CN220777442U - Direct penetrating type breathable mold cup and underwear - Google Patents

Abstract

The utility model provides a direct penetration type breathable mold cup and underwear, the direct penetration type ventilation mold cup comprises: a surface layer; the bottom layer is arranged at the bottom layer, the bottom layer and the surface layer are arranged in a lamination way; the middle layer is clamped between the surface layer and the bottom layer, the middle layer is respectively and fixedly connected with the surface layer and the bottom layer, the middle layer comprises a single sub middle layer or a plurality of sub middle layers along the lamination direction of the surface layer to the bottom layer, the middle layer is provided with a first surface and a second surface which are oppositely arranged, the first surface faces the surface layer, the second surface faces the bottom layer, and the second surface faces the bottom layerThe sub-intermediate layer is provided with a plurality of ventilation holes which penetrate through the first surface and the second surface of the sub-intermediate layer, and a single ventilation hole is provided with a pore diameter range D ₁ The said pore size range D ₁ The method meets the following conditions: d (D) ₁ Not less than 3.5mm, so that sweat can be rapidly discharged through the ventilation holes in the movement process of a user, and bacterial breeding is reduced.

Description

Direct penetrating type breathable mold cup and underwear

Technical Field

The utility model relates to the field of underwear, in particular to a direct penetration type breathable mold cup and underwear.

Background

Women often need wear athletic undergarment in the athletic scene, and athletic undergarment is more pursued parcel nature and supportability than daily underwear, needs to play the absorbing effect simultaneously, gives certain protection and the support of chest, and rocking, friction and the injury to the chest when reducing the motion easily produce chest sagging and irreversible damage otherwise.

In order to provide adequate support and shock absorption, athletic undergarments have a thicker layer design than everyday undergarments. However, if the sports underwear is not good in air permeability during the sports process of wearing the thick sports underwear, sweat cannot be discharged timely, so that bacteria are bred in the sports underwear, and the chest health is endangered.

Disclosure of Invention

In a first aspect, the present application provides a direct penetration type ventilation mold cup comprising:

a surface layer;

the bottom layer and the surface layer are arranged in a lamination manner; and

The middle layer is clamped between the surface layer and the bottom layer, the middle layer is respectively fixedly connected with the surface layer and the bottom layer, the middle layer comprises a single sub-middle layer or a plurality of sub-middle layers which are laminated along the direction that the surface layer points to the bottom layer, the middle layer is provided with a first surface and a second surface which are arranged in opposite directions, the first surface faces the surface layer, the second surface faces the bottom layer, the sub-middle layer is provided with a plurality of ventilation holes, the ventilation holes penetrate through the first surface and the second surface of the sub-middle layer, and the ventilation holes are provided with a pore diameter range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ ≥3.5mm。

Wherein when the intermediate layer comprises a plurality of sub-intermediate layers, the plurality of sub-intermediate layers are sequentially laminated, and the sub-intermediate layers have a thickness range H ₁ The thickness range H ₁ The method meets the following conditions: h ₁ 15mm or less, and the intermediate layer has a thickness range H ₂ The thickness range H ₂ The method meets the following conditions: h is 15mm or less ₂ ≤50mm。

Wherein when the intermediate layer comprises a plurality of sub-intermediate layers, the vent of one of the plurality of sub-intermediate layers is at least partially opposite the vent of another one of the plurality of sub-intermediate layers.

The middle layer is provided with a first edge and a second edge which are connected in a bending way, the middle layer is provided with a body part and a pressing part, the body part is provided with a plurality of ventilation holes, the pressing part is arranged on one side of the body part adjacent to the second edge and is respectively and fixedly connected with the surface layer and the bottom layer, and the pressing part is provided with a thickness range H ₃ The body portion has a thickness range H ₄ The thickness range H ₃ And the thickness range H ₄ The method meets the following conditions: h ₃ ＜H ₄ 。

Wherein the thickness range H ₃ The method meets the following conditions: h is more than or equal to 0.5mm ₃ And less than or equal to 1.5mm, wherein the thickness range H ₄ Satisfy H which is not less than 15 ₄ ≤50mm。

Wherein, the thickness of the body portion gradually increases from the first edge to the second edge, and the plurality of ventilation holes include:

a first sub-ventilation hole arranged at the part of the body part adjacent to the first edge and having an aperture range D ₂ The pore diameter range D ₂ The method meets the following conditions: d (D) ₂ Not less than 6.5mm; and

A second sub-ventilation hole arranged at the part of the body part adjacent to the second edge and spaced from the first sub-ventilation hole, and having an aperture range D ₃ The pore diameter range D ₃ The method meets the following conditions: d (D) ₃ ≥7mm。

Wherein the plurality of ventilation holes comprise a plurality of first sub-ventilation hole groups, each first sub-ventilation hole group comprises a plurality of first sub-ventilation holes, and a distance range D is arranged between two adjacent first sub-ventilation holes in each first sub-ventilation hole group ₄ A distance range D is arranged between two adjacent first sub-vent groups ₅ The distance range D ₄ At the distance from the aboveRange D ₅ The method meets the following conditions: d (D) ₄ ≤D ₅ 。

Wherein a distance range D is arranged between the edge of the air hole and the edge of the middle layer ₆ The distance range D ₆ The method meets the following conditions: d (D) ₆ ≥5mm。

The surface of the surface layer is provided with a first grid, the first grid is used for permeating gas, the surface of the bottom layer is provided with a second grid, and the second grid is used for permeating gas.

