CN114750474A - Comfortable warm keeping sweater fabric, preparation method thereof and dyeing device - Google Patents

Abstract

The application relates to the technical field of textile fabrics, in particular to a comfortable and warm keeping sweater fabric, a preparation method thereof and a dyeing device. A comfortable and warm keeping sweater fabric comprises an external contact layer, a middle connecting layer and an internal warm keeping layer which are sequentially arranged from outside to inside, wherein the external contact layer is made of combed cotton yarn, the middle connecting layer is made of DTY, the internal warm keeping layer is made of imitative polar bear hair-Thermolite, and fluff is arranged inside the internal warm keeping layer. The comfortable and warm keeping sweater fabric has the advantages of being breathable, warm keeping and light.

Description

Comfortable warm keeping sweater fabric, preparation method thereof and dyeing device

Technical Field

The application relates to the technical field of textile fabrics, in particular to a comfortable and warm keeping sweater fabric, a preparation method thereof and a dyeing device.

Background

Along with the improvement of the quality of life, the requirement of people on heat preservation in cold weather is higher and higher, and therefore, the heat preservation effect of the fabric gradually becomes a more important point for attracting consumers to purchase. At present, common thermal fabrics in the market comprise three types of pure cotton fabrics, fibrous thermal fabrics and space cotton thermal fabrics.

Wherein, the pure cotton surface fabric is soft and ventilative, consequently possesses comparatively good comfort level, but warmth retention property is relatively poor. The animal fluff is added into the fibrous thermal fabric in an interlayer mode, so that the thermal performance of the fibrous thermal fabric is effectively improved on the premise of ensuring the air permeability, but the fibrous thermal fabric is relatively overstaffed when being worn. The space cotton thermal fabric is plated with the metal film in an interlayer mode, so that the thermal performance is improved, but the air permeability of the space cotton thermal fabric is poor.

Therefore, the applicant thinks that a thermal fabric with the characteristics of ventilation, heat preservation and portability needs to be found urgently in the market at present.

Disclosure of Invention

In order to overcome the defect that the warm keeping fabric is difficult to have the characteristics of ventilation, warm keeping and portability, the application provides a comfortable warm keeping sweater fabric, a preparation method thereof and a dyeing device.

In a first aspect, the application provides a comfortable and warm keeping sweater fabric, which adopts the following technical scheme:

a comfortable and warm keeping sweater fabric comprises an external contact layer, a middle connecting layer and an internal warm keeping layer which are sequentially arranged from outside to inside, wherein the external contact layer is made of combed cotton yarn, the middle connecting layer is made of DTY, the internal warm keeping layer is made of imitative polar bear hair-Thermolite, and fluff is arranged inside the internal warm keeping layer.

Because the external contact layer is made of the combed cotton yarn, the comfortable and warm keeping sweater fabric has the characteristics of excellent air permeability, glossiness and softness of the combed cotton yarn, electrostatic adsorption prevention and pilling and fuzzing prevention. Because the middle connecting layer is made of DTY, the comfortable warm keeping sweater fabric has excellent elasticity and elasticity of DTY. Because the inner warm-keeping layer is made of imitative polar bear hair-Thermolite, the comfortable warm-keeping underwear fabric has the characteristic of portability on the premise of ensuring excellent warm-keeping performance. In addition, the arrangement of the fluff of the inner thermal layer can further improve the thermal effect of the comfortable thermal sweater fabric.

In a second aspect, the application provides a preparation method of a comfortable and warm keeping sweater fabric, which adopts the following technical scheme: a preparation method of comfortable and warm keeping sweater fabric comprises the following steps:

s1, weaving the combed cotton yarn, the DTY and the Arctic bear hair-Thermolite from outside to inside to form a thermal fabric base material with an external contact layer, a middle connecting layer and an internal thermal layer;

s2, carrying out napping treatment on the inner wall of the inner warm-keeping layer through a light napping process to form a warm-keeping fabric preparation material with fluff;

s3, adding a warm-keeping auxiliary agent into the coloring agent, and then dyeing the warm-keeping fabric preparation material to obtain the comfortable warm-keeping sanitary garment fabric.

By adopting the technical scheme, the light napping process can effectively reduce the possibility that the warmth retention performance of the Arctic bear-Thermolite is damaged due to napping, so that the warmth retention performance of the comfortable warm-keeping sweater fabric is indirectly improved. In addition, the light napping process can also promote the fluff to be denser and has a better anti-hair-slip effect. Moreover, the addition of the warm-keeping auxiliary agent can promote the comfortable warm-keeping sweater fabric to have more excellent warm-keeping performance.

Preferably, the light napping process adopts four napping, the cloth speed is 32-36m/min, the tension of a cloth guide roller is 10-14%, and the rotation speed of a needle roller is 6-10 r/min.

By adopting the technical scheme, the following experimental data show that when the light napping process is adopted, the comfortable and warm-keeping sweater fabric has better warm-keeping performance, and the reason for the light napping process is that the comfortable and warm-keeping sweater fabric can be promoted to form more fluff, and the possibility of hair falling of the Arctic bear-Thermolite is effectively reduced.

Preferably, the addition amount of the thermal insulation auxiliary agent is 0.5-1.5 g/L.

