阅读说明：本技术 双功能纺丝+长丝纤维织造毛圈降温毛巾 (Dual-function spinning and filament fiber weaving terry cooling towel ) 是由 大卫·查德·劳伦斯 于 2020-01-22 设计创作，主要内容包括：本发明的实施方案提供了包括配置成表现出吸收能力的第一面和配置成表现出降温能力的第二面的毛圈织物。所述第一面可以包括含有多根绒头经纱的纺丝纤维线圈,所述第二面可以包括多根纬纱和多根地经纱,其中所述多根纬纱和所述多根地经纱中的至少一者包括合成长丝纱。(Embodiments of the present invention provide a terry fabric comprising a first side configured to exhibit absorbent capacity and a second side configured to exhibit cooling capacity. The first face may include spun fiber loops comprising a plurality of pile warp yarns and the second face may include a plurality of weft yarns and a plurality of ground warp yarns, wherein at least one of the plurality of weft yarns and the plurality of ground warp yarns comprises synthetic filament yarns.)

1. A terry fabric, the fabric comprising:

a first side, wherein said first side comprises a spun fiber loop comprising a plurality of pile warp yarns; and

a second side, wherein the second side comprises a plurality of weft yarns and a plurality of ground warp yarns, wherein at least one of the plurality of weft yarns and the plurality of ground warp yarns comprises a synthetic filament yarn.

2. The fabric of claim 1 wherein the spun fiber loops comprise one of cotton and cotton/synthetic filament blends.

3. The fabric of claim 2, wherein the cotton is a cotton-based blend.

4. The fabric of claim 2, wherein the cotton/synthetic filament blend is one of a cotton/polyester blend, a cotton/nylon blend, a cotton/polyester/nylon blend.

5. The fabric of claim 1 wherein the synthetic filament yarn is one of polyester, nylon, and polyester/nylon blends.

6. The fabric of claim 1, wherein the first side comprises a pile loop.

7. The fabric of claim 1, further comprising two pile loops.

8. The fabric of claim 1, further comprising:

at least one other synthetic filament yarn coating said synthetic filament yarn.

9. A fabric according to claim 8, wherein the at least one other synthetic filament yarn is coated with the synthetic filament yarn by one of single coating, double coating, and air jet coating techniques.

10. A fabric according to claim 8, wherein the synthetic filament yarns are wrapped by the at least one other synthetic filament yarn and spun to form a single yarn.

11. The fabric of claim 1 wherein the spun fiber loops have a pile height of greater than 0.5 mm.

12. The fabric of claim 1, wherein the fabric is associated with a heat flux of at least 10000 cumulative watts per square meter.

13. The fabric as claimed in claim 1, wherein said fabric comprises at least 10% synthetic filament yarns.

14. The fabric of claim 1, wherein the first side is configured to absorb at least four times the weight of the fabric of liquid.

15. The fabric according to claim 1, wherein the plurality of pile warp yarns, the plurality of weft yarns, and the plurality of ground warp yarns are implemented in a 3-weft terry loop construction.

16. A fabric as claimed in claim 1 wherein said plurality of ground warp yarns comprise synthetic spun yarns.

Technical Field

The present application relates to a dual function, multi-layer terry fabric.

Background

The name terry fabric comes from the knitting method used to form the fabric, i.e., terry knitting. Terry fabrics, such as terry towels, typically correspond to warp pile fabrics that include uncut pile loops on each side of the fabric. The pile loops on each side of the fabric may be used to absorb liquid (e.g., water). Thus, the terry loop fabric may be used in bathing and/or exercise activities to absorb excess water and/or perspiration. However, since such fabrics are typically composed of 100% cotton, they have reduced evaporative cooling capabilities. Furthermore, although synthetic fabrics have improved evaporative cooling capabilities compared to cotton-based fabrics, synthetic fabrics do not absorb liquids as efficiently as cotton-based fabrics.

Accordingly, there is a need for a solution that can overcome at least some of the deficiencies described herein.

