CN112444615A

CN112444615A - Method for adjusting hand feeling of fabric through directional transmission

Info

Publication number: CN112444615A
Application number: CN202011247511.5A
Authority: CN
Inventors: 张帅; 罗锦
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-10
Filing date: 2020-11-10
Publication date: 2021-03-05
Anticipated expiration: 2040-11-10
Also published as: CN112444615B

Abstract

The invention discloses a method for adjusting the directional transmission of fabric hand feeling, which comprises the following steps: s1, testing through a multi-factor multi-level orthogonal experiment to obtain the corresponding relation between the fabric parameters and the relative hand feeling and the corresponding relation between the process parameters and the relative hand feeling, and establishing a fabric parameter library, a process parameter library and a hand feeling database; s2, providing a target fabric, traversing the hand feeling database after obtaining the fabric parameters of the target fabric, and finding out the relative hand feeling corresponding to the fabric parameters of the target fabric; and S3, after finding out the relative hand feeling, traversing the process parameter library, finding out the process parameters corresponding to the relative hand feeling under the fabric parameters of the target fabric, and finishing the directional adjustment of the process parameters to produce the target fabric. The method can correlate fabric parameters, process parameters and relative hand feeling through reasonable design, is simple and practical, can effectively guide enterprise production, and greatly improves the production efficiency.

Description

Method for adjusting hand feeling of fabric through directional transmission

Technical Field

The invention relates to the technical field of fabrics, in particular to a method for adjusting the directional transmission of fabric hand feeling.

Background

Fabric style is the effect of the inherent mechanical properties of fabric on the human senses. Can be divided into two categories: touch style, also known as hand feel; visual style, including appearance and luster, is also known as look and feel. Therefore, evaluation and identification of fabric style have been carried out by subjective official feelings of experts for a long time, and objective evaluation tools and methods are lacked. Pinching the fabric in the hand to deform it and inducing a tactile sensation by the fingers to determine whether the fabric is desirable is an important attribute of product quality in relation to consumer perception. Sales on lines that are increasing year by year in the sales duty of clothing and fabrics have been plagued by a problem: the appearance and luster of garments and fabrics can be displayed in the form of pictures, but the hand does not convey objective criteria to the consumer. Meanwhile, the clothing and fabric producers also suffer from no standard for selecting proper fabric for clothing processing, thereby better meeting the requirements of consumers. Meanwhile, in the production field, a large amount of commercial disputes are caused because of no standard of hand feeling quantitative rating.

The evaluation of the hand feeling of the fabric is carried out by 4 types of equipment at present, namely a KES-FB system in Japan, which is developed by Japan in 1970 and belongs to first generation hand feeling quantification test equipment. However, the method has the disadvantages of large equipment quantity, high cost, time-consuming operation (about 4 hours for a whole set of experiment), various test indexes, complex paraphrase, correlation between test results and Japanese expert experience data and high subjectivity. In 1990, FAST test system developed by the institute of Federal science and industry in Australia has simple test, but the application market is limited because the logical relationship between test result and hand feeling is not established. An FTT fabric touch tester developed by hong Kong tally university in 2012 belongs to a single-machine system, but still has the problems of complicated test process, no establishment of the relation between test results and hand feeling and the like. Developed by Nu Cybertek, Inc. of Xinsaibao science and technology in the same period of 2007

The single-machine equipment system successfully solves the problem, can output specific numerical values (opposite hand feeling values) of evaluation data, has extremely high test repeatability and evaluation reliability, and is uniformly praised by organizations and experts in various industries. At present, the number of the current day,

has become the designated test instrument of the American AATCC (American Association of textile chemists and dyeing chemists) hand feeling test standard. But in the face of more and more fabric types, special requirements and special product mass production requirements,

cannot establish hand feeling and produceThe correlation of the process parameters cannot guide enterprises to produce related products.

Disclosure of Invention

The invention aims to provide a fabric hand feeling directional transmission adjusting method, which can correlate fabric parameters, process parameters and relative hand feeling through reasonable design, is simple and practical, can effectively guide enterprise production, and greatly improves the production efficiency.

