CN220000880U - 5D dynamic three-dimensional tailoring clothing - Google Patents

Abstract

The utility model discloses a 5D dynamic three-dimensional tailoring garment, which comprises a front piece, a rear piece and sleeve pieces which are connected with each other, wherein a first filling part is formed at a front clamping ring part between the front piece and the sleeve pieces, a second filling part is formed at a rear clamping ring part between the rear piece and the sleeve pieces, the front clamping part of the front clamping ring is lower than the rear clamping ring in the vertical direction so as to reduce the vertical distance from the front clamping part to the rear clamping ring, the rear clamping part of the rear clamping ring is lower than the rear clamping ring in the vertical direction so as to reduce the vertical distance from the rear clamping part to the rear clamping ring, the front clamping ring and the rear clamping ring jointly enclose an armhole so as to increase the movement space of a shoulder part and an armpit part of the garment through the first filling part and the second filling part, and the front clamping part is connected with the rear clamping part so as to improve the body repairing effect of the shoulder part and the armpit part of the garment. According to the utility model, the 5D dynamic three-dimensional tailoring design is carried out on the clothing structure, so that the clothing structure is shaped and combined, the free stretching of the human body action is ensured, the hand lifting amount of the arm is increased, and the movement is not hindered.

Description

5D dynamic three-dimensional tailoring clothing

Technical Field

The utility model relates to the field of clothing, in particular to 5D dynamic three-dimensional tailoring clothing.

Background

With the continuous rise of health consciousness of people, sports have become an indispensable part of daily life, and demands of people on the functionality and comfort of sports wear are also increasing. The existing clothing pattern making modes mainly comprise a planar cutting method and a stereoscopic cutting method, and because the human body is an irregular body, the stereoscopic cutting is superior to the planar cutting in the fit degree of clothing, and the appearance of the cut clothing is more attractive. However, the stereoscopic cutting only considers the fit problem of the clothing when the human body is in a static state, but does not fully consider the motion state of the human body, and when the human body moves, particularly when the motion amplitude is large, the influence of the amplitude and the angle of different motions on the clothing functionality and the influence of phenomena such as skin extension, slippage and the like on the clothing comfort degree when the human body moves are considered.

In the existing sportswear, if a stereoscopic cutting mode is adopted, although the beautiful effect of body shaping and fitting can be achieved, problems such as pulling, wrinkling and the like can occur when a human body moves, for example: when the arm lifting action is performed, the shoulder and the armpit of the garment can prevent the arm from lifting upwards, the lower hem of the garment can be greatly pulled upwards along with the lifting of the arm, the arm falls down and is accumulated at the waist, so that the comfort and the aesthetic property are affected, and the action standardization is also adversely affected.

In order to improve the freedom degree, some sportswear is designed into a loose and enlarged format, and although the limitation on the limb actions of people is reduced, the aesthetic feeling of the fit is lacking, and the sportswear fabric can swing or slide uncontrollably when the human body acts, and the sportswear experience is seriously affected.

Disclosure of Invention

The utility model aims to provide a 5D dynamic three-dimensional tailoring garment, which can not only be shaped and fit, but also ensure the free stretching of human body actions by carrying out 5D dynamic three-dimensional tailoring design on a garment structure. The specific technical scheme is as follows:

A5D dynamic three-dimensional tailoring garment comprises a front piece, a rear piece and sleeve pieces which are connected with each other, wherein a first filling part is formed at a front clamping ring part between the front piece and the sleeve pieces, a second filling part is formed at a rear clamping ring part between the rear piece and the sleeve pieces, the front clamping part of the front clamping ring is lower than the rear clamping ring in the vertical direction so as to reduce the vertical distance from the front clamping part to the rear clamping ring, the rear clamping part of the rear clamping ring is lower than the rear clamping ring in the vertical direction so as to reduce the vertical distance from the rear clamping part to the rear clamping ring, an armhole is formed by the front clamping ring and the rear clamping ring in a surrounding mode, the movement space of a shoulder part and an armpit part of the garment is increased through the first filling part and the second filling part, and the front clamping part is connected with the rear clamping part so as to improve the body shaping effect of the shoulder part and the armpit part of the garment.

Further, in the vertical direction, the position height of the sleeve center line of the sleeve piece near the cuff portion is higher than the position height in the back collar of the garment.

Further, the part of the sleeve center line of the sleeve sheet near the cuff is close to the back collar in the vertical direction, so that the vertical distance from the part of the sleeve center line near the cuff to the back collar is reduced.