Disclosure of Invention

According to one embodiment, the present invention is directed to a terry fabric comprising a first side configured to exhibit absorbent capacity and a second side configured to exhibit cooling capacity. According to one embodiment, the first side may comprise spun fiber loops comprising a plurality of pile warp yarns and the second side may comprise a plurality of weft yarns and a plurality of ground warp yarns, wherein at least one of the plurality of weft yarns and the plurality of ground warp yarns comprises synthetic filament yarns (and/or synthetic spun yarns).

Drawings

Fig. 1 shows a cross-sectional view of an improved terry loop fabric according to an exemplary embodiment of the present invention.

Fig. 2 shows a 3-weft woven terry having one pile loop according to an exemplary embodiment of the present invention.

Fig. 3 shows a 3 weft woven terry having two pile loops according to an exemplary embodiment of the present invention.

Fig. 4A to 4B show cross-sectional views of a synthetic filament yarn according to an exemplary embodiment of the present invention.

Fig. 5A to 5D show a coated synthetic filament yarn according to an exemplary embodiment of the present invention.

Detailed Description

The following description of the embodiments provides non-limiting representative examples of reference numbers to particularly describe features and teachings of various aspects of the present invention. The described embodiments are to be understood as capable of being practiced separately from or in combination with other described embodiments from the described embodiments. Those of ordinary skill in the art, with access to the description of the embodiments, will be able to learn and understand the various described aspects of the present invention. The description of the embodiments is intended to facilitate an understanding of the invention, and other embodiments not specifically contemplated, but within the knowledge of one skilled in the art upon reading the description of the embodiments will be understood to be consistent with the use of the invention.

According to one embodiment, evaporative cooling performance can be added to cotton-based terry fabrics (e.g., towels) by inserting synthetic filament yarns (polyester-based or nylon-based) during the weaving process. Terry fabrics typically consist of 100% cotton or cotton-based blends (CVC), i.e., greater than 50% cotton, and typically weigh between 340 and 370 grams per square meter (gsm). The improved terry fabric is capable of absorbing more than four times its weight of liquid (e.g., sweat or water) on the loop side of the fabric after insertion of the synthetic filament yarns, while also being capable of conductive cooling to the human skin on a flat non-loop side, more than 20 degrees fahrenheit below the human average core body temperature (e.g., in moderately warm weather conditions), and a cooling capacity of more than 10000 cumulative watts after wet activation. According to one embodiment, the improved terry fabric may include a combination of synthetic and cotton yarns, which may correspond to at least one of ground, pile and weft yarns, respectively.

According to one embodiment, one side of the improved terry fabric is configured to exhibit absorbent capacity. The face may include raised loops having a lint height greater than 0.5mm on the loop face. The raised coils may be varied in length to other lengths depending on the desired amount of absorption and weight. In addition, the other side of the terry fabric is configured to exhibit cooling capability. The other face may include synthetic filament yarns configured to impart additional evaporative temperature reduction properties to impart a cooling sensation to the user.

According to one embodiment, the percent wet pick up (WPU%) of the improved terry fabric may be greater than 400% (or four times) of the fabric weight. In addition, the improved terry fabric may produce greater than 10000W/m as measured on the non-loop side of the fabric²(Watt/square meter) and may exhibit a cumulative cooling capacity of greater than 700w/m²At one peak per minute, in watts per square meter (heat flux) output. Further, according to one embodiment, the improved loop fabric may remain wet for a duration of greater than 10 hours.

In addition, the unique combination of synthetic filament yarns with spun cellulose yarns and/or synthetic yarns is configured to increase cooling characteristics (e.g., maximum compartmentalization cooling capability and cooling feel) as well as moisture transport and evaporation. In particular, specially modified cross-section synthetic filament yarns may be added to the structure to aid in moisture transport and evaporation. These yarns may also incorporate embedded temperature reducing particle technology (e.g., jadeite or mica) to increase the Q-max rating (instant cool feel) of the material on the non-coil side. In addition, conjugate yarns with modified pie-shaped cross-sections (e.g., polyester and nylon) may be added in place of the spun fibers to enhance moisture retention and evaporation.

