WO2022089387A1

WO2022089387A1 - Staple fiber yarn and fabric obtained therefrom

Info

Publication number: WO2022089387A1
Application number: PCT/CN2021/126236
Authority: WO
Inventors: 陈娟; 范志恒; 倪春健; 滨田润二
Original assignee: 东丽纤维研究所（中国）有限公司
Priority date: 2020-10-27
Filing date: 2021-10-26
Publication date: 2022-05-05
Also published as: TW202217098A; CN116234950A

Abstract

A staple fiber yarn and a fabric obtained therefrom. The staple fiber yarn is composed of more than 40 wt% of high anti-permeability short fibers, the high anti-permeability short fibers being short fibers having an inorganic particle content of 7.0-30.0 wt%. Fabric prepared from said yarn not only has excellent ultraviolet light resistance, anti-permeability and heat-shielding properties, but also has excellent sweat resistance.

Description

Staple yarn and fabrics made therefrom

technical field

The present invention relates to a spun fiber yarn and a fabric prepared therefrom.

Background technique

With the continuous improvement of living standards, people have higher and higher requirements for clothing, not only requiring novel styles, but also putting forward higher requirements for comfort. For the yarns that make up fabrics, various functional high value-added spun yarns are constantly being introduced.

For example, the patent document CN206843638U discloses an anti-see-through spun fiber yarn, which includes a cladding layer and a core bundle layer, the cladding layer is a hollow structure, the core bundle layer is located in the hollow of the cladding layer, and the core bundle layer is composed of several core layers , This structure has multiple scattering effects, and at the same time, it is supplemented by fiber fine denier, surface roughening, and yarn porosification to achieve the anti-penetration effect of light-colored and thin fabrics, but the fiber cross-section design is more complicated, and the core layer needs to be in the The eccentric setting in the cladding layer can bring a very good degree of curling to improve the scattering path, which is difficult in the process and is not conducive to control.

For another example, patent document WO2019/091447A discloses a core-sheath composite fiber and fabric with high anti-penetration resistance. The composite fiber has a core-sheath composite cross-sectional shape, the core component contains a high concentration of inorganic particles, and the sheath component contains a low concentration of inorganic particles, and the obtained composite fiber has good spinning processability, and also has excellent Anti-penetration, anti-ultraviolet, heat shielding properties. However, such composite fibers are 100 wt% long fibers, and have a strong chemical fiber feel, and their application range is limited.

For another example, the patent document CN105734772A discloses an anti-penetration woven fabric and a production method thereof. More than 60wt% of the yarns of the woven fabric are anti-permeable polyester yarns with a core-sheath structure and titanium dioxide content between 3 and 7%. The high anti-permeability and UV resistance of the fabric are achieved by using anti-permeable polyester yarns. sex. However, such anti-penetration polyester yarns are also 100wt% long fibers, and have a strong chemical fiber feel, and their application scope is limited.

SUMMARY OF THE INVENTION

The purpose of the present invention is to provide a spun fiber yarn with simple and easy process, not only good UV resistance, anti-permeability and heat shielding properties, but also good anti-perspiration property and a fabric prepared therefrom.

Technical solution of the present invention:

(1) The spun fiber yarn of the present invention is composed of 40 wt% or more of high-permeability-resistant short fibers, wherein the high-permeability-resistant staple fibers are short fibers with an inorganic particle content of 7.0 to 30.0 wt%.

(2) The spun yarn of (1) above, which is a uniform blended yarn, and in the four quadrants of the cross section, the standard deviation of the blending ratio of the high-impermeable staple fibers in each quadrant is within 10.

(3) The spun fiber yarn of the above (1), wherein the inorganic particles in the highly impermeable staple fiber are one or more of titanium dioxide, calcium carbonate and zinc oxide.

(4) The spun yarn of the above (1), wherein the highly impermeable staple fiber is polyester or polyamide.