By adopting the technical scheme, the experiments show that when the gradual addition amount of warm keeping is in the range, the comfortable warm keeping sweater fabric can have better warm keeping performance, and meanwhile, the addition amount of the warm keeping auxiliary agent can be effectively reduced, so that the cost is reduced.

Preferably, the heat-insulating auxiliary agent is one or a mixture of more of Queenlight HT-B, HOLPOSON HOT and medical stone powder.

Preferably, the heat-preservation auxiliary agent is Queenlight HT-B.

The Queenlight HT-B is a heat-preservation auxiliary agent which can convert visible light, far infrared light and the like of sunlight into heat, and has the effects of temperature sensing and heat storage in the forms of heat storage and heat preservation to improve the heat preservation performance.

The HOLPOSON HOT is a warm-keeping auxiliary agent which can make steam around the fabric condense into water drops to generate condensation heat, so that retina feels warm, and further the functions of heat storage and warm keeping are achieved.

The medical stone contains a large amount of zircon, and the zircon can release alpha rays or infrared rays, so that the medical stone has the effects of temperature sensing and heat storage.

Compared with the single use of HOLPOSON HOT and medical stone powder or the random combination of the three materials, the single use of Queenlight HT-B can promote the comfortable and warm keeping sweater fabric to have more excellent warm keeping performance.

The third aspect, this application provides a dyeing apparatus of comfortable cold-proof sweater surface fabric, adopts following technical scheme: a dyeing device for comfortable and warm keeping sweater fabrics comprises a dyeing tank, a cloth feeding component, a guiding component and a traction component, wherein the cloth feeding component is arranged at one end of the dyeing tank, the traction component is arranged at the other end of the dyeing tank, the guiding component is arranged in the dyeing tank, and the guiding component is positioned between the cloth feeding component and the traction component;

the guide assembly comprises a first guide part and a second guide part, wherein the first guide part comprises a first guide bracket fixedly connected to the bottom of the dyeing tank and a plurality of first guide rollers rotatably connected to the first guide bracket; the second guide piece comprises a lifting cylinder fixedly connected to the top of the dyeing tank, a second guide support fixedly connected to a piston rod of the lifting cylinder and a plurality of second guide rollers rotatably connected to the second guide support, and the plurality of first guide rollers and the plurality of second guide rollers are mutually staggered to form a wavy guide channel;

the second guide support comprises a support part fixedly connected to a piston rod of the lifting cylinder, an elastic part arranged on the support part and a vibrating machine arranged on the elastic part, and the second guide roller is rotatably connected to the elastic part.

By adopting the technical scheme, when dyeing operation needs to be carried out on the comfortable and warm-keeping sweater fabric, a worker can place the undyed comfortable and warm-keeping sweater fabric at the cloth feeding assembly, and then the end part of the comfortable and warm-keeping sweater fabric penetrates through the dyeing tank and is connected with the traction assembly.

Then, the worker can open the lifting cylinder, the lifting cylinder forces the first guide roller and the second guide roller to be mutually staggered and form a wavy guide channel through the second guide support, so that the comfortable and warm-keeping sweater fabric is completely immersed in the dyeing tank, the dyeing distance is prolonged, then the traction assembly can drive the comfortable and warm-keeping sweater fabric to gradually advance, and further the comprehensive dyeing operation of the comfortable and warm-keeping sweater fabric is completed.

And at the in-process that dyes comfortable cold-proof sweater surface fabric, the bobbing machine can also force first guide roller to take place to last the shake to impel first guide roller ejection of compact to rock outside the dyeing agent in the dyeing pond, first guide roller can also impel dyeing agent and comfortable cold-proof sweater surface fabric contact more even through shaking, effectively improves dyeing efficiency.

Preferably, the side wall of the supporting part is provided with a first contact, the wall of the dyeing tank is provided with a second contact, and when the first contact is communicated with the second contact, the vibrator operates.

When first guide roller submergence totally in the dyeing pond, first contact and second contact interconnect to impel the bobbing machine operation, effectively reduce the bobbing machine and open in advance or still the possibility of operation when first guide roller breaks away from the dyeing pond, the condition that indirectly reduces the coloring agent and splashes takes place, indirectly improves the dyeing environment.

Preferably, the cloth feeding assembly comprises a transfer plate, a fabric transfer piece and a fabric conveying piece, wherein a transfer connecting block is arranged on the side wall of the transfer plate, a transfer connecting groove is formed in the transfer connecting block, and a locking clamp used for clamping comfortable and warm-keeping sweater fabric is connected in the transfer connecting groove in a sliding manner;

the fabric transfer piece comprises a transfer cylinder fixedly connected to one end of the transfer plate, which is far away from the dyeing tank, a push plate fixedly connected to a piston rod of the transfer cylinder, and a material placing plate fixedly connected to the dyeing tank, wherein a supporting plate is arranged at one end of the material placing plate, which is far away from the transfer cylinder, a placing column for sleeving comfortable and warm-keeping sweater fabric is arranged on the supporting plate, a placing hole is formed in one side of the push plate, which is far away from the transfer cylinder, the placing column is inserted into the placing hole, a material placing connecting block is arranged on the supporting plate, a material placing connecting groove for a locking clamp to slide in a reciprocating manner is formed in the material placing connecting block, and the material placing connecting groove is communicated with the transfer connecting groove;

the fabric conveying piece comprises a sliding block, a clamping cylinder and a locking block, the clamping cylinder is arranged on the sliding block, the locking block is arranged on a piston rod of the clamping cylinder, and a clamping space for clamping a locking clamp is formed between the locking block and the sliding block; the side wall of the dyeing tank is provided with a sliding groove, two ends of the sliding groove are provided with electromagnets, a magnetic block is arranged on the sliding block, and the sliding block slides in the sliding groove in a reciprocating manner through the electromagnets and the magnetic block.

