TWI806776B - Design method of systematic modular clothing pattern - Google Patents

Abstract

A system modularized garment pattern design method is applied to a system modularized device and executes a modular pattern structure or a piercing board structure in the system modularized device. In this way, the system modularized garment pattern design method proposed in the present invention can be used to define a flat garment pattern as a system modularized device with a geometric shape of a piece of art, and the proposed method is also a zero-waste fabric The method of use is to cut all the fabrics into geometric shapes. In addition to efficiently cutting and using the original rectangular fabric, it will not throw away a lot of waste from the corners and corners after cutting like the traditional conventional pattern. Using geometrically shaped fabrics in different combinations can produce ever-changing three-dimensional clothing styles. It is no longer limited to one type of clothing and can only produce one type of clothing.

Description

Design method of systematic modular clothing pattern

The present invention relates to a system modularized garment pattern design method, especially relates to the use of a system modularized device for defining a flat garment pattern as a geometric shape with a clever board, especially the available geometric shape The fabrics are assembled in different ways to produce ever-changing three-dimensional clothing styles, and it is no longer limited to the method that only one type of clothing can only produce one type of clothing.

Clothing structure requires the fabric to be cut into many pieces during the manufacturing process, usually including collar pieces, sleeve pieces, front body pieces, and back body pieces, etc. In addition to increasing the trouble of cutting and sorting, making it more inconvenient to make, sewing is also more costly, because the speed of making clothes usually depends on the number of seams. When there are more seams, the more laborious the product will be The easier it is to have defects and defects and lead to return incidents. As for the saving of fabrics, the use of the remaining fabrics is generally not considered during typesetting, so after the traditional conventional layout is cut, a lot of corner waste needs to be discarded. However, under the premise of saving cloth, it has to spend extra time and manpower when designing paper patterns and typesetting. Therefore, this traditional process limits the possibility of increasing the production speed.

Shown in the 16th and 17th figures is the relationship between the flat version (cut pieces) and three-dimensional clothing of all conventional clothes at present. The clothing-making process of this modular version is a flat version specially designed for a single style of clothing, which can only be assembled into a single three-dimensional garment, and the assembly method is to assemble the components by sewing, but Sewing requires equipment and sewing skills, so it is only suitable for garment workers with basic knowledge and technical experience. An ideal dress, because there is no standard pattern to follow, that is, often It is impossible to make the samples required for this style of clothing, so it is very unsatisfactory in work.

For this reason, in view of the lack of disadvantages in the conventional technology, there is an urgent need for improvement, and the development of a set of technical limitations that can break through the technical limitations of assembling components by sewing with a tailor's locomotive and a single version of the previous case can only be produced. It is necessary to invent the technical shortcomings of a garment.

The main purpose of the present invention is to overcome the above-mentioned problems encountered in the prior art and provide a method that can be used to define a flat garment version as a system modularized device with a geometric shape of a piece of art. This method is also a kind of The zero-waste fabric use method cuts all the fabric into geometric shapes. In addition to efficiently cutting and using the original rectangular fabric, it will not lose a lot of edges and corners after cutting like traditional conventional patterns. Waste materials can also be used in different combinations of geometric shapes to produce ever-changing three-dimensional clothing styles. It is no longer limited to a systematic modular clothing pattern design method that can only produce one type of clothing.

In order to achieve the above purpose, the present invention is a system modularized garment pattern design method, which is used to define the plane garment pattern as a geometric shape with a smart board. The method at least includes the following steps: Step 1: According to the user It is necessary to select a modular pattern structure or a chipboard structure for geometric group arrangement; and step 2: when the user selects the modular pattern structure and uses the modular pattern structure to build several When using the geometric components, provide the user with the choice of a basic pattern design combination or a creative pattern design combination based on the geometric components to form different three-dimensional clothing styles; or step 3: when the user chooses to use the wearing When using the chipboard structure to build six geometric modules, each of the geometric modules is provided with holes that form several perforations on its edges, providing the user with a diagrammatic or creative way The six geometric modules are arranged into corresponding or creative shapes, and then fixed and assembled through the holes through the ropes to form different three-dimensional clothing styles.

In the above-mentioned embodiment of the present invention, when the user is a fashion designer, choose to use For the module version structure, when the user is the wearer, he chooses to use the chipboard structure.