(5) The spun fiber yarn according to any one of (1) to (4) above, wherein the highly impermeable staple fiber is a composite fiber having a core-sheath cross-sectional structure or a composite fiber having a multi-layer cross-sectional structure of three or more layers.

(6) The spun fiber yarn according to (5) above, wherein the highly impermeable staple fiber is a composite fiber having a multi-layered cross-sectional structure of 3 to 15 layers.

(7) A fabric containing the spun yarn according to any one of (1) to (6).

(8) The fabric according to (7) above, wherein the absolute value of the difference in reflectance between wet and dry conditions is 7% or less.

The spun fiber yarn of the present invention comprises more than 40 wt % of high-impermeability short fibers, and the inorganic particles in the high-impermeability short fibers are used to increase the refractive index of light, which can enhance the reflection of visible light and blue light, so that the high-impermeability short fibers have a blue tone , the naked eye looks whiter, bringing anti-transmission effect; and the high content of inorganic particles can absorb a large number of ultraviolet wavelengths, and the anti-ultraviolet effect is superior; at the same time, these inorganic particles can reflect visible light and infrared light, and block the light in the infrared region, thus It has a good heat shielding effect by suppressing the temperature rise caused by the sun. In addition, the fabric made of the spun yarn of the present invention has a small difference in reflectivity between dry and wet states, that is to say, the color difference between the dry state and the wet state is not obvious, which can well resolve the sweat stains caused by sweating. of embarrassment.

Description of drawings

Fig. 1 is a cross-sectional photograph of the spun yarn of the present invention.

Detailed ways

The spun fiber yarn of the present invention contains 40% by weight of high-impermeability staple fibers. That is, the spun yarn according to the present invention may be a spun yarn composed of 100% by weight of high-permeability-resistant staple fibers, or may be a composite spun yarn formed by blending high-permeability-resistant staple fibers with other staple fibers. If the content of the high anti-penetration staple fiber is less than 40 wt %, the anti-penetration effect and anti-ultraviolet effect of the spun fiber yarn are not good.

The other short fibers here are not particularly limited, such as natural fibers such as cotton, hemp, wool, and silk, regenerated fibers such as cupro, viscose, and acetate, and synthetic fibers such as polyester, acrylic, and polyamide, etc., which can be selected according to needs. one or more of. The above polyester fiber may be polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polytrimethylene terephthalate (PTT), or the like.

In the highly impermeable short fibers of the present invention, the content of inorganic particles is 7.0-30.0 wt %, preferably 7.0-15.0 wt %. When the content of inorganic particles is less than 7.0wt%, although there is no problem in spinning performance and fiber physical properties, the reflection and absorption effects of light are affected, and the anti-ultraviolet, anti-permeability and anti-perspiration properties are not good; and inorganic particles When the content is higher than 30.0 wt %, the phenomenon of filament breakage and filament floating easily occurs in the spinning process, and the strength of the final product is poor, and the application range is limited.

The spun yarn of the present invention is preferably a blended spun yarn. As an index representing the uniformity of the blended spun yarn, in the four quadrants on the cross section of the spun yarn, the standard deviation of the blending rate of the high anti-penetration staple fibers in each quadrant is within 10. If the standard deviation exceeds 10, there may be a phenomenon that the high anti-penetration short fibers are gathered on one side, the light can easily pass through the area with a low content of high anti-penetration fibers, and the anti-penetration, UV resistance and heat shielding properties tend to decrease. .

In the highly impermeable short fibers of the present invention, the types of inorganic particles are not particularly limited and can be selected according to needs, and are preferably one or more of titanium dioxide, calcium carbonate and zinc oxide. Among them, titanium dioxide particles have the best light scattering effect, and have good properties such as safety, stability, and dispersibility, and are therefore more preferable. Titanium dioxide particles are classified into anatase type and rutile type according to the crystal form. The crystal structure of anatase titanium dioxide particles is unstable, and free radicals are easily generated. When the free radicals accumulate to a certain amount, the light fastness of the polymer may be affected. When a large amount of anatase-type titanium dioxide particles is contained in the fibers, the light resistance of the fibers tends to be deteriorated. Therefore, rutile-type titanium dioxide particles are preferred.