Before dyeing the comfortable and warm-keeping sweater fabric, a worker can firstly place the fabric barrel wound with the comfortable and warm-keeping sweater fabric on the transfer plate, and then clamp the locking clamp at the end part of the comfortable and warm-keeping sweater fabric. Then the transferring cylinder can force the material cylinder to be sleeved on the placing column through the pushing plate, and when the placing column is inserted in the placing hole, the locking operation of the material cylinder is completed.

Afterwards, the clamping cylinder limits the locking clamp through the locking block and the sliding block, then, the electromagnet located at the traction assembly forces the sliding block to automatically slide towards the traction assembly in the sliding groove through the magnetic block, so that the operation of manually transferring the comfortable and warm-keeping sweater fabric by workers is omitted, and the dyeing efficiency of the comfortable and warm-keeping sweater fabric is effectively improved.

Preferably, the traction assembly comprises a discharge plate and a fabric traction piece, the fabric traction piece comprises a discharge transfer cylinder, a discharge transfer plate, a traction plate and a driving motor, the discharge transfer cylinder is fixedly connected to the upper end face of the discharge plate, and the discharge transfer plate is rotatably connected to a piston rod of the discharge transfer cylinder;

a material storage barrel is arranged on the discharging plate, a first square groove is formed in the side wall of the material storage barrel in a penetrating mode, and a clamping groove used for limiting and locking a clamp is formed in the outer peripheral face of the material storage barrel; the dyeing pond is characterized in that the traction plate is fixedly connected to the dyeing pond, the driving motor is fixedly connected to the upper end face of the traction plate, a square column is fixedly connected to an output shaft of the driving motor, a second square groove is formed in the discharging transfer plate, and the square column penetrates through the first square groove and is inserted into the second square groove.

When the comfortable warm-keeping sweater fabric needs to be dyed, a worker can firstly place the storage barrel on the discharge plate and control the card connecting groove to face the cloth feeding assembly. The ejection of compact shifts the cylinder then shifts the board through the ejection of compact and locates the square column with the storage cylinder cover afterwards, and when the square column was pegged graft in the second square groove, just accomplished the locking operation to the storage cylinder.

And when comfortable cold-proof sweater surface fabric transferred to the subassembly department of pulling under the drive of surface fabric conveying piece, the locking was pressed from both sides at first the joint in the draw-in groove, and then the clamping cylinder loosens the locking to the locking clamp, and the electro-magnet that is located into cloth subassembly department forces the sliding block to advance the cloth subassembly through the magnetic path and slides, and driving motor forces the storage section of thick bamboo rotatory through the square column, comfortable cold-proof sweater surface fabric alright with remove in the dyeing bath, and then accomplish the dyeing operation to comfortable cold-proof sweater surface fabric, effectively improve the dyeing efficiency of comfortable cold-proof sweater surface fabric.

In summary, the present application has the following beneficial effects:

1. the combed cotton yarn, the DTY and the Arctic bear hair-Thermolite are used in a superposed manner, so that the effects of ventilation, heat preservation and portability are achieved;

2. the light napping process in the application can effectively reduce the possibility that the warmth retention performance of the Arctic bear hair-Thermolite is damaged due to napping, and can promote the fluff to be denser;

3. the bobbing machine can also force first guide roller to take place to last the shake to make the first guide roller ejection of compact can rock outside the coloring agent in the dyeing pond, first guide roller can also make coloring agent and comfortable cold-proof sweater surface fabric contact more even through the shake, effectively improves dyeing efficiency.

Drawings

FIG. 1 is a schematic structural view of a comfortable thermal sweater fabric;

FIG. 2 is a schematic view of the construction of a dyeing apparatus for comfortable thermal sweater fabric;

FIG. 3 is a schematic, partially exploded view of the cloth feed assembly;

FIG. 4 is a schematic view of the structure of a staining bath;

FIG. 5 is an enlarged schematic view of portion A of FIG. 4;

FIG. 6 is a schematic structural view of the tow assembly;

fig. 7 is a schematic structural view of the guide assembly.

Description of reference numerals: 1. a dyeing tank; 2. a cloth feeding assembly; 3. a guide assembly; 4. a traction assembly; 5. an external contact layer; 6. a middle connection layer; 7. an inner thermal layer; 21. a transfer plate; 22. a fabric transfer member; 23. a fabric conveying member; 31. a first guide member; 32. a second guide member; 41. a discharge plate; 42. a fabric traction member; 211. transferring the connecting block; 212. transferring a connecting groove; 213. a locking clip; 221. a transfer cylinder; 222. a push plate; 223. a material placing plate; 224. placing holes; 225. a support plate; 226. placing the column; 227. a discharging connecting block; 228. discharging and connecting grooves; 231. a sliding block; 232. a clamping cylinder; 233. a locking block; 234. a clamping space; 235. a sliding groove; 236. an electromagnet; 237. a magnetic block; 311. a first guide bracket; 312. a first guide roller; 321. a lifting cylinder; 322. a second guide bracket; 323. a second guide roller; 324. a guide channel; 411. a storage cylinder; 412. a first square groove; 413. a clamping groove; 414. a second square groove; 421. a discharge transfer cylinder; 422. a discharge transfer plate; 423. a traction plate; 424. a drive motor; 425. a square column; 3221. a support portion; 3222. an elastic portion; 3223. a vibrator; 32221. an elastic frame; 32222. a connecting shaft; 32223. a limiting plate; 32211. an elastic groove; 32212. an elastic pad; 32213. a first contact; 32214. a second contact.