In a second aspect, the present application provides an undergarment comprising the direct penetration ventilation die cup. The directly penetrating type ventilation mold cup comprises a surface layer, a bottom layer and a middle layer, wherein the sub-middle layer is provided with a plurality of ventilation holes, the ventilation holes penetrate through the first surface and the second surface of the sub-middle layer, and a single ventilation hole is provided with an aperture range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ Not less than 3.5mm, so that the direct penetration type ventilation mold cup has a sufficient ventilation effect, sweat can be rapidly discharged through the ventilation holes in the movement process of a user, thereby reducing bacteria breeding and guaranteeing the use comfort and the physical health of the user.

Drawings

In order to more clearly illustrate the technical solutions of the present utility model, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained by those skilled in the art without the inventive effort.

FIG. 1 is a schematic side view of a direct penetration ventilation mold cup in accordance with an embodiment of the present application;

FIG. 2 is a schematic diagram of an exploded construction of a direct penetration gas permeable molded cup according to an embodiment of the present application;

FIG. 3 is a schematic structural view of an intermediate layer according to a first embodiment of the present application;

FIG. 4 is a schematic side view of an intermediate layer of a first embodiment of the present application;

FIG. 5 is a schematic cross-sectional view of the direct penetration type air permeable mold cup provided in FIG. 1 along line A-A;

FIG. 6 is a schematic structural view of a cross-section of a direct penetration type air permeable mold cup along line A-A according to an embodiment of the present application;

FIG. 7 is a schematic structural view of an intermediate layer according to a second embodiment of the present application;

FIG. 8 is a schematic diagram of an exploded construction of a direct penetration gas permeable molded cup according to an embodiment of the present application;

fig. 9 is a schematic structural view of an undergarment according to an embodiment of the present application.

Reference numerals illustrate:

1-underwear, 10-direct penetration ventilation cup, 20-shoulder strap, 11-face layer, 12-bottom layer, 13-middle layer, 111-first grid, 121-second grid, 131-sub-middle layer, 132-first surface, 133-second surface, 134-vent, 135-first edge, 136-second edge, 137-body portion, 138-press fit, 134 a-first sub-vent set, 1341-first sub-vent, 1342-second sub-vent.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without making any inventive effort, are intended to fall within the scope of the present utility model.

The terms first, second and the like in the description and in the claims of the present application and in the above-described figures, are used for distinguishing between different objects and not for describing a particular sequential order. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those listed steps or elements but may include other steps or elements not listed or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" or "an implementation" means that a particular feature, structure, or characteristic described in connection with the embodiment or implementation may be included in at least one embodiment of the present application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

Please refer to fig. 1, 2, 3, 4, 5, 6 and 7. The present application provides a direct penetration type ventilation mold cup 10, wherein the direct penetration type ventilation mold cup 10 comprises a surface layer 11, a bottom layer 12 and a middle layer 13. The bottom layer 12 and the surface layer 11 are stacked. The middle layer 13 is sandwiched between the surface layer 11 and the bottom layer 12, and the middle layer 13 is fixedly connected with the surface layer 11 and the bottom layer 12 respectively, the middle layer 13 comprises a single sub middle layer 131 or a plurality of sub middle layers 131 stacked along the direction that the surface layer 11 points to the bottom layer 12, the middle layer 13 has a first surface 132 and a second surface 133 which are oppositely arranged, the first surface 132 faces the surface layer 11, the second surface 133 faces the bottom layer 12, the sub middle layers 131 have a plurality of ventilation holes 134, the ventilation holes 134 penetrate through the first surface 132 and the second surface 133 of the sub middle layers 131, and the ventilation holes 134 have a pore diameter range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ ≥3.5mm。

The direct-penetration type ventilation mold cup 10 may be, but is not limited to, suitable for use in the thick bra underwear 1, and it is understood that the direct-penetration type ventilation mold cup 10 may also be suitable for use in other types of underwear 1, and the application scenario of the direct-penetration type ventilation mold cup 10 should not be limited to the direct-penetration type ventilation mold cup 10 provided in this embodiment.

The directly penetrating type ventilation cup 10 specifically means that the ventilation holes 134 may be, but not limited to, directly penetrating through the middle layer 13 of the cup, and the surface layer 11 and the bottom layer 12 may be made of ventilation materials, so that the gas can pass through the cup relatively rapidly, thereby achieving ventilation effect.

