CN111876986B - Intelligent cutting device and method for garment design - Google Patents

Abstract

The invention discloses an intelligent cutting device for garment design, which comprises a shell, a cloth rolling tube, a cutting mechanism, a dyeing mechanism, a turnover mechanism, a sewing mechanism and a control system, wherein the control system is used for controlling cloth on the cloth rolling tube to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism; the invention also discloses an intelligent cutting method for garment design, which comprises the following steps: s1, manufacturing a two-dimensional picture, and scanning and identifying the two-dimensional picture; s2, generating a three-dimensional model, and finely trimming the three-dimensional model; s3, determining the size of the clothes; s4, cutting and coloring to generate clothes; the method comprises the steps of automatically converting a two-dimensional clothing design drawing into a three-dimensional model by using a computer system, and then generating clothing, thereby solving the technical problem that the clothing style in the prior art is difficult to rapidly and accurately produce in quantity after the drawing is designed.

Description

Intelligent cutting device and method for garment design

Technical Field

The invention relates to the field of garment design, in particular to an intelligent cutting device and an intelligent cutting method for garment design.

Background

Along with the improvement of living standard of people, people are pursuing diversification to style of clothes, and the position of clothes design in life is more and more important. At present, from garment designer designing to garment production, a plurality of steps are needed, the garment needs to be designed, style garments need to be manufactured, the garments need to be produced according to the style garments, the garments need to be modified according to different statures of each person, and the method is very troublesome and cannot be rapidly produced in large quantity. The inability to produce in large quantities quickly also results in slower speeds for garment designers to design garments because the market cannot digest the designed product in time. Thereby slowing down the development of the whole garment industry. In addition, the garment design drawing is mainly six views, and the whole garment is basically determined by determining the six views, so that a garment designer only needs to design the six views and theoretically determine the shape and color of the garment, and the garment can be produced.

Therefore, there is a need for improvement of the prior art to solve the above technical problems.

Disclosure of Invention

In view of this, the present invention aims to provide an intelligent cutting device and method for garment design, which solves the technical problem that it is not easy to rapidly and accurately produce the style of garment in mass production after the design drawing is designed for the style of garment in the prior art. The method is realized by the following technical scheme:

the invention provides an intelligent cutting method for clothing design, which comprises a shell, a cloth rolling drum, a cutting mechanism, a dyeing mechanism, a turnover mechanism, a sewing mechanism and a control system, wherein the control system is used for controlling cloth on the cloth rolling drum to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism, and the control system can adopt a PLC circuit or a circuit controlled by a single chip microcomputer;

the cloth cutting mechanism comprises a bottom plate, a cutting knife arranged above the bottom plate, a control frame I for controlling the cutting knife to move in the horizontal direction, a telescopic rod for controlling the cutting knife to move in the vertical direction and a press roller arranged above the bottom plate, after cloth on a cloth rolling cylinder enters the cutting mechanism, the press roller can move in the horizontal direction through cutting of the cutting knife and is used for controlling the cloth on the bottom plate to cling to the bottom plate and move horizontally on the bottom plate, and the press roller can move according to the shape of the cut cloth and always press the edge of the cloth on the bottom plate;

The dyeing mechanism comprises a color spraying needle arranged above the bottom plate and a control frame II for controlling the color spraying needle to move in the horizontal direction, and the color spraying needle is used for spraying color on the cloth on the bottom plate;

the turnover mechanism comprises an upper turnover plate, a turnover device connected with the upper turnover plate, a lower supporting plate and a connecting rod connected with the lower supporting plate, wherein the turnover device is used for controlling the upper turnover plate to rotate 180 degrees; the upper turning plate and the lower supporting plate are both provided with air suction holes, the cloth is sucked on the upper turning plate by the air suction holes and is tightly attached to the upper turning plate, the upper turning plate is turned for 180 degrees, the cloth is prevented from being on the lower supporting plate, the air suction holes on the lower supporting plate adsorb the cloth, meanwhile, the air suction holes on the upper turning plate do not suck the cloth any more, as the color is sprayed on the front side of the cloth, the cloth is usually sewn from the inside of the clothes during sewing, a turning mechanism is arranged to turn the cloth, and the next sewing step is convenient;

the sewing mechanism comprises a sewing needle, a control frame III for controlling the sewing needle to move in the horizontal direction and a vertical rod for controlling the sewing needle to move in the vertical direction.

