CN112501851A - Processing equipment for high-wear-resistance breathable moisture-conducting fabric - Google Patents

Abstract

The invention relates to the technical field of textile fabric processing equipment, in particular to processing equipment for a high-wear-resistance breathable moisture-conducting fabric, which comprises: the heating pipe is arranged in the loading tank; the top sealing mechanism is arranged at the top of the containing tank, and the longitudinal moving mechanism is arranged on the top sealing mechanism; the stirring mechanism is arranged at the output end of the longitudinal moving mechanism, the feeding mechanism is arranged outside the containing tank, and the inside and the outside of the containing tank are communicated when the feeding mechanism is in a working state; the dehydration mechanism is arranged at the bottom of the containing tank, and the output end of the dehydration mechanism is positioned inside the containing tank; the output end of the drainage mechanism is communicated with the interior of the containing tank; hot-air drying mechanism, hot-air drying mechanism's output all sets up in top closing mechanism's output, and hot-air drying mechanism is used for blowing hot-air to the inside of holding the jar, and this technical scheme can carry out automatic dyeing, washing water and stoving to the surface fabric, has strengthened the practicality of equipment, has improved work efficiency greatly.

Description

Processing equipment for high-wear-resistance breathable moisture-conducting fabric

Technical Field

The invention relates to the technical field of textile fabric processing equipment, in particular to processing equipment for a high-wear-resistance breathable moisture-conducting fabric.

Background

Knitted fabrics include weft knitted fabrics and warp knitted fabrics according to the weaving method. The weft knitting fabric is usually made by taking low-elasticity polyester yarns or special-shaped polyester yarns, nylon yarns, cotton yarns, wool yarns and the like as raw materials and adopting plain stitch, changed plain stitch, rib plain stitch, double rib plain stitch, jacquard weave, terry stitch and the like to be knitted on various weft knitting machines;

the garment is made of fabric, and the fabric is used for making the garment. As one of the three elements of the garment, the fabric not only can explain the style and the characteristics of the garment, but also directly controls the expression effects of the color and the shape of the garment. Presents the advantages of high price and perfect self and soft hand feeling.

The material for making the appearance of the clothes is called as the clothes fabric. Garment making is generally divided into: the garment comprises a garment body, a garment body and a fabric, wherein the garment body is made of the fabric, lining materials and other auxiliary materials, and some garments do not have the lining materials, so the fabric is the most important garment body. The fabric usually accounts for more than 30% of the garment cost, so the quality of the garment fabric has great influence on the finished product.

Chinese patent: CN201710893668.7 discloses a processing technology of a high-wear-resistance breathable moisture-conductive fabric, which comprises the following steps: a. the selection of materials is as follows: selecting 18.45tex cotton yarn as warp, 2.22tex spandex and 2.22tex nylon filament mixed yarn as first weft and 5.56tex/72f polypropylene as second weft; b. weaving the cloth body: an 18.45tex cotton yarn: 2.22tex spandex and 2.22tex nylon filament mixed yarn: 5.56tex/72f polypropylene 65%: 6%: the proportion of 29% is woven by a knitting machine using a multilayer plating technique. The invention has the advantage of simple processing technology.

However, at present, no automatic processing equipment for dyeing, washing and drying in the patent is available, so that the processing equipment for the high-wear-resistance breathable moisture-conducting fabric needs to be provided, the fabric can be automatically dyed, washed and dried, the practicability of the equipment is enhanced, and the working efficiency is greatly improved.

Disclosure of Invention

In order to solve the technical problem, the processing equipment for the high-wear-resistance breathable moisture-conducting fabric is provided, the technical scheme can automatically dye, wash and dry the fabric, the practicability of the equipment is enhanced, and the working efficiency is greatly improved.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows:

the utility model provides a processing equipment of high wear-resisting ventilative wet surface fabric that leads, includes:

the heating pipe is arranged in the loading tank;

the top sealing mechanism is arranged at the top of the loading tank and is used for semi-sealing a feeding and discharging port at the top of the loading tank;

the longitudinal moving mechanism is arranged on the top closing mechanism;

the stirring mechanism is arranged at the output end of the longitudinal moving mechanism, the longitudinal moving mechanism is used for lowering the stirring mechanism into the containing tank, and the stirring mechanism is used for stirring the inside of the containing tank;

the feeding mechanism is arranged outside the containing tank, and the inside and the outside of the containing tank are communicated when the feeding mechanism is in a working state;

the dehydration mechanism is arranged at the bottom of the containing tank, and the output end of the dehydration mechanism is positioned inside the containing tank;

the output end of the drainage mechanism is communicated with the interior of the containing tank;

the output end of the hot air drying mechanism is arranged at the output end of the top sealing mechanism, and the hot air drying mechanism is used for blowing hot air to the inside of the containing tank.

