JP2013517864A - Footwear shaft arrangement and footwear including the same - Google Patents

Abstract

The shaft arrangement (22) for footwear (2) of the present invention comprises a water vapor permeable mounting sole (36) and a shaft bottom (34) having a shaft bottom functional layer laminate (38), a surface ply (24) and a shaft. It is comprised from the shaft area | region (23) which has a functional layer laminated body (26). The sole side shaft end region is connected to the shaft bottom (34), and the shaft bottom functional layer laminate (38) has a two-ply structure.
[Selection] Figure 1

Description

  The following invention relates to footwear shaft arrangements and footwear comprising such shaft arrangements.

  Footwear is known in the prior art that has a waterproof and water vapor permeable shaft so that moisture from sweating can be removed despite the waterproofness of the shaft area. In the sole region, a sole functional layer having waterproofness and water vapor permeability has been provided in the sole region of footwear so that moisture caused by sweating can be released to the outside. As one example, the patent document discloses that not only the shaft bottom but also the remaining shaft region has a water-permeable functional layer that is waterproof, and the shaft bottom is separated from the shaft region. ing.

German Patent Application Publication No. 029296 (A1); 10 2008

  However, in such footwear, the sole area is the place where moisture from sweating that must be moved far away is the most generated, and the place where moisture tends to remain most, which is cold and frozen especially in cold weather Problems such as sensation may occur. The ability to remove moisture in this region is limited with conventional breathable footwear.

  Accordingly, it is an object of the present invention to provide a footwear shaft arrangement and footwear including the same that will improve the removal of moisture, particularly in the sole region, so as to avoid the feeling of cold and freezing of the foot at that location. .

  This object is achieved by the materials described in the independent claims. Effective applications are clarified in the dependent claims.

  The footwear shaft arrangement of the present invention comprises a shaft bottom having a water vapor permeable mounting sole and a shaft bottom functional layer laminate, and a shaft region having a surface ply and a shaft functional layer laminate. The sole side shaft end region is connected to the peripheral end of the shaft bottom. For this purpose, there are several design applications described below.

  The shaft bottom functional layer laminate and the shaft functional layer laminate are preferably connected to each other with a waterproof property, for example, by a continuous adhesive, and a waterproof seal is formed between the two functional layer laminates. You may make it do. The area where the two functional layer laminates and the corresponding two functional layers are joined together by a sealing adhesive to produce a waterproof adhesion is not water vapor permeable. Such a sealing adhesive for forming a waterproof adhesive between the two functional layer laminates may be any desired suitable waterproof adhesive.

  This structure, created by adhering the shaft functional layer laminate to the shaft bottom functional layer laminate, is waterproof around the entire shoe and is water vapor permeable except for a waterproof adhesive formed with a sealing adhesive It is.

  In all embodiments, the shaft functional layer laminate can be suitably attached to the outer material, for example by sewing on its upper side.

  According to the present invention, the shaft bottom functional layer laminate has a two-ply structure. Due to the two-ply shaft bottom functional layer laminate and due to the water vapor permeable mounting sole at the shaft bottom, the moisture from sweating is more pronounced in the shoe compared to a normal shaft arrangement with a three-ply shaft bottom functional layer laminate. Easily move from the bottom to the outside. Here, it is exempted to add a third layer to the shaft bottom functional layer laminate. This makes it possible to save costs for this third layer, and also increases the amount of moisture from perspiration that can be moved far away because one layer of barrier that water vapor must overcome is reduced. You can also. The omitted layer may more specifically be a lattice woven fabric or mesh.

  According to a first embodiment of the invention, the two-ply shaft bottom functional layer laminate comprises a shaft bottom functional layer or membrane and a supporting fabric ply. The support fabric ply is configured to be water vapor permeable but not waterproof. The shaft bottom functional layer or membrane is configured to be waterproof and water vapor permeable, for example, during process or manufacturing.

