CN112444615B - Directional transfer adjustment method for fabric hand feeling - Google Patents

Abstract

The invention discloses a method for directionally transmitting and adjusting 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 handfeel and the corresponding relation between the technological parameters and the relative handfeel, and establishing a fabric parameter library, a technological parameter library and a handfeel database; s2, providing a target fabric, traversing a hand feeling database after obtaining fabric parameters of the target fabric, and finding out relative hand feeling corresponding to the fabric parameters of the target fabric; s3, traversing the process parameter library after the relative hand feeling is found, finding out the process parameter corresponding to the relative hand feeling under the fabric parameter of the target fabric, and finishing the directional adjustment of the process parameter to produce the target fabric. The method can be used for associating fabric parameters, process parameters and relative handfeel through reasonable design, is simple and practical, can effectively guide enterprise production, and greatly improves production efficiency.

Description

Directional transfer adjustment method for fabric hand feeling

Technical Field

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

Background

Fabric style is the effect that the mechanical properties inherent in fabrics have on the human sense. Can be divided into two categories: feel style, also known as hand; visual styles, including appearance and gloss, also known as look and feel. So, the evaluation and identification of the fabric style have been carried out by subjective sense of expert for a long time, and objective evaluation tools and methods are lacked. Holding the fabric in the hand to deform and feel with the fingers to determine whether the fabric is desirable is an important attribute of product quality in connection with consumer sensory. On-line sales, which have been rising year by year in the clothing and fabric sales ratio, have been plagued by a problem: the appearance and gloss of garments and fabrics can be presented in the form of pictures, but the hand does not convey objective criteria to the consumer. At the same time, garment and fabric manufacturers suffer from the lack of criteria to select the proper fabric for garment processing, thereby better meeting consumer needs. Meanwhile, in the production field, a large amount of business disputes are caused by the fact that the standard of handfeel quantification rating is not available.

Evaluation of hand feel of fabrics currently has 4 kinds of designsThe KES-FB system in Japan was developed in 1970 by Japan, and belongs to the first-generation hand feel quantification test equipment. However, the number of the equipment is large, the manufacturing cost is high, the operation is time-consuming (about 4 hours are needed for the whole set of experiments), the test indexes are numerous, the interpretation is complex, and the test results are related to Japanese expert experience data and are too subjective. In 1990, the Australian federal science and industry research institute developed a FAST test system, which was simple to test, but had limited application market because of not establishing a logical relationship between test results and hand feeling. FTT fabric touch tester is developed by hong Kong university in 2012, belongs to a single machine system, but still has the problems that the testing process is complicated, the relation between the testing result and the touch is not established, and the like. Developed by the United states Xinsaibao science and technology company (Nu Cybertek, inc.) in 2007 at the same timeThe single machine equipment system successfully solves the problem, can output specific values (relative hand feeling values) of evaluation data, has extremely high test repeatability and evaluation reliability, and is well-appreciated by institutions and specialists in various countries. At present (I)>Has become a designated test instrument for the hand feel test standard of AATCC (American society of textile chemists and printing and dyeing engineers). But facing more and more types of fabrics, specific requirements and mass production requirements of specific products, the method comprises the following steps of->The association of hand feeling and production process parameters cannot be established, and enterprises cannot be guided to produce related products.

Disclosure of Invention

The invention aims to solve the technical problem of providing the directional transfer adjustment method for the hand feeling of the fabric, which can correlate the parameters of the fabric, the technological parameters and the relative hand feeling through reasonable design, is simple and practical, can effectively guide the production of enterprises, and greatly improves the production efficiency.

In order to solve the technical problems, the invention provides a method for directionally transmitting and adjusting 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 handfeel and the corresponding relation between the technological parameters and the relative handfeel, and establishing a fabric parameter library, a technological parameter library and a handfeel database; s2, providing a target fabric, traversing a hand feeling database after obtaining fabric parameters of the target fabric, and finding out relative hand feeling corresponding to the fabric parameters of the target fabric; s3, traversing the process parameter library after the relative hand feeling is found, finding out the process parameter corresponding to the relative hand feeling under the fabric parameter of the target fabric, and finishing the directional adjustment of the process parameter 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 when the multi-factor multi-level orthogonal experiment is performed, 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 is greater than the threshold value and is classified into different types.

