Washable crease-resistant sports shoesTechnical Field
The application relates to the technical field of sports shoes, in particular to a washable crease-resistant sports shoe.
Background
Athletic footwear, which is a daily item of footwear, requires frequent cleaning to ensure the clean interior environment. However, the conventional sports shoes are easily wrinkled after being washed, which not only affects the beauty of the shoes, but also reduces the wearing comfort.
Currently, in order to solve the problem of wrinkles formed after cleaning of the sports shoes, the mainstream anti-wrinkle sports shoes in the market mainly use specific vamp materials, such as anti-wrinkle synthetic leather or fabrics treated with special coatings. These special materials do resist the generation of wrinkles to some extent, maintaining the flatness of the upper. However, these materials gradually suffer from a deterioration in their wrinkle resistance during prolonged washing, and even fail completely.
Disclosure of utility model
In order to solve the problems of water washing resistance and crease resistance of the sports shoes, the application provides the water washing resistance crease-resistant sports shoes.
The application provides a washable crease-resistant sports shoe which adopts the following technical scheme:
The washable crease-resistant sports shoes comprise uppers and soles, wherein the uppers are connected to the soles, each upper comprises a supporting part and a protecting part, each supporting part is provided with a shoe opening for a human foot to extend in, a foam cushion is arranged in each supporting part, each protecting part is connected to each supporting part and used for abutting against the instep of a wearer, and each protecting part comprises a breathable grid layer, an elastic fiber grid layer and a soft layer which are sequentially arranged from outside to inside.
By adopting the technical scheme, the sponge cushion with good rebound ability is utilized to form a support for the supporting part, so that on one hand, the vamp is ensured to support the ankle of a wearer, on the other hand, the crease resistance of the supporting part is ensured, the elastic fiber mesh layer with good elasticity and recovery ability is arranged between the breathable mesh layer and the soft layer, and the water washing resistance and crease resistance of the protecting part are ensured, thereby realizing the water washing resistance and crease resistance of the sports shoes.
Optionally, the ventilation grid layer is provided with a plurality of ventilation holes in a penetrating way, and the ventilation holes are uniformly distributed on the ventilation grid layer.
By adopting the technical scheme, the ventilation performance of the vamp is improved.
Optionally, a microporous breathable layer is arranged between the soft layer and the elastic fiber mesh layer.
By adopting the technical scheme, the ventilation performance of the vamp is further improved.
Optionally, the elastic fiber mesh layer is made of nano elastic fiber.
By adopting the technical scheme, compared with the traditional elastic fiber, the nanoscale elastic fiber has more excellent elasticity and recovery capability, and the risk of wrinkling of the vamp is further reduced.
Optionally, an elastic band is arranged at the edge of the support part, which is used for being connected with the protection part, and the elastic band extends along the width direction of the upper, and the protection part is connected with the elastic band.
Through adopting above-mentioned technical scheme, the guard portion is connected with the elastic band to utilize the elastic band to establish elastic connection between supporting part and guard portion, the elastic band takes place adaptive deformation and drives the guard portion and reset fast in the person of dress walking, reduces the vamp and produces the risk of fold.
Optionally, the protection part is connected to a side edge of the elastic belt, which is close to the supporting part, and the elastic belt is abutted to the outer surface of the protection part.
By adopting the technical scheme, on one hand, the elastic belt is provided with a larger area for connecting the protective part, the cutting accuracy requirement on the edge of the protective part is lower, and on the other hand, the elastic belt is abutted against the outer surface of the protective part, the perception of elasticity of a wearer is weakened, and the wearing comfort of the sports shoes is ensured.
Optionally, the microporous air-permeable layer is provided with two layers, the two layers of microporous air-permeable layers are both arranged between the soft layer and the elastic fiber mesh layer, and a plurality of elastic balls are fixed between the two layers of microporous air-permeable layers.
By adopting the technical scheme, the elastic ball is utilized to increase the buffering performance of the vamp, and provides additional supporting force when the sports shoes are impacted, thereby playing an effective role in protecting the instep of the wearer.
Optionally, a lightweight cavity is provided inside the elastic ball.
By adopting the technical scheme, the quality of the elastic ball is reduced, and the wearing comfort of the sports shoes is improved.
In summary, the present application includes at least one of the following beneficial technical effects:
1. the supporting part with the foam cushion and the protective part with the elastic fiber mesh layer are arranged, so that the water resistance and the wrinkle resistance of the sports shoes are considered;
2. By arranging the elastic belt, the elastic belt is utilized to establish elastic connection between the supporting part and the protecting part, the elastic belt is adaptively deformed and drives the protecting part to reset rapidly in the walking process of a wearer, and the risk of wrinkling of the vamp is reduced;
3. through setting up the elastic ball, improve the barrier propterty of guard portion.
Drawings
Fig. 1 is a schematic overall structure of embodiment 1 of the present application.
Fig. 2 is a schematic diagram for showing the structure of the sponge pad in example 1.
Fig. 3 is a schematic view for showing the structure of the guard in embodiment 1.
Fig. 4 is a schematic structural view of the middle guard portion in embodiment 2 of the present application.
Fig. 5 is a schematic view for showing the structure of the elastic ball in example 2.
The reference numerals comprise 1, upper, 11, supporting part, 111, foam cushion, 12, protecting part, 121, air-permeable mesh layer, 122, elastic fiber mesh layer, 123, microporous air-permeable layer, 124, soft layer, 13, elastic belt, 14, elastic ball, 141, light cavity, 2 and sole.