Further, the sleeve piece comprises a main sleeve piece and a small sleeve piece, the first end of the main sleeve piece is connected with the front piece and the rear piece, and the first end of the small sleeve piece is connected at the front clamping ring of the front piece and is connected with the main sleeve piece; the first edge of the small sleeve piece is connected with the first edge of the main sleeve piece, and the second edge of the small sleeve piece is connected with the second edge of the main sleeve piece so as to jointly enclose a sleeve; the second end of the small sleeve piece and the second end of the main sleeve piece enclose cuffs together.

Further, the main sleeve piece comprises a front sleeve piece and a rear sleeve piece, the second edge of the front sleeve piece is connected with the first edge of the rear sleeve piece to jointly form the main sleeve piece, and a receiving space is formed at the position, close to the shoulder of the main sleeve piece, of the second edge of the front sleeve piece and the first edge of the rear sleeve piece so as to improve the slimming effect of the shoulder and the armpit of the garment.

Further, the sleeve comprises a splicing piece, wherein the splicing piece is attached and fixed at the joint of the front piece and the rear piece and at the low-clamping part of the front low-clamping part and the low-clamping part of the rear low-clamping part, and extends towards the cuff direction along the joint part of the sleeve piece.

Further, the first filling portion may be formed on the sleeve sheet and/or the front sheet, and the second filling portion may be formed on the sleeve sheet and/or the rear sheet.

Further, the vertical distance decrease of the front clip low and the rear clip low into the rear collar has a value of 1-1.5cm.

Further, the vertical distance from the part of the sleeve center line close to the sleeve opening to the back collar is 4-6cm or 18-20cm.

Further, the garment comprises a tights, a windsuit, a down jacket, a short sleeve and a sweater.

According to the 5D dynamic three-dimensional tailoring clothes, the dynamic tailoring design is carried out on the clothes structure, so that the clothes can be shaped and fit, the free stretching of the human body action can be ensured, the hand lifting amount of the arm is increased, the clothes can be stretched along with the human body action when the human body moves, the movement is not hindered, and the clothes are comfortable and attractive.

Drawings

Fig. 1 is a perspective view of a compression garment made using the method of making a 5D dynamic stereoscopic cut garment of the present utility model.

Fig. 2a is a front view of the compression garment of the present utility model, and fig. 2b is a rear view.

Fig. 3a is a schematic diagram of a pattern of a tights according to the present utility model, and fig. 3b is a schematic diagram of a pattern of a conventional tights.

Fig. 4a is a front view of a wind jacket manufactured by the method for manufacturing 5D dynamic stereoscopic cut garments according to the present utility model, and fig. 4b is a front view of a conventional wind jacket.

Fig. 5a is a paper pattern diagram of the wind jacket according to the present utility model, and fig. 5b is a paper pattern diagram of a conventional wind jacket.

Fig. 6a is a front view of a down jacket made by the method of making a 5D dynamic stereoscopic cut garment of the present utility model, and fig. 6b is a front view of a conventional down jacket.

Fig. 7a is a schematic paper pattern of a down jacket according to the present utility model, and fig. 7b is a schematic paper pattern of a conventional down jacket.

Fig. 8a is a front view of a short sleeve made by the method for making 5D dynamic stereoscopic cut garments of the present utility model, and fig. 8b is a front view of a conventional short sleeve.

Fig. 9 is a schematic diagram of a pattern of the short sleeve according to the present utility model.

Fig. 10a is a front view of a sanitary wear manufactured by the method for manufacturing a 5D dynamic stereoscopic cut garment according to the present utility model, and fig. 10b is a front view of a conventional sanitary wear.

Fig. 11 is a schematic diagram of a paper pattern of a sanitary wear according to the present utility model.

FIG. 12a is a schematic illustration of the front, side and back of an athlete wearing a test garment A prior to exercise; FIG. 12b is a graph showing the changes in the front, side and back of the test specimen A after the athlete has performed a large exercise.

FIG. 13a is a schematic illustration of the front, side and back of an athlete wearing a test garment B prior to exercise; FIG. 13B is a graph showing the change in form of the front, side and back of the test sample garment B after the athlete has performed a large exercise.

FIG. 14a is a schematic illustration of a front, side and back view of an athlete wearing a 5D dynamic stereoscopic cut garment of the present utility model prior to exercise; fig. 14b is a pattern diagram of the front, side and back of a 5D dynamic stereoscopic cut garment after a large motion of an athlete.