The surface of the direct penetration type ventilation cup 10 may be, but is not limited to, a cambered surface, and the surface of the direct penetration type ventilation cup 10 may be, but is not limited to, a design having a convex shape in a direction from the bottom layer 12 toward the face layer 11.

The facing layer 11 may be, but is not limited to being, remote from the wearer's chest relative to the intermediate layer 13 during use of the direct penetration ventilation cup 10. The material of the surface layer 11 may be, but not limited to, cotton fabric, chemical fiber fabric, rayon fabric, or blended fabric, etc., and preferably, the surface layer 11 may be made of a material with good air permeability and low gram weight, so that the air permeability of the directly penetrating type air-permeable mold cup 10 is good and the air-permeable mold cup has a light effect.

The bottom layer 12 may be, but is not limited to being, adjacent to the wearer's chest relative to the middle layer 13 during use of the direct penetration ventilation mold cup 10. The material of the bottom layer 12 may be, but is not limited to, cotton fabric, chemical fiber fabric, artificial fiber fabric, blended fabric, etc. The material of the bottom layer 12 and the material of the surface layer 11 may be, but are not limited to, the same or different, which is not limited in this application. Preferably, the surface layer 11 may be made of a material with good air permeability and low gram weight, so that the air permeability of the direct penetration type air permeable mold cup 10 is good, which is beneficial to sweat discharge and reduces bacterial growth.

The bottom layer 12 and the surface layer 11 are laminated, the middle layer 13 is sandwiched between the surface layer 11 and the bottom layer 12, preferably, the middle layer 13 is adhered to the surface layer 11 and the bottom layer 12. The material of the intermediate layer 13 may be, but is not limited to, sponge, aqueous polyurethane material, upright cotton, latex, or silica gel, etc., and in this embodiment, the material of the intermediate layer 13 is exemplified by sponge, so that the air permeability of the direct penetration type air permeable mold cup 10 is good and elastic.

The intermediate layer 13 is respectively connected with the surface layer 11 and the bottom layer 12 are fixedly connected, and the middle layer 13 may be fixedly connected with the surface layer 11 and the bottom layer 12 by, but not limited to, glue bonding, stitching, or the like. In this embodiment, the middle layer 13 is adhered to the surface layer 11 and the bottom layer 12 by glue, which may be, but not limited to, polyurethane hot melt adhesive (Polyurethane Reactive, PUR), aqueous glue, ultraviolet light curing (UV) glue, or other environment-friendly glue.

Further, the adhesion between the middle layer 13 and the surface layer 11 and the bottom layer 12 may be, but not limited to, a process of numerical control dispensing, so as to improve the dispensing speed and the dispensing quality.

The intermediate layer 13 includes sub-intermediate layers 131, and the number of the sub-intermediate layers 131 may be, but is not limited to, one (fig. 5), two, three (fig. 6), four, five, or the like. When the number of the sub-intermediate layers 131 is plural, the plurality of sub-intermediate layers 131 may be, but not limited to, stacked in a direction in which the face layer 11 is directed toward the bottom layer 12.

The intermediate layer 13 further has a first surface 132 and a second surface 133 disposed opposite to each other, the first surface 132 faces the surface layer 11, and the first surface 132 may be, but is not limited to, disposed to be attached to the surface layer 11. The second surface 133 is oriented toward the bottom layer 12, and the second surface 133 may be, but is not limited to being, configured to fit against the bottom layer 12.

The sub-intermediate layer 131 has a plurality of ventilation holes 134, and the number of ventilation holes 134 may be, but is not limited to, 10, 15, 20, 25, 30, etc., it is understood that the number of ventilation holes 134 may be other values, and the number of ventilation holes 134 should not be limited to the direct penetration type ventilation cup 10 according to the present embodiment. In the schematic diagrams provided in the embodiments of the present application, the ventilation holes 134 densely distributed in the sub-intermediate layer 131 are taken as an example for illustration, so that the direct penetration ventilation cup 10 has a sufficient ventilation effect.

The shape of the ventilation holes 134 may be, but is not limited to, circular, elliptical, square, polygonal, or other irregular shapes. In the first embodiment (fig. 3), the shape of the ventilation holes 134 is illustrated as including polygonal and irregular shapes. In the second embodiment (fig. 7), the shape of the ventilation holes 134 includes a hexagonal honeycomb shape.

The plurality of ventilation holes 134 may be, but not limited to, arranged in different ways, so that when the user wears the undergarment 1 using the direct penetration type ventilation cup 10, the ventilation holes 134 form air flow under the pressure difference of air pressure along with the shaking of the breast, thereby greatly improving ventilation effect, so that sweat can be rapidly discharged through the ventilation holes 134 during movement when the user wears the undergarment 1 using the direct penetration type ventilation cup 10, thereby reducing bacterial growth.