In order to solve the technical problem, the invention provides a method for adjusting the directional transmission of the hand feeling of a fabric, which comprises the following steps: s1, testing through a multi-factor multi-level orthogonal experiment to obtain the corresponding relation between the fabric parameters and the relative hand feeling and the corresponding relation between the process parameters and the relative hand feeling, and establishing a fabric parameter library, a process parameter library and a hand feeling database; s2, providing a target fabric, traversing the hand feeling database after obtaining the fabric parameters of the target fabric, and finding out the relative hand feeling corresponding to the fabric parameters of the target fabric; and S3, after finding out the relative hand feeling, traversing the process parameter library, finding out the process parameters corresponding to the relative hand feeling under the fabric parameters of the target fabric, and finishing the directional adjustment of the process parameters to produce the target fabric.

In a preferred embodiment of the present invention, in step S1, a threshold is set for the degree of influence of the fabric parameters and the process parameters on the relative hand feeling during the test of the multi-factor multi-level orthogonal experiment, and the degree of influence on the relative hand feeling is not greater than the threshold and is classified into the same category; the degree of influence on the relative hand feeling is greater than a threshold value, and the relative hand feeling is classified into different categories.

In a preferred embodiment of the present invention, the method further includes step S1, wherein the test method of the multi-factor multi-level orthogonal experiment is an orientation adjustment method of similar unspecified fabrics: selecting any one fabric in any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; producing a 2 nd fabric by using the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, producing a p-th fabric by using the p-th process parameters, grading the p-th fabric, and respectively recording the p-th fabric parameters, the p-th process parameters and the p-th opponent feels corresponding to the p-th process parameters into a fabric parameter library, a process parameter library and a feel database; wherein p is a natural number not less than.

In a preferred embodiment of the invention, the method further comprises the step of transmitting the fabric parameters, the process parameters and the relative hand feeling back to the fabric parameter library, the process parameter library and the hand feeling database after the fabric under the orientation adjustment of the similar and unspecified fabric reaches the hand feeling of a target sample.

In a preferred embodiment of the invention, when orientation adjustment of similar and unspecified fabrics is performed, different process parameters are packaged into the orientation adjustment process bag according to the direction of the relative hand feeling which needs to be adjusted.

In a preferred embodiment of the present invention, in step S1, the method for performing the test by the multi-factor multi-level orthogonal experiment to adjust the orientation of the specific fabric includes: producing a 1 st fabric by using the 1 st fabric parameter and the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; producing a 2 nd fabric by using the 1 st fabric parameter and the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, respectively; the method comprises the steps of producing the 1 st fabric parameter and the nth process parameter to obtain the nth fabric, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth process parameter and the nth opposite hand feeling corresponding to the nth fabric parameter and the nth process parameter into a fabric parameter base, a process parameter base and a hand feeling database; the method comprises the steps of producing and obtaining n +1 fabrics by using the 2 nd fabric parameter and the 1 st process parameter, grading the n +1 th fabrics, and respectively inputting the n +1 th fabric parameter, the n +1 th process parameter and the n +1 th opposite hand feeling respectively corresponding to the n +1 th fabric parameter and the n +1 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing and obtaining n +2 fabrics by using the 2 nd fabric parameter and the 2 nd process parameter, grading the n +2 th fabrics, and respectively inputting the n +2 th fabric parameter, the n +2 th process parameter and the n +2 th opposite hand feeling respectively corresponding to the n +2 th fabric parameter and the n +2 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, respectively; the 2 nth fabric is produced by using the 2 nd fabric parameter and the nth process parameter, the 2 nth fabric is graded, and the 2 nth fabric parameter, the 2 nth process parameter and the 2 nth counterpart hand respectively corresponding to the 2 nth fabric parameter and the 2 nth counterpart hand are respectively recorded into a fabric parameter base, a process parameter base and a hand feeling database; …, respectively; the method comprises the steps of producing and obtaining an mn +1 fabric by using an mth fabric parameter and a 1 st process parameter, grading the mn +1 fabric, and respectively inputting the mn +1 fabric parameter, the mn +1 process parameter and an mn +1 opposite hand feeling respectively corresponding to the mn +1 process parameter into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing and obtaining an mn +2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mn +2 fabric, and respectively inputting the mn +2 fabric parameter, the mn +2 process parameter and an mn +2 opposite hand feeling respectively corresponding to the mn +2 process parameter into a fabric parameter base, a process parameter base and a hand feeling database; …, respectively; the method comprises the steps of producing and obtaining an mn + n fabric by using an mth fabric parameter and an nth process parameter, grading the mn + n fabric, and respectively inputting the mn + n fabric parameter, the mn + n process parameter and an mn + n corresponding counter-hand feeling into a fabric parameter base, a process parameter base and a hand feeling database; wherein m and n are both natural numbers not less than 1.