According to one embodiment, the cooling may be activated as follows: after the material is used to absorb undesirable perspiration, the improved terry fabric may then be wetted, twisted and snapped (snap) to form a cooling device that provides cooling primarily on the non-coil side of the fabric. Furthermore, in order to inhibit microbial growth, the terry fabric may be treated with an antimicrobial chemical or special yarns may be added thereto, thereby making it odorless after repeated use and wash care. However, the cooling material does not require chemicals to impart cooling capability. In addition, the improved loop fabric is machine washable and dryable. In addition, the improved terry fabric has a cooler feel (or higher Q-max) due to the use of a cooling yarn (e.g., a synthetic filament yarn) on the non-loop side of the material.

Thus, with the improved terry fabric, a single material can provide both absorption and cooling, e.g., one side configured to absorb liquid/moisture to dry sweat or absorb moisture, while the other side is configured to provide conductive cooling. For example, as described above, one face (e.g., the non-coil cooling face) may consist essentially of polyester or nylon yarn, which may consist of modified cross-section yarn and may contain embedded particles (e.g., jadeite or mica), which help transport and evaporate moisture while providing a cool feel. The opposite side (e.g., loop absorbent side) may be composed primarily of cotton yarn, which enables the improved terry fabric to absorb and retain moisture.

In view of the above, the improved loop fabric may provide the following advantages: (i) dual functions of absorption and conduction cooling, (ii) a temperature decrease of 30 degrees below the average core body temperature when wetted after 5 minutes and a decrease of 20 degrees below the average skin temperature after only 2 minutes as measured in a controlled conditions laboratory, (iii) a duration of cooling of more than 10 hours in a conditioned laboratory environment, (iv) a WPU% of more than four times its weight, which is significantly higher than cooling fabrics currently on the market, and (v) an increased Q-max (cool feel) on the cooled non-coil side of the material.

Fig. 1 shows a cross-sectional view of an improved terry fabric according to an exemplary embodiment of the present invention. According to one embodiment, the improved terry fabric 100 may include an absorbent side 110 and a cooling side 120. According to one embodiment, the absorbent surface 110 may correspond to a loop of spun fibers, such as cotton (or a cotton/synthetic blend), that includes a plurality of pile warp yarns 115. In addition, the cooling surface 120 includes a plurality of weft yarns 125 and a plurality of warp yarns 126. According to one embodiment, the plurality of weft yarns 125 may comprise synthetic filament yarns (e.g., polyester-based or nylon-based synthetic filament yarns). Similarly, the plurality of ground warp yarns 126 may also comprise polyester-based or nylon-based synthetic filament yarns. According to one embodiment, if the terry fabric 100 is a cotton/polyester blend, the blend should contain at least 10% polyester in total. Further, if the terry fabric 100 is a cotton/nylon blend, the blend should contain at least 10% nylon in total. Further, if the terry fabric 100 is a cotton/polyester/nylon blend, the blend should comprise at least 10% nylon and 10% polyester in total. Furthermore, according to one embodiment, other spinning fibers, such as modal, rayon, bamboo from rayon, tencel, and the like, may also be used in place of cotton in one of the above blends. Furthermore, instead of cotton, it is also possible to use a blend of cotton and at least one other spinning fiber. Further, according to one embodiment, the terry fabric 100 may include a weight range of 160gsm to 700 gsm.

The cooling effect of the loop fabric 100 follows the evaporative cooling principle. The principle is in particular that water has to be heated to change from liquid to vapour. Once evaporation occurs, this heat from the liquid water is carried away due to the evaporation, resulting in a cooler liquid. After the loop fabric 100 is wetted with water and preferably twisted to remove excess water, a snap or quick turn in air is a recommended process as it helps to promote and accelerate the movement of moisture from the absorbent surface 110 where water is stored to the cooling surface 120 where water evaporation occurs. Snapping or rapid rotation in air also increases the evaporation rate and allows the material temperature to decrease more rapidly by exposing a larger surface area of the material to the air and increased air flow. More specifically, the loop fabric 100 serves as a means to facilitate and accelerate the evaporation process.