Detailed Description

For a better understanding of the objects, structures and functions of the present utility model, the 5D dynamic stereoscopic cut garment of the present utility model will be described in further detail with reference to the accompanying drawings.

Example 1

Fig. 1 to 3a show an embodiment of a 5D dynamic stereoscopic cut garment according to the utility model, in particular a tights, and fig. 3b shows the construction of a tights according to the prior art. In order to more clearly illustrate the differences and advantages of the tights and the method for manufacturing the same according to the present utility model compared with the prior art, the design scheme of the tights according to the prior art will be briefly described below.

Fig. 3b shows a paper pattern structure of a conventional tights, which can be seen to include a front panel 110, a rear panel 120 and sleeve panels 130 connected to each other, the side edges of the front panel 110 and the rear panel 120 being sewn together to form a body part of the tights, and the first side 140 and the second side 150 of the sleeve panels 130 being sewn together to form sleeve parts of the tights. In order to make the tights more beautiful when worn, when the existing tights are cut, the fabrics at the front clamping ring 160 between the front piece 110 and the sleeve piece 130 are cut in a large amount, and the fabrics at the rear clamping ring 170 between the rear piece 120 and the sleeve piece 130 are cut in a large amount, so that the space allowance of the fabrics at the front clamping ring 160 and the rear clamping ring 170 is reduced, and therefore, after the front clamping ring 160 and the rear clamping ring 170 are sewn, shoulder parts of the clothes can be more attached to a human body visually, and the beautiful effect is achieved.

However, because the space margin at the shoulder part is small, when the human body performs a great deal of movement, especially when the human body performs forward or lateral arm lifting and lifting actions, the garment can excessively pull the limbs, so that strong resistance is generated to the human body movement, the movement standardization is affected, and the hem of the garment can greatly and upwardly displace under the pull, thereby affecting the beauty and comfort.

In addition, as shown in fig. 3b, the sleeve center line 180 of the conventional tights sleeve piece 130 tends to extend obliquely downward, and the portion of the sleeve center line 180 near the cuff is vertically lower than the rear collar 190, so that a remarkable downward pressing feeling is generated at the deltoid muscle and the armlet muscle group during exercise, and the arm lifting action is affected.

Based on the above description of the design structure of the existing tights, the tights manufactured by the 5D dynamic stereoscopic cutting manufacturing method in the present utility model will be described in detail.

As shown in fig. 1 to 3a, the compression garment of the present utility model includes a front panel 11, a rear panel 12 and a sleeve panel 13 connected to each other, and as shown in fig. 3a, a first filling portion 14 is formed at a front nip between the front panel 11 and the sleeve panel 13, the first filling portion 14 may provide a more sufficient amount of movement space for a portion where the front nip is located, a second filling portion 15 is formed at a rear nip between the rear panel 12 and the sleeve panel 13, and the second filling portion 15 may provide a more sufficient amount of movement space for a portion where the rear nip is located. Wherein the first filling portion 14 may be formed on the sleeve sheet 13 and/or the front sheet 11, and the second filling portion 15 may be formed on the sleeve sheet 13 and/or the rear sheet 12.

Referring to the conventional tights shown in fig. 3b, the front grip height 141 of the front grip ring of the tights of the present utility model is vertically closer to the rear collar 16 to reduce the vertical distance of the front grip height to the rear collar 16, and the rear grip height 151 of the rear grip ring is vertically closer to the rear collar 16 to reduce the vertical distance of the rear grip height 151 to the rear collar 16, as compared to the vertical distance a of the front grip height 161 and the rear grip height 171 of the conventional tights to the rear collar 190.

The front clamping ring and the rear clamping ring of the sewn tights jointly enclose an armhole, the whole movement space of the shoulder and armpit parts of the clothing can be increased through the movement space provided by the first filling part 14 and the second filling part 15, meanwhile, the front clamping low 141 and the rear clamping low 151 of the clothing are connected, and the positions of the front clamping low 141 and the rear clamping low 151 are improved towards the position of the rear collar 16, so that the purpose of improving the body shaping effect of the shoulder and the armpit parts of the clothing is achieved.

Preferably, the vertical distance between the front grip lower 141 and the rear grip lower 151 of the compression garment of the present utility model to the rear collar 16 is reduced by a value of 1-1.5cm, compared to the existing compression garment, so that the garment can have a good slim and aesthetic effect while providing a sufficient amount of movement space.