Preferably, the top closure mechanism comprises:

the annular plate is positioned at the feed and discharge port at the top of the loading tank, and the longitudinal moving mechanism is arranged at the top of the annular plate;

the threaded rod and the guide rod are symmetrically arranged on two sides of the top of the containing tank, the threaded rod is rotatably connected with the containing tank, the guide rod is fixedly connected with the containing tank, the threaded rod penetrates through the annular plate and is in threaded connection with the annular plate, and the guide rod penetrates through the annular plate and is in sliding connection with the annular plate;

the first servo motor is arranged on the containing tank, and the output end of the first servo motor is connected with the threaded rod.

Preferably, the longitudinal moving mechanism includes:

the longitudinal frame is arranged at the top of the annular plate;

the first cylinder is arranged on the longitudinal frame;

the annular support sets up in the output of first cylinder, and rabbling mechanism sets up in the bottom of annular support, and the top symmetry of annular support is provided with the gag lever post, and the gag lever post runs through vertical frame and rather than sliding connection.

Preferably, the stirring mechanism includes:

the closing plate is arranged at the bottom of the annular support;

the second servo motor is arranged at the top of the sealing plate;

the stirring rod is arranged at the bottom of the sealing plate and is rotatably connected with the sealing plate, and the output end of the second servo motor is connected with the stirring rod.

Preferably, the feeding mechanism comprises:

the outer wall of the containing tank is provided with an opening, and the turnover plate is positioned at the opening;

the hinged seat is arranged outside the containing tank, and the bottom of the turnover plate is hinged with the hinged seat;

the stiff end of second cylinder is articulated with the outside of holding the jar, and the output of second cylinder is articulated with the stress end of returning face plate.

Preferably, the dehydration mechanism includes:

the water filtering cylinder is positioned inside the containing tank;

the top end of the driving rod is fixedly connected with the bottom of the water filtering cylinder, and the bottom end of the driving rod penetrates through the containing tank and is rotatably connected with the containing tank;

the rotary driving assembly is arranged at the bottom of the containing tank, and the output end of the rotary driving assembly is in transmission connection with the bottom end of the driving rod.

Preferably, the rotary drive assembly comprises:

the third servo motor is arranged at the bottom of the containing tank;

the first belt pulley is arranged at the output end of the third servo motor;

the second belt pulley sets up in the bottom of actuating lever, connects through belt transmission between first belt pulley and the second belt pulley.

Preferably, the drain mechanism includes:

the water valve is arranged at the water outlet below the containing tank;

one end of the water discharging pipe is connected with the water valve;

the other end of the water discharge pipe is connected with the output end of the water suction pump.

Preferably, the hot air drying mechanism includes:

a hot air blowing assembly for generating hot air;

the air inlet ends of the four air supply pipes are connected with the output end of the hot air blowing assembly;

and the air valves are respectively arranged at the air outlet ends of the four air supply pipes, and the four air supply pipes are arranged at four corners of the output end of the top sealing mechanism through the air valves.

Preferably, the hot wind blowing assembly includes:

one end of the air duct is opened and is connected with the air inlet ends of the four air supply pipes;

the other end of the air duct is hollowed, and the fourth servo motor is arranged at the hollowed part of the air duct;

the fan blade is positioned inside the air duct and arranged at the output end of the fourth servo motor;

the heating plate is arranged inside the air duct.