The support fabric ply is arranged either on the inner side of the shaft bottom or on the outer side of the shaft bottom, depending on the structure of the shaft arrangement. The support fabric ply is water vapor permeable and provides protection for the shaft bottom functional layer.

  In either case, the shaft bottom functional layer is disposed between the support fabric ply and the water vapor permeable mounting sole.

  According to a further embodiment of the present invention, the shaft functional layer laminate of the remaining shaft may have a conventional three-ply structure, but as can be seen from the above, the shaft functional layer laminate is likewise predetermined. It is also possible to improve the ability to remove moisture in the upper and side regions of the shaft arrangement.

  As a design example of the shaft arrangement of the present invention, a water vapor permeable mounting sole, often known as an insole, is placed above the shaft bottom functional layer laminate. Here, the two-ply shaft bottom functional layer laminate extends more laterally than the mounting sole so that the laminate can adhere to the sole side end region and the surface ply of the shaft bottom functional layer laminate.

  In this case, the support fabric ply of the two-ply shaft bottom functional layer laminate is disposed on the lowermost side. The foot contacts the mounting sole.

  In this structure, the water vapor permeable mounting sole may be sewn to the sole side end region of the shaft functional layer laminate by, for example, strobebell stitching or zigzag stitching. Further, the end region of the outer ply may be additionally fixed to the shaft bottom functional layer laminate.

  In another structure of shaft arrangement, often referred to as booties, the sole end region of the shaft functional layer laminate is sewn to the peripheral end functional layer laminate at the bottom of the shaft, for example by zigzag stitching. With this type of construction, a water vapor permeable mounting sole is placed under the shaft bottom functional layer stack.

  The support fabric ply of the two-ply shaft bottom functional layer laminate is placed on the uppermost side and is in direct contact with the foot. The mounting sole forms the bottom layer of the shaft bottom.

  With this form of construction, the sole side end region of the outer ply is sewn to a water vapor permeable mounting sole as a first alternative.

  In an alternative structure, the sole side end region of the outer ply is fixed to the mounting sole.

  In principle, the shaft arrangement of the present invention is not limited to a particular design example, but rather finds utility in design diversity.

  The present invention also provides footwear having at least one shaft arrangement of the above type having a sole unit secured to the bottom surface thereof. The sole unit can be connected to the shaft arrangement in any manner, preferably by adhering or sandwiching the sole unit to the shaft arrangement. In order to be able to remove moisture with high efficiency, it is necessary that the sole unit is provided with an opening of at least one through hole or is made porous and guided outward in a downward or lateral direction.

Definition and testing methods Footwear:
Covering the foot with an opening for inserting the foot and a closed top (shaft arrangement) containing at least one sole or sole unit.

Shaft outer material:
The material that forms the outer surface of the shaft, and thus the shaft arrangement, consisting of, for example, leather, fabric, plastic or any other known material, or a combination thereof, and typically consists of a material that is water vapor permeable . The lower end portion on the sole side of the shaft outer surface forms a region in contact with the upper end portion of the sole or the sole unit, or a region above the boundary surface between the shaft and the sole or the sole unit.

Mounting sole (insole):
The mounting sole forms part of the shaft bottom. The lower region of the shaft end on the sole side is fixed to the mounting sole.

Sole:
A shoe has at least one outsole, but may have multiple types of sole plies that overlap each other to form a sole unit.

Outsole:
The outsole is the part of the sole area that touches the floor / ground or is primarily in contact with the floor / ground. The outsole has at least one ground plane in contact with the floor.

Intermediate sole:
If the outsole is not directly attached to the shaft arrangement, an intermediate sole can be inserted between the outsole and the shaft arrangement. The intermediate sole serves, for example, as a cushion, cushion, or filler.

Booty:
The bootie is a sock-type inner liner with a shaft arrangement. The booties form a pouch-type liner with a shaft arrangement that essentially completely covers the interior of the footwear.