Furthermore, the cloth winding drums comprise a plurality of cloth winding drums, the cloth on each cloth winding drum is different in material, and the control system is used for controlling the cloth on the specific cloth winding drum to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism.

Further, a door is arranged on the shell and used for taking out the sewn cloth.

Further, the control frame I comprises a left-right moving frame for controlling the cutting knife to move left and right and a front-back moving frame for controlling the cutting knife to move front and back.

In a second aspect of the embodiments of the present invention, there is provided an intelligent cutting method for garment design, including the steps of:

s1, making a two-dimensional picture, scanning and identifying the two-dimensional picture, wherein the system can be set as a computer for setting a specific program, the two-dimensional picture of the clothing design drawing can be input into the system, and the system identifies the clothing design drawing through an identification system;

s2, generating a three-dimensional model, finely trimming the three-dimensional model, wherein the three-dimensional model generated according to the two-dimensional picture of the garment design drawing is possibly in and out of detail with the design of a designer, and the designer finely trims the three-dimensional model;

s3, determining the size of the clothes, determining the clothes with different sizes according to different people and different body shapes, and setting the size of the clothes to be a uniform number;

S4, cutting and coloring to generate clothes, and controlling the sewing machine and the coloring device by the system to process the cloth to generate real clothes;

the step S1 specifically includes:

s11, making a View group View of the garment, wherein the View group View comprises a front View, a rear View, a left View, a right View, an upper View and a lower View, and a designer can draw six views through the system;

s12, scanning a view group, scanning six views, and determining shape and color data Shapecolor of the clothes;

the step S2 specifically includes:

s21, generating a three-dimensional model according to the data in the step S12, namely generating a three-dimensional perspective view of the clothes;

s22, inputting modification items and modification data, and modifying the three-dimensional model, wherein a designer can perform fine adjustment modification on the three-dimensional model due to the fact that the three-dimensional model generated according to the six views possibly has errors;

step S3 specifically includes:

s31, inputting body data, wherein different body data can be input according to different statures of each person, and the body data can also be uniformly input by setting the body data as a uniform number;

s32, generating clothing model data according to the body data;

step S4 specifically includes:

s41, selecting cloth, and selecting the material of the cloth according to the requirement;

S42, cutting the cloth, and reserving blank cloth at the edge of the cloth, wherein the blank cloth needs to be spliced;

s43, coloring the cloth by adopting modes such as color spraying, water dyeing and the like;

and S44, splicing the cloth to generate the garment, wherein the garment can be spliced by adopting a sewing or bonding mode.

Further, the step S12 specifically includes:

s121, generating a variable hexahedron Hex, and scanning a picture P observed according to Visual angle in View group View;

s122, comparing the picture P with the variable hexahedron Hex, modifying the variable hexahedron Hex to generate modified variable hexahedron Hex ', wherein the shape and color information of the Hex ' observed according to the Visual angle Visual is SCV, and the SCV is f (Hex, P), which represents that the shape and color distribution of a two-dimensional graph of the variable hexahedron Hex ' observed according to the Visual angle Visual are the same as those of the picture P, and the Hex ' is replaced by the Hex ';

and S123, repeating the step S121 and the step S122 in the View group View until all pictures in the View group View are compared with the variable hexagon Hex to generate a modified variable hexagon, wherein the modified variable hexagon is modified at least 6 times, a three-dimensional stereo model of the garment is generated by a two-dimensional picture of the garment, the shape data color data information of the modified variable hexagon is Shapecolor, Shapecolor ∑ f (Hex, View), and the shape and the color of the modified variable hexagon Hex are the same as those of the picture of any picture in the View according to the View angle observation of the View angle.

Further, the step S22 specifically includes:

s221, determining shape color information SC of the three-dimensional model before modification, and inputting a three-dimensional coordinate Coord of a modification position, namely determining the modification position;

s222, inputting a modified direction;

s223, inputting modified data Date, wherein the Date can be positive or negative, positive numbers represent that the clothes are stretched in the Direct direction, and negative numbers represent that the clothes are shrunk in the Direct direction;

s224, generating shape color information SC 'of the modified three-dimensional model, wherein SC' is SC + g (Coord, Direct, Date), and g (Coord, Direct, Date) represents that the shape and the color of the three-dimensional model are modified on coordinates Coord according to a modification direction Direct, and the modified data is Date;

and S225, replacing SC ', and modifying the three-dimensional model according to the SC'.

