HIGH TENSILE NYLON 6.6 YARN

Abstract

A nylon 6.6 yarn suitable for a tire cord reinforcement for pneumatic tires includes higher than 12,0 g/dtex Tensile Reinforcement Index (TRI) and tenacity between 9,3 g/dtex-10,5 g/dtex, where the TRI is defined as: TRI (g/dtex)=Tenacity (g/dtex) +Stress at 7% Elongation. The nylon 6.6 yarn is suitable for using as tire cord reinforcement in pneumatic tires.

Claims

1. A nylon 6.6 yarn for a tire cord reinforcement for pneumatic tires comprising a Tensile Reinforcement Index (TRI) and a tenacity, wherein the TRI is defined as below:
TRI(g/dtex)=Tenacity(g/dtex)+Stress at 7% Elongation; wherein the TRI is higher than 12,0 g/dtex, and wherein the tenacity is between 9,3 a/dtex-10.5 g/dtex.

2. The nylon 6.6 yarn according to claim 1, wherein the TRI is lower than 13,5 g/dtex.

3. The nylon 6.6 yarn according to claim 1, wherein the nylon 6.6 yarn has a minimum linear density of 200 dtex and a maximum linear density of 3000 dtex.

4. The nylon 6.6 yarn according to claim 1, wherein then nylon 6.6 yarn is used as the tire cord reinforcement for the pneumatic tires.

5. The nylon 6.6 yarn according to claim 2, wherein the nylon 6.6 yarn has a minimum linear density of 200 dtex and a maximum linear density of 3000 dtex.

6. The nylon 6.6 yarn according to claim 2, wherein the nylon 6.6 yarn is used as the tire cord reinforcement for the pneumatic tires.

7. The nylon 6.6 yarn according to claim 3, wherein the nylon 6.6 yarn is used as the tire cord reinforcement for the pneumatic tires.

8. The nylon 6.6 yarn according to claim 5, wherein the nylon 6.6 yarn is used as the tire cord reinforcement for the pneumatic tires.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] FIG. 1. is an example of a known crossflow quench and coupled spin-draw apparatus mentioned in the background of the invention (Prior art example).

[0008] FIG. 2. is a stress-strain curve of invention with the control A and B.

[0009] All parts of the figures are numbered which are referenced as shown below: [0010] 1. Inlet [0011] 2. Spin pack [0012] 3. Undrawn filament [0013] 4. Crossflow cooling air [0014] 5, Chamber [0015] 6. Conventional yarn [0016] 7. Feed roll assembly [0017] 8. First draw roll pair [0018] 9. Tube [0019] 10. Second draw roll pair [0020] 11. Relaxation roll [0021] 12. Let-down roll [0022] 13. Guide [0023] 14. Yarn package

[0024] In FIG. 1, an example of a known crossflow quench and coupled spin-draw apparatus is shown for producing high modulus nylon 6.6 yarn. In FIG. 1, a melted polyamide is introduced at inlet (1) to a spin pack (2). The polymer is extruded as undrawn filaments (3) from the spin pack (2), which has orifices designed to give the desired cross section. The undrawn filaments (3) are quenched after they exit the capillary of the spin pack (2) to cool the fibers by crossflow cooling air (4). These filaments are converged into a conventional yarn (6) with application of a conventional finish lubricant in a chamber (5) and forwarded by a feed roll assembly (7). The conventional yarn (6) is then fed to a first draw roll pair (8) and then to a second and hot draw roll pair (10). A hot tube (9), or draw assist, may be used to facilitate the second stage of the draw process. The conventional yarn (6) is relaxed at puller rolls (11, 12), One of the puller rolls is also known as a relaxation roll (11); it can run at lower speeds than draw roll assembly (10) to control conventional yarn (6) shrinkage and stability of physical properties. Other roll is also known as a let-down roll (12) relaxes the conventional yarn (6) tension to allow winding on at a lower tension than the conventional yarn (6) experiences in drawing. A guide (13) lays down the conventional yarn (6) on a yarn package (14), where it is wound up. The process, apparatus and methods that are explained above are similar with prior art, and literature however standard operational conditions are differentiated to produce high TRI nylon 6.6 yarn different from the conventional yarn with reduced relaxation after hot-drawing.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0025] The present invention relates to high tensile nylon 6.6 yarn having high Tensile Reinforcement Index (TRI) which is defined as below;

TRI(g/dtex)=Tenacity(g/dtex)+SASE at 7% Elongation(g/dtex)

Wherein;

[0026] Tenacity: Breaking force/linear density (g/dtex)
SASE: Stress At Specified Elongation (g/dtex)

LASE: Load At Specified Elongation.

[0027] As well known, tensile strength (tenacity) and modulus, especially stress at 7% elongation (SASE) are two important tensile properties having significant effects on tire performance parameters like, high speed durability, rolling resistance and fuel saving.

[0028] In order to give the final properties to the cords, they subjected to the dipping (for static and dynamic adhesion) and heat-setting process (3T or hot stretching process) under high tension and temperature to enhance molecular orientation and dimensional stability further, Under the same 31 (Time, Tension and Temperature) conditions, nylon 6.6 cords prepared from high TRI nylon 6.6 yarn, give higher TRI value than the conventional nylon 6.6 cords.

[0029] Nylon 6,6 yarns having TRI value higher than 12,0 g/dtex and at the same time having tenacity between 9,3 g/dtex and 10,5 g/dtex are more suitable than the nylon 6.6 yarns with lower TRI. TRI which is higher than 12 g/dtex provides balance between high modulus and high strength. Regular nylon 6.6 yarns with high tenacity and low modulus or low tenacity and high modulus do not provide enough initial strength for final cords.

[0030] The nylon 6.6 yarns with Tensile Reinforcement Index (TRI) higher than 12,0 g/dtex have optimized and balanced tenacity and SASE which are suitable for tire cords which can be used as carcass and cap ply reinforcement in pneumatic tires. If the TRI parameter is higher than 13,5 g/dtex, due to excessive molecular orientation, the breaking energy or toughness of the yarn can be too low, and filaments could be brittle. Besides minimum 12,0 g/dtex TRI parameter, minimum 9,3 g/dtex and maximum 10,5 g/dtex tenacity will be preferable.

[0031] The linear density of the nylon 6.6 yarn produced according to invention is minimum 200 dtex and maximum 3000 dtex.

[0032] Table 1 shows comparison between the properties of the nylon 6.6 yarn produced according to the invention and control yarns A and B:

TABLE-US-00001 TABLE 1 Form Conditioned* 1400 dtex Yarn Properties Unit Control A Control B Invention Breaking Force kgf 12.2 13.20 13.20 Tenacity g/dtex 8.7 9.4 9.4 Elongation at Break % 21.0 21.0 18.8 7% LASE kgf 3.18 3.04 3.82 7% SASE g/dtex 2.27 2.17 2.73 TRI g/dtex 11.03 11.62 12.13 *Condition 24° C. ± 1° C., 55% HR ± 2%

[0033] In table-1; Control A is regular tenacity and regular modulus (LASE) yarn having TRI<12,0 g/dtex, Control B is high tenacity, but regular modulus (LASE) yarn having TRI<(12,0 g/dtex and Invention is high tenacity, and high modulus (LASE) yarn having TRI>12,0 g/dtex.

[0034] The high TRI nylon. 6.6 yarns are used as tire cord reinforcement in pneumatic tires.