Method of Industrial Producing Elastomeric Yarn and Fabric thereof

Abstract

The present invention relates to make stretch yarn by using at least two roving and two elastomeric filaments with variable draft to allow the yarn made in the fabric to get good stretch, good recovery and good shrinkage. The invention is applicable for all types of fibers material and is not limited in the yarn count. The said invention yarn is woven into fabrics exhibiting the excellent stretch characteristics and functional performance for commercial application.

Claims

1. A ring spun stretch yarn comprising at least two elastomeric filaments with at least two different mean drafts, wherein the mean draft on individual filament is varied and two fibrous sheath of at least one staple fiber, and wherein the elastomeric filaments have a denier from 20 to 140 and said the fibrous sheath has an English cotton yarn count Ne from 4 to 60.

2. The stretch yarn of claim 1, wherein said fibrous sheath comprises natural or synthetic staple fibers, cotton, polyester, rayon, wool, nylon, acrylic or combination thereof.

3. The stretch yarn of claim 1, wherein the mean draft of the elastomeric filament is from 1.05 to 5.

4. The stretch yarn of claim 1, wherein the mean draft is calculated by individual actual draft/time along that elastomeric filament.

5. The stretch yarn of claim 1, wherein the draft/time of the elastomeric filament is controlled by electronic but not limited.

6. The stretch yarn of claim 1, wherein draft on individual filament is varied in the range from ±50% of the mean draft, but not limited to this range.

7. The stretch yarn of claim 1, wherein the elastomeric filament is spandex/elastane/elastomer but not limited.

8. The stretch yarn of claim 1, wherein the elastomeric filament can be at least one type material.

9. The stretch yarn of claim 1, wherein the fibrous sheath can be natural fibers, regenerated fibers, synthetic fibers and a combination thereof.

10. The stretch yarn of claim 1, wherein the stretch yarn can be used in producing slub yarn/normal yarn which can get some special fancy effect.

11. A woven fabric comprising the stretch yarn of claim 1 in warp or filling or both.

12. The woven fabric of claim 11, wherein the fabric is denim or piece dyed.

13. A knitted fabric comprising the stretch yarn of claim 1.

14. A sweater comprising the stretch yarn of claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] FIG. 1 depicts the side view of the apparatus for the present invention of normal ring spinning machine.

[0026] FIG. 2 depicts the side view of the apparatus for the present invention of using two elastomeric filaments with different drafts with two roving.

[0027] FIG. 3 depicts the view of position of the elastomeric filaments in the yarn with variable draft in the same yarn.

[0028] FIG. 4 depicts the view of position of the elastomeric filament in the yarn if the draft is the same.

[0029] FIG. 5 depicts the side view of the apparatus for the present invention of using three elastomeric filaments with different drafts with three roving.

[0030] FIG. 6 depicts the view of position of three elastomeric filaments in the yarn with variable draft.

DETAILED DESCRIPTION

[0031] The objective of the present invention is to find a way to produce a ring spun yarn by using elastomeric filament (not limited to spandex and other elastomers also applicable) to achieve good elongation, good recovery and less shrinkage without affecting other physical properties both in yarn and in fabric. The present yarn is suitable for denim, piece dyed, circular knit and sweater as well. The present invention is a ring spun yarn comprising at least two elastomeric filaments (not limited to spandex and other elastomers also applicable) with at least two different mean drafts. And said the filament ranges from 20 deniers to 500 deniers, and preferably from 20 deniers to 140 deniers, wherein the draft of the filaments ranges from 1.05 to 5. In another embodiment, the yarn count of the ring spun yarn has no limitation and said ranges from Ne 4 to 60 preferable.

[0032] It is well known that the ways of making staple spun yarns are ring spinning, Open-End Spinning and that of Jet Spinning, amongst those, Ring Spinning is one of the most common way. The present invention is using this Ring Spinning Technology.

[0033] The embodiments and the examples disclosed herein are made to show the present invention and are not intended to be limiting.