In a preferred embodiment of the present invention, the method further includes a step S1, wherein the testing method of the multi-factor multi-level orthogonal experiment is a method of orientation adjustment of similar non-specific fabrics: selecting any one of any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameters, grading the 1 st fabric, and respectively inputting the 1 st fabric parameters, the 1 st process parameters and the 1 st relative handfeel corresponding to the 1 st fabric parameters and the 1 st relative handfeel into a fabric parameter library, a process parameter library and a handfeel database; 2 nd fabrics are produced by using the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel corresponding to the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database; … the p-th fabric is produced by using the p-th process parameters, the p-th fabric is rated, and the p-th fabric parameters, the p-th process parameters and the p-th relative handfeel respectively corresponding to the p-th fabric parameters and the p-th relative handfeel are respectively input into a fabric parameter library, a process parameter library and a handfeel database; wherein p is a natural number not smaller 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 of the fabric subjected to directional adjustment similar to the unspecified fabric back to the fabric parameter library, the process parameter library and the hand feeling database after the hand feeling of the target sample is reached.

In a preferred embodiment of the present invention, the method further comprises packaging different process parameters into the orientation adjustment process kit according to the direction of the relative hand feeling to be adjusted when the orientation adjustment of the similar non-specific fabrics is performed.

In a preferred embodiment of the present invention, the method for performing the test on the multi-factor multi-level orthogonal experiment in step S1 is a method for adjusting the orientation of the specific fabric, which comprises: the 1 st fabric is produced by using the 1 st fabric parameter and the 1 st process parameter, the 1 st fabric is rated, and the 1 st fabric parameter, the 1 st process parameter and the 1 st relative hand feeling respectively corresponding to the 1 st fabric parameter and the 1 st process parameter are respectively input into a fabric parameter library, a process parameter library and a hand feeling database; 2 nd fabrics are produced by using the 1 st fabric parameters and the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel respectively corresponding to the 2 nd fabric parameters and the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database; …; the method comprises the steps of producing an nth fabric by using a 1 st fabric parameter and an nth technological parameter, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth technological parameter and the nth relative hand feeling corresponding to the nth fabric parameter and the nth technological parameter into a fabric parameter library, a technological parameter library and a hand feeling database; the method comprises the steps of producing the (n+1) th fabric by using the (2) th fabric parameter and the (1) st process parameter, grading the (n+1) th fabric, and respectively inputting the (n+1) th fabric parameter, the (n+1) th process parameter and the (n+1) th relative hand feeling corresponding to the (n+1) th fabric parameter, the (n+1) th process parameter and the (n+1) th relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing the 2 nd fabric parameter and the 2 nd process parameter to obtain the n+2 th fabric, grading the n+2 th fabric, and respectively inputting the n+2 th fabric parameter, the n+2 th process parameter and the n+2 nd relative hand feeling corresponding to the n+2 th fabric parameter and the n+2 th process parameter into a fabric parameter library, a process parameter library and a hand feeling database; …; 2 nd fabric is produced by using the 2 nd fabric parameter and the nth technological parameter, the 2 nd fabric is rated, and the 2 nd fabric parameter, the 2 nd technological parameter and the 2 nd relative hand feeling corresponding to the 2 nd fabric parameter and the 2 nd technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database; …; the method comprises the steps of producing an mth plus 1 fabric by using an mth fabric parameter and a 1 st process parameter, grading the mth plus 1 fabric, and respectively inputting the mth plus 1 fabric parameter, the mth plus 1 process parameter and the corresponding mth plus 1 relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing an mth plus 2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mth plus 2 fabric, and respectively inputting the mth plus 2 fabric parameter, the mth plus 2 process parameter and the corresponding mth plus 2 relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …; the mth plus n fabric is produced by using the mth fabric parameter and the nth technological parameter, the mth plus n fabric is rated, and the mth plus n fabric parameter, the mth plus n technological parameter and the mth plus n relative hand feeling respectively corresponding to the mth plus n technological parameter and the mth plus n technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database; wherein m and n are natural numbers not less than 1.

In a preferred embodiment of the present invention, the fabric parameters further include at least a fabric application area, a material composition and a weaving mode.