In the above-mentioned embodiments of the present invention, the modular version structure includes a basic assembling unit. The basic assembling unit is composed of several calculated common radians of the human body, which can correspond to the radians of the crotch position, neckline position, and armpit position. The required long and short rectangular linear components, as well as interlocking U-shaped convex components and half U-arc concave components are used to assemble the same set of geometric components with the same shape in a completely exhaustive way to form the basis of different garments Style design combination.

In the above-mentioned embodiments of the present invention, the basic assembling unit is to assemble the same set of geometric components with the same shape into three basic styles of tops, dresses and trousers.

In the above-mentioned embodiment of the present invention, the modular version structure includes a creative grouping unit, which is composed of 8 completely different shapes of straight line components and curved components, including an obtuse angled arc trapezoidal concave component, An acute-angled trapezoidal concave component with an arc, a semicircular convex component, a U-shaped convex component, a U-arc rectangular concave component, a rectangular component, an isosceles right-angled triangular component, and a trapezoidal component. Freely align the positions without using up all the geometric components to assemble a clothing style. You can use the appropriate geometric components and the corresponding quantity to combine according to your needs. The unused geometric components can be used in other garments The creative fit design portfolio.

In the above-mentioned embodiment of the present invention, the creative grouping unit can define the 8 different geometric components as a single component group or a mixed component group.

In the above-mentioned embodiments of the present invention, the hole member is any one or a combination of the processing method that can punch holes in the cloth or add the auxiliary material with holes or the webbing.

In the above-mentioned embodiment of the present invention, the piercing board structure includes a geometric module unit, which is composed of a circular convex module, a rectangular concave module with a right angle with an arc, an obtuse trapezoidal concave module with an arc, and a half-arc five It is composed of six geometric modules including a side-shaped concave module, a half-arc trapezoidal concave module and a rectangular module, and these geometric modules can be assembled into at least one three-dimensional clothing style.

In the above-mentioned embodiment of the present invention, the see-through board structure includes a string unit, which is worn Set between the several perforations, according to the geometric combination pattern of the clothing style selected by the user or create by oneself, select the geometric module corresponding to the shape required for the selected clothing style geometric combination pattern from these geometric modules Arranging, assembling the selected geometric modules by means of holes and ropes to complete a geometric combination pattern corresponding to the selected clothing style or the self-created three-dimensional clothing style.

In the above-mentioned embodiment of the present invention, the piercing board structure includes a graphic database, which stores several geometric combination patterns of clothing styles for users to choose and use, and the geometric combination patterns of several clothing styles are related to The three-dimensional clothing styles assembled by the geometric modules correspond to each other.

100: System modularization device

1: Module version structure

11:Basic assembly unit

111, 112, 111a, 112a: rectangular straight line components

113: U-shaped convex component

114: Half U arc concave component

115: Selvedge

12:Creative assembly unit

121: obtuse angle trapezoidal concave component with arc

122: Trapezoidal concave component with acute angle and arc

123: Semicircular convex component

124: U-shaped convex component

125: U arc rectangular concave component

126: Rectangular components

127: Isosceles right triangle components

128: Ladder component

2: Piece structure

21: Geometry Module Unit

211: Round convex module

212: Right-angle rectangular concave module with arc

213: obtuse angle trapezoidal concave module with arc

214: Semi-arc pentagon concave module

215: semi-circular trapezoidal concave module

216: rectangular module

217: perforation

218: hole parts

22:Graphic database

221:Geometric combination pattern of clothing style

23: Cord unit

s11~s13: steps

Figure 1 is a schematic diagram of the system modularized clothing layout design process of the present invention.

Fig. 2 is a system block schematic diagram of the system modularization device of the present invention.

Fig. 3 is a schematic diagram of the basic assembling unit of the module version structure of the present invention.

Fig. 4 is a schematic diagram of a basic assembling mode of the basic assembling unit of the present invention.

Fig. 5 is a schematic diagram of 3D simulation molding of one of the basic assembling methods of the present invention.

Fig. 6 is a schematic diagram of the second basic assembling mode of the basic assembling unit of the present invention.

Fig. 7 is a schematic diagram of 3D simulation molding of the second basic assembling method of the present invention.

Fig. 8 is a schematic diagram of the third basic assembling mode of the basic assembling unit of the present invention.

Figure 9 is a schematic diagram of the 3D simulation molding of the third basic assembly method of the present invention.

Fig. 10 is a schematic diagram of the creative assembly unit of the module version structure of the present invention.