[0034] In the ring spinning production, spinning is the final stage of processing that produces a continuous twisted strand of fibers which has received its final attenuation. In FIG. 1, it shows the skills in the art.

[0035] During the normal spinning process, the main sections include material [A], drafting [B] and twisting [C] as in FIG. 1. In the present invention, the material used in [A] is those natural or synthetics staple fibers, not limited to cotton, rayon, polyester, wool, acrylic, etc. or a combination thereof. It consists of two roving with the same material or two different materials.

[0036] In the drafting system [B] consists of three pair of rolls 41, 42, 43 and for most system, aprons are mounted with the middle rolls 42. The speed ratio of each pair of roll is so adjusted that the fibers 10 are delivered through a trumpet 61 from a slowly moving pair of rolls 43 towards a rapidly moving pair of rolls 41. The final yarn count depends on the yarn count of the material 10 and the ratio of the linear speed between these pair of rolls 41, 43 for those normal yarns. The strength of the yarn depends on the material and the twist added in the twisting section [C].

[0037] The present invention of this stretch yarn is produced by inserting at least two elastomeric filaments into the core of the fibers sheath of the described ring spun yarn. The apparatus [D] is shown in FIG. 2. The material of these two types of elastomeric filaments 21, 31 can be the same or with different material, like those spandex or elastomer or a combination thereof. The draft is one of the most important related factors in the present invention. During the spinning process, the elastomeric filaments 21 are unwound from the rollers 22, 23 whereas elastomeric filaments 31 are unwound from the rollers 32, 33. The draft on the elastomeric filament 21 is controlled by the ratio of the surface speed of front roller 41 and roller 23 whereas the draft on the elastomeric filament 31 is controlled by the ratio of the surface speed of front roller 41 and the roller 33. In one embodiment of the present invention, the mean drafts of these filaments are ranging from 1.05 to 5. And that the elastomeric filament is positioned in the left to center of the fibrous sheath but not limited.

[0038] In the present invention, the ratio of the surface speed of the front roller 41 and roller 23, and the surface speed of roller 41 and roller 33 are controlled by program throughout the spinning process. The variables are denoted as:

Surface speed of roller 41/surface speed of roller 23: D.sub.231, D.sub.232, D.sub.233 . . . D.sub.23X
Surface speed of roller 41/surface speed of roller 33: D.sub.331, D.sub.332, D.sub.333 . . . D.sub.33X

[0039] The draft of D.sub.231, D.sub.232, D.sub.233 D.sub.23X is running at different time as in

T.sub.231, T.sub.232, T.sub.233 . . . T.sub.23X

[0040] The draft of D.sub.331, D.sub.332, D.sub.333 . . . & D.sub.33X is running at different time as in

T.sub.331, T.sub.332, T.sub.333 . . . T.sub.33X

[0041] Therefore, the mean draft [D.sub.21] of that filament 21 is calculated as

[00001]$D_{21}=\frac{D_{231}\times T_{231}+D_{232}\times T_{232}+D_{233}\times T_{233}\mathrm{.Math.}+D_{23X}\times T_{23X}}{T_{231}+T_{232}+T_{233}\mathrm{.Math.}+T_{23X}}$

[0042] The mean draft [D.sub.31] of that filament 31 is calculated as

[00002]$D_{31}=\frac{D_{331}\times T_{331}+D_{332}\times T_{332}+D_{333}\times T_{333}\mathrm{.Math.}+D_{33X}\times T_{33X}}{T_{331}+T_{332}+T_{333}\mathrm{.Math.}+T_{33X}}$

[0043] In practical, the difference of those variable drafts is ±50% amongst individual mean draft, but not limited.

[0044] It is calculated as:

0.50≤(D.sub.231−1)/(D.sub.21−1)≤1.50

0.50≤(D.sub.232−1)/(D.sub.21−1)≤1.50

0.50≤(D.sub.23X−1)/(D.sub.21−1)≤1.50 . . . etc.