Compared with the prior art, the invention has the beneficial effects that: firstly, a worker places a cloth body which is manufactured in an output end of a dewatering mechanism, then cloth boiling liquid which is prepared by mixing a refining agent and a dispersing agent is added into a containing tank, a top sealing mechanism starts to work, the output end of the top sealing mechanism starts to descend and drives a stirring mechanism to enter the containing tank, a feed port and a discharge port of the containing tank are sealed through the top sealing mechanism and the stirring mechanism, a heating pipe is electrified and heats the inside of the containing tank to 95 ℃ for boiling cloth, and the cloth boiling time is 45-50 min; after a preset time, the longitudinal moving mechanism starts to work, the output end of the longitudinal moving mechanism pulls the stirring mechanism to rise, so that a material inlet and a material outlet of the loading tank are in a semi-closed state, the raw materials in the loading tank are placed still, when the cloth body is cooled to normal temperature, the longitudinal moving mechanism seals the material inlet and the material outlet of the loading tank through the stirring mechanism again, the feeding mechanism starts to work, a worker adds dyeing liquid into a dye machine through a communication part of the interior of the loading tank, the interior of the loading tank is heated to 45 ℃ at the speed of 7 ℃/min through a heating pipe, the temperature is continuously kept for 10-20min to color the cloth body, the drainage mechanism starts to work, the drainage mechanism discharges water in the loading tank, deionized water is added into the loading tank through a communication port opened by the feeding mechanism, a neutralizer is added into the water, the stirring mechanism starts to work, the stirring mechanism stirs the cloth body in the dehydration mechanism for 20min, heating to 100 ℃ at the speed of 5 ℃/min through a heating pipe, preserving heat for 30min, standing, opening a semi-closed opening for cooling, adding a hydrophilic agent into the containing tank through a communication opening opened by a feeding mechanism, standing for 10-15min, discharging liquid in the containing tank through a drainage mechanism, starting a dewatering mechanism to work, driving a cloth body to spin-dry by an output end of the dewatering mechanism, starting a hot air drying mechanism to work, heating the inside of the containing tank by the output end of the hot air drying mechanism for 40min, opening the top of the containing tank into a semi-closed state in the process so as to ventilate, and cooling to obtain the high-wear-resistance breathable moisture-conductive fabric after preset time;

1. through the arrangement of the top closing mechanism, the longitudinal moving mechanism and the stirring mechanism, semi-closing and full-closing can be carried out according to different working modes, and stirring work can be carried out;

2. through the arrangement of the equipment, the fabric can be automatically dyed, washed and dried, the practicability of the equipment is enhanced, and the working efficiency is greatly improved.

Drawings

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

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

FIG. 3 is a front view of the holding tank, top closure mechanism, longitudinal movement mechanism, feed mechanism and dewatering mechanism of the present invention;

FIG. 4 is a schematic perspective view of the first embodiment of the present invention;

FIG. 5 is a schematic view showing the internal structure of the holding tank, the top closing mechanism, the longitudinal moving mechanism, the feeding mechanism and the dehydrating mechanism of the present invention;

FIG. 6 is a schematic perspective view of the second embodiment of the present invention showing the structure of the loading tank, the top closing mechanism, the longitudinal moving mechanism, the feeding mechanism and the dewatering mechanism;

FIG. 7 is a side view of the holding tank, top closure mechanism, longitudinal movement mechanism, feed mechanism and dewatering mechanism of the present invention;

FIG. 8 is a front view of the present invention;

FIG. 9 is a schematic perspective view of the second embodiment of the present invention;

fig. 10 is a schematic view of an internal structure of the hot wind blowing module according to the present invention.

The reference numbers in the figures are:

1-a containing tank; 1 a-heating tube;

2-a top closure mechanism; 2 a-an annular plate; 2 b-a threaded rod; 2 c-a guide bar; 2 d-a first servo motor;

3-a longitudinal moving mechanism; 3 a-a longitudinal frame; 3 b-a first cylinder; 3 c-a ring-shaped scaffold; 3c 1-stop lever;

4-a stirring mechanism; 4 a-closing plate; 4 b-a second servo motor; 4 c-a stirring rod;

5-a feeding mechanism; 5 a-a turnover plate; 5 b-a hinged seat; 5 c-a second cylinder;

6-a dewatering mechanism; 6 a-a water filtering cylinder; 6 b-a drive rod; 6 c-a rotary drive assembly; 6c 1-third servomotor; 6c2 — first pulley; 6c 3-second pulley;

7-a drainage mechanism; 7 a-a water valve; 7 b-a drain pipe; 7 c-a water pump;

8-a hot air drying mechanism; 8 a-a hot air blowing assembly; 8a 1-wind cone; 8a 2-fourth servomotor; 8a 3-leaf; 8a 4-hot plate; 8 b-a blast pipe; 8 c-gas valve.

Detailed Description

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

Referring to fig. 1 to 2, a processing device for a high wear-resistant breathable moisture-conductive fabric comprises:

the device comprises a containing tank 1, wherein a heating pipe 1a is arranged inside the containing tank 1;

the top sealing mechanism 2 is arranged at the top of the containing tank 1, and the top sealing mechanism 2 is used for semi-sealing a feeding and discharging port at the top of the containing tank 1;

the longitudinal moving mechanism 3 is arranged on the top closing mechanism 2;

the stirring mechanism 4 is arranged at the output end of the longitudinal moving mechanism 3, the longitudinal moving mechanism 3 is used for lowering the stirring mechanism 4 into the containing tank 1, and the stirring mechanism 4 is used for stirring the inside of the containing tank 1;