Fig. 11 is a schematic diagram of a single component assembly of the creative assembly unit of the present invention.

Fig. 12 is a schematic diagram of a mixed component assembly of the creative assembly unit of the present invention.

Fig. 13 is a schematic diagram of the structure of the chipboard structure of the present invention.

Fig. 14 is a schematic diagram of several kinds of clothing styles built in by the present invention.

Fig. 15 is a schematic diagram of the operation mode of the assembly module using perforated binding ropes according to the present invention.

Figure 16 is a schematic diagram of a plane version designed for a single style of clothing.

Figure 17 is a schematic diagram of the only three-dimensional clothing that can only be assembled with a flat version.

Please refer to "Fig. 1 to Fig. 15", which are respectively a schematic diagram of the design process of the system modularized clothing pattern of the present invention, a schematic diagram of the system block diagram of the system modularized device of the present invention, and a modular pattern structure of the present invention. The schematic diagram of the basic assembling unit of the present invention, the schematic diagram of the basic assembling method 1 of the basic assembling unit of the present invention, the schematic diagram of the 3D simulation molding of the basic assembling method 1 of the present invention, the schematic diagram of the basic assembling method 2 of the basic assembling unit of the present invention, the present invention Schematic diagram of 3D simulation forming of basic assembling method 2, schematic diagram of basic assembling method 3 of the basic assembling unit of the present invention, schematic diagram of 3D simulation molding of basic assembling method 3 of the present invention, creative assembling unit of the module layout structure of the present invention Schematic diagram, a schematic diagram of a single component assembly of the creative assembly unit of the present invention, a schematic diagram of the mixed component assembly of the creative assembly unit of the present invention, a schematic diagram of the structure of the piercing board structure of the present invention, and a geometric assembly of several built-in clothing styles in the present invention Schematic diagram of the pattern, and a schematic diagram of the operation state of the assembly module using perforated tie ropes in the present invention. As shown in the figure: the present invention is a system modularized clothing pattern design method, which is applied to a system modularized device 100 and a modular pattern structure 1 or a dress in the system modularized device 100 The board structure 2 is executed, which at least includes the following steps:

Step s11: Select the modular pattern structure 1 or the panel structure 2 according to the needs of the user for geometrical grouping and arrangement.

Step s12: When the user selects the module layout structure 1 and uses the module layout structure 1 to build several geometric components, provide the user with a choice of a basic layout design combination based on the geometric components Or a combination of creative version designs to form different three-dimensional clothing styles.

Step s13: When the user chooses to use the piecing board structure 2 and uses the piecing board structure 2 When building six geometric modules, each of the geometric modules is provided with several perforated holes on its edges, so that the user can arrange the six geometric modules into corresponding or creative shapes according to the graphic method or his own creativity , and then fix the combination by threading the rope through the holes to form different three-dimensional clothing styles. If so, a brand-new method for systematically modularizing clothing layout design is formed through the above-mentioned disclosed process.

When in use, this method is applied to a system modularization device 100 that defines a flat garment pattern as a geometric shape of a jigsaw puzzle, so that different assembly methods can be used like a jigsaw puzzle to produce ever-changing three-dimensional clothing The style is no longer limited to one version and only one garment can be produced. The present invention will be described in detail with two sets of exemplary applications, but the following examples are only examples for understanding the details and connotation of the present invention, but are not used to limit the patent scope of the present invention.

<Example 1> Module layout structure

When the user is a fashion designer, he can select the modular layout structure 1 through the system modularization device 100 for design combination. As shown in Figure 2, the modular version structure 1 includes a basic assembling unit 11 and a creative assembling unit 12. The modular version structure 1 is built with several geometric components cut from cloth, The user can be provided with a choice of a basic pattern design combination or a creative pattern pattern design combination to form different three-dimensional clothing styles.

[Basic grouping example]

In one of the preferred embodiments of the present invention, the geometric components mentioned above are applied to fabrics with a width of 160 centimeters and a length of 90 centimeters, that is, an integral number of one yard, as shown in Figure 3. The basic assembling unit 11 has a set of geometric components that have calculated the common curvature of the human body and can correspond to the curvature requirements of the crotch position, neckline position, and armpit position. Using the fit of the common curve to the human body, the same A set of geometric components of the same shape can be assembled into three basic styles of tops, vests, dresses and pants.