The type of the highly impermeable staple fiber of the present invention is not particularly limited, as long as it is a fiber that can be mixed with inorganic particles, such as polyester, polyamide, acrylonitrile, regenerated cellulose fibers, etc., preferably polyester or Polyamides. Specifically, the polyesters can be polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT), polybutylene terephthalate (PBT), etc.; The polyamides can be polyamide 6, polyamide 66 and the like.

The cross-sectional shape of the highly impermeable staple fiber of the present invention is not particularly limited, either, and may be circular, cross-shaped, multilobal or other irregular shapes. The high-impermeability short fibers of the present invention may be single-component fibers or multi-component composite fibers, preferably composite fibers. Among them, the cross-sectional structure of the composite fiber can be a composite form such as a core-sheath and a multi-layer, and such a composite form can maximize the content of titanium dioxide particles, so it is more preferable. As a composite fiber having a core-sheath cross-sectional structure, the weight ratio of the inorganic particles in the core part and the sheath part is preferably 50 to 95:50 to 5. The number of layers of the conjugate fiber having a multi-layered cross-sectional structure is not particularly limited, but in consideration of cross-sectional formability and basic fiber physical properties, 3 or more layers are preferred, 3 to 15 layers are more preferred, and 3 to 9 layers are most preferred.

A composite fiber with a multi-layer cross-sectional structure, the polymer A and the polymer B are alternately arranged on the multi-layer cross-sectional structure, and at least one layer is formed by the polymer A with an inorganic particle content of 10.0-70.0 wt%, and the polymer A accounts for the composite fiber. 10 to 70 wt % of the fibers, and the outermost layer is formed of polymer B with an inorganic particle content of 5.0 wt % or less.

In the present invention, the components of the polymer A and the polymer B are not particularly limited, but are preferably polyester-based polymers or polyamide-based polymers. Specifically, the polyester polymer can be polyethylene terephthalate (PET), polytrimethylene terephthalate (PTT), polybutylene terephthalate (PBT), etc. Homopolymers, or their copolymers; the polyamide polymers can be polyamide 6, polyamide 66, and the like. According to the content of inorganic particles in polymer B, polymer B can be divided into large gloss, semi-extinction and full extinction. Functional ingredients, such as antistatic ingredients, hygroscopic ingredients, flame retardant ingredients, antibacterial ingredients, etc., can also be added to these polymers.

The present invention does not specifically stipulate the form of the multi-layer cross-sectional structure, which may be arranged in concentric circles, parallel arrangements, or perpendicularly intersecting arrangements between layers. When the multi-layer cross-sectional structure is arranged in concentric circles, the innermost central layer may be a polymer layer or a hollow layer.

The production method of the spun yarn of the present invention is not particularly limited, and may be a method of blending raw cotton in the cotton blending or carding step, and overlapping and compounding the sliver in the drawing step or the blending and carding step. A method of supplying a plurality of rovings or slivers for worst spinning and twisting in the worst spinning process, and the like.

More specifically, for example, when the other staple fibers are cotton staple fibers, the high-impermeability staple fibers are first passed through a carding machine to make them into sliver, and then compounded with the sliver of other staple fibers in the subsequent drawing process, preferably Make three or more draws. When the other short fibers are other synthetic fibers or regenerated fibers, they are preferably mixed when the raw cotton is mixed, and then enter the carding machine, and more preferably beaten twice or more.

The fabric is prepared by using the spun yarn of the present invention as all or part of the raw material. The fabrics here can be woven fabrics or knitted fabrics. When the spun yarn of the present invention is partially used, other yarns are not particularly limited and can be selected as needed. The fiber raw materials of these yarns include polyethylene terephthalate fibers, polyamide fibers, and polyolefins. fiber, polyurethane fiber, etc.

