effectively avoided.

Wherein, the hole drilling machine of the invention leads the reciprocating rotary shaft cylinder 1414 to slide on the supporting shaft 1413 in a lifting way by the reciprocating rotary shaft cylinder 1414 and leads the reciprocating rotary shaft cylinder 1414 to rotate in a reciprocating way by the S-shaped slideway 1416 on the inner wall of the reciprocating rotary shaft cylinder 1414, when the reciprocating rotary shaft cylinder 1414 rotates in a reciprocating way, the chopping tooth 1417 on the bottom surface of the reciprocating rotary shaft cylinder 1414 performs rotary cutting on the surface of the textile cloth, so that the surface of the textile cloth is expanded into a plurality of round holes, the bottom surface of the reciprocating rotary shaft cylinder 1414 passes through the middle part of the abdication chip storage groove 1419 on the bottom surface and is provided with a second exhaust hole 1420, the textile cloth scraps stuck on the bottom surface of the reciprocating rotary shaft cylinder 1414 are exhausted downwards through the second exhaust hole 1420, the scraps are blown out from the abdication chip storage groove 1419, thereby effectively improving the cleaning of the abdication chip storage groove 1419 and avoiding the scraps in the process of tapping from blocking the bottom surface of the reciprocating rotary shaft cylinder 1414, affecting the cutting of the reciprocating rotating shaft 1414.

Example 2

With continued reference to fig. 1-9, a high elastic breathable textile material is shown, which is similar to example 1 above, and which is not further described herein, except for the following specific differences:

a high-elastic breathable textile material comprises a textile fabric 4, a first adhesive cloth 17 and a second adhesive cloth 18, wherein the textile fabric 4 is arranged in a middle layer, the first adhesive cloth 17 is bonded on the top layer of the textile fabric 4, the second adhesive cloth 18 is bonded on the top layer of the textile fabric 4, and the textile fabric 4 is made of cotton cloth; the first adhesive patch 17 and the second adhesive patch 18 are both nonwoven fabrics with diamond-shaped mesh surfaces. Wherein, the glue for sticking is doped with bacteriostatic agent, and the bonded textile cloth is immersed in a bacteriostatic agent box and drained to realize bacteriostatic function.

The cloth shaking mechanism 12 comprises a third support rod 1211 vertically fixed at the top end of the bacteriostatic preparation box 16, a second electric push rod 1210 is fixedly installed in the middle of the third support rod 1211, a push rod extends leftwards from the second electric push rod 1210, and the top end of the push rod of the second electric push rod 1210 is rotatably connected with a second pasting roller 1208;

a fixed slide block 1202 is fixedly installed on the left side of the top end of the bacteriostatic agent box 16, a spring hole 1203 is formed in the right end of the fixed slide block 1202, a compression spring 1204 is installed in the spring hole 1203, a lifting slide bar 1205 is connected in the spring hole 1203 in a sliding mode, and a first pasting roller 1206 is connected to the right end of the lifting slide bar 1205 in a rotating mode; the colored textile material passes between the first applicator roller 1206 and the second applicator roller 1208.

A row of first air nozzles 1207 is fixedly installed at the bottom end of the fixed slider 1202, a second air nozzle 1209 is fixedly installed at the left side of the third support rod 1211, a second air pump 1212 is arranged on the second air nozzle 1209 to provide an air source, and the second air pump 1212 is fixedly installed on the third support rod 1211;

the top end of the fixed sliding block 1202 is fixedly provided with an oil supply pump 1201, and the oil supply pump 1201 is connected with the first air nozzle 1207 and provides an air source for the first air nozzle 1207.

The bottom ends of the first pasting roller 1206 and the second pasting roller 1208 are respectively fixedly provided with a fixed support 1217, the bottom end of the fixed support 1217 is hinged with an elastic swing link 1214, the bottom end of the fixed support 1217 on each side is provided with a fixed limit plate 1216, the elastic swing link 1214 is fixedly provided with a first balance spring 1215 on the fixed limit plate 1216, and the other side of the elastic swing link 1214 and the middle part of the fixed support 1217 are fixedly provided with a second balance spring 1213.

A V-shaped third scraping edge 1218 is secured to the bottom end of the resilient pendulum 1214 on each side of the textile material.

Wherein, the cloth shaking mechanism 12 of the invention is arranged above the bacteriostatic agent box 16, uses the reciprocating push of the second electric push rod 1210 to shake the textile cloth absorbing the bacteriostatic agent in a reciprocating way, and uses the compression spring 802 inside the first pasting roller 1206 to make the first pasting roller 1206 follow the reciprocating movement of the second pasting roller 1208 to realize the reciprocating sliding through the clamping of the first pasting roller 1206 and the second pasting roller 1208, and the textile cloth is pressed by the first pasting roller 1206, so that the textile cloth can not be shaken constantly, thereby improving the effective shaking control on the textile cloth after absorbing the bacteriostatic agent, avoiding the random swinging of the textile cloth, and making the redundant bacteriostatic agent attached on the textile cloth surface after absorbing the bacteriostatic agent shaken off quickly through the reciprocating push on the textile cloth after absorbing the bacteriostatic agent, thereby making the surface of the textile cloth absorbing the bacteriostatic agent adsorbed uniformly, second air nozzle 1209 and first air nozzle 1207 of cooperation below are mouth gas downwards, accelerate to adsorb the weaving cloth surface that has bacteriostatic agent and adhere to unnecessary bacteriostatic agent and drip downwards, utilize wind-force can accelerate the stoving speed that adsorbs the weaving cloth that has bacteriostatic agent, wherein, through second air nozzle 1209 and first air nozzle 1207 mouth gas downwards, the reciprocal slip of cylinder 1206 and second sticking cylinder 1208 is pasted in the cooperation, make second air nozzle 1209 and first air nozzle 1207 at mouth gas in-process downwards, the reciprocal shake of weaving cloth, the simulation air current is at weaving cloth surface reciprocal swing, thereby improve the installation fastness of weaving cloth effectively.