The basic assembling unit 11 is composed of several very simple and regular longer and shorter rectangular linear components 111, 112, and interlocking U-shaped convex components 113 and half U-arc concave components 114 to form a group of geometric components. And the width of 160 centimeters includes the longer and The shorter rectangular linear components 111a, 112a can be used as decorative strips, and can function in the following designs, presenting extra points for detailed features.

1. Basic assembly method 1: Vest dress

First, as shown in Figure 4, the semi-U-arc concave components 114 are respectively arranged as the armholes of the front and rear body pieces, the longer rectangular linear components 111 are used as the front center and the rear center, and the shorter rectangular linear components 112 are combined to form Shoulder straps, and the two U-shaped convex components 113 are used as the radians of the front shoulder straps, and then the longer and shorter rectangular linear components 111a, 112a with selvage 115 are arranged at the hem, if the selvage 115 has other requirements Edge or contrasting color features can be highlighted on the hem, so that the combination of vest and dress is completed.

The present invention uses 3D software to actually simulate the shape of the pattern, and the results obtained by the combination method are shown in Figure 5. (a), (b) and (c) in the figure are the front, back and side respectively. After being knotted in pairs, they will fall on the shoulders to form a bow-like shape. The original U-shaped convex component 113 at the end of the front shoulder strap will hang down on the back after being knotted. If the seam is connected with the body piece, it will produce ruffles, and if the elastic band is pressed on the cutting line of the front and back middle pieces, the wrinkle design effect can be added to the outline, and the shape sense of the basic style clothing can be enriched .

2. Basic assembly method 2: coat

Then try to assemble and arrange the same components in another way as shown in Figure 6, use the semi-U arc concave component 114 as the neckline of the front and rear body pieces, and use the U-shaped convex component 113 as two pieces pressed on the front piece. Small pocket, then the longer rectangular linear assembly 111a with selvedge 115 is combined on the left and right sides of the front body, and the shorter rectangular linear assembly 112a with selvage 115 is assembled on the upper half of the sleeve, so that the entire front The piece can increase the fun of splicing through the selvedge 115, and the long and short rectangular linear components 111, 112 without the selvedge 115 are respectively assembled in the lower half of the sleeve of the front piece, the left and right sides of the back piece, the sleeves, and as Side inserts.

Through the simulation of 3D software, you can get the forming result of grouping method 2, as shown in Figure 7 As shown, (a), (b) and (c) in the figure are the front, back and side respectively. The semi-U arc concave component 114 presents an ideal neckline. If the drawstring is wrapped around the neckline, some pleats can be drawn out, enriching the lines of the neck and shoulders, and the U-shaped convex component 113 also forms a pocket of appropriate size. After the clothes are worn, the gussets on the sides will be tilted at an angle, forming an interesting silhouette on the sides, and the characteristic selvedge 115 is used on the cut line between the upper edge of the sleeves and the front piece, which will also add to the clothing. The extra three-dimensional effect can also be worn as a smock coat if the front center seam is not sewn.

3. Basic assembly method three: pants

Finally, the present invention will try to apply the combination method of the lower body to verify that a single curve can solve the flexibility of different curvatures of the body. As shown in Figure 8, the semi-U arc concave components 114 are combined in pairs, and the curves can be used as trousers The crotch of the left and right pieces, and other rectangular linear components 111, 112, are assembled in units of one long and one short, and then arranged side by side to form a trouser body. The following two U-shaped convex components 113 are used as cover sheets, and are combined with the remaining two shorter rectangular linear components 112 to form pockets on the sides of the trouser legs.

Through the simulation of 3D software, the forming result of the assembly method 3 can be obtained, as shown in Figure 9, in which (a), (b) and (c) are the front, back and side respectively. The U-arc concave component 114 at the crotch provides sufficient space for the crotch, lower abdomen and buttocks. The drawstring or elastic band is wrapped around the waist, so that the trousers can be worn in a good fit, and they are arranged on the selvedge of the front panel 115, just like the ironing line of general suit trousers, it can show the effect of modifying the line of the legs. Finally, the side pockets are opened at the height of the arm, which is convenient to use. In this way, a side opening is completed. Pocket basic pants.