Further, as shown in fig. 3a, unlike the conventional tights, the sleeve center line 17 of the tights sleeve 13 of the present utility model is raised in the vertical direction as a whole, and the sleeve center line 17 is located at a position closer to the sleeve opening than the position of the rear collar 16 of the garment, and is located at the upper portion of the rear collar 16. By adopting the design mode, when the arm moves, the deltoid muscle and the large arm muscle group hardly feel downward pressing sense, and the comfort and the freedom of the arm lifting movement are greatly improved.

Further, the sleeve panel 13 includes a main sleeve panel 131 and a small sleeve panel 132, a first end of the main sleeve panel 131 is connected to the front panel 11 and the rear panel 12, and a first end of the small sleeve panel 132 is connected to the front panel 11 at a front nip and is connected to the main sleeve panel 131. The first side of the small sleeve piece 132 is connected to the first side of the main sleeve piece 131, and the second side of the small sleeve piece 132 is connected to the second side of the main sleeve piece 131 to enclose a sleeve together. The second end of the small sleeve piece 132 and the second end of the main sleeve piece 131 together enclose a cuff. The design of the small sleeve piece 132 can change the integral mechanical property of the sleeve part of the garment, and further improves the comfort and the freedom of the arm lifting action. Of course, instead of the above preferred arrangement, the sleeve panels of the compression garment of the present utility model may be of a unitary one-piece construction.

Further, the tights of the present utility model further comprises a panel 18, wherein the panel 18 has a strip-shaped sheet structure, is attached to and fixed to the seam between the front panel 11 and the rear panel 12, and is disposed at the low portion of the front grip and the rear grip, and extends in the direction of the cuffs along the seam portion of the sleeve 13. The arcuate curved tiles 18 may further promote the amount of movement space of the garment.

By adopting the design mode, the tights can provide larger movement space, fit and shape, the lower hem of the clothes is not easy to shift upwards along with the movement of the arms, and the tights have better comfort and attractive appearance.

Example two

Fig. 4a and 5a show a second embodiment of a 5D dynamic stereoscopic cut garment according to the present utility model, in particular a wind coat, and fig. 4b and 5b show the structure of a wind coat according to the prior art.

Referring to fig. 5b, similar to the structure of the conventional tights described in the above-described embodiment one, the conventional windwear includes a front panel 210, a rear panel 220 and a sleeve panel 230 connected to each other, the side edges of the front panel 210 and the rear panel 220 are sewn together to form a body part of the windwear, and the first side edge and the second side edge of the sleeve panel 230 are sewn together to form a sleeve part of the windwear. In order to make the wind jacket more beautiful when wearing, when cutting, the fabric at the front clamping ring 240 between the front piece 210 and the sleeve piece 230 is cut in a collecting amount, and the fabric at the rear clamping ring 250 between the rear piece 220 and the sleeve piece 230 is cut in a collecting amount, so that the space allowance of the fabric at the front clamping ring 240 and the rear clamping ring 250 is reduced, and therefore, after the front clamping ring 240 and the rear clamping ring 250 are sewn, the shoulder part of the wind jacket can be more attached to the human body visually, and the beautiful effect is realized.

However, because the space allowance of the shoulder part is small, when a human body performs a large-scale movement, particularly when the human body performs forward or lateral arm lifting and arm lifting actions, the wind coat can pull limbs, resistance is generated on the human body movement, the movement standardization is affected, and the hem of the garment can be greatly and upwards displaced under the pull, so that the aesthetic property is affected, and the comfort is also affected. In addition, because the sleeve center line 260 is inclined downward and extends, the part of the sleeve center line 260 close to the sleeve opening is lower than the part 270 in the back collar in the vertical direction, and obvious downward pressing sense can be generated at the deltoid muscle and the armlet muscle group during movement, so that the arm lifting action is influenced.

Based on the above description of the design structure of the existing wind jacket, the wind jacket manufactured by the 5D dynamic three-dimensional cutting manufacturing method in the utility model will be described in detail.