Functional layer:
A waterproof and / or water vapor permeable layer, such as a membrane or a suitably treated or finished material, such as a plasma-treated fabric. A functional layer in the form of a shaft bottom functional layer can form at least one layer of the shaft bottom of the shaft arrangement, but may additionally be provided as a shaft functional layer that at least partially lining the shaft. Not only the shaft functional layer but also the shaft bottom functional layer may be part of a multilayer stack of usually two, three or four membranes. Each of the shaft functional layer and the shaft bottom functional layer may be part of a functional layer bootie. When a shaft functional layer and a separate shaft bottom functional layer are used instead of the functional layer booties, for example, in the lower region on the sole side of the shaft arrangement, they are sealed with water resistance. The shaft bottom functional layer and the shaft functional layer can be formed of the same or different materials.

  Suitable materials for the waterproof water vapor permeable functional layer include, among others, polyurethanes, polypropylenes and polyesters and polyethers containing the polyether esters described in US Pat. No. 4,725,418 and US Pat. No. 4,493,870. It is a laminate. In one embodiment, the functional layer is made of microporous expanded polytetrafluoroethylene (ePTFE), for example as described in US Pat. No. 3,953,566 and US Pat. No. 4,187,390. In one embodiment, the functional layer is comprised of expanded polytetrafluoroethylene and / or a hydrophilic layer with a hydrophilic saturant added (see, for example, US Pat. No. 4,194,401). The microporous functional layer is a functional layer having an average pore size of about 0.2 μm to 0.3 μm.

Laminate:
The laminated body is usually an aggregate composed of a plurality of layers adhered to each other and fixed to give durability. In the case of a functional layer laminate, the waterproof water vapor permeable functional layer is provided with at least one fabric ply. At least one fabric ply serves primarily to protect the functional layer during its processing. This is referred to as a two-ply laminate. The three-ply laminate includes a waterproof water vapor permeable functional layer embedded between two fabric plies. The fixing between the functional layer and the at least one fabric ply is for example performed by a continuous water vapor permeable layer of adhesive or a discontinuous layer of water vapor impermeable adhesive. In one embodiment, the adhesive may be applied in a dotted pattern between the functional layer and the fabric ply, or both. The reason for applying the adhesive in a dotted or discontinuous manner is that there is a possibility that the water vapor permeability of the functional layer may be hindered by the uniform layer of the water vapor impermeable adhesive itself.

Barrier layer:
The barrier layer is a barrier that prevents intrusion into a layer of material to be protected, in particular in the form of particles such as pebbles or foreign bodies, more specifically a structurally sensitive functional layer or functional layer film. As a role.

Reference: European standard EN344-1, especially chapter 43.3 (Intrusion resistance)

Waterproof:
If the functional layer / functional layer laminate / membrane is properly stitched, the functional layer / functional layer laminate / membrane is considered waterproof if it guarantees an injection water pressure of at least 1 × 10 ⁴ Pa. . Preferably, the material of the functional layer ensures an injection water pressure of 1 × 10 ⁵ Pa or more. The injection water pressure is measured by the following test method. Distilled water at 20 ± 2 ° C. is added to the 100 cm ² functional layer sample while gradually increasing the pressure. The water pressure rise is 60 ± 3 cm water pressure head per minute. The injection water pressure is the pressure when water first appears on the opposite side of the sample. Detailed procedures are mandated by ISO Standard 0811; 1981 edition.

  The waterproofness of a shoe may be tested using, for example, a class of centrifuges described in US Pat. No. 5,329,807.

Water vapor permeability:
When the water vapor transmission ratio is 150 m ² * Pa * W-1 or less, the functional layer / functional layer laminate is considered to have water vapor permeability. Water vapor permeability is performed according to the Hohenstein skin model. This test method is described in DIN EN 31092 (02/94) and ISO 11092 (1993).