[Example of creative combination]

The above-mentioned basic assembly is a set of geometric components with the same shape, which is assembled in a completely exhaustive manner to form a combination of basic pattern designs of different garments. In one of the preferred embodiments of the present invention, the proposed creative assembling unit 12 escapes the restriction through creative assembling, and develops the possibility of system modularization in a broader sense. Users or designers, It is not necessary to use up all the geometric components to assemble a suit Clothing styles are combined by taking appropriate geometric components and corresponding quantities according to requirements, and unused geometric components will not be reduced to waste, because all fabrics have been defined as geometric components and can be flexibly used in other ready-to-wear designs.

The present invention firstly plans the geometric components of the creative assembling unit 12 as shown in Figure 10, and is divided into an obtuse-angled trapezoidal concave component 121 with an arc, an acute-angled trapezoidal concave component 122 with an arc, a semicircular convex component 123, a U-shaped convex component 124, a U-arc rectangular concave component 125, a rectangular component 126, an isosceles right-angled triangle component 127, and a trapezoidal component 128, a total of 8 kinds of straight line components and curve components of different shapes are formed, and they interact with each other. The tight buckle is composed of the concept principle of the jigsaw puzzle, and can be freely aligned.

Once you think about it from the perspective of system modularization in a broad sense, you can find that the flexibility of combining these components is actually beyond imagination. Just play with two or three components of the same type, you can pass through The transformation of the angle and the change of the alignment direction create an infinite variety of rich graphic appearances. The present invention attempts to use these 8 different components separately, and take 2 to 3 pieces of the same shape to respectively arrange three different combinations. , the result is shown in Figure 11. From the results of the experiment, it can be known that many shapes that were not in the original components can be achieved by combining them. For example, there is no square in this group of components, but it can be achieved through two The isosceles right-angled triangle components 127 are assembled, and the semicircular convex components 123 and U-shaped convex components 124 seem to be deformed, but after increasing the number of pieces, they can be arranged into childlike and beautiful wavy lace shapes, and even many special and because of the use of common curves, the arcs of all components can be easily combined to form new lines and spaces. For example, two trapezoidal concave components 121 with obtuse angles and arcs can be combined through different angles. To extend the radian and camber of the curve.

In fact, the three combinations presented here for each component are just a small part of them, and there are still many ways to combine them that are not as diverse as the ones that can be loaded. The pattern is simplified into straight line components, and the concave-convex components composed of only one common curve can also create infinite patterns and profiles through creative assembly. shape.

After testing the application flexibility of the single-component combination, the present invention proceeds to further test the mixed-component combination, which is a creative way of combining different components to form a garment. The following are six different creative assembly methods, and sort out which types of components are used in each method, and how many components are used in total. The more components, the longer it takes to assemble.

As shown in Figure 12, the combination takes two obtuse-angled arc trapezoidal concave components 121, two acute-angled arc-shaped trapezoidal concave components 122 and one U-arc rectangular concave component 125, and the obtuse angled arc-shaped trapezoidal concave component 121 and the acute-angled strip The curved edges of the arc-trapezoidal concave component 122 are brought together to form a neckline, forming a Lachlan spliced top; the second combination is a U-arc rectangular concave component 125, obtuse-angled arc-trapezoidal concave component 121, and acute-angled arc-trapezoidal concave component 122 , 2 pieces of rectangular components 126 each, continuing the method of combination 1, and then combining the rectangular components 126 as sleeves on the side, and shortening the fixed height of the front center, you can get a Lachlan splicing jacket with three-quarter sleeves; combination Three take two U-arc rectangular concave components 125, connect them in an arc shape to form a neckline, then take three semicircular convex components 123 and three U-shaped convex components 124 and arrange them into a hem lace, and a short wave blouse is completed ; Combination 4 Take 2 U-shaped convex components 124 and 1 isosceles right-angled triangle component 127 to form a heart shape, and then take 2 trapezoidal components 128 and attach them to the left and right sides to form a body, thus forming a peach heart collar small Cute; Combination Five Take U-arc rectangular concave component 125 and 2 rectangular components 126 each. The arc edges of the U-arc rectangular concave component 125 are combined to form a neckline, and the rectangular component 126 is put together at the hem to extend the length of the garment. Finally, take 4 pieces The trapezoidal components 128 are used to form the sleeves, which can be assembled into a flying squirrel sleeve top; the combination of 6 takes 2 trapezoidal components 128 and 1 rectangular component 126 to form the front piece, and then takes 2 isosceles right-angled triangle components 127 to form the back piece , thus completing a V-neck camisole.