As shown in fig. 4a and 5a, the wind coat of the present utility model includes a front panel 21, a rear panel 22 and a sleeve panel 23 connected to each other, and as shown in fig. 5a, a first filling portion 24 is formed at a front nip between the front panel 21 and the sleeve panel 23, the first filling portion 24 may provide a more sufficient amount of movement space for a portion where the front nip is located, a second filling portion 25 is formed at a rear nip between the rear panel 22 and the sleeve panel 23, and the second filling portion 25 may provide a more sufficient amount of movement space for a portion where the rear nip is located. Wherein the first filling portion 24 may be formed on the sleeve sheet 23 and/or the front sheet 21, and the second filling portion 25 may be formed on the sleeve sheet 23 and/or the rear sheet 22.

The front clip low 241 of the front clip of the wind coat in the present utility model is vertically closer to the rear collar 26 than the front clip low and the rear clip low of the existing wind coat are to the rear collar 270 to reduce the vertical distance of the front clip low 241 to the rear collar 26, and the rear clip low 251 of the rear clip is vertically closer to the rear collar 26 to reduce the vertical distance of the rear clip low 251 to the rear collar 26.

The front clamping ring and the rear clamping ring of the sewn wind coat jointly enclose an armhole, the total movement space of the shoulder and the armpit of the coat can be increased through the movement space provided by the first filling part 24 and the second filling part 25, meanwhile, the front clamping low 241 and the rear clamping low 251 of the wind coat are connected, and the positions of the front clamping low 241 and the rear clamping low 251 in the direction of the rear collar 26 are improved, so that the purpose of improving the body shaping effect of the shoulder and the armpit of the coat is achieved.

Preferably, the vertical distance between the front grip lower 241 and the rear grip lower 251 of the wind coat and the rear collar 26 is reduced by 1-1.5cm compared with the existing wind coat, so that the wind coat can provide a sufficient amount of movement space and has good shape and beautiful appearance.

Further, as shown in fig. 5a, the sleeve panel 23 includes a main sleeve panel and a minor sleeve panel 232, wherein the main sleeve panel includes a front sleeve panel 231 and a rear sleeve panel 233, and a second edge of the front sleeve panel 231 is connected with a first edge of the rear sleeve panel 233 to jointly constitute the main sleeve panel.

The first end of the main sleeve piece is connected with the front piece 21 and the rear piece 22, and the first end of the small sleeve piece 232 is connected with the front clamping ring of the front piece 21 and is connected with the main sleeve piece. The first side of the small sleeve piece 232 is connected to the first side of the main sleeve piece, and the second side of the small sleeve piece 232 is connected to the second side of the main sleeve piece to jointly enclose a sleeve. The second end of the small sleeve piece 232 and the second end of the main sleeve piece together enclose a cuff. The design of the small sleeve piece 232 can change the integral mechanical property of the sleeve part of the garment, and further improves the comfort and the freedom of the arm lifting action.

The second edge of the front sleeve piece 231 and the first edge of the rear sleeve piece 233 are formed with a receiving space 27 near the shoulder of the main sleeve piece, and the front sleeve piece 231 and the rear sleeve piece 233 are sewn together, so that the receiving space 27 can further improve the slimming effect of the shoulder and the armpit of the garment.

Further, as shown in fig. 5a, unlike the conventional wind coat, the sleeve center line 28 of the wind coat sleeve panel 23 of the present utility model is raised in the vertical direction, and the position of the sleeve center line 28 near the cuff is higher than the position of the rear collar 26 of the garment, and is located at the upper part of the rear collar 26. By adopting the design mode, when the arm moves, the deltoid muscle and the large arm muscle group hardly feel downward pressing sense, and the comfort and the freedom of the arm lifting movement are greatly improved.

Further, the wind coat of the present utility model further comprises a panel 29, wherein the panel 29 is a strip-shaped sheet structure, is attached and fixed at the joint between the front panel 21 and the rear panel 22, and at the lower part of the front lower part 241 connected with the rear lower part 251, and extends along the joint part of the sleeve panel 23 toward the cuff direction. The arcuate curved tiles 29 may further promote the amount of movement space of the garment.

By adopting the design mode, the wind coat can provide larger movement space, is more fit and is more attractive, and the wind coat has larger arm lifting space and better comfort and aesthetic property on the premise that the lower hem of the wind coat is not shifted upwards along with the movement of arms as shown in fig. 4a and 4 b.

Example III

Fig. 6a and 7a show a third embodiment of a 5D dynamic stereoscopic cut garment according to the present utility model, in particular a down jacket, and fig. 6b and 7b show the structure of a down jacket according to the prior art.