Once the temperature of the remaining water in the cooling surface 120 drops by evaporation, heat exchange occurs within the water by convection, between the water and the fabric by conduction, and within the fabric by conduction. Accordingly, the temperature of the loop fabric 100 is lowered. The evaporation process continues further by wicking water from the absorbent surface 110 to the cooling surface 120 until the stored water is used up. The evaporation rate decreases as the temperature of the loop fabric 100 decreases. The temperature of the loop fabric 100 gradually drops to a point where a balance is reached between the rate of heat absorption from the environment into the material and the rate of heat release by evaporation.

Once the wetted loop fabric 100 is placed on a person's skin, the cooling energy from the loop fabric 100 is transmitted by conduction. After the cooling energy transfer has occurred, the temperature of the cooling fabric is raised to equilibrate with the skin temperature. Once this occurs, the wetted loop fabric 100 can be easily reactivated by snapping or rapid rotation to allow the temperature to drop again.

Fig. 2 shows a 3-weft woven terry having one pile loop according to an exemplary embodiment of the present invention. According to one embodiment, woven terry loop 200 includes pile warp yarn 210, ground warp yarns 220 and 230, and weft (i.e., picks) yarns 240, 250, and 260. According to one embodiment, the front and back pile warp yarns 210 and the first and second ground warp yarns 220 and 230, respectively, may be utilized to form a so-called 2/1 weft rib weave structure. In this weave structure, one pile warp yarn 210 leads a ground warp yarn (e.g., 220 or 230) by one weft yarn. For example, in a 1:1 warp sequence, each warp yarn end is followed by a pile warp yarn end, whereas in a 2:2 warp sequence, two warp yarn ends are followed by two pile warp yarn ends. According to one embodiment, the figure depicts a 2:1 warp yarn order between the warp yarn ends and the pile warp yarn ends. According to another embodiment, a 2:2 warp structure using pile yarns on only one face is also possible.

As shown in table 1 below, the woven loop 200 may be configured in a number of ways, where "C" corresponds to cotton or regenerated cellulose spun fibers (where the fiber size is in the range of 8Ne (cotton count to english) to 60Ne (cotton count to english)), "S" corresponds to synthetic filament yarns (where the filament size is in the range of 10 denier to 300 denier), "CS" corresponds to cotton/synthetic blend spun fibers (where the fiber size is in the range of 8Ne to 60 Ne), and "SS" corresponds to synthetic spun fibers (where the fiber size is in the range of 8Ne to 60 Ne).

TABLE 1

According to one embodiment, S may be one of polyester, nylon, and polyester/nylon blends. Similarly, the SS may also be one of polyester, nylon, and polyester/nylon blends. Further, the CS may be one of a cotton/polyester blend, a cotton/nylon blend, a cotton/polyester/nylon blend, a cotton/modal blend, a cotton/tencel blend, a cotton/rayon blend, and a cotton/viscose blend. Other combinations of yarns used to weave the loop 200 may also be included according to one embodiment. For example, pile 1 may be SS, ground 1 and ground 2 may be SS, and first, second, and third weft yarns are S.

Fig. 3 shows a 3-weft woven terry having two pile loops according to an exemplary embodiment of the present invention. According to one embodiment, woven terry 300 includes pile warp yarns 310 and 320, ground warp yarns 330 and 340, and weft (i.e., picks)350, 360, and 370. The weave structure of fig. 3 is similar to that of fig. 2, except that the pile warp ends alternate to two separate faces, such as the front and back faces in fig. 3, according to one embodiment. According to one embodiment, the pile height of the pile warp yarn ends on one face is greater than the pile height of the pile warp yarn ends on the other face. In particular, the pile height of the shorter pile warp yarn ends may be less than 0.5 mm. In this regard, the face with the greater pile height may be used for absorption, while the face with the shorter pile height may be used to provide more evaporative cooling (e.g., because more evaporative cooling yarns are added at the pile warp ends)

As shown in table 2 below, woven loops 200 may be configured in a number of ways.