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

In a preferred embodiment of the present invention, the method for obtaining the relative hand feeling further includes: based onOne or more of the mechanical properties of the facing were rated.

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

The invention has the beneficial effects that:

according to the method for directionally transferring and adjusting the hand feeling of the fabric, after quantitative characterization of the hand feeling of the fabric is carried out, the hand feeling of the fabric is related to the mechanical property index of the fabric and is graded, and meanwhile, the index adjustment is related to the printing and dyeing process parameters, so that the aim of directionally improving one or more relative hand feeling indexes of the fabric is fulfilled. The method is simple and practical, can effectively guide enterprises to produce related products, and greatly improves production efficiency.

Drawings

FIG. 1 is a schematic flow chart of a method for establishing a library for adjusting the hand-feeling directional transmission of a fabric according to a preferred embodiment of the present invention;

FIG. 2 is a schematic flow chart of a method for adjusting the hand orientation of a fabric according to a preferred embodiment of the present invention;

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

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the invention and practice it.

Examples

The invention discloses a method for directionally transmitting and adjusting hand feeling of a fabric, which is shown by referring to 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 handfeel and the corresponding relation between the technological parameters and the relative handfeel, and establishing a fabric parameter library, a technological parameter library and a handfeel database;

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

s3, traversing the process parameter library after the relative hand feeling is found, finding out the process parameter corresponding to the relative hand feeling under the fabric parameter of the target fabric, and finishing the directional adjustment of the process parameter to produce the target fabric.

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

In step S1, one of the multiple-factor multiple-level orthogonal experiments is a method for adjusting orientation of similar non-specific fabrics:

selecting any one of any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameters, grading the 1 st fabric, and respectively inputting the 1 st fabric parameters, the 1 st process parameters and the 1 st relative handfeel corresponding to the 1 st fabric parameters and the 1 st relative handfeel into a fabric parameter library, a process parameter library and a handfeel database;

2 nd fabrics are produced by using the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel corresponding to the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database;

…

the p-th fabric is produced by using the p-th process parameters, the p-th fabric is rated, and the p-th fabric parameters, the p-th process parameters and the p-th relative handfeel respectively corresponding to the p-th fabric parameters and the p-th relative handfeel are respectively input into a fabric parameter library, a process parameter library and a handfeel database; wherein p is a natural number not smaller than. When the method is used for directional transmission adjustment production, the influence of fabric parameters on relative handfeel can be blurred, the influence of technological parameters on handfeel is emphasized, the complexity of establishing a parameter library and a database is greatly simplified, and the method is quicker in searching and quicker in directional adjustment.

After the fabric subjected to directional adjustment similar to the unspecified fabric reaches the hand feeling of the target sample, the fabric parameters, the process parameters and the relative hand feeling 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 the orientation adjustment of similar non-specific fabrics is performed, different process parameters can be packed into an orientation adjustment process bag according to the direction of the relative hand feeling to be adjusted, and when different types of relative hand feeling are required to be improved or reduced, multiple parameters can be changed at the same time, so that the efficiency of orientation adjustment is improved.

In step S1, another method for performing a test by using a multi-factor multi-level orthogonal experiment is a method for adjusting the orientation of a specific fabric, which comprises the following steps:

the 1 st fabric is produced by using the 1 st fabric parameter and the 1 st process parameter, the 1 st fabric is rated, and the 1 st fabric parameter, the 1 st process parameter and the 1 st relative hand feeling respectively corresponding to the 1 st fabric parameter and the 1 st process parameter are respectively input into a fabric parameter library, a process parameter library and a hand feeling database;

2 nd fabrics are produced by using the 1 st fabric parameters and the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel respectively corresponding to the 2 nd fabric parameters and the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database;

…

the method comprises the steps of producing an nth fabric by using a 1 st fabric parameter and an nth technological parameter, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth technological parameter and the nth relative hand feeling corresponding to the nth fabric parameter and the nth technological parameter into a fabric parameter library, a technological parameter library and a hand feeling database;

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

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

…

2 nd fabric is produced by using the 2 nd fabric parameter and the nth technological parameter, the 2 nd fabric is rated, and the 2 nd fabric parameter, the 2 nd technological parameter and the 2 nd relative hand feeling corresponding to the 2 nd fabric parameter and the 2 nd technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database;