Referring to fig. 7b, the conventional wind coat is very similar to the structure of the conventional wind coat described in the second embodiment, and the conventional down jacket includes the front panel 310, the rear panel 320 and the sleeve panel 330 connected with each other, and for more slim and beautiful appearance, the fabric at the front clamping ring 340 and the rear clamping ring 350 is cut in a receiving amount to be more visually fitted to the human body, and the part of the sleeve center line 360 of the sleeve panel 330 near the cuffs is vertically lower than the rear collar 370. Also, the design structure can generate resistance to human body movement, and the lower hem moves upwards to influence the arm lifting action.

As shown in fig. 6a and 7a, similar to the wind coat structure of the present utility model described in the above-mentioned second embodiment, the down jackets of the present utility model include a front panel 31, a rear panel 32 and sleeve panels 33 connected to each other, a first filling portion 34 is formed at a front nip between the front panel 31 and the sleeve panels 33, a second filling portion 35 is formed at a rear nip between the rear panel 32 and the sleeve panels 33, the first filling portion 34 may be formed on the sleeve panels 33 and/or the front panel 31, and the second filling portion 35 may be formed on the sleeve panels 33 and/or the rear panel 32 to provide a sufficient amount of movement space. The front clip low 341 and the rear clip low 351 of the down jacket are closer to the rear collar 36 in the vertical direction, so that the vertical distance from the front clip low 341 and the rear clip low 351 to the rear collar 36 is reduced, and the body-building effect of the shoulder and the armpit parts of the garment is improved.

Preferably, the vertical distance of the front grip low 341 and the rear grip low 351 of the down jacket to the rear collar 36 in the present utility model is reduced by a value of 1-1.5cm compared to the existing down jackets, so as to have a good slimming and aesthetic effect while providing a sufficient amount of movement space.

Further, as shown in fig. 7a, the sleeve panel 33 includes a main sleeve panel 331 and a small sleeve panel 332, and the main sleeve panel includes a front sleeve panel 331 and a rear sleeve panel 333, and the front sleeve panel 331, the rear sleeve panel 333, and the small sleeve panel 332 form sleeves in the same manner as the sleeve structure of the wind coat in the above-described second embodiment. Similarly, the second edge of the front sleeve 331 and the first edge of the rear sleeve 333 are formed with a receiving space 37 near the shoulder of the main sleeve, and the receiving space 37 can further enhance the effect of shaping the shoulder and the armpit of the down jacket.

Further, in the vertical direction, the position of the sleeve center line 38 of the down jacket sleeve piece 33 near the cuff is higher than the position of the back collar 36 of the garment, so as to reduce the pressing feeling of deltoid muscle and armlet muscle group.

Further, the down jacket of the present utility model further comprises a panel 39, wherein the panel 39 is attached to and fixed to the joint between the front panel 31 and the rear panel 32, and the front grip 341 and the rear grip 351 are connected to each other at a grip portion extending in the cuff direction along the joint portion of the sleeve 33.

As shown in fig. 6a and 6b, the down jacket of the utility model has larger arm lifting space and better comfort and aesthetic property on the premise of ensuring that the down jacket hem does not shift upwards along with the movement of arms.

Example IV

Fig. 8a and 9 show a fourth embodiment of the 5D dynamic stereoscopic cut garment according to the present utility model, in particular, a short sleeve, comprising a front panel 41, a rear panel 42 and a sleeve panel 43 connected to each other, a first filling portion 44 being formed at a front nip between the front panel 41 and the sleeve panel 43, a second filling portion 45 being formed at a rear nip between the rear panel 42 and the sleeve panel 43, the first filling portion 44 being formed on the sleeve panel 43 and/or on the front panel 41, and the second filling portion 45 being formed on the sleeve panel 43 and/or on the rear panel 42 to provide a sufficient amount of movement space. The front clamping low 441 and the rear clamping low 451 of the short sleeve are closer to the rear collar 46 in the vertical direction, so that the vertical distance from the front clamping low 441 and the rear clamping low 451 to the rear collar 46 is reduced, and the body shaping effect of the shoulder and the armpit of the garment is improved.

Preferably, the vertical distance between the front grip lower 441 and the rear grip lower 451 of the short sleeve and the rear collar 46 of the present utility model is reduced by a value of 1-1.5cm compared to the existing short sleeve, so as to provide a good slimming and aesthetic effect while providing a sufficient amount of movement space.