According to the above experimental results, it can be known that as long as the geometric components are properly planned, each component of different shapes has a different shape-shaping function, that is, it has room to play in clothing design, so even if it is not like the above-mentioned Like the base set, all 8 components are completely in one garment are used, but each piece is a useful and functional element when all components can be flexibly used in different designs.

<Example 2> Piece structure

When the user is the wearer, he can select the chipboard structure 2 through the system modularization device 100 for design combination. As shown in Fig. 2, the shroud structure 2 includes a geometric module unit 21, a graphic database 22 and a string unit 23, and the shroud structure 2 is built with six geometric shapes cut from cloth. The modules are each provided with hole pieces forming several perforations at their edges, so that clothes, various dresses and accessories can be combined in an easy way like a child's string toy.

In order to break through the technical limitation of assembling components by sewing with a tailor's locomotive, the penetrating board structure 2 proposed in the present invention is through adding perforations on the edge of the module, just like children's perforated boards for threading games, which can be easily operated by the general public. The way of stringing the straps is to pass through the necessary holes to assemble the modules together, but where the strings are not worn, neat holes can be left as lace decorations to maintain the visual beauty. Therefore, the present invention reduces the difficulty of assembling modules by using the holes in the smart board structure 2 that can be threaded with ropes, so that all the public can directly participate in the fun of assembling with their hands, and experience the fun and mystery of this design method At the same time, create a three-dimensional clothing style exclusive to your personal style.

Described piercing board structure 2 is as shown in the 13th figure, and this geometric module unit 21 is made up of a circular convex module 211, a rectangular concave module 212 with an arc at right angles, a trapezoidal concave module with an obtuse angle with an arc 213, and a half arc with five sides. Concave module 214, semi-arc trapezoidal concave module 215, and a rectangular module 216 are composed of six modules, each module 211~216 is provided with a hole piece 218 forming several perforations 217 on the edge, and the hole piece 218 can be used in the The processing method of punching holes on the fabric or adding any one or a combination of holed accessories or ribbons; one or a combination thereof.

The graphic database 22 stores several clothing styles geometric combination patterns 221 for users to choose and use, and the several clothing styles geometric combination patterns 221 are related to these The three-dimensional clothing styles assembled by the modules 211-216 correspond to each other, as shown in FIG. 14 .

The thread unit 23 has several thread bodies of different colors, which can be threaded between the several perforations 217. As shown in FIG. , from these modules 211~216, select the modules 211~216 corresponding to the required shape of the selected garment style geometric combination pattern 221 to arrange, and use the holes to thread the ropes to fix the selected modules 211~216 into groups Complete a three-dimensional clothing style corresponding to the selected geometric combination pattern 221 of the clothing style or the self-creation.

In order to make the concept of multi-component assembly more easily communicated and popularized to the general public, the present invention proposes a piercing board structure 2. Users can arrange the modules into corresponding shapes through illustrations, and then fix them together by wearing ropes. Give full play to one's own creativity and make up the appearance you want. Conceptually, it is an ideal appearance of sustainable clothing, because clothing is no longer limited to a single style, but allows users to determine their existence at any time and as they wish. Style, as long as it is a piece of clothing made of smart boards, even if it is a dress that is only worn once in a long time, it does not have to lie in the closet and collect dust all the time, but it will immediately become a daily favorite item, accompanying users to experience more There are so many different moments in life. In addition to being interesting and sustainable, it can also carry the memories brought by each combination of clothes and become a piece of clothing with a story.

In this way, the system modularized garment pattern design method proposed in the present invention can be used to define a flat garment pattern as a system modularized device with a geometric shape of a piece of art, and the proposed method is also a zero-waste fabric The method of use is to cut all the fabrics into geometric shapes. In addition to efficiently cutting and using the original rectangular fabric, it will not throw away a lot of waste from the corners and corners after cutting like the traditional conventional pattern. Using geometrically shaped fabrics in different combinations can produce ever-changing three-dimensional clothing styles. It is no longer limited to one type of clothing and can only produce one type of clothing.

To sum up, the present invention is a systematic modularized garment pattern design method, which can effectively improve various conventional shortcomings, and is used to define a flat garment pattern as a geometric shape with a smart board. The system is modularized. This method is also a zero-waste method of using fabrics. All the fabrics are cut into geometric shapes. In addition to efficiently cutting and using the original rectangular fabrics, it will not be like traditional conventional patterns. After cutting, a lot of scraps are discarded, and geometric shapes of fabrics can be used in different combinations to produce ever-changing three-dimensional clothing styles. It is no longer limited to one version and only one garment can be produced. To make the invention more advanced, more practical, and more in line with the needs of users, and indeed meet the requirements for invention patent applications, a patent application should be filed according to law.