TABLE 2

Fig. 4A to 4B show cross-sectional views of a synthetic filament yarn according to an exemplary embodiment of the present invention. For example, fig. 4A depicts a synthetic filament yarn (e.g., polyester and/or nylon) having a unique cross-section. According to one embodiment, the unique cross-section creates channels in the yarn for the moisture to move and evaporate more rapidly. Thus, the synthetic filament yarn of fig. 4A may be implemented through the cooling surface 120 of the terry fabric 100. Furthermore, fig. 4B depicts a synthetic filament yarn having a star-shaped cross-section. In this regard, the star-shaped cross-section provides higher absorption and therefore more efficient retention of water. Thus, the synthetic filament yarn of fig. 4B may be implemented through the absorbent side 110 of the terry fabric 100. According to one embodiment, the different cross-sections facilitate the movement and diffusion of moisture to the outer layer of the fabric. Furthermore, the synthetic filament yarn may also comprise absorbent micro-fibres. According to one embodiment, the absorbent microfiber yarn may be less than 1 denier per filament (dpf). In addition, the absorbent microfiber yarn may use multiple filaments (e.g., 72 filaments) to provide absorbent properties. In addition, according to another embodiment, a conjugate bicomponent special cross-section yarn can be used to provide excellent absorption characteristics. Furthermore, by splitting the yarns, a greater surface area and thus more hollow parts of the double-layer fabric can be formed for absorption.

According to one embodiment, the synthetic filament yarn comprises a thickness of half the thickness of cotton yarn. Thus, to balance the thickness of the cotton yarn, two ends of the synthetic filament yarn may be added instead of one end. This can be achieved by covering the main synthetic spun yarn or filament yarn with another synthetic yarn filament. Fig. 5A to 5D show a coated synthetic filament yarn according to an exemplary embodiment of the present invention. For example, fig. 5A shows a double-coated synthetic filament yarn. In particular, fig. 5A depicts a coated synthetic filament yarn 500 comprising a core of predominantly synthetic spun yarn or filament yarn 502 coated in a double-coated manner by another synthetic filament yarn 504. Figure 5B shows a single-covered synthetic filament yarn. In this regard, fig. 5B depicts a core of a predominantly synthetic spun yarn or filament yarn 502 being coated in a single-coating manner by another synthetic filament yarn 504. Further, fig. 5C shows an air-jet coated synthetic filament yarn. In this regard, fig. 5B depicts a core of a predominantly synthetic spun yarn or filament yarn 502 coated by another synthetic filament yarn 504 by an air jet coating technique. Finally, fig. 5D shows core spun synthetic filament yarn. In this regard, a core of predominantly synthetic spun yarn or filament yarn 502 is wrapped by other synthetic filament yarn 504 and spun into a single yarn 500. The table in table 3 below describes possible combinations of the core synthetic filament yarn 502 and the further synthetic filament yarn 504.

TABLE 3

According to one embodiment, by increasing the thickness of the synthetic filament yarns, not only does the weight of the synthetic filament yarns balance the weight of the cotton, but the cooling strength of the overall terry fabric is also increased.

Furthermore, although the present invention has been described with respect to a 3-pick loop construction, it may also be implemented with 2-pick loop, 3-pick loop, 4-pick loop, 5-pick loop or even more pick loop constructions, according to one embodiment. In this regard, the present invention may be practiced in any fabric that utilizes a loop construction.

In the foregoing description of embodiments, various features may be grouped together in a single embodiment for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claims require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus the following claims are hereby incorporated into this description of the embodiments, with each claim standing on its own as a separate embodiment of the invention.

Further, it will be apparent to those skilled in the art from consideration of the specification and practice of the present disclosure that various modifications and changes can be made to the disclosed system without departing from the scope of the present disclosure as claimed. It is intended, therefore, that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.