Further, compared with the conventional short sleeve, the part of the sleeve center line 48 of the short sleeve piece 43 close to the sleeve opening is closer to the rear collar 46 in the vertical direction, so that the vertical distance from the part of the sleeve center line 48 close to the sleeve opening to the rear collar 46 is reduced. The adoption of the design structure can also reduce the pressing sense of deltoid muscle and large arm muscle groups to a certain extent. Specifically, the part of the center line 48 of the existing short sleeve near the cuff is usually 8-10cm below the back collar 46, and the part of the center line 48 of the short sleeve near the cuff is 4-6cm below the back collar 46.

Further, the short sleeve according to the present utility model further includes a panel 49, and the panel 49 is attached to and fixed to the seam between the front panel 41 and the rear panel 42, and the front grip portion 441 and the rear grip portion 451 are connected to each other at a grip portion thereof, and extend in the cuff direction along the seam portion of the sleeve panel 43.

As shown in fig. 8a and 8b, the short sleeve provided by the utility model has a larger arm lifting space and better comfort and aesthetic property on the premise that the short sleeve hem is not shifted upwards along with the movement of the arm.

Example five

Fig. 10a and 11 show an embodiment five of the 5D dynamic stereoscopic cut garment of the present utility model, in particular, a sanitary garment, comprising a front panel 51, a rear panel 52 and a sleeve panel 53 connected to each other, a first filling portion 54 being formed at a front nip between the front panel 51 and the sleeve panel 53, a second filling portion 55 being formed at a rear nip between the rear panel 52 and the sleeve panel 53, the first filling portion 54 being formed on the sleeve panel 53 and/or on the front panel 51, and the second filling portion 55 being formed on the sleeve panel 53 and/or on the rear panel 52 to provide a sufficient amount of movement space. The front clip low 541 and the rear clip low 551 of the sweater are closer to the rear collar 56 in the vertical direction, so that the vertical distance from the front clip low 541 and the rear clip low 551 to the rear collar 56 is reduced, and the body shaping effect of the shoulder and armpit parts of the sweater is improved.

Preferably, the vertical distance of the front grip lower 541 and the rear grip lower 551 of the present utility model to the rear collar 56 is reduced by a value of 1-1.5cm, compared to the existing bathroom suit, to have a good slimming and aesthetic effect while providing a sufficient amount of movement space.

Further, the part of the sleeve center line 58 of the sanitary wear sleeve panel 53 near the cuff in the present utility model is vertically closer to the rear collar 56 than the conventional sanitary wear, so that the vertical distance from the part of the sleeve center line 58 near the cuff to the rear collar 56 is reduced. The adoption of the design structure can also reduce the pressing sense of deltoid muscle and large arm muscle groups to a certain extent. Specifically, the existing Wei Yixiu center line 58 is generally positioned 20-23cm below the rear collar 56, and the sleeve center line 58 of the inventive garment is positioned 18-20cm below the rear collar 56.

Further, the sanitary wear of the present utility model further includes a panel 59, and the panel 59 is attached to and fixed to the joint between the front panel 51 and the rear panel 52, and the front grip 541 and the rear grip 551 are connected to each other at a grip-down portion, and extend in the cuff direction along the joint portion of the sleeve panel 53.

As shown in fig. 10a and 10b, the sanitary wear has a larger arm lifting space and better comfort and aesthetic property on the premise of ensuring that the sanitary wear hem does not shift upwards along with the movement of the arm.

In order to verify that the 5D dynamic three-dimensional cut garment has good wearing effect, two existing tights are selected for comparison test with the tights.

FIG. 12a is a schematic illustration of the front, side and back of an athlete wearing a test garment A prior to exercise; FIG. 12b is a graph showing the changes in the front, side and back of the test specimen A after the athlete has performed a large exercise. It is obvious that the test sample garment A has obvious wrinkles at the chest and armpit parts and the lower hem moves upwards.

FIG. 13a is a schematic illustration of the front, side and back of an athlete wearing a test garment B prior to exercise; FIG. 13B is a graph showing the change in form of the front, side and back of the test sample garment B after the athlete has performed a large exercise. It is obvious that the test sample garment A has obvious wrinkles at the chest and armpit parts and the lower hem moves upwards.

FIG. 14a is a schematic illustration of a front, side and back view of an athlete wearing a 5D dynamic stereoscopic cut garment of the present utility model prior to exercise; fig. 14b is a pattern diagram of the front, side and back of a 5D dynamic stereoscopic cut garment after a large motion of an athlete. It is obvious that the folds of the chest and armpit parts of the tights are not obvious before and after the exercise, and the upper hem is not obvious.