In the manufacturing process of the fabric of the present invention, suitable water-absorbing agents, water-repellent agents, softeners, etc. can be selected for processing according to the needs in the post-finishing process. These agents can be commercially available or self-prepared products. Specially limited. Among them, polyester-based resins, acrylic resins, etc. are exemplified as water-absorbing agents, and fluorocarbon-based resins, hydrocarbon-based resins, and the like are exemplified as water-absorbing agents. As the softener, silicone-based resins and the like can be exemplified.

The absolute value of the difference between the reflectance in the wet state and the reflectance in the dry state on one side of the fabric using the spun fiber yarn of the present invention is below 7%, and the evaluation of discoloration and fading is grade 3-4 and above. The color difference of the knitted fabric is not obvious in the dry and wet state, which can resolve the embarrassment caused by sweat stains after sweating.

Preferably, the anti-permeability rate of the fabric of the present invention is more than 85%, and the anti-permeability performance is excellent.

The present invention will be further described below with reference to Examples and Comparative Examples, but the present invention is not limited thereto. Each parameter involved in the present invention is measured by the following methods.

(1) The content of high anti-penetration short fiber

Ten spun yarns of any length were selected as test samples. Take one of the spun fiber yarns, and decompose raw cotton 1 (highly impermeable short fiber raw cotton), raw cotton 2, raw cotton 3... Then according to the JIS L 1015:2010 test method, the average fineness of the high-impermeability short fiber raw cotton is calculated as a1, and the average fineness of other raw cottons is recorded as a2, a3... . Then take the cross-sectional photos of 10 staple fiber yarns, count the number of high-proof short fiber raw cotton on each photo according to the cross-sectional shape under the microscope, calculate the sum of the total number and record it as b1, the high-proof short fiber The weight of X=a1×b1. Count the number of other raw cottons separately, calculate the sum of the total number and record it as b2, b3..., the total weight Y=a1×b1+a2×b2+a3×b3..., calculate the high anti-penetration short fiber The content of =(X/Y)×100%.

Among them, the cross-sectional shape of the cellulose fibers in the blended raw materials can be exemplified as follows: the cross-section of the cotton fiber is an irregular waist circle with a middle cavity, and the cross-section of the ramie fiber is a waist circle with a middle cavity and a crack in the cell wall. The section of wool is approximately circular or oval, the section of mulberry silk is an irregular triangle, the section of cupro fiber is circular, the section of viscose fiber is serrated and circular, and the section of acetate fiber is leaf-shaped.

(2) Content of inorganic particles in high anti-penetration short fibers

According to the difference of the cross-sectional shape and the content of inorganic particles (paraffin embedding method), about 4g of high-impermeability short fibers were decomposed, and the samples were melted and measured by X-ray fluorescence spectrometer (manufacturer: Rigaku, model: ZSX PrimusⅢ+). The content of inorganic particles.

(3) Standard deviation of the mixing rate of high anti-penetration short fibers

Five spun yarns of any length were selected as test samples. Select one of them, take a photo of its cross-section using the paraffin embedding method, draw a circle (circumscribed circle) including all single fibers, take the center of the circle as the center point, divide the cross-section into four quadrants, and distinguish each fiber according to the shape of the fiber cross-section. The types of fibers in each quadrant and the high-impermeability short fibers are identified. All single fibers in each quadrant are cut and placed in four quadrants. The total weight of all single fibers in each quadrant and the The total weight of the high anti-penetration short fibers in each quadrant, and the mixing rate of the high anti-penetration short fibers in each quadrant in the quadrant was calculated. According to the same method, the mixing ratio of the high anti-penetration staple fibers in each quadrant of the remaining 4 samples was obtained, a total of 20 sets of data were obtained, and the sample standard deviation of the 20 sets of data was calculated as the high anti-penetration short fiber of the present invention. The standard deviation of the mixing rate.