the feeding mechanism 5 is arranged outside the containing tank 1, and when the feeding mechanism 5 is in a working state, the inside and the outside of the containing tank 1 are communicated;

the dehydration mechanism 6 is arranged at the bottom of the containing tank 1, and the output end of the dehydration mechanism 6 is positioned inside the containing tank 1;

the output end of the drainage mechanism 7 is communicated with the interior of the containing tank 1;

the output end of each hot air drying mechanism 8 is arranged at the output end of the top sealing mechanism 2, and the hot air drying mechanisms 8 are used for blowing hot air to the interior of the containing tank 1;

firstly, a worker places a cloth body which is manufactured in an output end of a dewatering mechanism 6, then a cloth boiling liquid which is prepared by mixing a refining agent and a dispersing agent is added into a containing tank 1, a top sealing mechanism 2 starts to work, the output end of the top sealing mechanism 2 starts to descend and drives a stirring mechanism 4 to enter the containing tank 1, a material inlet and a material outlet of the containing tank 1 are sealed through the top sealing mechanism 2 and the stirring mechanism 4, a heating pipe 1a is electrified and heats the inside of the containing tank 1 to 95 ℃ for boiling cloth, and the cloth boiling time is 45-50 min; after a preset time, the longitudinal moving mechanism 3 starts to work, the output end of the longitudinal moving mechanism 3 pulls the stirring mechanism 4 to rise so that the material inlet and outlet of the containing tank 1 is in a semi-closed state, the raw materials in the containing tank 1 are kept standing, when the cloth body is cooled to normal temperature, the longitudinal moving mechanism 3 seals the material inlet and outlet of the containing tank 1 through the stirring mechanism 4 again, the feeding mechanism 5 starts to work, a worker adds dyeing liquid into the dyeing machine through a communication part with the inside of the containing tank 1, the inside of the containing tank 1 is heated to 45 ℃ at the speed of 7 ℃/min through the heating pipe 1a, the cloth body is continuously colored at the temperature of 10-20min, the drainage mechanism 7 starts to work, the drainage mechanism 7 discharges the water in the containing tank 1, deionized water is added into the containing tank 1 through the communication port opened by the feeding mechanism 5, and a neutralizer is added into the water, the stirring mechanism 4 starts to work, after the stirring mechanism 4 stirs the cloth body in the dewatering mechanism 6 for 20min, the temperature is raised to 100 ℃ at the speed of 5 ℃/min through the heating pipe 1a, the temperature is kept for 30min, then the cloth body is stood and cooled by opening the semi-closed opening, then the hydrophilic agent is added into the loading tank 1 through the communication opening opened by the feeding mechanism 5, the standing is carried out for 10-15min, the liquid in the loading tank 1 is discharged through the drainage mechanism 7, the dewatering mechanism 6 starts to work, the cloth body is driven by the output end of the dewatering mechanism 6 to be dried, the hot air drying mechanism 8 starts to work, the temperature of the interior of the loading tank 1 is raised by the output end of the hot air drying mechanism 8, the drying time is 40min, in the process, the top of the loading tank 1 is opened to be in a semi-closed state so as to ventilate, and after the preset.

The top closure 2 as shown in fig. 3 comprises:

the annular plate 2a is positioned at a feeding and discharging port at the top of the loading tank 1, and the longitudinal moving mechanism 3 is arranged at the top of the annular plate 2 a;

the screw rod 2b and the guide rod 2c are symmetrically arranged on two sides of the top of the containing tank 1, the screw rod 2b is rotatably connected with the containing tank 1, the guide rod 2c is fixedly connected with the containing tank 1, the screw rod 2b penetrates through the annular plate 2a and is in threaded connection with the annular plate, and the guide rod 2c penetrates through the annular plate 2a and is in sliding connection with the annular plate 2 a;

the first servo motor 2d is arranged on the containing tank 1, and the output end of the first servo motor 2d is connected with the threaded rod 2 b;

the top closing mechanism 2 starts to work, the output end of the first servo motor 2d drives the annular plate 2a to descend through the threaded rod 2b, the annular plate 2a drives the stirring mechanism 4 to enter the containing tank 1, and the guide rod 2c is used for guiding the moving direction of the annular plate 2 a.