Detailed Description

The present application will be described in further detail with reference to the accompanying drawings 1 to 7, examples and comparative examples.

Raw materials

The raw material components in the application are shown in a table 1:

TABLE 1 sources of the raw material components

Raw materials	Type/manufacturer
		Combed cotton yarn	Sinkiang cotton yarn 30
DTY	Terylene DTY 15D
		Maifanitum powder	1000 mesh screen

Examples

Example 1

A preparation method of comfortable and warm keeping sweater fabric comprises the following steps:

s1, weaving the combed cotton yarn, the DTY and the Arctic bear hair-Thermolite from outside to inside to form a thermal fabric base material (shown in figure 1) with an external contact layer 5, a middle connecting layer 6 and an internal thermal layer 7, wherein the thermal fabric base material has a fabric structure as follows: 270g/m2 (+ -20), 60 wt% combed cotton yarn, 15 wt% DTY, 25 wt% Arctic hair-Thermolite;

s2, carrying out napping treatment on the inner wall of the inner warm-keeping layer 7 through a light napping process to form a warm-keeping fabric preparation material with fluff; the light napping process adopts four napping processes, wherein the cloth speed is 32-36m/min, the cloth guide roller tension is 10-14%, and the clockwise roller rotating speed is 6-10r/min, and because the cloth speed, the cloth guide roller tension and the clockwise roller rotating speed have relatively weak correlation on the napping effect, the cloth speed, the cloth guide roller tension and the clockwise roller rotating speed are only described by taking 35m/min, 12% and 8r/min as examples in the application;

s3, adding a warm-keeping auxiliary agent Queenlight HT-B into a dyeing agent in an adding amount of 1g/L, and then dyeing the warm-keeping fabric prepared material through a dyeing device to obtain a comfortable warm-keeping sweater fabric; in this embodiment, the conventional coloring agent may be selected from commercially available conventional coloring agents according to actual situations;

the dyeing device for the comfortable and warm keeping sweater fabric has the following specific structure:

referring to fig. 2, the dyeing apparatus for comfortable and warm keeping sweater fabric comprises a dyeing tank 1, a cloth feeding component 2, a guiding component 3 and a traction component 4, wherein the cloth feeding component 2 is arranged at one end of the dyeing tank 1, the traction component 4 is arranged at the other end of the dyeing tank 1, the guiding component 3 is arranged in the dyeing tank 1, and the guiding component 3 is positioned between the cloth feeding component 2 and the traction component 4.

When dyeing operation needs to be carried out on the comfortable and warm-keeping sweater fabric, a worker can directly place the fabric barrel wound with the comfortable and warm-keeping sweater fabric at the cloth feeding component 2, the cloth feeding component 2 automatically enables the comfortable and warm-keeping sweater fabric to penetrate through the guide component 3 and be connected with the traction component 4, and then the traction component 4 can force the comfortable and warm-keeping sweater fabric to move in the dyeing tank 1, so that dyeing operation on the comfortable and warm-keeping sweater fabric is completed.

Referring to fig. 2 and 3, the cloth feeding assembly 2 includes a transfer plate 21, a fabric transfer member 22 and a fabric conveying member 23, wherein the transfer plate 21 is fixedly connected to a side wall of the dyeing tank 1, one side of the transfer plate 21 is fixedly connected with a transfer connecting block 211, a transfer connecting groove 212 is formed in an inner wall of the transfer connecting block 211, and a locking clamp 213 for clamping an end portion of the comfortable and warm-keeping sweater fabric is slidably connected to the transfer connecting groove 212.

The fabric transferring member 22 comprises a transferring cylinder 221, a pushing plate 222 and a material placing plate 223, the transferring cylinder 221 is fixedly connected to one end of the transferring plate 21 far away from the dyeing tank 1, the pushing plate 222 is fixedly connected to a piston rod of the transferring cylinder 221, and a placing hole 224 is formed in one side of the pushing plate 222 far away from the transferring cylinder 221.

The material placing plate 223 is fixedly connected to one end, close to the transfer cylinder 221, of the dyeing pond 1, the material placing plate 223 is fixedly connected to one end, far away from the transfer cylinder 221, of the supporting plate 225, the placing column 226 is fixedly connected to the center of the supporting plate 225, the fabric barrel of comfortable and warm-keeping sweater fabric is wound on the placing column 226, and the placing column 226 can be inserted into the placing hole 224. The side wall of the supporting plate 225 is fixedly connected with a discharging connecting block 227, the side wall of the discharging connecting block 227 is provided with a discharging connecting groove 228 for the locking clip 213 to slide in a reciprocating manner, and the discharging connecting groove 228 is communicated with the transfer connecting groove 212.