(4) Anti-transmission rate

Use a hue meter (model 650, manufacturer datacolour) to test the L values of the whiteboard and blackboard: L (white), L (black). Take 3 pieces of 10×10cm sample cloth, and test their L values against the whiteboard and blackboard respectively. The L value of the whiteboard and the sample cloth is recorded as L1, and the L value of the blackboard and the sample cloth is recorded as L2. The permeability of the cloth:

Barrier rate (%)=100%-[(L1-L2)*100%].

(5) Absolute value of reflectivity difference

Cut 2 flat and wrinkle-free 10cm×10cm samples, one of which is used as the test sample in the dry state, and the other is used as the test sample in the wet state. Use an ultraviolet spectrophotometer to measure the reflectance of the sample in the dry state and in the wet (wet saturation) state, respectively, and then calculate the absolute value of the difference between the two. The wet (wet-saturated) state refers to soaking the sample in water, taking it out when it is completely wet, and then laying it flat in an environment with a temperature of 20°C and a humidity of 65%, and it is called the wet-saturated state when it is not dripping. The dry state refers to a state in which an environment of 20° C. and a humidity of 65% has been equilibrated for 24 hours. According to the same method, a total of 5 sets of data are measured, and the average value is taken as the absolute value of the reflectivity difference of the present invention.

(6) UV resistance (UV resistance, UPF value)

According to GB/T 6529-2008 standard.

(7) Heat shielding property

A piece of 15cm*15cm sample cloth is first pretreated at 50℃*1 hour, and then placed in a standard environment of 20℃*65%RH to adjust humidity for more than 12 hours. Using the equipment with lamp model: PRS500W, lamp power: 500W, the irradiation distance is 50cm, the black cardboard and the sample are kept at a distance of 5mm, a temperature sensor is placed in the middle of the reverse side of the black cardboard, and the surface of the sample cloth is irradiated with a lamp. The irradiation time is For 15 minutes, the temperature was recorded every 1 minute, and the temperature at the 10th minute was taken as the data of the heat shielding property of the present invention. The lower the temperature, the better the heat shielding property.

Example 1

The core-sheath structure PET raw cotton with a rutile-type titanium dioxide particle content of 12.1 wt% is selected as the high-impermeable short fiber raw material, and the cotton-beating process, the carding process, the drawing process, the roving process and the siro compact spinning process are followed in turn. Cotton beating process: two times cotton beating, drawing process: two times drawing, siro compact spinning process: the number of revolutions is 12500rpm, the draft ratio is 20 to 40 times, and the average negative pressure of the suction port is 2000Pa. The high anti-penetration short fiber content is: 100wt% Ne 45 Staple Yarn.

The above-mentioned spun fiber yarn is used as warp and weft yarn, 1/1 plain weave is woven, the warp density is 110/inch, and the weft density is 76/inch to obtain grey fabric, and then scouring (90 ° C × 20 minutes) → dyeing (dispersion). dyestuff, 130°C × 30 minutes) → post-finishing (polyester water-absorbing softener, 80° C × 20 minutes) → drying process (150° C × 1 minute) to obtain the woven fabric of the present invention, and the performance parameters are shown in the table 1.

Example 2

The multi-layered PET raw cotton with a rutile-type titanium dioxide particle content of 7.7 wt % and a semi-matte cationic PET raw cotton with a titanium dioxide particle content of 0.3 wt % were selected as raw materials, wherein the cotton mixing process: two times of cotton beating, and the drawing process: two Second drawing, the rest are the same as in Example 1, to obtain 45-inch staple fiber yarn and woven fabric with a high anti-penetration short fiber content of 85wt%, the performance parameters are shown in Table 1.

Among them, the multi-layer structure PET raw cotton has a three-layer structure, and the cross-section is an outer layer, a middle layer and an inner layer from the outside to the inside. The three layers are all PET containing white titanium dioxide particles. The content of titanium dioxide particles in the intermediate layer is 15wt% The proportion of the middle layer in the whole section is 50%, and the content of titanium dioxide particles in both the outer layer and the inner layer is 0.3 wt%.