The plurality of ventilation holes 134 penetrate through the first surface 132 and the second surface 133 of the sub-middle layer 131, so that air can circulate through the sub-middle layer 131, that is, the directly penetrating ventilation cup 10 has sufficient ventilation, thereby facilitating the discharge of sweat and increasing the wearing comfort of the directly penetrating ventilation cup 10.

The individual vents 134 have a pore size range D ₁ The pore diameter range D ₁ May be, but is not limited to, a range of a distance between maximum two points of the ventilation holes 134 in the lateral direction.

Further, the pore size range D ₁ May be, but is not limited to, 3.5mm, or 4mm, or 4.5mm, or 5mm, or 5.5mm, or 6mm, or 6.5mm, or 7mm, or 8mm, or 9mm, etc., it is understood that the aperture range D of the ventilation holes 134 is ₁ Other values are also possible.

Preferably, in one mode of the present application, the pore size range D ₁ May be, but not limited to, 3.5 mm.ltoreq.D ₁ 10mm or less, thereby making the resultThe direct penetration type ventilation cup 10 does not cause the aperture range D of the ventilation holes 134 ₁ Too small to allow rapid perspiration to affect the user experience, and the direct penetration ventilation cup 10 does not suffer from the pore size D of the vent 134 ₁ Too large to affect the structural stability and durability of the direct penetration type ventilation mold cup 10. When the pore diameter is within the range D ₁ Satisfies D of 3.5mm or less ₁ When the thickness of the directly penetrating type ventilation mold cup 10 is less than or equal to 10mm, the directly penetrating type ventilation mold cup 10 can have sufficient ventilation effect when being applied to thick underwear 1, the weight of the directly penetrating type ventilation mold cup 10 is lightened, and the structural stability and durability of the directly penetrating type ventilation mold cup 10 are ensured, so that tearing and damage can not be generated in the movement process of a user.

In summary, the direct penetration type ventilation cup 10 provided in this embodiment includes the surface layer 11, the bottom layer 12 and the middle layer 13, the sub-middle layer 131 has a plurality of ventilation holes 134, the plurality of ventilation holes 134 penetrate through the first surface 132 and the second surface 133 of the sub-middle layer 131, and a single ventilation hole 134 has a pore size range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ Not less than 3.5mm, the weight of the direct penetration type ventilation mold cup 10 can be reduced to avoid excessively heavy underwear 1, and the direct penetration type ventilation mold cup 10 has a sufficient ventilation effect, so that sweat can be rapidly discharged through the ventilation holes 134 in the movement process of a user, the direct penetration type ventilation mold cup 10 can be dry and ventilated, thereby reducing the breeding of bacteria, enabling the breasts to breathe freely, improving the comfort of the user when using the direct penetration type ventilation mold cup 10 and the underwear 1, and guaranteeing the physical health of the user.

Please refer to fig. 6 again. When the intermediate layer 13 includes a plurality of sub-intermediate layers 131, the plurality of sub-intermediate layers 131 are sequentially stacked, and the sub-intermediate layers 131 have a thickness range H ₁ The thickness range H ₁ The method meets the following conditions: h ₁ 15mm or less, and the intermediate layer 13 has a thickness range H ₂ The thickness range H ₂ The method meets the following conditions: h is 15mm or less ₂ ≤50mm。

Specifically, the plurality of sub-intermediate layers 131 may be, but not limited to, manufactured by a process of compression molding.

Thickness range H of the sub-interlayer 131 ₁ May be, but not limited to, the maximum value of the range of the interval between two points of the sub-intermediate layer 131 in the thickness direction.

Further, the thickness range H of the sub-interlayer 131 ₁ May be, but is not limited to, 8mm, or 9mm, or 10mm, or 11mm, or 12mm, or 13mm, or 14mm, or 15mm, etc., it being understood that the thickness range H ₁ Other values are also possible, provided that H is satisfied ₁ And less than or equal to 15mm, so that the direct penetration type ventilation mold cup 10 does not influence the wearing comfort of the user due to the excessive thickness of the sub-middle layer 131.

Thickness range H of the intermediate layer 13 ₂ May be, but is not limited to, the maximum value of the range of the interval between two points of the intermediate layer 13 in the thickness direction.

Further, the thickness range H of the intermediate layer 13 ₂ May be, but is not limited to, 15mm, or 20mm, or 25mm, or 30mm, or 35mm, or 40mm, or 45mm, or 50mm, etc., it being understood that the thickness range H ₂ Other values are also possible, as long as H is 15mm < H ₂ The thickness of the directly penetrating type ventilation mold cup 10 is not more than 50mm, so that the wearing comfort of a user is not influenced due to the fact that the thickness of the directly penetrating type ventilation mold cup 10 is too thick, meanwhile, the stability of the directly penetrating type ventilation mold cup 10 can be considered, the directly penetrating type ventilation mold cup 10 can also have enough supporting force on the chest in the movement process of the user, the user can play a good damping effect on the breast in the wearing process, the shaking radian and range of the breast are reduced, and the sagging of the breast is delayed.