Before dyeing the comfortable and warm sweater fabric, a worker may first place the fabric tube wound with the comfortable and warm sweater fabric on the transfer plate 21, then clamp the locking clip 213 to the end of the comfortable and warm sweater fabric, and place the locking clip 213 in the transfer connecting groove 212.

The transfer cylinder 221 then forces the cartridge to fit over the placement post 226 via the pushing plate 222, and when the placement post 226 is inserted into the placement hole 224, the locking clip 213 is transferred into the discharge connection slot 228, thereby completing the locking operation of the opposing cartridge.

Referring to fig. 4 and 5, the fabric feeding member 23 includes a slide block 231, a clamping cylinder 232, and a locking block 233, wherein the clamping cylinder 232 is fixedly connected to a side wall of the slide block 231, the locking block 233 is fixedly connected to a piston rod of the clamping cylinder 232, and a clamping space 234 for clamping the locking clamp 213 is formed between the locking block 233 and the slide block 231.

The inner wall of dyeing pond 1 has been seted up and has been slided groove 235, and the equal fixedly connected with electro-magnet 236 in both ends of groove 235 that slides, the lower part fixedly connected with magnetic path 237 of sliding block 231, sliding block 231 slides through electro-magnet 236 and magnetic path 237 and connects in groove 235 that slides. It should be noted that in the present embodiment, two fabric conveying members 23 and two sliding grooves 235 are provided, so as to promote more stable conveyance of the comfortable and warm sweater fabric.

Specifically, after the fabric barrel is locked, the clamping cylinder 232 firstly limits the locking clamp 213 through the locking block 233 and the sliding block 231, and then the electromagnet 236 at the traction assembly 4 forces the sliding block 231 to automatically slide towards the traction assembly 4 in the sliding groove 235 through the magnetic block 237, thereby completing the operation of conveying the comfortable thermal sweater fabric.

Referring to fig. 4 and 6, the drawing assembly 4 includes a discharging plate 41 and a web drawing member 42, and the web drawing member 42 includes a discharging transfer cylinder 421, a discharging transfer plate 422, a drawing plate 423, and a driving motor 424. Wherein, the traction plate 423 is fixedly arranged at one end of the dyeing tank 1 far away from the cloth feeding assembly 2, and the discharging plate 41 is fixedly connected to the end of the traction plate 423.

The discharging transfer cylinder 421 is fixedly connected to the upper end face of one end of the discharging plate 41 far away from the traction plate 423, and the discharging transfer plate 422 is rotatably connected to the piston rod of the discharging transfer cylinder 421. The upper end face of the discharging plate 41 is provided with a storage barrel 411 for winding comfortable warm keeping sweater fabric after dyeing, the side wall of the storage barrel 411 is provided with a first square groove 412 in a penetrating way, and the peripheral face of the storage barrel 411 is provided with a clamping groove 413 for limiting the locking clamp 213.

Driving motor 424 fixed connection keeps away from the up end of the one end of play material board 41 in traction plate 423, fixedly connected with square column 425 on the output shaft of driving motor 424 amount, the ejection of compact shifts one side that board 422 kept away from ejection of compact and shifts cylinder 421 and has seted up second square groove 414, and first square groove 412 and plug in square groove are worn to establish by square column 425.

When dyeing comfortable warm-keeping sweater fabric is required, a worker can firstly place the material storage barrel 411 on the material discharge plate 41 and control the clamping groove 413 to face the cloth feeding assembly 2. Then the material storage cylinder 411 is sleeved on the square column 425 through the material discharging transfer cylinder 421, and when the square column 425 is inserted into the second square groove 414, the locking operation of the material storage cylinder 411 is completed.

When the comfortable and warm-keeping sweater fabric is transferred to the traction assembly 4 under the driving of the fabric conveying piece 23, the locking clamp 213 is firstly clamped in the clamping groove, then the clamping cylinder 232 releases the locking of the locking clamp 213, the electromagnet 236 at the cloth feeding assembly 2 forces the sliding block 231 to slide towards the cloth feeding assembly 2 through the magnet 237, the driving motor 424 forces the material storage barrel 411 to rotate through the square column 425, and the comfortable and warm-keeping sweater fabric can move in the dyeing tank 1, so that the dyeing operation of the comfortable and warm-keeping sweater fabric is completed.

Referring to fig. 4 and 7, the guide assembly 3 includes a first guide member 31 and a second guide member 32, wherein the first guide member 31 includes a first guide bracket 311 and a plurality of first guide rollers 312, the first guide bracket 311 is fixedly connected to the bottom of the dyeing bath 1, and the plurality of first guide rollers 312 are rotatably connected to the first guide bracket 311.

The second guiding member 32 comprises a lifting cylinder 321, a second guiding bracket 322 and a plurality of second guiding rollers 323, wherein the lifting cylinder 321 is fixedly connected to the upper end surface of the dyeing tank 1, the second guiding bracket 322 is fixedly connected to the piston rod of the lifting cylinder 321, the plurality of second guiding rollers 323 are rotatably connected to the second guiding bracket 322, and the plurality of first guiding rollers 312 and the plurality of second guiding rollers 323 are staggered with each other to form a wavy guiding channel 324.

The number of the first guide roller 312, the second guide roller 323, and the lifting cylinder 321 may be set arbitrarily in practice, but in the present embodiment, four first guide rollers 312, four second guide rollers 323, and four lifting cylinders 321 are provided.