In the process of reciprocating shaking of the textile cloth by the first pasting roller 1206 and the second pasting roller 1208, the third scraping blade 1218 below is used for scraping the redundant bacteriostatic agent which is solidified into a solid state on the surface of the textile cloth after the bacteriostatic agent is adsorbed, so that in the process of scraping the bacteriostatic agent which is not solidified into a factor state on the surface of the textile cloth when the second air nozzle 1209 and the first air nozzle 1207 are blown downwards, the removal of the redundant bacteriostatic agent on the surface of the textile cloth can be effectively improved by the third scraping blade 1218, and the uniformity of the bacteriostatic agent adsorbed by the textile cloth is effectively improved.

The elastic swing link 1214 and the fixed support rod 1217 of the invention are elastically supported by the second balance spring 1213 and the first balance spring 1215, so that the elastic support of the second balance spring 1213 and the first balance spring 1215 is realized, the elastic swing link 1214 is more tightly attached to the surface of the woven cloth, and the fixed limit plate 1216 is arranged at the top end of the fixed support rod 1217, so that the elastic swing link 1214 is limited by the fixed limit plate 1216, and the limit swing link 1214 is effectively prevented from being pushed upwards by the woven cloth to cause the excessive swing of the elastic swing link 1214.

The foregoing illustrates and describes the principles, general features, and advantages of the present 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 given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A preparation and treatment method of a high-efficiency antibacterial textile material is characterized by comprising the following steps:

s7, opening holes in the textile cloth: perforating the dyed and drained textile cloth in the step S6 to uniformly form a plurality of air holes on the surface of the textile cloth;

2. The preparation and treatment method of high-efficiency antibacterial textile material according to claim 1, the preparation and treatment method of the high-efficiency antibacterial textile material in the steps S1-S8 is specifically completed by matching a high-efficiency antibacterial textile material preparation and treatment device, the high-efficiency antibacterial textile material preparation treatment device comprises a bottom workbench and a glue spreader frame arranged at the top end of the bottom workbench, the bottom workbench is horizontally arranged, a plurality of bottom supporting legs are fixedly arranged at the bottom end of the bottom workbench at equal intervals, the left side of the top end of the bottom workbench is fixedly provided with a plurality of gluing supporting legs, the middle part of the top end of each gluing supporting leg is rotatably connected with a plurality of winding frames, the winding frame at the topmost end is wound with first adhesive cloth, the winding frame at the middle part is wound with textile cloth, and the winding frame at the lowest end is wound with second adhesive cloth;

3. The method for preparing and treating the high-efficiency antibacterial textile material according to claim 2, wherein the cloth shaking mechanism comprises a third support rod vertically fixed at the top end of the antibacterial agent box, a second electric push rod is fixedly installed in the middle of the third support rod, a push rod extends leftwards from the second electric push rod, and the top end of the push rod of the second electric push rod is rotatably connected with a second pasting roller;

the bacteriostatic agent case top left side fixed mounting has fixed slider, the spring hole has been seted up to fixed slider right-hand member, install compression spring in the spring hole, sliding connection has the lift slide bar in the spring hole, the lift slide bar right-hand member rotates and is connected with first pasting the cylinder.

4. The preparation and treatment method of the high-efficiency bacteriostatic textile material according to claim 3, characterized in that a row of first air nozzles are fixedly arranged at the bottom end of the fixed sliding block, a second air nozzle is fixedly arranged at the left side of the third supporting rod, the second air nozzle is provided with a second air pump for providing an air source, and the second air pump is fixedly arranged on the third supporting rod;

5. The method for preparing and treating the efficient bacteriostatic textile material according to claim 3, wherein a fixed supporting rod is fixedly arranged at the bottom end of each of the first pasting roller and the second pasting roller, an elastic swing rod is hinged to the bottom end of the fixed supporting rod, a fixed limiting plate is arranged at the bottom end of the fixed supporting rod at each side, a first balance spring is fixedly arranged on the fixed limiting plate by the elastic swing rod, and a second balance spring is fixedly arranged at the other side of the elastic swing rod and the middle part of the fixed supporting rod.

6. The method for preparing and treating the high-efficiency antibacterial textile material as claimed in claim 3, wherein V-shaped third scrap shoveling blades are fixed at the bottom end of the elastic swing rod on each side of the textile material.

7. The efficient antibacterial textile material is characterized by comprising textile cloth, first adhesive cloth and second adhesive cloth, wherein the textile cloth is arranged in the middle layer, the first adhesive cloth is bonded on the top layer of the textile cloth, the second adhesive cloth is bonded on the top layer of the textile cloth, and the textile cloth is cotton cloth; the first adhesive cloth and the second adhesive cloth are non-woven fabrics with diamond net surfaces, wherein a bacteriostatic agent is doped in glue for adhesion, and the bonded textile cloth is immersed in the bacteriostatic agent box and drained to realize a bacteriostatic function.