Please refer to fig. 4 and 6 again. When the intermediate layer 13 includes a plurality of sub-intermediate layers 131, the ventilation holes 134 of one of the plurality of sub-intermediate layers 131 are at least partially opposite to the ventilation holes 134 of the other one of the plurality of sub-intermediate layers 131.

In particular, the vent 134 of one of the plurality of sub-interlayer 131 may be, but is not limited to being, the vent 134 of another one of the plurality of sub-interlayer 131 that is being, or is partially being, adjacent thereto.

Preferably, the vent 134 of one of the plurality of sub-interlayer 131 is completely or almost completely opposite to the vent 134 of another one of the plurality of sub-interlayer 131. The ventilation holes 134 of the plurality of sub-middle layers 131 may be, but not limited to, all right to each other, so that gas can flow between the ventilation holes 134 of the plurality of sub-middle layers 131 quickly, so that the direct penetration ventilation cup 10 has a sufficient ventilation effect, and sweat can be discharged through the ventilation holes 134 quickly during the movement process of a user, thereby avoiding bacteria growing due to accumulation of sweat, and keeping the direct penetration ventilation cup 10 and the underwear 1 dry and clean.

Please refer to fig. 3 and fig. 4 again. The middle layer 13 has a first edge 135 and a second edge 136 which are connected by bending, the middle layer 13 has a body portion 137 and a pressing portion 138, the body portion 137 has the plurality of ventilation holes 134, the pressing portion 138 is disposed on one side of the body portion 137 adjacent to the second edge 136 and fixedly connected with the surface layer 11 and the bottom layer 12, respectively, and the pressing portion 138 has a thickness range H ₃ The body portion 137 has a thickness range H ₄ The thickness range H ₃ And the thickness range H ₄ The method meets the following conditions: h ₃ ＜H ₄ 。

The first edge 135 may be, but is not limited to being, arcuate, or approximately arcuate. The second edge 136 may be, but is not limited to being, arcuate, or approximately arcuate. The first edge 135 is folded over and connected to the second edge 136, and the bent connection of the first edge 135 and the second edge 136 may be but is not limited to an arc shape, that is, the first edge 135 and the second edge 136 of the intermediate layer 13 may be gently connected, so as to ensure the wearing comfort of the direct penetration type ventilation cup 10.

The body 137 and the pressing portion 138 may be, but are not limited to, integrally formed. The nip 138 may be, but is not limited to, molded from the raw material from which the sub-interlayer 131 is made.

The press-fit portion 138 is fixedly connected to the surface layer 11 and the bottom layer 12, and specifically, the surface layer 11 may be, but not limited to, molded with the middle layer 13 after being molded with an arc, and then the bottom layer 12 is molded with the surface layer 11 and the middle layer 13, and is adhered by glue to perform the fixed connection.

The nip 138 has a thickness range H ₃ Thickness range H of the press-fit portion 138 ₃ May be, but is not limited to, the maximum value of the range of the interval between two points of the nip 138 in the thickness direction.

The body portion 137 has a thickness range H ₄ The thickness range H of the body 137 ₄ May be, but is not limited to, the maximum value of the range of the interval between two points of the body portion 137 in the thickness direction.

The thickness range H ₃ And the thickness range H ₄ Satisfy the following requirements the method comprises the following steps: h ₃ ＜H ₄ Namely, the middle layer 13 can be thinned at the edge position, so that the middle layer 13 is prevented from making the edge of the direct penetration type ventilation cup 10 hard after compression molding, and wearing comfort of the direct penetration type ventilation cup 10 is further improved.

Please refer to fig. 3 and fig. 4 again. The thickness range H ₃ The method meets the following conditions: h is more than or equal to 0.5mm ₃ And less than or equal to 1.5mm, wherein the thickness range H ₄ Satisfy H which is not less than 15 ₄ ≤50mm。

Specifically, the thickness range H of the nip 138 ₃ May be, but is not limited to, 0.5mm, or 0.7mm, or 0.9mm, or 1mm, or 1.2mm, or 1.3mm, or 1.5mm, etc., it being understood that the thickness range H of the nip 138 is ₃ Other values are also possible, as long as H is 0.5 mm.ltoreq.H ₃ And less than or equal to 1.5mm, so that the press-fit portion 138 is not hard enough to affect wearing comfort of a user, and at the same time, the press-fit portion 138 is not too thin to affect durability.

The body portion 137Thickness range H ₄ May be, but is not limited to, 15mm, or 20mm, or 25mm, or 30mm, or 35mm, or 40mm, or 45mm, or 50mm, etc., it being understood that the thickness range H of the body portion 137 ₄ Other values are also possible, as long as H is 15mm < H ₄ And the vibration of the breast is less than or equal to 50mm, so that the body 137 has enough supporting force and vibration reduction effect on the breast, and the shaking radian and range of the breast are reduced, thereby achieving the effect of stabilizing the breast.