After the end of the comfortable and warm-keeping sweater fabric passes through the dyeing tank 1 and is connected with the traction component 4, the lifting cylinder 321 forces the first guide roller 312 and the second guide roller 323 to be mutually staggered through the second guide bracket 322 and form a wavy guide channel 324, so that the comfortable and warm-keeping sweater fabric is completely immersed in the dyeing tank 1 and the dyeing distance is prolonged, and then the traction component 4 can drive the comfortable and warm-keeping sweater fabric to gradually advance.

In addition, in this embodiment, the second guiding support 322 includes a supporting portion 3221, an elastic portion 3222, and a vibrating mechanism 3223, wherein the supporting portion 3221 is fixedly connected to the piston rod of the lifting cylinder 321, the elastic portion 3222 is disposed on the supporting portion 3221, the vibrating mechanism 3223 is fixedly connected to the elastic portion 3222, and the plurality of second guiding components are rotatably connected to the elastic portion 3222.

Specifically, the elastic portion 3222 includes an elastic frame 32221, four connecting shafts 32222, and two limiting plates 32223, the four connecting shafts 32222 are all fixedly connected inside the elastic frame 32221, the second guiding roller 323 is sleeved on the connecting shafts 32222, an elastic groove 32211 is disposed on the lower end surface of the supporting portion 3221, an elastic pad 32212 is embedded in the elastic groove 32211, two ends of the elastic frame 32221 penetrate through the elastic groove 32211 and are connected to the limiting plates 32223, and one side of the limiting plate 32223 close to the elastic frame 32221 abuts against the supporting portion 3221.

The outer sidewall of the upper end of the supporting portion 3221 is mounted with a first contact point 32213, the wall of the dyeing bath 1 is mounted with a second contact point 32214, and when the second guide roller 323 is completely immersed in the dyeing bath 1, the first contact point 32213 and the second contact point 32214 are communicated with each other, and the vibrator 3223 operates. When the second guiding roller 323 is separated from the dyeing bath 1, the second contact point 32214 and the second contact point 32214 are staggered, and the vibrating machine 3223 stops operating.

It should be noted that, the above-mentioned fixed connection may be implemented by welding, bolting, integrally forming, or other conventional fixed connection methods. The rotary connection can be realized by adopting conventional rotary connection modes such as pin connection or bearing connection according to the actual application.

Examples 2 to 3

The difference from example 1 is that the fabric structure of the thermal fabric base material is different, and is specifically shown in table 2.

Table 2 fabric construction of examples 1-3 table (wt%)

	Combed cotton yarn	DTY	Arctic bear hair imitation Thermolite
				Example 1	60	15	25
Example 2	75	10	15
				Example 3	45	20	35

Example 4

The difference from example 1 is that the light napping process in S2 employs three napping operations.

Example 5

The difference from example 1 is that the light napping process in S2 employs five napping passes.

Example 6

The difference from example 1 is that in S3, the warming auxiliary, QueenLight HT-B, was replaced with HOLPOSON HOT.

Example 7

The difference from example 1 is that in S3, the warming aid QueenLight HT-B was replaced with a medical stone powder.

Example 8

The difference from example 1 is that in S3, the warming auxiliary QueenLight HT-B was replaced by a mixture of QueenLight HT-B and HOLPOSON HOT, and the ratio of QueenLight HT-B to HOLPOSON HOT was 1: 1.

Example 9

The difference from example 1 is that in S3, the heat retention aid QueenLight HT-B was replaced with a mixture of QueenLight HT-B and medical stone powder, and the ratio of the addition of the QueenLight HT-B to the medical stone powder was 1: 1.

Example 10

The difference from example 1 is that the amount of the warming auxiliary added is 0.5 g/L.

Example 11

The difference from example 1 is that the amount of the warming assistant added was 1.5 g/L.

Comparative example

Comparative example 1

The difference from example 1 is that comparative example 1 consists of only the outer contact layer and the middle tie layer, and the facing structure of comparative example 1 is: 270g/m²(+ -20), 75 wt% combed cotton yarn, 25 wt% DTY.

Comparative example 2

The difference from example 1 is that the inner warmth retention layer is not provided with fluff inside, i.e., light napping treatment is not performed in S2.

Performance test

Detection method

First, average thermal resistance test

Three samples were selected from examples 1-5 and comparative examples 1-2, and then the average thermal resistance was measured and averaged with reference to GB/T18398-. (the test requirement is more than or equal to 0.03m²·K/W)

Second, temperature rise test

Three samples were selected from example 1 and examples 6 to 11, and then the average temperature rise and the maximum temperature rise were measured for 30min with reference to GB/T30127-2013 test and evaluation of far infrared performance of textiles, and the average values were obtained. (the effective area of the test hot plate is more than or equal to the circular surface with the diameter of 60mm, the temperature is 34 +/-1 ℃, the test distance is 500mm, the test frequency is 30 s/time,

testing requirements are as follows: 30min average temperature rise is more than or equal to 3 ℃, and the highest temperature rise is more than or equal to 4℃)

And (3) detection results: the results of the tests of examples 1 to 11 and comparative examples 1 to 2 are shown in Table 3.