But the above-mentioned ones are only preferred embodiments of the present invention, and should not limit the scope of the present invention; therefore, all simple equivalent changes and modifications made according to the patent scope of the present invention and the contents of the description of the invention , should still fall within the scope covered by the patent of the present invention.

s11~s13: steps

Claims (9)

A system modularized garment pattern design method, which defines the plane garment pattern as a geometric shape with a smart board, and the method at least includes the following steps: Step 1: Select a modular pattern structure or a wearing pattern according to the user's needs Geometric assembly and arrangement of the clever board structure; and step 2: when the user selects the modular layout structure and uses the modular layout structure to build several geometric components cut from cloth, provide The user selects the basic version design combination or the creative version design combination according to the several geometric components to form different three-dimensional clothing styles; or step 3: when the user chooses to use the frame structure, and When using the chipboard structure to build six geometric modules cut into geometric shapes from cloth, each of the geometric modules is provided with holes that form several perforations on the edges, providing the user with a graphic method or self-creation Arrange the six geometric modules into corresponding or creative shapes, and then fix the combination through the holes and strings to form different three-dimensional clothing styles. According to the system modular clothing layout design method described in item 1 of the scope of the patent application, when the user is a clothing designer, he chooses to use the modular layout structure, and when the user is a wearer, he chooses to use The chipboard structure. According to the system modular clothing pattern design method described in item 1 of the scope of the patent application, the modular pattern structure includes a basic assembling unit, and the basic assembling unit is composed of several calculated common arcs of the human body. The long and short rectangular linear components corresponding to the radian requirements of the crotch position, neckline position, and underarm position, and interlocking U-shaped convex components and half U-arc concave components are used to combine the same set of geometric components with the same shape. Combining this basic silhouette into different garments in a completely exhausting manner. According to the system modularized clothing pattern design method described in item 1 of the scope of patent application, the modular pattern structure includes a creative assembling unit, and the creative assembling unit is composed of 8 completely different The shape consists of a straight line component and a curve component, including an obtuse trapezoidal concave component with an arc, an acute trapezoidal concave component with an arc, a semicircular convex component, a U-shaped convex component, a U-arc rectangular concave component, a rectangular component, and a The isosceles right-angled triangle component and a trapezoidal component are tightly fastened to each other and can be freely aligned. There is no need to use up all the geometric components to assemble a clothing style. The appropriate geometric components and corresponding components are selected according to the needs. The unused geometric components can be used in the combination of this creative version design of other garments. According to the system modular clothing layout design method described in item 4 of the scope of the patent application, the creative assembling unit can define the 8 different geometric components as a single component assembling or a mixed component assembling. According to the system modularized clothing pattern design method described in item 1 of the scope of the patent application, the hole part is a processing method that can punch holes in the cloth or add any auxiliary material with holes or webbing or any of them combination. According to the system modularized clothing layout design method described in item 1 of the scope of patent application, the piercing board structure includes a geometric module unit, and the geometric module unit is composed of a circular convex module, a rectangular concave with a right angle and an arc. module, an obtuse-angle trapezoidal concave module with an arc, a half-arc pentagonal concave module, a half-arc trapezoidal concave module, and a rectangular module, etc., which are composed of six geometric modules, and these geometric modules can be assembled into at least one three-dimensional clothing style . According to the system modularized clothing layout design method described in item 1 of the scope of the patent application, wherein, the chipboard structure includes a string unit, which is threaded between the several perforations, according to the clothing selected by the user. Style geometric combination pattern or self-creation, select geometric modules corresponding to the shape required for the selected clothing style geometric combination pattern from these geometric modules and arrange them, and fix the selected geometric modules by means of holes and ropes Assembling completes a three-dimensional clothing style corresponding to the geometric combination pattern of the selected clothing style or the self-creation. According to the system modularized clothing layout design method described in item 1 of the scope of the patent application, the panel structure includes a graphic database, which stores several geometric patterns of clothing styles for the user to choose used, and the geometric combination patterns of the several clothing styles correspond to the three-dimensional clothing styles assembled by the geometric modules.

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