Please refer to fig. 3 again. The thickness of the body 137 gradually increases from the first edge 135 to the second edge 136, and the plurality of ventilation holes 134 includes a first sub ventilation hole 1341 and a second sub ventilation hole 1342. The first sub-ventilation holes 1341 are disposed at the portion of the body 137 adjacent to the first edge 135, and the first sub-ventilation holes 1341 have a pore size range D ₂ The pore diameter range D ₂ The method meets the following conditions: d (D) ₂ And is more than or equal to 6.5mm. The second sub-ventilation holes 1342 are disposed at the portion of the body 137 adjacent to the second edge 136, the second sub-ventilation holes 1342 are disposed at intervals in the first sub-ventilation holes 1341, and the second sub-ventilation holes 1342 have an aperture range D ₃ The pore diameter range D ₃ The method meets the following conditions: d (D) ₃ ≥7mm。

The thickness of the body portion 137 increases gradually from the first edge 135 to the second edge 136, so that the direct penetration type ventilation cup 10 can better fit the breast and has better support and gathering effects on the breast.

The number of the first sub-ventilation holes 1341 may be, but is not limited to, 20, or 30, or 40, or 50, or 60, etc., and it is understood that the number of the first sub-ventilation holes 1341 may be other values, and the number of the first sub-ventilation holes 1341 should not be limited to the direct-penetration ventilation cup 10 provided in this embodiment.

The shape of the first sub-ventilation holes 1341 may be, but is not limited to, circular, elliptical, square, polygonal, or other irregular shapes. In the schematic diagrams provided in this embodiment, the first sub-ventilation holes 1341 are illustrated as irregular shapes.

The first sub-vent 1341 has a pore size range D ₂ The pore diameter range D ₂ May be, but is not limited to, the maximum value of the interval range between two points of the first sub-airing holes 1341 in the lateral direction.

Further, the pore size range D ₂ May be, but is not limited to, 6.5mm, or 6.7mm, or 6.9mm, or 7mm, or 7.2mm, or 7.4mm, or 7.8mm, or 8mm, etc., it is understood that the aperture range D of the first sub-ventilation holes 1341 ₂ Other values are also possible, provided that D is satisfied ₂ And the diameter is more than or equal to 6.5mm.

The number of the second sub-ventilation holes 1342 may be, but is not limited to, 5, or 8, or 10, or 12, or 15, or 20, etc., it is understood that the number of the second sub-ventilation holes 1342 may be other values, and the number of the second sub-ventilation holes 1342 should not be limited to the direct penetration type ventilation cup 10 according to the present embodiment.

The shape of the second sub-ventilation holes 1342 may be, but is not limited to, circular, oval, square, polygonal, or other irregular shapes. In the schematic diagrams provided in this embodiment, the shape of the second sub-ventilation holes 1342 is exemplified by a circular shape.

The second sub-vent 1342 has a pore size range D ₃ The pore diameter range D ₃ May be, but is not limited to, the maximum value of the interval range between two points of the second sub-airing holes 1342 in the lateral direction.

Further, the pore size range D ₃ May be, but is not limited to, 7mm, or 7.4mm, or 7.8mm, or 8mm, or 8.4mm, or 8.8mm, or 9mm, etc., it is understood that the aperture range D of the second sub-ventilation holes 1342 ₃ Other values are also possible, provided that D is satisfied ₃ And the diameter is more than or equal to 7 mm.

The aperture range D of the second sub-ventilation holes 1342 ₃ May be larger than the aperture range D of the first sub-vent 1341 ₂ Whereby the needleThe region with more sweat on the breast is cooled, and meanwhile, the direct penetration type ventilation mold cup 10 has a thicker thickness adjacent to the second edge 136, and the second sub-ventilation holes 1342 have a larger aperture, so that the ventilation property of the direct penetration type ventilation mold cup 10 can be ensured, and the support strength of the direct penetration type ventilation mold cup 10 is ensured, and meanwhile, sweat can be discharged in time.

Please refer to fig. 3 again. The plurality of ventilation holes 134 includes a plurality of first sub-ventilation hole sets 134a, the first sub-ventilation hole sets 134a include a plurality of first sub-ventilation holes 1341, and a space D is provided between two adjacent first sub-ventilation holes 1341 in the first sub-ventilation hole sets 134a ₄ A distance range D is provided between two adjacent first sub-vent groups 134a ₅ The distance range D ₄ And the distance range D ₅ The method meets the following conditions: d (D) ₄ ≤D ₅ 。

The number of the first sub ventilation hole sets 134a may be, but not limited to, 5, or 10, or 15, or 20, or 25, etc.

Each of the first sub-vent groups 134a may be, but not limited to, the first sub-vents 1341 including 2, or 3, or 4, or 5, etc. In the schematic diagram provided in this embodiment, the first sub-ventilation hole set 134a includes 3 first sub-ventilation holes 1341 as an example.