Embodiments shown as examples of the present invention will be described more specifically with reference to the accompanying drawings.
FIG. 1 is a cross-sectional view of the forefoot region of the first shoe of the first embodiment of the present invention shown by way of example. FIG. 2 is a cross-sectional view of the forefoot region of the second shoe of the embodiment shown as further illustrative of the present invention. FIG. 3 is a cross-sectional view of a portion of the shaft bottom functional layer laminate at the shaft bottom in the shaft arrangement of FIG. 1. FIG. 4 is a cross-sectional view of the forefoot region of the third shoe of the embodiment shown as an example of the present invention. FIG. 5 is a cross-sectional view of the forefoot region of the fourth shoe of the embodiment shown as further illustrative of the present invention. FIG. 6 is a cross-sectional view of the forefoot region of the fifth shoe of the embodiment shown as further illustrative of the present invention. FIG. 7 is a cross-sectional view of the forefoot region of the sixth shoe of the embodiment shown as an example of the present invention. FIG. 8 is a schematic view of the shaft arrangement of the third shoe shown as an example in FIG. 4 as viewed from below. FIG. 9 is a schematic view of the shaft arrangement of the third shoe shown as an example in FIG. 4 as viewed from below. FIG. 10 is a schematic view of the shaft arrangement of the third shoe shown as an example in FIG. 4 as viewed from below. FIG. 11 is a schematic view of the shaft arrangement of the third shoe shown as an example in FIG. 4 as viewed from below. 12 is a cross-sectional view of the suction member shown as an example in FIG.

  Hereinafter, all the shoes of the examples described as examples have a sole unit and a shaft arrangement fixed thereto. In the exemplary embodiment described below, the sole unit is bonded to the shaft arrangement. Similarly, the sole unit can be sandwiched between shaft arrangements.

  The following description is given as an outline, and dimensions and sizes are not necessarily the same as those in reality.

  FIG. 1 is a cross-sectional view of the front foot region of the first shoe 2 of the first embodiment of the present invention shown as an example.

  The first shoe 2 includes a sole unit 4 and a shaft arrangement 22, both of which are joined together and do not move.

  The shaft arrangement 22 includes a shaft bottom 34 and a shaft region 23 joined at the peripheral end thereof, and the left and right sides of the shaft portion shown in FIG. For the sake of brevity, the upper portion of the shaft region 23 is not shown in this and the following figures.

  The shaft region 23 includes a water vapor permeable outer ply 24 and a shaft functional layer laminate 26 consisting of a net-like band or mesh 28, a shaft functional layer or shaft membrane 30 and a shaft liner 32 from the outside to the inside.

  The lower end region on the sole side of the outer ply 24 is curved inward with respect to a basically vertical portion, and is fixed to the multi-layer shaft bottom 34 with a durable adhesive 44.

  The multi-layer shaft bottom 34 comprises, from top to bottom, a mounting sole or insole 36, a shaft bottom functional layer laminate 38 having a shaft bottom functional layer 40 and a lowermost support fabric ply 42 disposed thereunder. Further, the attachment sole 36 is coupled to the peripheral end portion thereof by a seam 46, for example, Strobel stitch or zigzag stitching, in the sole side end region of the shaft functional layer laminate 38.

  Thus, the shaft bottom functional layer laminate 38 is configured as a two-layer laminate. As can be easily seen from FIG. 1, the shaft bottom functional layer can be connected to the sole side end region of the shaft functional layer laminate 26 and the outer ply 24 while the mounting sole 36 is waterproof by adhesion, for example. The laminate 38 has a greater lateral width than the mounting sole 36.

  The lower end region on the sole side of the outer ply 24 is permanently bonded to the bottom surface of the peripheral end portion of the shaft bottom functional layer laminate 38 by a durable adhesive 44.

  The lower end region on the sole side of the shaft functional layer laminate 26 is raised from the lower end region on the sole side of the outer ply 24. As a result, a space is created between the shaft functional layer laminate 26 and the surface ply 24 at the end of the shaft region 23, and the surface ply 24 is expanded toward the end of the shaft region 23.