Detailed Description
The application is described in further detail below with reference to fig. 1-5.
The embodiment of the application discloses a washable crease-resistant sports shoe.
Example 1
Referring to fig. 1 and 2, a washable anti-wrinkle sports shoe includes an upper 1 and a sole 2, the upper 1 being connected to the sole 2. The upper 1 includes a support portion 11 and a protection portion 12, the support portion 11 is provided with a welt for a human foot to extend in, and a foam pad 111 is provided inside the support portion 11, so that wearing comfort of the sports shoe is improved by the foam pad 111 on the one hand, and wrinkle resistance of the support portion 11 is improved by restoration ability of the foam pad 111 on the other hand.
Referring to fig. 3, the guard portion 12 is connected to the support portion 11, and the guard portion 12 is used for abutting against the instep of the wearer. The protection part 12 comprises a breathable mesh layer 121, an elastic fiber mesh layer 122, a microporous breathable layer 123 and a soft layer 124 which are sequentially arranged from outside to inside, and the breathable mesh layer 121, the elastic fiber mesh layer 122, the microporous breathable layer 123 and the soft layer 124 are mutually adhered and fixed.
Wherein the air-permeable mesh layer 121 is made of a wear-resistant and air-permeable synthetic fiber material. The ventilation grid layer 121 is perforated with a plurality of ventilation holes, and the ventilation holes are uniformly distributed on the ventilation grid layer 121 to ensure the ventilation performance of the protection part 12 and further ensure the ventilation performance of the sports shoes.
The elastic fiber mesh layer 122 has excellent elasticity and recovery, and when the vamp is subjected to external force, the elastic fiber mesh layer 122 can rebound rapidly, so that the risk of wrinkling of the vamp is reduced. In this embodiment, the elastic fiber mesh layer 122 is made of nanoscale elastic fibers, which have better elasticity and recovery ability than conventional elastic fibers, so as to further reduce the risk of wrinkling of the vamp.
The microporous breather layer 123 has a plurality of micropores, and the micropore only passes through for the gas, and obstructs the hydrone and passes through for the vamp has better waterproof performance when having good air permeability. The microporous breathable layer 123 can be supported by a WERS waterproof membrane or made of GORE-TEX material.
The soft layer 124 is supported by cotton cloth or linen cloth, and has ventilation and sweat absorbing effects so as to ensure wearing comfort of the sports shoe.
Further, the edge of the support portion 11 for connecting with the protection portion 12 is provided with an elastic band 13, and the elastic band 13 is provided to extend in the width direction of the upper 1. The protection part 12 is connected with the elastic belt 13, so that elastic connection is established between the supporting part 11 and the protection part 12 by utilizing the elastic belt 13, and the elastic belt 13 is adaptively deformed and drives the protection part 12 to reset rapidly in the walking process of a wearer, so that the risk of wrinkling of the vamp is reduced.
The protecting part 12 is connected to the side edge of the elastic belt 13 near the supporting part 11, and the elastic belt 13 is abutted against the outer surface of the protecting part 12. By the design, on one hand, the elastic belt 13 is provided with a larger area for connecting the protective part 12, the cutting accuracy requirement on the edge of the protective part 12 is lower, and on the other hand, the elastic belt 13 is abutted against the outer surface of the protective part 12, so that the perception of elasticity of a wearer is weakened, and the wearing comfort of the sports shoes is ensured.
The embodiment 1 is implemented on the principle that, when the upper of the sports shoe is produced, the elastic band 13 is sewn at the edge position of the support portion 11 near the protection portion 12, and the edge of the protection portion 12 is sewn to the side of the elastic band 13 near the support portion 11. Since the supporting portion 11 is provided with the foam pad 111 having a good rebound resilience, and the protecting portion 12 is provided with the nano elastic fiber mesh layer 122 having excellent elasticity and recovery ability, the vamp has good water-washing resistance and wrinkle resistance.
Example 2
Referring to fig. 4 and 5, this embodiment is different from embodiment 1 in that the microporous breathable layer 123 is provided with two layers, and both of the two microporous breathable layers 123 are located between the elastic fiber mesh layer 122 and the soft layer 124. A plurality of elastic balls 14 are arranged between the two microporous breathable layers 123. Thereby utilizing the elastic ball 14 to increase the cushioning properties of the upper and provide additional support when the athletic shoe is impacted, and effectively protecting the instep of the wearer.
Further, the interior of the elastic ball 14 is provided with a light cavity 141 to reduce the mass of the elastic ball 14 and improve the wearing comfort of the sports shoes. The lightweight cavity 141 may be formed when the elastic ball 14 is molded, or may be formed by opening the elastic ball 14 after molding.
To ensure the air permeability of the microporous air-permeable layer 123, the two microporous air-permeable layers 123 are sewn and fixed by a plurality of stitches. Each stitch track is circular such that the two microporous breather layers 123 form a receiving cavity for receiving the resilient ball 14 at the location of the stitch. And since no glue is used when fixing the elastic ball 14 and the two microporous breathable layers 123, the influence on the breathability of the microporous breathable layers 123 is small.
The above embodiments are not intended to limit the scope of the application, so that the equivalent changes of the structure, shape and principle of the application are covered by the scope of the application.