Example 3

The core-sheath structure PET raw cotton and Xinjiang cotton with a rutile-type titanium dioxide particle content of 12.1 wt% were selected as raw materials to obtain sliver, namely, a cotton sliver formed by the core-sheath structure PET raw cotton and a cotton sliver formed by 100% Xinjiang cotton, respectively, In the drawing process, three times of drawing were used, and the rest were the same as those in Example 1, to obtain a 45-inch spun yarn and a woven fabric with a high anti-penetration short fiber content of 65 wt%. The performance parameters are shown in Table 1.

Example 4

The core-sheath structure PET raw cotton with a rutile-type titanium dioxide particle content of 29.5 wt% and viscose fibers with a titanium dioxide particle content of 0.3 wt% were selected as raw materials, and the rest were the same as in Example 2, and a 45-inch high-impermeable short fiber content of 65 wt% was obtained. Count spun fiber yarn and woven fabric, the performance parameters are shown in Table 1.

Example 5

The core-sheath structure PET raw cotton and Xinjiang cotton with a rutile-type titanium dioxide particle content of 20.0 wt% were selected as raw materials to obtain cotton sliver, and the rest were the same as in Example 3, and the 45-inch staple fiber yarn with a high anti-penetration short fiber content of 65 wt% was obtained. And woven fabrics, the performance parameters are shown in Table 1.

Example 6

The core-sheath structure PET raw cotton and Xinjiang cotton with a rutile-type titanium dioxide particle content of 12.1 wt % are used as raw materials to obtain sliver respectively, and the drawing process is adopted twice, and the rest are the same as in Example 3, to obtain a high anti-penetration short fiber content. It is 65wt% 45-inch staple fiber yarn and woven fabric, and the performance parameters are shown in Table 1.

Example 7

Selecting calcium carbonate particle content to be 12.1wt% core-sheath structure PET raw cotton and U.S. cotton as raw materials to make sliver respectively, all the other are the same as in Example 3, to obtain high anti-penetration short fiber content and be 45 British count spun fiber yarns of 65wt% and The performance parameters of the woven fabric are shown in Table 1.

Example 8

Select rutile-type titanium dioxide particle content of 7.7wt% of multi-layer structure of PET raw cotton and titanium dioxide particle content of 0.3wt% of viscose fiber as raw materials, the rest are the same as in Example 2, to obtain high anti-penetration short fiber content of 85wt% 45 British count spun yarn and woven fabric, the performance parameters are shown in Table 1.

Among them, the multi-layer structure PET raw cotton has a 7-layer structure, and the cross-section is the first layer, the second layer, the third layer...the seventh layer, and the seven layers are all PET containing white titanium dioxide particles. The second layer, The content of titanium dioxide particles in the fourth and sixth layers is 15 wt%, and the total proportion of these three layers in the entire section is 50%. The first, third, fifth, and seventh layers are titanium dioxide particles The content of particles was all 0.3 wt %.

Example 9

The core-sheath structure PET raw cotton and American cotton with an anatase type titanium dioxide particle content of 12.1 wt% were selected as raw materials to obtain sliver, and the rest were the same as in Example 3, and the 45-inch staple fiber with a high anti-penetration short fiber content of 65 wt% was obtained. Yarn and woven fabric, the performance parameters are shown in Table 1.

Example 10

Selecting the multi-layered PET raw cotton and American cotton with a rutile-type titanium dioxide particle content of 7.7 wt% as raw materials to obtain sliver, the rest are the same as in Example 3, and the 30-inch staple fiber yarn with a high anti-penetration short fiber content of 65 wt% is obtained. .

On a 28-needle circular knitting machine, plain stitches are used to knit to obtain grey fabric, and then scouring (90℃×20min)→dyeing (disperse dye, 130℃×30min)→finishing (polyester-based water-absorbing softener, 80℃ × 20 minutes) → drying process (150° C. × 1 minute) to obtain the circular knitted fabric of the present invention, and the performance parameters are shown in Table 1.