  The shaft bottom functional layer laminate 38 slightly extends into this space. This space, which is not occupied by the end region of the shaft bottom functional layer stack 38, is usually filled with air or water vapor or a mixture thereof.

  Further, the bottom surface of the sole side end region of the shaft functional layer laminate 26 surrounds the seam 46 on the upper side of the peripheral end portion of the shaft bottom functional layer laminate 38 by the sealing adhesive 48 or the seam (46). In the case where not only the waterproofness but also the water vapor permeable functional layers 26 and 38 are used, the entire water vapor permeable shaft arrangement is waterproofed.

  This sealing adhesive 48 functions to seal two functional layers that penetrate the net-like band 28 and are relatively separated from each other, and fix and seal the shaft bottom functional layer laminate 38 to the shaft functional layer laminate 26. As it does, no other adhesive is required.

  The sole unit 4 is assembled with a lower end region on the sole side of the outer ply 24 and is fixed by a sole adhesive applied at least above the peripheral end region of the sole unit 4. In the illustrated embodiment, the first sole adhesive layer 20 is applied to the upper side of the peripheral end region of the sole unit 4, and the second sole adhesive layer 50 is the lower end portion on the sole side of the outer ply 24. Applied to the area.

  The sole unit 4 forms an outer region that surrounds the sole unit 4, extends somewhat upward in the outer direction, forms a region for accommodating the curved region of the outer ply 24, and has a central notch upward. , A support bar ply 8, a barrier layer 16, and a comfort ply 10 having a comfort bar above the barrier layer 16.

  As can be easily seen from FIG. 1, the adhesive layer 20 extends over the upper side of the sole ply 6 and the upper side of the comfort bar of the comfort ply 10. This is only the region of the right side portion of the sole ply 6 below the right end portion of the shaft bottom functional layer laminate 38, the comfort bar portion of the adjacent comfort bar ply 10, and the comfort bar ply 10 is composed of an adhesive layer. It may be formed without using 20.

  FIG. 1 shows a support bar of three support bar plies 8 and a comfort bar of three comfort plies 10, but the comfort ply 10 is configured somewhat wider than the support bar located below it. Yes. Furthermore, the comfort ply 10 includes a narrow comfort bar portion starting from the inside of the sole ply 6.

  The bottom surfaces of the sole ply 6 and the support bar ply 8 form a running surface, that is, a ground contact surface 14. In order to make the sole ply 6 having the support bar 8 water vapor permeable and / or air permeable, a notch, that is, an opening 12 of a sole ply through hole is formed between the support bars of the support bar ply 8.

  The sole ply 6 may be one piece or more than two pieces in different colors, as shown.

  The opening 12 of the through hole of the sole ply is made as large as possible so that the water vapor permeability of the sole ply 6 having the support bar 8 and the sole unit 4 is high.

  The sole unit 4 is provided with a barrier layer 16 as a structural protection so that the shaft bottom functional layer laminate 38 is not damaged by foreign matters such as pebbles biting into the opening 12 of the through hole of the sole ply, for example. . The barrier layer 16 extends slightly into the sole ply 6, and is thereby fixed to the sole ply 6 and is durablely connected. In one embodiment, the barrier layer 16 is made of a fibrous material hardened by heat, and may be additionally formed as a stable material in the sole unit 4.

  The support bar ply 8 and the comfort ply 10 are made of a different material from the sole ply 6 as shown by different diagonal lines in terms of reducing the weight of the sole unit 4, increasing the cushioning of the sole, or both. Also good. Alternatively, the support bar ply 8, the comfort ply 10 and the sole ply 6 may be made of the same material.