The longitudinal movement mechanism 3 shown in fig. 3 and 4 includes:

a longitudinal frame 3a arranged on the top of the annular plate 2 a;

a first cylinder 3b provided on the vertical frame 3 a;

the annular support 3c is arranged at the output end of the first cylinder 3b, the stirring mechanism 4 is arranged at the bottom of the annular support 3c, the top of the annular support 3c is symmetrically provided with limiting rods 3c1, and the limiting rods 3c1 penetrate through the longitudinal rack 3a and are in sliding connection with the longitudinal rack;

the longitudinal moving mechanism 3 starts to work, the output end of the first air cylinder 3b pulls the stirring mechanism 4 to rise through the annular support 3c, at the moment, the top of the loading tank 1 is in a semi-closed state through the annular plate 2a, the limiting rod 3c1 is used for guiding the moving direction of the annular support 3c, and the longitudinal frame 3a is used for fixing and supporting.

As shown in fig. 5, the stirring mechanism 4 includes:

a closing plate 4a arranged at the bottom of the annular support 3 c;

the second servo motor 4b is arranged at the top of the sealing plate 4 a;

the stirring rod 4c is arranged at the bottom of the sealing plate 4a and is rotatably connected with the sealing plate, and the output end of the second servo motor 4b is connected with the stirring rod 4 c;

when shrouding 4a closed the mesopore department of annular plate 2a, the business turn over material mouth of containing jar 1 seals, when shrouding 4a left the mesopore department to annular plate 2a, the business turn over material mouth of containing jar 1 was in semi-closed, and the output of second servo motor 4b drives puddler 4c and rotates, and puddler 4c stirs the inside of containing jar 1.

As shown in fig. 7, the feed mechanism 5 includes:

the outer wall of the containing tank 1 is provided with an opening, and the turnover plate 5a is positioned at the opening;

the hinged seat 5b is arranged outside the containing tank 1, and the bottom of the turnover plate 5a is hinged with the hinged seat 5 b;

the fixed end of the second cylinder 5c is hinged with the outside of the loading tank 1, and the output end of the second cylinder 5c is hinged with the stressed end of the turnover plate 5 a;

the feeding mechanism 5 starts to work, the output end of the second cylinder 5c contracts and drives the turnover plate 5a to turn over, the turnover plate 5a turns over outwards and opens the opening, and the hinged seat 5b is used for fixing and supporting.

As shown in fig. 6, the dewatering mechanism 6 includes:

a water filtering cylinder 6a positioned inside the containing tank 1;

the top end of the driving rod 6b is fixedly connected with the bottom of the water filtering cylinder 6a, and the bottom end of the driving rod 6b penetrates through the containing tank 1 and is rotatably connected with the containing tank;

the rotary driving component 6c is arranged at the bottom of the loading tank 1, and the output end of the rotary driving component 6c is in transmission connection with the bottom end of the driving rod 6 b;

the dewatering mechanism 6 starts to work, the output end of the rotary driving component 6c drives the driving rod 6b to rotate, the driving rod 6b drives the driving rod 6b to rotate, and the driving rod 6b enables the cloth body to be dewatered in the rotating process.

The rotary drive assembly 6c shown in fig. 6 includes:

a third servo motor 6c1 arranged at the bottom of the loading tank 1;

a first belt pulley 6c2 arranged at the output end of the third servo motor 6c 1;

the second belt pulley 6c3 is arranged at the bottom end of the driving rod 6b, and the first belt pulley 6c2 is in transmission connection with the second belt pulley 6c3 through a belt;

the rotary driving assembly 6c starts to work, the output end of the third servo motor 6c1 drives the first belt pulley 6c2 to rotate, the first belt pulley 6c2 drives the second belt pulley 6c3 to rotate through the belt, and the second belt pulley 6c3 drives the driving rod 6b to rotate.

As shown in fig. 8, the drainage mechanism 7 includes:

the water valve 7a is arranged at the water outlet below the containing tank 1;

one end of the water discharge pipe 7b is connected with the water valve 7 a;

the other end of the water suction pump 7c and the water discharge pipe 7b are connected with the output end of the water suction pump 7 c;

the water valve 7a is opened, and the water pump 7c pumps out the liquid in the carrying tank 1 through the water outlet pipe 7 b.

As shown in fig. 9, the hot air drying mechanism 8 includes:

a hot air blowing unit 8a for generating hot air;

the number of the air supply pipes 8b is four, and the air inlet ends of the four air supply pipes 8b are connected with the output end of the hot air blowing component 8 a;

the air valves 8c are respectively arranged at the air outlet ends of the four air supply pipes 8b, and the four air supply pipes 8b are arranged at four corners of the output end of the top closing mechanism 2 through the air valves 8 c;

the hot air drying mechanism 8 starts to work, the air valve 8c is opened, the hot air blowing assembly 8a continuously blows hot air to the inside of the containing tank 1 through the four air supply pipes 8b, and the cloth body is dried through the hot air.