D.sub.21,D.sub.231,D.sub.232 . . . D.sub.23X≥1 and

0.50≤(D.sub.331−1)/(D.sub.31−1)≤1.50

0.50≤(D.sub.332−1)/(D.sub.31−1)≤1.50

0.50≤(D.sub.333−1)/(D.sub.31−1)≤1.50 . . . etc.

D.sub.31,D.sub.331,D.sub.332 . . . D.sub.33X≥1

[0045] In FIG. 3, it is the view of the position of that elastomeric filament on the yarn with different draft ratio and time whereas, in FIG. 4, the draft ratio on single elastomeric filament is the same and not limited that both draft of the elastomeric filament is the same.

[0046] Another embodiment of the invention, have inserted 3 elastomeric filaments into the core of the fibers sheath as in FIG. 5. The material of these three types of elastomeric filaments 21, 31, 51 can be the same or with different material but at least two of them are elastomeric filaments (spandex) and the other one can be those polyester, nylon, PE synthetic filaments, not limited to elastic or inelastic or a combination thereof. During the spinning process, the filament 21 is unwound from the rollers 22, 23 whereas filament 31 is unwound from the rollers 32, 33 and filament 51 is unwound from the rollers 52, 53. The draft on the filament 21 is controlled by the ratio of the surface speed of front rollers 41 and roller 23 whereas the draft on the filament 31 is controlled by the ratio of the surface speed of front roller 41 and the roller 33 and the same. The draft on the filament 51 is controlled by the surface speed of front roller 41 and roller 53. In one embodiment of the present invention, the mean drafts of these filaments are ranging from 1.05 to 5. And that the elastomeric filament is positioned in the left to center of the fibrous sheath but not limited.

[0047] In the present invention, the ratio of the surface speed of the front roller 41 and roller 23, the surface speed of roller 41 and roller 33, and the surface speed of roller 41 and roller 53 are controlled by program. The variables are denoted as:

Surface speed of roller 41/surface speed of roller 23: D.sub.231, D.sub.232, D.sub.233 . . . D.sub.23X
Surface speed of roller 41/surface speed of roller 33: D.sub.331, D.sub.332, D.sub.333 . . . D.sub.33X
Surface speed of roller 41/surface speed of roller 53: D.sub.531, D.sub.532, D.sub.533 . . . D.sub.53X

[0048] The draft of D.sub.231, D.sub.232, D.sub.233 . . . D.sub.23X is running at different time as in

T.sub.231, T.sub.232, T.sub.233 . . . T.sub.23X

[0049] The draft of D.sub.331, D.sub.332, D.sub.333 . . . D.sub.33X is running at different time as in

T.sub.331, T.sub.332, T.sub.333 . . . T.sub.33X

[0050] The draft of D.sub.531, D.sub.532, D.sub.533 . . . D.sub.53X is running at different time as in

T.sub.531, T.sub.532, T.sub.533 . . . T.sub.53X

[0051] Therefore, the mean draft [D.sub.21] of that filament 21 is calculated as

[00003]$D_{21}=\frac{D_{231}\times T_{231}+D_{232}\times T_{232}+D_{233}\times T_{233}\mathrm{.Math.}+D_{23X}\times T_{23X}}{T_{231}+T_{232}+T_{233}\mathrm{.Math.}+T_{23X}}$

[0052] The mean draft [D.sub.31] of that filament 31 is calculated as

[00004]$D_{31}=\frac{D_{331}\times T_{331}+D_{332}\times T_{332}+D_{333}\times T_{333}\mathrm{.Math.}+D_{33X}\times T_{33X}}{T_{331}+T_{332}+T_{333}\mathrm{.Math.}+T_{33X}}$

[0053] The mean draft [D.sub.51] of that filament 51 is calculated as

[00005]$D_{51}=\frac{D_{531}\times T_{531}+D_{532}\times T_{532}+D_{533}\times T_{533}\mathrm{.Math.}+D_{53X}\times T_{53X}}{T_{531}+T_{532}+T_{533}\mathrm{.Math.}+T_{53X}}$

[0054] In practice, the difference of those variable drafts is ±50% amongst individual mean draft, but not limited.