Further, the body data in step S31 specifically includes a chest circumference, a waist circumference, a hip circumference, a front chest width, a back width, a chest height, a front waist pitch length, a back length, a front clothing length, a back clothing length, a chest distance, a neck circumference, a shoulder width, a sleeve length, an arm circumference, a wrist size, an armpit circumference, a cane circumference, a head circumference, a trousers length, a thigh circumference, and a crotch, and several body data that must be input may be set, and other data may be selectively input.

Further, the step S41 specifically includes:

s411, setting a prestoring Cloth set of Cloth, wherein the Cloth is { Cloth1, Cloth2 … … Clothn }, Cloth1 and Cloth2 … … Clothn represent different kinds of Cloth, n is more than 0, and n is a natural number;

s412, manually inputting clothing cloth Clothk, wherein k is more than 0 and less than or equal to n, and k is a natural number.

Further, the step S43 is to spray pigment for coloring the cloth, so the coloring treatment is more suitable for the working mode of the system, and is also convenient for mass production.

Further, the colors of the pigments in step S43 include red, yellow and blue, and an excessive amount of pigments is required, thereby facilitating the operation.

Further, the fabric is spliced in the step S44 by sewing, so that the style splicing is tighter and the splicing manner of most garments is also met.

The positive and beneficial technical effects of the invention comprise: by inputting the two-dimensional pictures of the clothes style, the system can automatically generate a three-dimensional model to automatically produce clothes, which is beneficial to rapid batch and streamlined production of clothes design; the three-dimensional model can be refined, so that the three-dimensional model is more consistent with the design scheme of a designer, and the generated three-dimensional model is more accurate; the clothes can be properly produced according to the stature of each person, and the clothes can also be set to be uniform in size, so that the clothes are suitable for mass production; the designer can rapidly produce the clothes in mass production after designing the clothes, and the factory production is convenient; other advantageous effects of the present invention will be further described with reference to the following specific examples.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a perspective view of an embodiment of the present invention;

FIG. 2 is an internal perspective view of an embodiment of the present invention;

FIG. 3 is a side view of an embodiment of the present invention;

FIG. 4 is a top view of the present invention;

fig. 5 is a system flow chart according to an embodiment of the present invention, in which arrows represent signal transmission directions.

In the figure:

1-a shell; 2-rolling a cloth cylinder; 3-a bottom plate; 4-cutting out a knife; 5-control frame I; 6, a telescopic rod; 7-pressing rolls; 8-color spraying needle; 9-control frame II; 10-an upper turning plate; 11-a turning device; 12-a lower supporting plate; 13-a connecting rod; 14-a sewing needle; 15-control frame III; 16-vertical rod; 17-opening the door.

Detailed Description

Example 1: an intelligent cutting method for clothing design is disclosed, as shown in fig. 1-4, and comprises a shell 1, a cloth roller 2, a cutting mechanism, a dyeing mechanism, a turnover mechanism, a sewing mechanism and a control system, wherein the control system is used for controlling cloth on the cloth roller 2 to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism, and the control system can adopt a PLC circuit or a circuit controlled by a single chip microcomputer;

The cutting mechanism comprises a bottom plate 3, a cutting knife 4 arranged above the bottom plate 3, a control frame I5 for controlling the horizontal movement of the cutting knife 4, a telescopic rod 6 for controlling the vertical movement of the cutting knife 4 and a press roller 7 arranged above the bottom plate 3, after cloth on a cloth rolling tube 2 enters the cutting mechanism, the cloth is cut by the cutting knife 4, the press roller 7 can move in the horizontal direction and is used for controlling the cloth on the bottom plate 3 to cling to the bottom plate 3 and horizontally move on the bottom plate 3, and the press roller 7 can move according to the shape of the cut cloth and always press the edge of the cloth on the bottom plate 3;

the dyeing mechanism comprises a color spraying needle 8 arranged above the bottom plate 3 and a control frame II9 for controlling the color spraying needle 8 to move in the horizontal direction, and the color spraying needle 8 is used for spraying color on the cloth on the bottom plate 3;