A space D is provided between two adjacent first sub-ventilation holes 1341 in the first sub-ventilation hole set 134a ₄ The distance range D ₄ May be, but is not limited to, the minimum value of the interval range between two points of the adjacent two first sub-ventilation holes 1341 in the lateral direction.

A distance D is provided between two adjacent first sub-vent groups 134a ₅ The distance range D ₅ May be, but is not limited to, the minimum value of the interval range between two points of the adjacent two first sub-vent groups 134a in the lateral direction.

The distance range D ₄ Less than or equal to the spacing range D ₅ Namely, the first sub-ventilation holes 1341 included in the first sub-ventilation hole set 134a have a relatively denser distribution state, so that the first sub-ventilation hole set 134a can perform rapid air circulation, and in the wearing process of the direct-penetration type ventilation cup 10, along with the shaking of the breast and the influence of external natural wind of the chest, the volume and the air pressure of the air chamber forming the first sub-ventilation hole set 134a of the direct-penetration type ventilation cup 10 are continuously changed, thereby accelerating the discharge of air in the air chamber, ensuring the air permeability of the direct-penetration type ventilation cup 10, and enabling the direct-penetration type ventilation cup 10 to be more dry and breathable.

Please refer to fig. 7 again. A distance D is provided between the edge of the ventilation hole 134 and the edge of the middle layer 13 ₆ The distance range D ₆ The method meets the following conditions: d (D) ₆ ≥5mm。

The distance range D ₆ May be, but is not limited to, a minimum distance range between the edge of the ventilation hole 134 and the edge of the intermediate layer 13.

The distance range D ₆ May be, but is not limited to, 5mm, or 5.5mm, or 6mm, or 6.5mm, or 7mm, or 8mm, etc., it being understood that the distance range D ₆ May be, but not limited to, other values as long as D is satisfied ₆ And the size is more than or equal to 5mm, so that the edge of the direct penetration type ventilation mold cup 10 is not punched by holes, the edge of the direct penetration type ventilation mold cup 10 forms an annular reinforcing belt, and the phenomenon that the edge of the direct penetration type ventilation mold cup 10 is enlarged or torn due to overlarge movement strength or over-strong water washing in the wearing process of the direct penetration type ventilation mold cup 10 can be avoided, so that the durable quality of the direct penetration type ventilation mold cup 10 is improved.

Please refer to fig. 8. The surface of the surface layer 11 has a first mesh 111, the first mesh 111 is for gas permeation, the surface of the bottom layer 12 has a second mesh 121, and the second mesh 121 is for gas permeation.

Specifically, the surface layer 11 is preferably a fabric with good air permeability and low gram weight, and the surface of the surface layer 11 may be, but is not limited to, a first grid 111 with dense arrangement, so as to facilitate the permeation of air by the surface layer 11.

The first grid 111 may be, but is not limited to being square, or approximately square, or honeycomb, or other shapes, etc.

The bottom layer 12 is preferably a fabric with good air permeability and low gram weight, and the surface of the bottom layer 12 may be, but is not limited to, a second grid 121 with dense arrangement, so as to facilitate the permeation of air by the bottom layer 12.

The second mesh 121 may be, but is not limited to, square, or approximately square, or honeycomb, or other shapes, etc.

The arrangement of the first mesh 111 and the second mesh 121 can enhance the air permeability of the surface layer 11 and the bottom layer 12, and effectively reduce the weight of the surface layer 11 and the bottom layer 12, so that the direct penetration type air permeable mold cup 10 is lighter.

Please refer to fig. 3 and 9. The embodiment of the present application also provides an undergarment 1, said undergarment 1 comprising said direct penetration ventilation cup 10.

The underwear 1 may further include an underwear 1 body and a shoulder strap 20, the direct penetration type ventilation cup 10 is accommodated in the underwear 1 body, and the shoulder strap 20 may be connected to the underwear 1 body and used for being worn by a user. And the undergarment 1 may be, but is not limited to being, comprised of the right and left symmetric direct penetration type ventilation cup 10. The sub-intermediate layer 131 of the direct penetration type ventilation cup 10 has a plurality of ventilation holes 134, and a single ventilation hole 134 has a pore diameter range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ Not less than 3.5mm, the weight of the direct penetration type ventilation mold cup 10 can be reduced to avoid excessively heavy underwear 1, and the direct penetration type ventilation mold cup 10 has a sufficient ventilation effect, so that sweat can be rapidly discharged through the ventilation holes 134 in the movement process of a user, the direct penetration type ventilation mold cup 10 can be dry and ventilated, thereby reducing the breeding of bacteria, enabling the breasts to breathe freely, improving the comfort of the user when using the direct penetration type ventilation mold cup 10 and the underwear 1, and guaranteeing the physical health of the user.