Example 11

Using rutile-type titanium dioxide particle content of 12.1wt% side-by-side structure PET raw cotton and American cotton as raw materials to make sliver respectively, the rest are the same as in Example 3, to obtain spun yarn and woven fabric with high anti-penetration short fiber content of 65wt%, The performance parameters are shown in Table 1.

Example 12

The core-sheath structure PET raw cotton with a rutile-type titanium dioxide particle content of 12.1 wt % and a semi-matte PET raw cotton with a titanium dioxide content of 0.3 wt % were selected as raw materials, and the rest were the same as in Example 2, and the short fibers with a high anti-penetration short fiber content of 41 wt % were obtained. Yarn and woven fabric, the performance parameters are shown in Table 1.

Example 13

Select rutile-type titanium dioxide content of 7.7wt% of multi-layered PET raw cotton and titanium dioxide content of 0.3wt% of viscose fiber as raw materials, the rest are the same as in Example 2, to obtain high anti-penetration short fiber content of 85wt% of short fibers Yarn and woven fabric, the performance parameters are shown in Table 1.

Among them, the multi-layer structure PET raw cotton has a 12-layer structure, and the cross-section is the first layer, the second layer, the third layer... The 12th layer and the 12th layer are all PET containing white titanium dioxide particles from the outside to the inside. The content of titanium dioxide particles in the middle is 15wt%, the proportion of the double-numbered layers in the entire section is 50%, and the content of titanium dioxide particles in the single-numbered layers is 0.3wt%.

Example 14

Select rutile-type titanium dioxide content to be 7.7wt% of multi-layered polyamide raw cotton and American cotton as raw materials to obtain cotton sliver, the rest are the same as in Example 3, to obtain high anti-penetration fiber content is 85wt% of spun fiber yarn and woven fabric , the performance parameters are shown in Table 1.

Among them, the multi-layer structure polyamide raw cotton has a 3-layer structure. The cross-section is an outer layer, a middle layer and an inner layer from the outside to the inside. The three layers are all polyamides containing white titanium dioxide particles. The content of titanium dioxide particles in the middle layer is 15wt. %, the proportion of the middle layer in the entire section is 50%, and the content of titanium dioxide particles in the outer layer and the inner layer are both 0.3 wt%.

Comparative Example 1

The round-section PET raw cotton with a rutile-type titanium dioxide particle content of 0.3 wt% was selected as the raw material, and the rest were the same as those in Example 1, to obtain spun yarn and woven fabric. The performance parameters are shown in Table 1.

Comparative Example 2

PET raw cotton with a circular section with an anatase type titanium dioxide particle content of 2.6 wt% was selected as the raw material, and the rest were the same as those in Example 1, to obtain spun yarn and woven fabric. The performance parameters are shown in Table 1.

Comparative Example 3

The content of high anti-penetration staple fiber is 35wt%, and the rest are the same as those in Example 3. The staple fiber yarn and woven fabric are obtained, and the performance parameters are shown in Table 1.

Table 1

According to the above table,

(1) It can be seen from Example 3 and Example 6 that, under the same conditions, the spun fiber yarn with the standard deviation of the mixing ratio of high anti-penetration staple fibers is 9.0 and the spun yarn with the standard deviation of the mixing ratio of high anti-penetration short fibers is 13.0. , the absolute value of the reflectivity difference of the former fabric is lower than that of the latter, that is to say, the fabric obtained by the former has better anti-perspiration effect than the latter, and the anti-penetration, UV resistance and heat shielding properties are also better than the latter.

(2) It can be seen from Example 3 and Example 7 that under the same conditions, the spun fiber yarn composed of the high permeability-proof short fibers containing titanium dioxide particles and the spun fiber yarn composed of the high permeability-resistant short fibers containing calcium carbonate particles are similar to each other. Compared with the latter, the absolute value of the reflectivity difference of the fabric obtained by the former is lower than that of the latter, that is to say, the anti-perspiration effect of the fabric obtained by the former is better than that of the latter, and the permeability, UV resistance and heat shielding properties of the fabric obtained by the former are also all good. better than the latter.