  More specifically, the material of the support bar ply 8 and the comfort ply 10 may be selected to be softer than the material of the sole ply 6. Ethylene vinyl acetate (EVA) is an example of a suitable material for one support bar ply 8 and / or comfort ply 10 if good sole cushioning is obtained. In the case where weight reduction can be obtained with respect to the material of the sole ply, a foamed plastic having a correspondingly small specific gravity is suitable. For example, foamed ethylene vinyl acetate (EVA) is suitable if both sole cushioning and weight reduction are improved in terms of sole ply material. There are many materials available.

Under the barrier layer 16, there is optionally provided a decorative ply 18 that can be seen from the back side to give the sole unit an attractive appearance.

  FIG. 2 shows a cross-sectional view of the forefoot region of the second shoe 52 of the second exemplary embodiment of the present invention.

  Like the first shoe 2, the second shoe 52 also comprises a sole unit 54 and a shaft arrangement 70, and is in a state that does not move to connect with each other. The shaft arrangement 70 is made according to the principle of booties, and comprises a shaft region 71 connected to the shaft bottom 80 and the former peripheral end, and the left and right sides of the shaft portion shown in FIG.

  The shaft region 71 includes a water vapor permeable outer ply 72, a three-layer shaft functional layer laminate 74 comprising an inner shaft liner 78, an outer shaft functional layer membrane 76 and a lattice woven fabric or mesh 75.

  The surface ply 72 of the shaft region 71 extends somewhat longer in the direction of the shaft bottom 80 from the shaft functional layer laminate 74. The shaft functional layer laminate 74 is connected to the shaft bottom functional layer laminate 84 of the shaft bottom 80 by stitches, more specifically, zigzag stitching. The seam 90 is sealed using a seam seal tape 92 so as to be waterproof to the outside.

  Similar to the shaft functional layer laminate 74, the shaft bottom functional layer laminate 84 has a two-layer structure including an inner support textile ply 88 and an outer shaft bottom functional membrane 86. The functional layers 76 and 86 and the fabric plies 78 and 88 of the shaft functional layer laminate 74 and the shaft bottom functional layer laminate 84 are sewn together so that the fabric plies 78 and 88 and the functional layers 76 and 86 are continuous.

  In the drawing of FIG. 2, it is depicted that the outer surface of the shaft functional layer 76 and the inner surface of the outer ply 72 are separated, but in practice these surfaces can be directly adjacent to each other.

  Surrounded by the outer ply 72 of the shaft region 71 and sewn to the sole side end region of the outer ply 72 is an attachment sole or insole 82, which is disposed under the shaft bottom functional layer laminate 84, Compared to this, it has a somewhat smaller width. The seam 94 between the sole side end region of the outer ply 72 and the peripheral end region of the attachment sole 82 can be specifically performed as Strobel stitch or zigzag stitch.

  Similar to the sole unit 4 of the first shoe 2, the sole unit 54 of the second shoe 52 is pre-assembled and fixed to the lower end region on the sole side of the outer ply 72. At least the upper side of the region is fixed to the lower edge region on the sole side of the mounting sole 82 with the adhesive of the sole.

  In the illustrated embodiment, the first sole adhesive layer 68 of the sole unit 54 is applied on the upper side of the peripheral edge region, and the second sole adhesive layer 96 is formed on the lower end of the outer ply 24 on the sole side. And the lower edge region on the sole side of the mounting sole 82.

  Similar to the sole unit 4, the sole unit 54 forms a cover for the outer region of the sole unit 54. From the bottom to the top, a support bar ply 58 having three support bars illustrated in FIG. 2 and a barrier layer 64 are disposed. And a sole ply 56 having a central notch. The barrier layer 64 horizontally traverses the sole unit 4 and extends so that the peripheral end region reaches the upper end of the sole ply 56. Thereby, the barrier layer 64 is reliably connected to the sole ply 56. The support bar extends from the barrier layer 64 to the bottom surface of the sole ply 56, and the bottom surface of the sole ply 56 and the bottom surface of the support bar 58 form a running surface, that is, a ground contact surface 62. Unlike the sole unit 4 of the first shoe 2, the sole unit 54 does not include a comfort ply, but can be added as necessary.