The hot wind blowing module 8a as shown in fig. 10 includes:

an air duct 8a1, wherein one end of the air duct 8a1 is opened and is connected with the air inlet ends of four air supply pipes 8 b;

the other end of the air duct 8a1 is hollowed out by a fourth servo motor 8a2, and the fourth servo motor 8a2 is arranged at the hollowed part of the air duct 8a 1;

the fan blade 8a3 is positioned inside the air duct 8a1, and the fan blade 8a3 is arranged at the output end of the fourth servo motor 8a 2;

a hot plate 8a4 disposed inside the air duct 8a 1;

the hot air blowing assembly 8a starts to work, the heating plate 8a4 is electrified and starts to generate heat, the output end of the fourth servo motor 8a2 drives the fan blades 8a3 to rotate so as to generate air flow, and the air flow drives the hot air generated by the heating plate 8a4 to enter the four air supply pipes 8b along the guide of the air duct 8a1 and then to be blown into the loading tank 1 through the four air supply pipes 8 b.

The working principle of the invention is as follows: firstly, a worker places a cloth body which is manufactured in a water filtering cylinder 6a, then a cloth boiling liquid which is prepared by mixing a refining agent and a dispersing agent is added into a containing tank 1, a top sealing mechanism 2 starts to work, the output end of the top sealing mechanism 2 starts to descend and drives a stirring rod 4c to enter the containing tank 1, a material inlet and a material outlet of the containing tank 1 are sealed through an annular plate 2a and a sealing plate 4a, a heating pipe 1a is electrified and heats the inside of the containing tank 1 to 95 ℃ for boiling cloth, and the cloth boiling time is 45-50 min; after the preset time, the longitudinal moving mechanism 3 starts to work, the output end of the first cylinder 3b pulls the stirring mechanism 4 to rise through the annular support 3c, at the moment, the top of the containing tank 1 is in a semi-closed state through the annular plate 2a, the raw materials in the containing tank 1 are kept standing, when the cloth body is cooled to the normal temperature, the longitudinal moving mechanism 3 seals the material inlet and the material outlet of the containing tank 1 through the stirring mechanism 4 again, the feeding mechanism 5 starts to work, the output end of the second cylinder 5c shrinks and drives the turnover plate 5a to turn over, the turnover plate 5a turns over outwards and opens the opening, a worker adds dyeing liquid into the dyeing machine through the opening, the inside of the containing tank 1 is heated to 45 ℃ at the speed of 7 ℃/min through the heating pipe 1a, the cloth body is continuously kept at the temperature for 10-20min to be dyed, the water valve 7a is opened, the water pump 7c pumps out the liquid in the containing tank 1 through the water drain pipe 7, deionized water is added into the loading tank 1 through a communication port opened by a feeding mechanism 5, a neutralizing agent is added into the water, a stirring mechanism 4 starts to work, an output end of a second servo motor 4b drives a stirring rod 4c to rotate, the stirring rod 4c stirs the cloth in the water filtering cylinder 6a for 20min, the temperature is raised to 100 ℃ at the speed of 5 ℃/min through a heating pipe 1a, the temperature is kept for 30min, then the stirring rod is stood and is opened to form a semi-closed port for cooling, then a hydrophilic agent is added into the loading tank 1 through the communication port opened by the feeding mechanism 5, the stirring rod is stood for 10-15min, the liquid in the loading tank 1 is discharged through a drainage mechanism 7, a dewatering mechanism 6 starts to work, an output end of a rotary driving component 6c drives a driving rod 6b to rotate, the driving rod 6b drives a driving rod 6b to rotate, and the driving rod 6b enables the cloth to, the hot air blowing assembly 8a starts to work, the heating plate 8a4 is electrified and starts to generate heat, the output end of the fourth servo motor 8a2 drives the fan blades 8a3 to rotate to enable the fan blades to generate air flow, the air flow drives the hot air generated by the heating plate 8a4 to enter the four air supply pipes 8b along the guide of the air duct 8a1, the hot air is blown into the containing tank 1 through the four air supply pipes 8b, the temperature inside the containing tank 1 rises, the drying time is 40min, the top of the containing tank 1 is opened in a semi-closed state in the process so as to be breathable, and after the preset time, the high-wear-resistance breathable moisture-conductive fabric is obtained through cooling.