the turnover mechanism comprises an upper turning plate 10, a turnover device 11 connected with the upper turning plate 10, a lower support plate 12 and a connecting rod 13 connected with the lower support plate 12, wherein the turnover device 11 is used for controlling the upper turning plate 10 to rotate 180 degrees, the connecting rod 13 is used for controlling the lower support plate 12 to move in the horizontal direction and the vertical direction, the lower support plate 12 is in contact with the upper turning plate 10 when located at the highest point, the lower support plate 12 is located under the upper turning plate 10 when located at the leftmost side and is located under the sewing mechanism when located at the rightmost side, and the left side and the right side are the left side and the right side in the drawing 3; the upper turning plate 10 and the lower supporting plate 12 are both provided with air suction holes, cloth is sucked on the upper turning plate 10 by the air suction holes and is tightly attached to the upper turning plate 10, the upper turning plate 10 is turned over for 180 degrees, the cloth is prevented from being arranged on the lower supporting plate 12, the air suction holes in the lower supporting plate 12 adsorb the cloth, meanwhile, the air suction holes in the upper turning plate 10 do not suck the cloth any more, as the color is sprayed on the front side of the cloth, the cloth is usually sewn from the inside of the clothes during sewing, a turnover mechanism is arranged to turn over the cloth, and the next sewing step is convenient;

The sewing mechanism comprises a sewing needle 14, a control frame III15 for controlling the horizontal movement of the sewing needle 14 and a vertical rod 16 for controlling the vertical movement of the sewing needle 14.

In this embodiment, the cloth winding drums 2 include a plurality of cloth winding drums 2, the material of the cloth on each cloth winding drum 2 is different, and the control system is used for controlling the cloth on a specific cloth winding drum 2 to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism.

In this embodiment, the housing 1 is provided with an opening door 17 for taking out the sewn fabric.

In this embodiment, the control frame I includes a left-right moving frame for controlling the cutting blade to move left and right and a front-back moving frame for controlling the cutting blade to move front and back, and the front and back are respectively the top and bottom in fig. 4.

Example 2: an intelligent tailoring method for garment design, as shown in fig. 5, comprises the device in embodiment 1, and comprises the following steps:

s1, making a two-dimensional picture of a clothing style, scanning and identifying the two-dimensional picture, wherein the system can be set as a computer with a specific program stored in the computer, the two-dimensional picture of a clothing design picture can be input into the system, and the system identifies the clothing design picture through an identification system;

s2, generating a three-dimensional model, finely trimming the three-dimensional model, wherein the three-dimensional model generated according to the two-dimensional picture of the garment design drawing is possibly in and out of detail with the design of a designer, and the designer finely trims the three-dimensional model;

S3, determining the size of the clothes, determining the clothes with different sizes according to different people and different body shapes, and setting the size of the clothes to be a uniform number;

s4, cutting and coloring to generate clothes, and controlling the sewing machine and the coloring device by the system to process the cloth to generate real clothes;

the step S1 specifically includes:

s11, making a View group View of the garment, wherein the View group View comprises a front View, a rear View, a left View, a right View, an upper View and a lower View, and a designer can draw six views through the system;

s12, scanning a view group, scanning six views, and determining shape and color data Shapecolor of the clothes;

the step S2 specifically includes:

s21, generating a three-dimensional model according to the data in the step S12, namely generating a three-dimensional perspective view of the clothes;

s22, inputting modification items and modification data, and modifying the three-dimensional model, wherein a designer can perform fine adjustment modification on the three-dimensional model due to the fact that the three-dimensional model generated according to the six views possibly has errors;

step S3 specifically includes:

s31, inputting body data, wherein different body data can be input according to different statures of each person, and the body data can also be uniformly input by setting the body data as a uniform number;

S32, generating clothing model data according to the body data;

step S4 specifically includes:

s41, selecting cloth, and selecting the material of the cloth according to the requirement;

s42, cutting the cloth, and reserving blank cloth at the edge of the cloth, wherein the blank cloth needs to be spliced;

s43, coloring the cloth by adopting modes such as color spraying, water dyeing and the like;

and S44, splicing the cloth to generate the garment, wherein the garment can be spliced by adopting a sewing or bonding mode.