In a preferred embodiment of the invention, the parameters of the fabric at least comprise the application field of the fabric, the material composition and the weaving mode.

In a preferred embodiment of the present invention, the process parameters further comprise at least processing and chemical additives.

In a preferred embodiment of the present invention, the method further comprisesThe relative hand feel is obtained by: based on

One or more of the mechanical properties of the fabric are rated.

In a preferred embodiment of the present invention, the mechanical properties further comprise at least softness, bone or toughness, smoothness, drapability and drape recovery.

The invention has the beneficial effects that:

the fabric hand feeling directional transmission adjustment method is related to the mechanical performance index of the fabric and carries out rating after the quantitative representation of the fabric hand feeling is carried out, and meanwhile, the index adjustment is related to the printing and dyeing process parameters, so that the aim of directionally improving one or more fabric relative hand feeling indexes is fulfilled. The method is simple and practical, and can effectively guide enterprises to produce related products, thereby greatly improving the production efficiency.

Drawings

FIG. 1 is a schematic flow chart of a library established by a fabric hand feeling directional transmission adjusting method in a preferred embodiment of the invention;

FIG. 2 is a schematic flow diagram of a library for use in a method of directional hand feel adjustment of a fabric according to a preferred embodiment of the invention;

fig. 3 is a schematic flow chart of relative hand feel orientation adjustment.

Detailed Description

The present invention is further described below in conjunction with the following figures and specific examples so that those skilled in the art may better understand the present invention and practice it, but the examples are not intended to limit the present invention.

Examples

The invention discloses a method for adjusting the directional transmission of fabric hand feeling, which is shown in figures 1-3 and comprises the following steps:

s1, testing through a multi-factor multi-level orthogonal experiment to obtain the corresponding relation between the fabric parameters and the relative hand feeling and the corresponding relation between the process parameters and the relative hand feeling, and establishing a fabric parameter library, a process parameter library and a hand feeling database;

s2, providing a target fabric, traversing the hand feeling database after obtaining the fabric parameters of the target fabric, and finding out the relative hand feeling corresponding to the fabric parameters of the target fabric;

and S3, after finding out the relative hand feeling, traversing the process parameter library, finding out the process parameters corresponding to the relative hand feeling under the fabric parameters of the target fabric, and finishing the directional adjustment of the process parameters to produce the target fabric.

In order to reduce the complexity of establishing the parameter library and the database, in step S1, a threshold may be set for the influence of the fabric parameters and the process parameters on the relative hand feeling during the test of the multi-factor multi-level orthogonal experiment, and the influence on the relative hand feeling is not greater than the threshold and is classified into the same category; the degree of influence on the relative hand feeling is greater than a threshold value, and the relative hand feeling is classified into different categories.

In step S1, the test method of the multi-factor multi-level orthogonal experiment is a directional adjustment method of similar unspecified fabrics:

selecting any one fabric in any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

producing a 2 nd fabric by using the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

…

the method comprises the steps of producing a p-th fabric by using p-th process parameters, grading the p-th fabric, and respectively inputting the p-th fabric parameters, the p-th process parameters and p-th opponent feels respectively corresponding to the p-th process parameters into a fabric parameter base, a process parameter base and a feel database; wherein p is a natural number not less than. When the method is used for directional transmission adjustment production, the influence of the fabric parameters on the relative hand feeling can be fuzzified, the influence of the process parameters on the hand feeling is emphasized, the complexity of establishing a parameter database and a database is greatly simplified, the searching is quicker, and the directional adjustment is quicker.

After the fabric under the orientation adjustment of the similar unspecific fabric reaches the hand feeling of a target sample, the fabric parameters, the process parameters and the relative hand feeling of the fabric can be transmitted back to the fabric parameter library, the process parameter library and the hand feeling database so as to enrich the parameter library and the database.

Referring to fig. 3, when orientation adjustment of similar unspecified fabrics is performed, different process parameters can be packaged into an orientation adjustment process bag according to the direction of relative hand feeling which needs to be adjusted, and when different types of relative hand feeling need to be improved or reduced, a plurality of parameters can be changed simultaneously, so that the efficiency of orientation adjustment is improved.