The device realizes the functions of the invention through the following steps, thereby solving the technical problems provided by the invention:

firstly, placing the manufactured cloth body in an output end of a dewatering mechanism 6 by a worker, and then adding a cloth boiling liquid prepared by mixing a refining agent and a dispersing agent into a containing tank 1;

step two, the top closing mechanism 2 starts to work, the output end of the top closing mechanism 2 starts to descend and drives the stirring mechanism 4 to enter the interior of the containing tank 1, and the feeding and discharging port of the containing tank 1 is closed through the top closing mechanism 2 and the stirring mechanism 4;

thirdly, electrifying the heating pipe 1a, heating the inside of the containing tank 1 to 95 ℃ and boiling the cloth, wherein the cloth boiling time is 45-50 min;

fourthly, the longitudinal moving mechanism 3 starts to work, the output end of the longitudinal moving mechanism 3 pulls the stirring mechanism 4 to rise, so that the material inlet and the material outlet of the containing tank 1 are in a semi-closed state, the raw materials in the containing tank 1 are kept stand, and the cloth body is cooled to the normal temperature;

fifthly, the longitudinal moving mechanism 3 seals the material inlet and the material outlet of the loading tank 1 through the stirring mechanism 4 again, the feeding mechanism 5 starts to work, and a worker adds dyeing liquid into the dye machine through a communication part between the longitudinal moving mechanism and the inside of the loading tank 1;

step six, heating the interior of the containing tank 1 to 45 ℃ at the speed of 7 ℃/min through a heating pipe 1a, and continuously keeping the temperature for 10-20min to color the cloth body;

seventhly, the drainage mechanism 7 starts to work, the drainage mechanism 7 discharges water in the loading tank 1, deionized water is added into the loading tank 1 through a communication port opened by the feeding mechanism 5, and a neutralizer is added into the water;

step eight, the stirring mechanism 4 starts to work, after the stirring mechanism 4 stirs the cloth body positioned in the dehydration mechanism 6 for 20min, the temperature is raised to 100 ℃ at the speed of 5 ℃/min through the heating pipe 1a, the temperature is preserved for 30min, then the mixture is stood, the semi-closed opening is opened for cooling, then the hydrophilic agent is added into the loading tank 1 through the communication opening opened by the feeding mechanism 5, and the mixture is stood for 10-15 min;

step nine, discharging the liquid in the containing tank 1 through a drainage mechanism 7, starting a dewatering mechanism 6 to work, and driving the cloth body to be dried through an output end of the dewatering mechanism 6;

step ten, the hot air drying mechanism 8 starts to work, the output end of the hot air drying mechanism 8 heats the interior of the containing tank 1, the drying time is 40min, the top of the containing tank 1 is opened to be in a semi-closed state in the process so as to be breathable, and after the preset time, the high-wear-resistance breathable moisture-conductive fabric is obtained through cooling.

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

Claims (10)

1. The utility model provides a processing equipment of high wear-resisting ventilative wet surface fabric that leads which characterized in that includes:

the device comprises a containing tank (1), wherein a heating pipe (1 a) is arranged in the containing tank (1);

the top sealing mechanism (2) is arranged at the top of the containing tank (1), and the top sealing mechanism (2) is used for semi-sealing a feeding and discharging port at the top of the containing tank (1);

the longitudinal moving mechanism (3) is arranged on the top closing mechanism (2);

the stirring mechanism (4) is arranged at the output end of the longitudinal moving mechanism (3), the longitudinal moving mechanism (3) is used for lowering the stirring mechanism (4) into the containing tank (1), and the stirring mechanism (4) is used for stirring the inside of the containing tank (1);

the feeding mechanism (5) is arranged outside the containing tank (1), and when the feeding mechanism (5) is in a working state, the inside and the outside of the containing tank (1) are communicated;

the dehydration mechanism (6) is arranged at the bottom of the containing tank (1), and the output end of the dehydration mechanism (6) is positioned inside the containing tank (1);

the output end of the drainage mechanism (7) is communicated with the interior of the containing tank (1);

the hot air drying mechanism (8) is arranged at the output end of the top sealing mechanism (2), and the output end of the hot air drying mechanism (8) is arranged at the output end of the top sealing mechanism (2), and the hot air drying mechanism (8) is used for blowing hot air into the containing tank (1).

2. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 1, wherein the top closing mechanism (2) comprises:

the annular plate (2 a) is positioned at a feeding and discharging port at the top of the loading tank (1), and the longitudinal moving mechanism (3) is arranged at the top of the annular plate (2 a);

the novel container comprises a threaded rod (2 b) and a guide rod (2 c), wherein the threaded rod (2 b) and the guide rod (2 c) are symmetrically arranged on two sides of the top of a containing tank (1), the threaded rod (2 b) is rotatably connected with the containing tank (1), the guide rod (2 c) is fixedly connected with the containing tank (1), the threaded rod (2 b) penetrates through an annular plate (2 a) and is in threaded connection with the annular plate, and the guide rod (2 c) penetrates through the annular plate (2 a) and is in sliding connection with the annular plate;

the first servo motor (2 d) is arranged on the containing tank (1), and the output end of the first servo motor (2 d) is connected with the threaded rod (2 b).

3. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 2, wherein the longitudinal moving mechanism (3) comprises:

a longitudinal frame (3 a) arranged on the top of the annular plate (2 a);

a first cylinder (3 b) arranged on the longitudinal frame (3 a);

annular support (3 c), set up in the output of first cylinder (3 b), rabbling mechanism (4) set up in the bottom of annular support (3 c), and the top symmetry of annular support (3 c) is provided with gag lever post (3 c 1), and gag lever post (3 c 1) run through vertical frame (3 a) and rather than sliding connection.

4. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 3, wherein the stirring mechanism (4) comprises:

a sealing plate (4 a) arranged at the bottom of the annular bracket (3 c);

the second servo motor (4 b) is arranged at the top of the sealing plate (4 a);

and the stirring rod (4 c) is arranged at the bottom of the sealing plate (4 a) and is rotatably connected with the sealing plate, and the output end of the second servo motor (4 b) is connected with the stirring rod (4 c).

5. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 1, wherein the feeding mechanism (5) comprises:

the outer wall of the containing tank (1) is provided with an opening, and the turnover plate (5 a) is positioned at the opening;

the hinged seat (5 b) is arranged outside the containing tank (1), and the bottom of the turnover plate (5 a) is hinged with the hinged seat (5 b);

the fixed end of the second cylinder (5 c) is hinged with the outside of the containing tank (1), and the output end of the second cylinder (5 c) is hinged with the stressed end of the turnover plate (5 a).

6. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 1, wherein the dewatering mechanism (6) comprises:

a water filtering cylinder (6 a) positioned inside the containing tank (1);

the top end of the driving rod (6 b) is fixedly connected with the bottom of the water filtering cylinder (6 a), and the bottom end of the driving rod (6 b) penetrates through the containing tank (1) and is rotatably connected with the containing tank;

the rotary driving component (6 c) is arranged at the bottom of the containing tank (1), and the output end of the rotary driving component (6 c) is in transmission connection with the bottom end of the driving rod (6 b).

7. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 6, wherein the rotary driving assembly (6 c) comprises:

a third servo motor (6 c 1) arranged at the bottom of the containing tank (1);

the first belt pulley (6 c 2) is arranged at the output end of the third servo motor (6 c 1);

and the second belt pulley (6 c 3) is arranged at the bottom end of the driving rod (6 b), and the first belt pulley (6 c 2) is in transmission connection with the second belt pulley (6 c 3) through a belt.

8. The processing equipment of the high-wear-resistance breathable moisture-conductive fabric according to claim 1, wherein the drainage mechanism (7) comprises:

the water valve (7 a) is arranged at the water outlet below the containing tank (1);

the water discharging pipe (7 b), one end of the water discharging pipe (7 b) is connected with the water valve (7 a);

the other end of the water suction pump (7 c) and the water discharge pipe (7 b) are connected with the output end of the water suction pump (7 c).

9. The processing equipment of the high-wear-resistance breathable moisture-conductive fabric according to claim 1, wherein the hot air drying mechanism (8) comprises:

a hot air blowing unit (8 a) for generating hot air;

the number of the air supply pipes (8 b) is four, and the air inlet ends of the four air supply pipes (8 b) are connected with the output end of the hot air blowing assembly (8 a);

and the air valves (8 c) are respectively arranged at the air outlet ends of the four air supply pipes (8 b), and the four air supply pipes (8 b) are arranged at four corners of the output end of the top closing mechanism (2) through the air valves (8 c).

10. The processing equipment for the high-wear-resistance breathable moisture-conductive fabric according to claim 9, wherein the hot air blowing assembly (8 a) comprises:

the air duct (8 a 1), one end of the air duct (8 a 1) is open and is connected with the air inlet ends of the four air supply pipes (8 b);

the other end of the air duct (8 a 1) is hollowed out by a fourth servo motor (8 a 2), and the fourth servo motor (8 a 2) is arranged at the hollowed-out position of the air duct (8 a 1);

the fan blade (8 a 3) is positioned inside the air duct (8 a 1), and the fan blade (8 a 3) is arranged at the output end of the fourth servo motor (8 a 2);

and a heating plate (8 a 4) disposed inside the air duct (8 a 1).

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