[0055] Same as previous, the variable draft should be as

0.50≤(D.sub.531−1)/(D.sub.51−1)≤1.50

0.50≤(D.sub.532−1)/(D.sub.51−1)≤1.50

0.50≤(D.sub.53−1)/(D.sub.51−1)≤1.50 . . . etc.

D.sub.51,D.sub.531,D.sub.532 . . . D.sub.53X≥1

[0056] The following examples demonstrate the present invention and its capability for use in manufacturing of different specification fabric.

Example 1: Denim Weft Stretch Fabric

[0057] A denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne 10 in the warp and with Ne16 Stretch yarn in accordance with the present invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.5. We can see the sample had weight 11.8 oz/sq.yd. (after washed), good stretch (26.13%), good shrinkage (−7%) and growth (3.6%).

Example 2: Denim Weft Stretch Fabric

[0058] A denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne 8 in the warp and with Ne16 Stretch yarn in accordance with the present invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.8. We can see the sample had weight 11.9 oz/sq.yd. (after washed), good stretch (36.26%), good shrinkage (−11%) and acceptable growth (4.9%).

Example 3: Denim Weft Stretch Fabric

[0059] A denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne10 slub in the warp and with Ne16 Stretch yarn in accordance with the present invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier with less pick, said 48. Both of the average draft is with 3.5. We can see the sample had weight 12 oz/sq.yd. (after washed) and resulted in high stretch (44.26%) and still have good shrinkage (−9%) and acceptable growth (4.8%).

Example 4: Denim Weft Stretch Fabric

[0060] A denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne10 slub in the warp and with 70% Polyester/30% Rayon Ne16 Stretch yarn in accordance with the present Invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.8. We can see the sample had weight 11.8 oz/sq.yd. (after washed), good stretch (31.33%), good shrinkage (−8%) and growth (3.2%).

Example 5: Denim Weft Stretch Fabric

[0061] A denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne14 slub in the warp and with 70% Polyester/30% Rayon Ne16 Stretch yarn in accordance with the present Invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.8. We can see the sample had weight 11.8 oz/sq.yd. (after washed) and have a higher stretch (65.2%) at good shrinkage (−13%) and acceptable growth (6.73%).

Example 6: Denim Weft Stretch Fabric

[0062] A denim stretch fabric, construction 3/1 RHT, with 50% cotton/50% Rayon Ne12 slub in the warp and with 70% Polyester/30% Rayon Ne16 Stretch yarn in accordance with the present Invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.8. We can see the sample had weight 12.2 oz/sq.yd. (after washed), good stretch (34.4%), good shrinkage (−9%) and growth (3.06%).

Example 7: Denim Warp & Weft Stretch Fabric

[0063] A two ways denim stretch fabric, construction 3/1 RHT, with 100% cotton Ne10 slub core 40D Spandex in the warp and with 70% Polyester/30% Rayon Ne16 Stretch yarn in accordance with the present Invention. The invention in the weft yarn is with cotton fibrous sheath and core with two 40D denier. Both of the average draft is with 3.8. We can see the sample had weight 13.5 oz/sq.yd. (after washed), good warp/weft stretch (14.13%/31.33%), good warp/weft shrinkage (−13%/−8%) and acceptable growth (2.93%/4.8%).

Example 8: Denim Weft Stretch Fabric

[0064] A denim stretch fabric, construction 3/1 RHT, with 91% cotton/9% Rubber Ne14 slub in the warp and with 74% cotton/26% rubber Ne10 Stretch yarn in accordance with the present invention. The invention in the weft yarn is with cotton fibrous sheath and core with two rubber threads. Both of the average draft is with 3.2. We can see the sample had weight 13 oz/sq.yd. (after washed), good stretch (55.4%), good shrinkage (−9%) and growth (5%).

[0065] The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiment is therefore to be considered in all respects as illustrative and not restrictive. The scope of the invention is indicated by the appended claims rather than by the foregoing description, and all changes that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.