(3) It can be seen from Example 3 and Example 9 that under the same conditions, the spun yarn formed from the highly impermeable short fibers containing anatase-type titanium dioxide particles and the spun yarn formed of the highly impermeable short fibers containing rutile-type titanium dioxide particles Compared with spun yarn, the absolute value of the reflectivity difference of the fabric obtained by the former is lower than that of the latter, that is to say, the anti-perspiration effect of the fabric obtained by the former is better than that of the latter, and the fabric obtained by the former has anti-penetration, UV resistance and shielding. The heat is also better than the latter.

(4) It can be seen from Example 8 and Example 13 that under the same conditions, the spun yarn formed of high-impermeability short fibers with a 7-layer cross-sectional structure and the short fiber yarn formed of high-impermeability short fibers with a 12-layer cross-sectional structure Compared with fiber yarn, the absolute value of the reflectivity difference of the former fabric is lower than that of the latter, that is to say, the fabric obtained by the former has better anti-perspiration effect than the latter, and the fabric obtained by the former has anti-penetration, UV resistance and heat shielding. Sex is also better than the latter.

(5) It can be seen from Comparative Example 1 and Example 1 that under the same conditions, the spun fiber yarn composed of short fibers with a titanium dioxide particle content of 0.3 wt % and the spun fiber yarn composed of short fibers with a titanium dioxide particle content of 12.1 wt % In comparison, the absolute value of the reflectivity difference of the former fabric is very high, which means that the former fabric has a poor anti-perspiration effect, and the former fabric has poor anti-penetration, UV resistance and heat shielding properties.

(6) From Comparative Example 2 and Example 1, it can be seen that under the same conditions, the spun fiber yarn composed of short fibers with a titanium dioxide particle content of 2.6 wt % and a spun fiber yarn with a titanium dioxide particle content of 12.1 wt % are in phase Compared with the former, the absolute value of the reflectivity difference of the former fabric is very high, that is to say, the former fabric has a poor anti-perspiration effect, and the former is also poor in anti-penetration, UV resistance and heat shielding.

(7) It can be seen from Comparative Example 3 and Example 12 that, under the same conditions, the spun fiber yarn with a mixing ratio of high anti-penetration staple fibers of 41 wt% and the spun fiber yarn with a mixing ratio of high anti-penetration staple fibers of 35 wt%, the former The absolute value of the reflectivity difference of the obtained fabric is very high, that is to say, the former fabric has poor anti-perspiration effect, and the former obtained fabric also has poor anti-permeability, UV resistance and heat shielding properties.

Claims

A spun fiber yarn is composed of more than 40wt% of high anti-permeability short fibers, characterized in that: the high anti-permeability short fibers are short fibers with an inorganic particle content of 7.0-30.0wt%.
The spun fiber yarn according to claim 1, characterized in that: the spun fiber yarn is a uniform blended yarn, and in four quadrants on the cross section of the spun fiber yarn, in each quadrant, the high anti-penetration short The standard deviation of the blending ratio of fibers was within 10.
The spun fiber yarn according to claim 1, wherein the inorganic particles in the high-impermeability short fibers are one or more of titanium dioxide, calcium carbonate and zinc oxide.
The spun fiber yarn according to claim 1, wherein the high anti-penetration staple fiber is polyester or polyamide.
The spun fiber yarn according to any one of claims 1 to 4, wherein the high anti-penetration staple fiber is a composite fiber with a core-sheath cross-sectional structure or a composite fiber with a multi-layer cross-sectional structure of three or more layers fiber.
The spun fiber yarn according to claim 5, wherein the high anti-penetration short fiber is a composite fiber with a multi-layer cross-sectional structure of 3 to 15 layers.
A fabric comprising the spun yarn according to any one of claims 1 to 6.
The fabric according to claim 7, wherein the absolute value of the difference in visible light reflectance of the fabric in a dry and wet state is below 7%.