TABLE 3 TABLE of examination results of examples 1 to 11 and comparative examples 1 to 2

	Average thermal resistance (m 2. K/W)	30min average temperature rise (. degree. C.)	Maximum temperature rise (. degree. C.)
				Example 1	0.0836	3.2	7.3
Example 2	0.0412	/	/
				Example 3	0.0903	/	/
Example 4	0.0786	/	/
				Example 5	0.0883	/	/
Example 6	/	2.8	8.7
				Example 7	/	3.0	6.3
Example 8	/	2.9	8.4
				Example 9	/	3.1	6.6
Example 10	/	2.8	6.1
				Example 11	/	3.4	7.4
Comparative example 1	0.0311	/	/
				Comparative example 2	0.0563	/	/

As can be seen by combining examples 1-3 and comparative example 1 with Table 3, the average thermal resistances of examples 1-3 are all improved compared to comparative example 1, thereby demonstrating that the Arctic bear hair-Thermolite can effectively improve the thermal performance of the comfortable thermal sweater fabric.

Compared with example 1, the average thermal resistance of example 2 is significantly reduced, and the average thermal resistance of example 3 is slightly improved, which shows that the thermal insulation performance of the comfortable and warm sweater fabric is gradually improved with the increase of the content of the imitative polar bear hair-Thermolite, but when the content of the imitative polar bear hair-Thermolite reaches 25 wt%, if the content of the imitative polar bear hair-Thermolite is increased, the increase of the thermal insulation performance of the comfortable and warm sweater fabric is not large, and example 1 is better for cost.

It can be seen by combining examples 1, 4-5 and comparative example 2 and combining table 3 that the average thermal resistance of examples 1 and 4-5 is improved compared with that of comparative example 2, thereby showing that the arrangement of the fluff can effectively improve the heat retention performance of the comfortable and warm keeping sweater fabric.

Compared with the embodiment 1, the average thermal resistance of the embodiment 4 is obviously reduced, and the average thermal resistance of the embodiment 5 is slightly improved, so that the napping times have influence on the heat preservation performance of the comfortable and warm sweater fabric, namely the heat preservation performance of the comfortable and warm sweater fabric is gradually improved along with the increase of the napping times, but when the napping times reach 4 times, the heat preservation performance of the comfortable and warm sweater fabric is not greatly improved if the napping times are increased.

Combining example 1, examples 6-7 and table 3, it can be seen that the maximum temperature rise of example 6 is significantly increased compared to example 1, but the average temperature rise of 30min is decreased, even to the test requirement. The reason for this may be that HOLPOSON HOT can absorb moisture and store heat, so as to promote the comfortable and warm-keeping sanitary garment fabric to be heated quickly, but the heat storage manner is not good in continuity, so that the average temperature rise in 30min is slightly low, and therefore, example 1 is better.

Compared with example 1, the average temperature rise and the maximum temperature rise in 30min in example 7 are reduced, so that QueenLight HT-B has a better effect of improving the heat preservation performance of the comfortable heat-preservation sweater fabric.

In combination with examples 1 and 8-9 and Table 3, the 30min average temperature rise and the maximum temperature rise of examples 8-9 were reduced relative to example 1, indicating that Queenlight HT-B is suitable for use alone.

It can be seen from the combination of example 1, examples 10 to 11 and table 3 that the average temperature rise and the maximum temperature rise of 30min in example 10 are both significantly reduced, and the average temperature rise and the maximum temperature rise of 30min in example 11 are both slightly improved, compared to example 1, thereby showing that the thermal performance of the comfortable thermal sweater fabric is gradually improved as the addition amount of the QueenLight HT-B is increased, but when the addition amount of the QueenLight HT-B reaches 1g/L, if the addition amount of the QueenLight HT-B is further increased, the increase of the thermal performance of the comfortable thermal sweater fabric is not large, and example 1 is superior for cost.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

Claims (10)

1. The comfortable and warm keeping sweater fabric is characterized by comprising an external contact layer (5), a middle connecting layer (6) and an internal warm keeping layer (7) which are sequentially arranged from outside to inside, wherein the external contact layer (5) is made of combed cotton yarn, the middle connecting layer (6) is made of DTY, the internal warm keeping layer (7) is made of imitative polar bear hair-Thermolite, and fluff is arranged inside the internal warm keeping layer (7).

2. A preparation method of comfortable and warm keeping sweater fabric is characterized by comprising the following steps:

s1, weaving combed cotton yarns, DTY and Arctic bear hair from outside to inside by using Thermolite to form a thermal fabric base material with an external contact layer (5), a middle connecting layer (6) and an internal thermal layer (7);

s2, carrying out napping treatment on the inner wall of the inner heat-preservation layer (7) through a light napping process to form a heat-preservation fabric preparation material with fluff;

s3, adding a warm-keeping auxiliary agent into the coloring agent, and then dyeing the warm-keeping fabric preparation material to obtain the comfortable warm-keeping sanitary garment fabric.

3. The method of making a comfortable and warm sweater fabric according to claim 2, characterized in that: the light napping process adopts four napping processes, the cloth speed is 32-36m/min, the tension of a cloth guide roller is 10-14%, and the rotation speed of a needle roller is 6-10 r/min.

4. The method of making a comfortable and warm sweater fabric according to claim 2, characterized in that: the addition amount of the heat-insulating auxiliary agent is 0.5-1.5 g/L.

5. The method of making a comfortable and warm sweater fabric according to claim 4, characterized in that: the heat-insulating auxiliary agent is one or a mixture of more of Queenlight HT-B, HOLPOSON HOT and medical stone powder.