In this embodiment, the step S12 specifically includes:

s121, generating a variable hexahedron Hex, and scanning a picture P observed according to Visual angle in View group View;

s122, comparing the picture P with the variable hexahedron Hex, modifying the variable hexahedron Hex to generate modified variable hexahedron Hex ', wherein the shape and color information of the Hex ' observed according to the Visual angle Visual is SCV, and the SCV is f (Hex, P), which represents that the shape and color distribution of a two-dimensional graph of the variable hexahedron Hex ' observed according to the Visual angle Visual are the same as those of the picture P, and the Hex ' is replaced by the Hex ';

and S123, repeating the step S121 and the step S122 in the View group View until all pictures in the View group View are compared with the variable hexagon Hex to generate a modified variable hexagon, wherein the modified variable hexagon is modified at least 6 times, a three-dimensional stereo model of the garment is generated by a two-dimensional picture of the garment, the shape data color data information of the modified variable hexagon is Shapecolor, Shapecolor ∑ f (Hex, View), and the shape and the color of the modified variable hexagon Hex are the same as those of the picture of any picture in the View according to the View angle observation of the View angle.

In this embodiment, the step S22 specifically includes:

s221, determining shape color information SC of the three-dimensional model before modification, and inputting a three-dimensional coordinate Coord of a modification position, namely determining the modification position;

s222, inputting a modified direction;

s223, inputting modified data Date, wherein the Date can be positive or negative, positive numbers represent that the clothes are stretched in the Direct direction, and negative numbers represent that the clothes are shrunk in the Direct direction;

s224, generating shape color information SC 'of the modified three-dimensional model, wherein SC' is SC + g (Coord, Direct, Date), and g (Coord, Direct, Date) represents that the shape and the color of the three-dimensional model are modified on coordinates Coord according to a modification direction Direct, and the modified data is Date;

and S225, replacing SC ', and modifying the three-dimensional model according to the SC'.

In this embodiment, the body data in step S31 specifically includes a chest circumference, a waist circumference, a hip circumference, a front chest width, a back width, a chest height, a front waist pitch length, a back length, a front clothing length, a back clothing length, a chest distance, a neck circumference, a shoulder width, a sleeve length, an arm circumference, a wrist size, an armpit circumference, a cane circumference, a head circumference, a trousers length, a thigh circumference, and a crotch, and several body data that must be input may be set, and other data may be selectively input.

In this embodiment, the step S41 specifically includes:

s411, setting a prestoring Cloth set of Cloth, wherein the Cloth is { Cloth1, Cloth2 … … Clothn }, Cloth1 and Cloth2 … … Clothn represent different kinds of Cloth, n is more than 0, and n is a natural number;

s412, manually inputting clothing cloth Clothk, wherein k is more than 0 and less than or equal to n, and k is a natural number.

In this embodiment, the step S43 is to spray pigment to color the cloth, so that the color spraying is more suitable for the working mode of the system, and is also convenient for mass production.

In this embodiment, the colors of the pigments in step S43 include red, yellow and blue, and an excessive amount of pigments is required, so that the operation is convenient.

In this embodiment, the fabric is spliced in step S44 by sewing, so that the style splicing is tighter and the splicing manner of most garments is also met.

Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.

Claims (7)

1. The utility model provides a device is tailor to intelligence for dress designing which characterized in that: the cloth cutting machine comprises a shell, a cloth winding drum, a cutting mechanism, a dyeing mechanism, a turnover mechanism, a sewing mechanism and a control system, wherein the control system is used for controlling cloth on the cloth winding drum to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism;

the cutting mechanism comprises a bottom plate, a cutting knife arranged above the bottom plate, a control frame I for controlling the cutting knife to move in the horizontal direction, a telescopic rod for controlling the cutting knife to move in the vertical direction and a press roller arranged above the bottom plate, wherein the press roller can move in the horizontal direction and is used for controlling cloth on the bottom plate to cling to the bottom plate and move horizontally on the bottom plate;

the dyeing mechanism comprises a color spraying needle arranged above the bottom plate and a control frame II for controlling the color spraying needle to move in the horizontal direction, and the color spraying needle is used for spraying color to the cloth on the bottom plate;

the turnover mechanism comprises an upper turnover plate, a turnover device connected with the upper turnover plate, a lower supporting plate and a connecting rod connected with the lower supporting plate, wherein the turnover device is used for controlling the upper turnover plate to rotate 180 degrees; the upper turning plate and the lower supporting plate are both provided with air suction holes;

The sewing mechanism comprises a sewing needle, a control frame III for controlling the sewing needle to move in the horizontal direction and a vertical rod for controlling the sewing needle to move in the vertical direction;

the cloth winding drums comprise a plurality of cloth winding drums, the cloth on each cloth winding drum is different in material, and the control system is used for controlling the cloth on the specific cloth winding drum to sequentially enter the cutting mechanism, the dyeing mechanism, the turnover mechanism and the sewing mechanism.