Reference in the present application to "an embodiment," "implementation" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the present application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly understand that the embodiments described herein may be combined with other embodiments. Furthermore, it should be understood that the features, structures, or characteristics described in the embodiments of the present application may be combined arbitrarily without any conflict with each other to form yet another embodiment without departing from the spirit and scope of the present application.

Finally, it should be noted that the above embodiments are merely for illustrating the technical solution of the present application and not for limiting, and although the present application has been described in detail with reference to the above preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or equivalent replaced without departing from the spirit and scope of the technical solution of the present application.

Claims (9)

1. A direct penetration type ventilation mold cup, characterized in that the direct penetration type ventilation mold cup comprises:

a surface layer;

the bottom layer and the surface layer are arranged in a lamination manner; and

The middle layer is clamped between the surface layer and the bottom layer, the middle layer is respectively fixedly connected with the surface layer and the bottom layer, the middle layer comprises a single sub-middle layer or a plurality of sub-middle layers which are laminated along the direction that the surface layer points to the bottom layer, the middle layer is provided with a first surface and a second surface which are arranged in opposite directions, the first surface faces the surface layer, the second surface faces the bottom layer, the sub-middle layer is provided with a plurality of ventilation holes, the ventilation holes penetrate through the first surface and the second surface of the sub-middle layer, and the ventilation holes are provided with a pore diameter range D ₁ The pore diameter range D ₁ The method meets the following conditions: d (D) ₁ ≥3.5mm；

The middle layer is provided with a first edge and a second edge which are connected in a bending way, the middle layer is provided with a body part and a pressing part, and the thickness of the body part gradually increases from the first edge to the second edge; the plurality of ventilation holes comprise a first sub ventilation hole and a second sub ventilation hole, the first sub ventilation hole is arranged at the part of the body part adjacent to the first edge, the second sub ventilation hole is arranged at the part of the body part adjacent to the second edge, and the aperture range of the second sub ventilation hole is larger than that of the first sub ventilation hole;

wherein the plurality of ventilation holes comprise a plurality of first sub-ventilation hole groups, each first sub-ventilation hole group comprises a plurality of first sub-ventilation holes, and a distance range D is arranged between two adjacent first sub-ventilation holes in each first sub-ventilation hole group ₄ A distance range D is arranged between two adjacent first sub-vent groups ₅ The distance range D ₄ And the distance range D ₅ The method meets the following conditions: d (D) ₄ ≤D ₅ 。

2. The direct penetration type air-permeable mold cup according to claim 1, wherein when the intermediate layer comprises a plurality of sub-intermediate layers, the plurality of sub-intermediate layers are sequentially laminated, the sub-intermediate layers having a thickness range H ₁ The thickness range H ₁ Satisfy the following requirements the method comprises the following steps: h ₁ 15mm or less, and the intermediate layer has a thickness range H ₂ The thickness range H ₂ The method meets the following conditions: h is 15mm or less ₂ ≤50mm。

3. The direct penetration type ventilation mold cup of claim 2, wherein when the intermediate layer comprises a plurality of sub-intermediate layers, the ventilation aperture of one of the plurality of sub-intermediate layers is at least partially aligned with the ventilation aperture of another one of the plurality of sub-intermediate layers.

4. The direct penetration type ventilation mold cup of claim 1, wherein the mold cup isThe body part is provided with the plurality of ventilation holes, the pressing part is arranged on one side of the body part adjacent to the second edge and is respectively fixedly connected with the surface layer and the bottom layer, and the pressing part is provided with a thickness range H ₃ The body portion has a thickness range H ₄ The thickness range H ₃ And the thickness range H ₄ The method meets the following conditions: h ₃ ＜H ₄ 。

5. The direct penetration type air permeable mold cup of claim 4 wherein said thickness range H ₃ The method meets the following conditions: h is more than or equal to 0.5mm ₃ And less than or equal to 1.5mm, wherein the thickness range H ₄ Satisfy H which is not less than 15 ₄ ≤50mm。

6. The direct penetration type ventilation mold cup of claim 4, wherein the first sub-ventilation holes have a pore size range D ₂ The pore diameter range D ₂ The method meets the following conditions: d (D) ₂ Not less than 6.5mm; and

The second sub-ventilation holes are arranged at intervals on the first sub-ventilation holes and have an aperture range D ₃ The pore diameter range D ₃ The method meets the following conditions: d (D) ₃ ≥7mm。

7. The direct penetration type ventilation mold cup as claimed in claim 1, wherein a distance D is provided between the edge of the ventilation hole and the edge of the intermediate layer ₆ The distance range D ₆ The method meets the following conditions: d (D) ₆ ≥5mm。

8. The direct penetration type gas permeable molded cup of claim 1, wherein the surface of the top layer has a first mesh for gas permeation and the surface of the bottom layer has a second mesh for gas permeation.

9. An undergarment comprising a direct penetration ventilation cup according to any one of claims 1 to 8.