6. The method of making a comfortable and warm sweater fabric according to claim 5, characterized in that: the heat-insulating auxiliary agent is Queenlight HT-B.

7. The utility model provides a dyeing apparatus of comfortable cold-proof sweater surface fabric which characterized in that: the cloth feeding device comprises a dyeing tank (1), a cloth feeding assembly (2), a guiding assembly (3) and a traction assembly (4), wherein the cloth feeding assembly (2) is arranged at one end of the dyeing tank (1), the traction assembly (4) is arranged at the other end of the dyeing tank (1), the guiding assembly (3) is arranged in the dyeing tank (1), and the guiding assembly (3) is positioned between the cloth feeding assembly (2) and the traction assembly (4);

the guide assembly (3) comprises a first guide part (31) and a second guide part (32), the first guide part (31) comprises a first guide bracket (311) fixedly connected to the bottom of the dyeing tank (1) and a plurality of first guide rollers (312) rotatably connected to the first guide bracket (311); the second guide piece (32) comprises a lifting cylinder (321) fixedly connected to the top of the dyeing tank (1), a second guide bracket (322) fixedly connected to a piston rod of the lifting cylinder (321), and a plurality of second guide rollers (323) rotatably connected to the second guide bracket (322), wherein the plurality of first guide rollers (312) and the plurality of second guide rollers (323) are mutually staggered to form a wavy guide channel (324);

the second guide bracket (322) comprises a supporting portion (3221) fixedly connected to a piston rod of the lifting cylinder (321), an elastic portion (3222) arranged on the supporting portion (3221) and a vibrator (3223) arranged on the elastic portion (3222), and the second guide roller (323) is rotatably connected to the elastic portion (3222).

8. The dyeing apparatus for comfortable and warm keeping sweater fabric according to claim 7, characterized in that: the side wall of the supporting part (3221) is provided with a first contact point (32213), the wall of the dyeing bath (1) is provided with a second contact point (32214), and when the first contact point (32213) and the second contact point (32214) are communicated with each other, the vibrating machine (3223) operates.

9. The dyeing apparatus for comfortable and warm keeping sweater fabric according to claim 7, characterized in that: the cloth feeding assembly (2) comprises a transfer plate (21), a fabric transfer piece (22) and a fabric conveying piece (23), wherein a transfer connecting block (211) is arranged on the side wall of the transfer plate (21), a transfer connecting groove (212) is formed in the transfer connecting block (211), and a locking clamp (213) used for clamping comfortable and warm-keeping sweater fabric is connected in the transfer connecting groove (212) in a sliding manner;

the fabric transfer piece (22) comprises a transfer cylinder (221) fixedly connected to one end of a transfer plate (21) far away from the dyeing tank (1), a push plate (222) fixedly connected to a piston rod of the transfer cylinder (221) and a material placing plate (223) fixedly connected to the dyeing tank (1), a support plate (225) is arranged at one end of the material placing plate (223) far away from the transfer cylinder (221), a placing column (226) for sleeving comfortable and warm-keeping sweater fabric is arranged on the support plate (225), a placing hole (224) is formed in one side of the push plate (222) far away from the transfer cylinder (221), the placing column (226) is inserted into the placing hole (224), a material placing connecting block (227) is arranged on the support plate (225), and a material placing connecting groove (228) for the locking clamp (213) to slide in a reciprocating manner is formed in the material placing connecting block (227), the discharging connecting groove (228) is communicated with the transferring connecting groove (212);

the fabric conveying piece (23) comprises a sliding block (231), a clamping cylinder (232) and a locking block (233), the clamping cylinder (232) is arranged on the sliding block (231), the locking block (233) is arranged on a piston rod of the clamping cylinder (232), and a clamping space (234) for clamping the locking clamp (213) is formed between the locking block (233) and the sliding block (231); a sliding groove (235) is formed in the side wall of the dyeing tank (1), electromagnets (236) are arranged at two ends of the sliding groove (235), a magnetic block (237) is arranged on the sliding block (231), and the sliding block (231) slides in the sliding groove (235) in a reciprocating mode through the electromagnets (236) and the magnetic block (237).

10. The dyeing apparatus for comfortable and warm keeping sweater fabric according to claim 9, characterized in that: the fabric traction assembly (4) comprises a discharging plate (41) and a fabric traction piece (42), the fabric traction piece (42) comprises a discharging transfer cylinder (421), a discharging transfer plate (422), a traction plate (423) and a driving motor (424), the discharging transfer cylinder (421) is fixedly connected to the upper end face of the discharging plate (41), and the discharging transfer plate (422) is rotatably connected to a piston rod of the discharging transfer cylinder (421);

a material storage barrel (411) is placed on the discharge plate (41), a first square groove (412) is formed in the side wall of the material storage barrel (411) in a penetrating mode, and a clamping groove (413) used for limiting the locking clamp (213) is formed in the outer peripheral surface of the material storage barrel (411); traction plate (423) fixed connection in on dyeing pond (1), driving motor (424) fixed connection in the up end of traction plate (423), fixedly connected with square column (425) on the output shaft of driving motor (424), ejection of compact shifts and has seted up second square groove (414) on board (422), square column (425) wear to establish first square groove (412) and insert connect in second square groove (414).

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