2. The intelligent cutting device for garment design according to claim 1, wherein: the shell is provided with a door for taking out the sewn cloth.

3. The intelligent cutting device for garment design according to claim 2, wherein: the control frame I comprises a left-right moving frame for controlling the cutting knife to move left and right and a front-back moving frame for controlling the cutting knife to move front and back.

4. An intelligent tailoring method for garment design for use with the apparatus of any of claims 1-3 comprising the steps of:

s1, manufacturing a two-dimensional picture, and scanning and identifying the two-dimensional picture;

s2, generating a three-dimensional model, and finely trimming the three-dimensional model;

s3, determining the size of the clothes;

s4, cutting and coloring to generate clothes;

the step S1 specifically includes:

S11, manufacturing a View group View of the garment, wherein the View group View comprises a front View, a rear View, a left View, a right View, an upper View and a lower View;

s12, scanning a view group, and determining shape and color data ShapeColor of the clothes;

the step S2 specifically includes:

s21, generating a three-dimensional model according to the data in the step S12;

s22, inputting modification items and modification data, and modifying the three-dimensional model;

the step S12 specifically includes:

s121, generating a variable hexahedron Hex, and scanning a picture P observed according to Visual angle in View group View;

s122, comparing the picture P with the variable hexahedron Hex, modifying the variable hexahedron Hex to generate modified variable hexahedron Hex ', wherein the shape and color information of the Hex ' observed according to the Visual angle Visual is SCV, SCV = f (Hex, P), the shape of a two-dimensional graph of the variable hexahedron Hex ' observed according to the Visual angle Visual is the same as the shape and color distribution of the picture P, and the Hex ' is replaced by the Hex ';

s123, repeating the step S121 and the step S122 in the View group View until all pictures in the View group View are compared with a variable hexagon Hex to generate a modified variable hexagon, wherein the shape data color data information of the modified variable hexagon is ShapeColor, ShapeColor = Σ f (Hex, View), and the shape and the color of the modified variable hexagon Hex are the same as those of the pictures at the View angle according to the View angle observation of any picture in the View;

The step S22 specifically includes:

s221, determining shape color information SC of the three-dimensional model before modification, and inputting a three-dimensional coordinate Coord of a modification position;

s222, inputting a modified direction;

s223, inputting modified data Date;

s224, generating shape color information SC ', SC' = SC + g (Coord, Direct, Date) of the modified three-dimensional model, wherein g (Coord, Direct, Date) represents that the shape and the color of the three-dimensional model are modified on a coordinate Coord according to a modification direction Direct, and the modified data is Date;

s225, replacing SC' = SC;

step S3 specifically includes:

s31, inputting body data;

s32, generating clothing model data according to the body data;

step S4 specifically includes:

s41, selecting cloth;

s42, cutting cloth;

s43, coloring the cloth;

and S44, splicing the cloth to generate the garment.

5. The intelligent cutting method for garment design according to claim 4, wherein: the body data in step S31 includes bust, waist, hip, front chest width, back width, chest height, front waist length, back length, front garment length, back garment length, chest distance, neck circumference, shoulder width, sleeve length, arm circumference, wrist size, axillary circumference, cane circumference, head circumference, trousers length, thigh circumference, and crotch.

6. The intelligent cutting method for garment design according to claim 5, wherein the step S41 specifically comprises:

s411, setting a prestoring Cloth set of Cloth, wherein, the Cloth is set with a set of Cloth of which the Cloth is prestored, and the Cloth is set with a set of Cloth of which the Cloth is not equal to { Cloth1, Cloth2 … … Cloth }, Cloth1 and Cloth2 … … Cloth represent different kinds of Cloth, n is more than 0, and n is a natural number;

s412, manually inputting clothing cloth Clothk, wherein k is more than 0 and less than or equal to n, and k is a natural number.

7. The intelligent cutting method for garment design according to claim 6, wherein: the step S43 is to color the cloth by spraying pigment.

Images