In step S1, another method for performing a multi-factor multi-level orthogonal experiment is to adjust the orientation of a specific fabric by:

producing a 1 st fabric by using the 1 st fabric parameter and the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

producing a 2 nd fabric by using the 1 st fabric parameter and the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

…

the method comprises the steps of producing the 1 st fabric parameter and the nth process parameter to obtain the nth fabric, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth process parameter and the nth opposite hand feeling corresponding to the nth fabric parameter and the nth process parameter into a fabric parameter base, a process parameter base and a hand feeling database;

the method comprises the steps of producing and obtaining n +1 fabrics by using the 2 nd fabric parameter and the 1 st process parameter, grading the n +1 th fabrics, and respectively inputting the n +1 th fabric parameter, the n +1 th process parameter and the n +1 th opposite hand feeling respectively corresponding to the n +1 th fabric parameter and the n +1 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

the method comprises the steps of producing and obtaining n +2 fabrics by using the 2 nd fabric parameter and the 2 nd process parameter, grading the n +2 th fabrics, and respectively inputting the n +2 th fabric parameter, the n +2 th process parameter and the n +2 th opposite hand feeling respectively corresponding to the n +2 th fabric parameter and the n +2 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

…

the 2 nth fabric is produced by using the 2 nd fabric parameter and the nth process parameter, the 2 nth fabric is graded, and the 2 nth fabric parameter, the 2 nth process parameter and the 2 nth counterpart hand respectively corresponding to the 2 nth fabric parameter and the 2 nth counterpart hand are respectively recorded into a fabric parameter base, a process parameter base and a hand feeling database;

…

the method comprises the steps of producing and obtaining an mn +1 fabric by using an mth fabric parameter and a 1 st process parameter, grading the mn +1 fabric, and respectively inputting the mn +1 fabric parameter, the mn +1 process parameter and an mn +1 opposite hand feeling respectively corresponding to the mn +1 process parameter into a fabric parameter library, a process parameter library and a hand feeling database;

the method comprises the steps of producing and obtaining an mn +2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mn +2 fabric, and respectively inputting the mn +2 fabric parameter, the mn +2 process parameter and an mn +2 opposite hand feeling respectively corresponding to the mn +2 process parameter into a fabric parameter base, a process parameter base and a hand feeling database;

…

the method comprises the steps of producing and obtaining an mn + n fabric by using an mth fabric parameter and an nth process parameter, grading the mn + n fabric, and respectively inputting the mn + n fabric parameter, the mn + n process parameter and an mn + n corresponding counter-hand feeling into a fabric parameter base, a process parameter base and a hand feeling database; wherein m and n are both natural numbers not less than 1. When the method is used for directional transmission adjustment production, the fabric parameters, the relative hand feeling and the process parameters correspond to each other pairwise, and the third data can be known by knowing any two data, so that the method has strong directional guiding significance for material selection, proportioning and process parameter setting of production.

The parameters of the fabric at least comprise the application field of the fabric, the material components and the weaving mode.

The process parameters at least comprise processing technology and chemical additives.

The method for obtaining the relative hand feeling comprises the following steps: based on

One or more of the mechanical properties of the fabric are rated.

The mechanical properties include at least softness, bone or toughness, smoothness, drapability, and wrinkle recovery.

The above-mentioned embodiments are merely preferred embodiments for fully illustrating the present invention, and the scope of the present invention is not limited thereto. The equivalent substitution or change made by the technical personnel in the technical field on the basis of the invention is all within the protection scope of the invention. The protection scope of the invention is subject to the claims.

Claims

1. A fabric hand feeling directional transmission adjusting method is characterized in that: the method comprises the following steps:

2. The method for adjusting the directional transmission of the hand feeling of a fabric according to claim 1, wherein: in step S1, setting a threshold for the degree of influence of the fabric parameters and the process parameters on the relative hand feeling during the test of the multi-factor multi-level orthogonal experiment, and classifying the fabric parameters and the process parameters into the same category if the degree of influence on the relative hand feeling is not greater than the threshold; the degree of influence on the relative hand feeling is greater than a threshold value, and the relative hand feeling is classified into different categories.

3. The method for adjusting the directional transmission of the hand feeling of a fabric according to claim 1, wherein: in step S1, the test method of the multi-factor multi-level orthogonal experiment is the orientation adjustment method of similar unspecified fabrics: selecting any one fabric in any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; producing a 2 nd fabric by using the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, producing a p-th fabric by using the p-th process parameters, grading the p-th fabric, and respectively recording the p-th fabric parameters, the p-th process parameters and the p-th opponent feels corresponding to the p-th process parameters into a fabric parameter library, a process parameter library and a feel database; wherein p is a natural number not less than.