…

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

the method comprises the steps of producing an mth plus 2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mth plus 2 fabric, and respectively inputting the mth plus 2 fabric parameter, the mth plus 2 process parameter and the corresponding mth plus 2 relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database;

…

the mth plus n fabric is produced by using the mth fabric parameter and the nth technological parameter, the mth plus n fabric is rated, and the mth plus n fabric parameter, the mth plus n technological parameter and the mth plus n relative hand feeling respectively corresponding to the mth plus n technological parameter and the mth plus n technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database; wherein m and n are natural numbers not less than 1. When the method is used for directional transmission adjustment production, the parameters of the fabric, the relative handfeel and the technological parameters are corresponding to each other, any two data are known, and the third data are known, so that the method has extremely strong directional guiding significance for the selection of materials, the proportioning and the setting of the technological parameters in production.

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

The technological parameters at least comprise a processing technology and chemical auxiliary agents.

The method for obtaining the relative hand feeling comprises the following steps: based onOne or more of the mechanical properties of the facing were rated.

The mechanical properties include at least softness, body bone or toughness, smoothness, drape and fold recovery.

The above-described embodiments are merely preferred embodiments for fully explaining the present invention, and the scope of the present invention is not limited thereto. Equivalent substitutions and modifications will occur to those skilled in the art based on the present invention, and are intended to be within the scope of the present invention. The protection scope of the invention is subject to the claims.

Claims (8)

1. A fabric hand feeling directional transmission adjusting method is characterized in that: the method 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 handfeel and the corresponding relation between the technological parameters and the relative handfeel, and establishing a fabric parameter library, a technological parameter library and a handfeel database;

the testing method of the multi-factor multi-level orthogonal experiment is a directional adjustment method of similar nonspecific fabrics: selecting any one of any group of similar fabrics, producing the 1 st fabric by using the 1 st process parameters, grading the 1 st fabric, and respectively inputting the 1 st fabric parameters, the 1 st process parameters and the 1 st relative handfeel corresponding to the 1 st fabric parameters and the 1 st relative handfeel into a fabric parameter library, a process parameter library and a handfeel database; 2 nd fabrics are produced by using the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel corresponding to the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database; … the p-th fabric is produced by using the p-th process parameters, the p-th fabric is rated, and the p-th fabric parameters, the p-th process parameters and the p-th relative handfeel respectively corresponding to the p-th fabric parameters and the p-th relative handfeel are respectively input into a fabric parameter library, a process parameter library and a handfeel database; wherein p is a natural number not smaller than;

in the step S1, a threshold value is set for the influence degree of the fabric parameters and the process parameters on the relative hand feeling when the multi-factor multi-level orthogonal experiment is tested, and the influence degree on the relative hand feeling is not more than the threshold value and is classified into the same type; the influence degree on the relative hand feeling is larger than a threshold value and is classified into different types;

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

s3, traversing the process parameter library after the relative hand feeling is found, finding out the process parameter corresponding to the relative hand feeling under the fabric parameter of the target fabric, and finishing the directional adjustment of the process parameter to produce the target fabric.

2. The method for directional transfer adjustment of a fabric hand feel according to claim 1, wherein: after the fabric subjected to directional adjustment similar to the unspecified 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.

3. The method for directional transfer adjustment of a fabric hand feel according to claim 1, wherein: when the orientation adjustment of similar nonspecific fabrics is carried out, different technological parameters are packed into an orientation adjustment technological package according to the direction of relative handfeel which is required to be adjusted.

4. A method for directional transfer adjustment of a textile hand according to any one of claims 1-3, characterized in that: the fabric parameters at least comprise the application field of the fabric, the material composition and the weaving mode.

5. A method for directional transfer adjustment of a textile hand according to any one of claims 1-3, characterized in that: the technological parameters at least comprise a processing technology and chemical auxiliary agents.

6. A method for directional transfer adjustment of a textile hand according to any one of claims 1-3, characterized in that: the method for obtaining the relative hand feeling comprises the following steps: one or more of the mechanical properties of the facing were rated based on phabrameter.