According to the 5D dynamic three-dimensional tailoring clothes, the dynamic tailoring design is carried out on the clothes structure, so that the clothes can be shaped and fit, the free stretching of the human body action can be ensured, the hand lifting amount of the arm is increased, the clothes can be stretched along with the human body action when the human body moves, the movement is not hindered, and the clothes are comfortable and attractive.

The utility model has been further described with reference to specific embodiments, but it should be understood that the detailed description is not to be construed as limiting the spirit and scope of the utility model, but rather as providing those skilled in the art with the benefit of this disclosure with the benefit of their various modifications to the described embodiments. The individual technical features described in the above embodiments may be combined in any suitable manner without contradiction. In order to avoid unnecessary repetition, various possible combinations of embodiments of the present utility model are not described in detail.

If directional indications (such as up, down, left, right, front, and rear … …) are involved in the embodiments of the present utility model, the directional indications are merely used to explain the relative positional relationship, movement, etc. between the components in a particular gesture (as shown in the drawings), and if the particular gesture is changed, the directional indications are correspondingly changed.

Claims (10)

1. The utility model provides a clothing is tailor to 5D developments solid, a serial communication port, including interconnect's front panel, back piece and sleeve piece, preceding clamp ring department between front panel and the sleeve piece is formed with first filling portion, back clamp ring department between back piece and the sleeve piece is formed with second filling portion, the front clamp of preceding clamp ring is low in being close to the back collar in vertical direction, in order to reduce the vertical distance that the front clamp was low to the back collar, the back clamp of back clamp ring is low in being close to the back collar in vertical direction, in order to reduce the vertical distance that the back clamp is low to the back collar, preceding clamp ring and back clamp ring enclose into the armpit jointly, in order to increase clothing shoulder and armpit position's amount of motion space through first filling portion and second filling portion, preceding clamp is low to be connected with the back clamp, in order to promote clothing shoulder and armpit position's body shaping effect.

2. The 5D dynamic stereoscopic cut garment of claim 1, wherein the sleeve center line of the sleeve panel is located closer to the cuff portion than in the rear collar of the garment in the vertical direction.

3. The 5D dynamic stereoscopic cut garment of claim 1, wherein a portion of the sleeve panel having the sleeve centerline near the cuff is vertically adjacent to the back collar to reduce a vertical distance from the portion of the sleeve centerline near the cuff to the back collar.

4. A 5D dynamic stereoscopic cut garment according to any one of claims 1 to 3, wherein the sleeve panel comprises a main sleeve panel and a small sleeve panel, the first end of the main sleeve panel being connected to the front and rear panels, the first end of the small sleeve panel being connected to the front panel at the front nip and to the main sleeve panel; the first edge of the small sleeve piece is connected with the first edge of the main sleeve piece, and the second edge of the small sleeve piece is connected with the second edge of the main sleeve piece so as to jointly enclose a sleeve; the second end of the small sleeve piece and the second end of the main sleeve piece enclose cuffs together.

5. The 5D dynamic stereoscopic cut garment of claim 4, wherein the main sleeve panel comprises a front sleeve panel and a rear sleeve panel, the second edge of the front sleeve panel being connected to the first edge of the rear sleeve panel to collectively form the main sleeve panel, the second edge of the front sleeve panel and the first edge of the rear sleeve panel forming a receiving space proximate to a shoulder of the main sleeve panel.

6. The 5D dynamic stereoscopic cut garment of claim 5, comprising a panel attached and fixed at a seam between the front and rear panels and at a low-grip portion where the front and rear grip portions are connected, and extending along the seam portion of the sleeve panel toward the cuffs.

7. A 5D dynamic stereocutting garment as claimed in claim 1, wherein the first filling portion is formed on the sleeve panel and/or on the front panel and the second filling portion is formed on the sleeve panel and/or on the rear panel.

8. The 5D dynamic stereoscopic cut garment of claim 1, wherein the vertical distance decrease in front clip low and rear clip low into the rear collar has a value of 1-1.5cm.

9. A 5D dynamic stereocutting garment as claimed in claim 3 wherein the vertical distance from the centre line of the sleeve near the cuff to the back collar is 4-6cm, or 18-20cm.

10. The 5D dynamic stereoscopic cut garment of claim 1, wherein the garment comprises a tights, a windcoat, a down coat, a short sleeve, a sweater.