4. The method for adjusting the directional transmission of the hand feeling of a fabric according to claim 3, wherein: and after the fabric under the orientation adjustment of the similar unspecific fabric reaches the hand feeling of the target sample, the fabric parameters, the process parameters and the relative hand feeling are transmitted back to the fabric parameter library, the process parameter library and the hand feeling database.

5. The method for adjusting the directional transmission of the hand feeling of a fabric according to claim 3, wherein: when the orientation adjustment of similar unspecific fabrics is carried out, different process parameters are packaged into the orientation adjustment process bag according to the direction of the relative hand feeling which needs to be adjusted.

6. The method for adjusting the directional transmission of the hand feeling of a fabric according to claim 1, wherein: in step S1, the method for performing the test by the multi-factor multi-level orthogonal experiment is to adjust the orientation of the specific fabric by: producing a 1 st fabric by using the 1 st fabric parameter and the 1 st process parameter, grading the 1 st fabric, and respectively inputting the 1 st fabric parameter, the 1 st process parameter and the 1 st corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; producing a 2 nd fabric by using the 1 st fabric parameter and the 2 nd process parameter, grading the 2 nd fabric, and respectively inputting the 2 nd fabric parameter, the 2 nd process parameter and a 2 nd corresponding hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, respectively; the method comprises the steps of producing the 1 st fabric parameter and the nth process parameter to obtain the nth fabric, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth process parameter and the nth opposite hand feeling corresponding to the nth fabric parameter and the nth process parameter into a fabric parameter base, a process parameter base and a hand feeling database; the method comprises the steps of producing and obtaining n +1 fabrics by using the 2 nd fabric parameter and the 1 st process parameter, grading the n +1 th fabrics, and respectively inputting the n +1 th fabric parameter, the n +1 th process parameter and the n +1 th opposite hand feeling respectively corresponding to the n +1 th fabric parameter and the n +1 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing and obtaining n +2 fabrics by using the 2 nd fabric parameter and the 2 nd process parameter, grading the n +2 th fabrics, and respectively inputting the n +2 th fabric parameter, the n +2 th process parameter and the n +2 th opposite hand feeling respectively corresponding to the n +2 th fabric parameter and the n +2 th opposite hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …, respectively; the 2 nth fabric is produced by using the 2 nd fabric parameter and the nth process parameter, the 2 nth fabric is graded, and the 2 nth fabric parameter, the 2 nth process parameter and the 2 nth counterpart hand respectively corresponding to the 2 nth fabric parameter and the 2 nth counterpart hand are respectively recorded into a fabric parameter base, a process parameter base and a hand feeling database; …, respectively; the method comprises the steps of producing and obtaining an mn +1 fabric by using an mth fabric parameter and a 1 st process parameter, grading the mn +1 fabric, and respectively inputting the mn +1 fabric parameter, the mn +1 process parameter and an mn +1 opposite hand feeling respectively corresponding to the mn +1 process parameter into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing and obtaining an mn +2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mn +2 fabric, and respectively inputting the mn +2 fabric parameter, the mn +2 process parameter and an mn +2 opposite hand feeling respectively corresponding to the mn +2 process parameter into a fabric parameter base, a process parameter base and a hand feeling database; …, respectively; the method comprises the steps of producing and obtaining an mn + n fabric by using an mth fabric parameter and an nth process parameter, grading the mn + n fabric, and respectively inputting the mn + n fabric parameter, the mn + n process parameter and an mn + n corresponding counter-hand feeling into a fabric parameter base, a process parameter base and a hand feeling database; wherein m and n are both natural numbers not less than 1.

7. The method for adjusting the directional transmission of the hand feeling of a textile according to any one of claims 1 to 6, wherein: the parameters of the fabric at least comprise the application field of the fabric, the material components and the weaving mode.

8. The method for adjusting the directional transmission of the hand feeling of a textile according to any one of claims 1 to 6, wherein: the process parameters at least comprise processing technology and chemical additives.

9. The method for adjusting the directional transmission of the hand feeling of a textile according to any one of claims 1 to 6, wherein: the relative hand feeling is obtained by the following steps: based on

One or more of the mechanical properties of the fabric are rated.

10. The method for adjusting the directional transmission of the hand feeling of a textile according to claim 9, wherein: the mechanical properties include at least softness, bone or toughness, smoothness, drapability, and wrinkle recovery.