7. The method for directional transfer adjustment of a fabric hand feel according to claim 6, wherein: the mechanical properties include at least softness, body bone or toughness, smoothness, drape and fold recovery.

8. A fabric hand feeling directional transmission adjusting method is characterized in that: the method 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 handfeel and the corresponding relation between the technological parameters and the relative handfeel, and establishing a fabric parameter library, a technological parameter library and a handfeel database;

the method for testing the multi-factor multi-level orthogonal experiment is a directional adjustment method of a specific fabric, and comprises the following steps: the 1 st fabric is produced by using the 1 st fabric parameter and the 1 st process parameter, the 1 st fabric is rated, and the 1 st fabric parameter, the 1 st process parameter and the 1 st relative hand feeling respectively corresponding to the 1 st fabric parameter and the 1 st process parameter are respectively input into a fabric parameter library, a process parameter library and a hand feeling database; 2 nd fabrics are produced by using the 1 st fabric parameters and the 2 nd process parameters, the 2 nd fabrics are rated, and the 2 nd fabric parameters, the 2 nd process parameters and the 2 nd relative handfeel respectively corresponding to the 2 nd fabric parameters and the 2 nd process parameters are respectively input into a fabric parameter library, a process parameter library and a handfeel database; …; the method comprises the steps of producing an nth fabric by using a 1 st fabric parameter and an nth technological parameter, grading the nth fabric, and respectively inputting the nth fabric parameter, the nth technological parameter and the nth relative hand feeling corresponding to the nth fabric parameter and the nth technological parameter into a fabric parameter library, a technological parameter library and a hand feeling database; the method comprises the steps of producing the (n+1) th fabric by using the (2) th fabric parameter and the (1) st process parameter, grading the (n+1) th fabric, and respectively inputting the (n+1) th fabric parameter, the (n+1) th process parameter and the (n+1) th relative hand feeling corresponding to the (n+1) th fabric parameter, the (n+1) th process parameter and the (n+1) th relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing the 2 nd fabric parameter and the 2 nd process parameter to obtain the n+2 th fabric, grading the n+2 th fabric, and respectively inputting the n+2 th fabric parameter, the n+2 th process parameter and the n+2 nd relative hand feeling corresponding to the n+2 th fabric parameter and the n+2 th process parameter into a fabric parameter library, a process parameter library and a hand feeling database; …; 2 nd fabric is produced by using the 2 nd fabric parameter and the nth technological parameter, the 2 nd fabric is rated, and the 2 nd fabric parameter, the 2 nd technological parameter and the 2 nd relative hand feeling corresponding to the 2 nd fabric parameter and the 2 nd technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database; …; the method comprises the steps of producing an mth plus 1 fabric by using an mth fabric parameter and a 1 st process parameter, grading the mth plus 1 fabric, and respectively inputting the mth plus 1 fabric parameter, the mth plus 1 process parameter and the corresponding mth plus 1 relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; the method comprises the steps of producing an mth plus 2 fabric by using an mth fabric parameter and a 2 nd process parameter, grading the mth plus 2 fabric, and respectively inputting the mth plus 2 fabric parameter, the mth plus 2 process parameter and the corresponding mth plus 2 relative hand feeling into a fabric parameter library, a process parameter library and a hand feeling database; …; the mth plus n fabric is produced by using the mth fabric parameter and the nth technological parameter, the mth plus n fabric is rated, and the mth plus n fabric parameter, the mth plus n technological parameter and the mth plus n relative hand feeling respectively corresponding to the mth plus n technological parameter and the mth plus n technological parameter are respectively input into a fabric parameter library, a technological parameter library and a hand feeling database; wherein m and n are natural numbers not less than 1;

in the step S1, a threshold value is set for the influence degree of the fabric parameters and the process parameters on the relative hand feeling when the multi-factor multi-level orthogonal experiment is tested, and the influence degree on the relative hand feeling is not more than the threshold value and is classified into the same type; the influence degree on the relative hand feeling is larger than a threshold value and is classified into different types;

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

s3, traversing the process parameter library after the relative hand feeling is found, finding out the process parameter corresponding to the relative hand feeling under the fabric parameter of the target fabric, and finishing the directional adjustment of the process parameter to produce the target fabric.