  An optional decoration ply 66 provided below the barrier layer 64 corresponds to the decoration ply 18 of the first sole unit 4.

  In the case of the shaft arrangement 22 of the first shoe 2 shown in FIG. 1 and the case of the shaft arrangement 70 of the second shoe 52 shown in FIG. 2, the shaft bottom functional layer laminates 38 and 84 each have a two-layer structure. It has only a single shaft bottom functional layer 40, 86 and support textile plies 42, 88 and no other layers. In the embodiment shown in FIGS. 1 and 2, a net-like band, or net material, often referred to as a mesh, is omitted.

  Especially at the shaft bottoms 34, 80, the sweat that occurs on the soles of the feet and has to be removed is maximized. In addition, at the bottom of the shaft bottoms 34, 80 are the largest holes in the form of notches 12, 60, respectively, which maximizes the ability to remove moisture at this location.

  The inventors of the present invention have found that the additional third layer of the shaft bottom functional layer stack 38, 84 is not required in this part, and the shaft functional layer stack 38, 84 has a two-layer structure in this region. I found it good. As a result, the cost for the third layer can be reduced, and the amount of sweat removed can be increased by eliminating the third layer. By eliminating the third layer of the shaft bottom functional layer laminate, the moisture barrier problem due to moisture is solved.

  Nevertheless, surprisingly, even if there is no extra ply, for example, a net-like band, a waterproof connection is possible.

  In the shaft arrangement 22 of the first shoe 2 shown in FIG. 1, it is arranged directly above the notch 12 of the two-layer shaft bottom functional layer laminate 38, and in particular effectively removes moisture from the inside of the shaft arrangement 22. be able to. In the shaft arrangement 70 of the second shoe 52 shown in FIG. 2, a two-layer shaft bottom functional layer laminate 84 is additionally arranged at the bottom of the mounting sole 82 and moisture needs to pass through it further.

  FIG. 3 shows a cross section of a portion of the two-layer shaft bottom functional layer stack 38 of the shaft bottom 34 of the shaft arrangement 22 of FIG.

  It can be readily seen that the lowermost support fabric ply 42 and the relatively thin shaft bottom functional layer 40 form a virtual membrane.

  FIG. 4 shows a cross-sectional view of the forefoot region of a third shoe 98 according to a further exemplary embodiment of the present invention.

  The third shoe 98 includes a shaft arrangement 100 corresponding to the shaft arrangement 22 of the first shoe 2 that includes the same sole unit 4 as the sole unit 4 of the first shoe 2 of FIG. 1 and a suction member 102 as an additional member. including.

  The same members of the third shoe 98 as the members of the first shoe 2 are indicated using the same reference symbols.

  The suction tape 102 extends from the space between the outer net band 28 of the shaft functional layer laminate 26 and the inside of the outer ply 24 and above the outer side of the shaft arrangement 100 under the support fabric ply 42. The suction member 102 includes a moisture-absorbing material such as cotton, and can draw liquid water or water vapor and carry it outside.

  The suction member 102 illustrated in FIG. 4 extends from the space between the shaft functional layer laminate 26 and the lowermost surface ply 24 of the vertical portion where the shaft region 23 does not move to a substantially central region below the support fabric ply 42. . The suction member 106 is placed in a space between the shaft functional layer laminate 26 and the inside of the outer ply 24 along the above-described region, and passes through the durable bonding portion 44 through the same curved path as the outer ply 24. Then, it extends to the central region at the bottom of the shaft bottom functional layer laminate 38. The suction member is placed and bonded directly onto the support fabric ply 42 of the shaft bottom functional layer laminate 38 with a part thereof under the shaft bottom functional laminate 38, and the shaft functional layer laminate 26 together with the space side portion. Alternatively, it may be bonded to the outer ply 24. For this purpose, the suction member 102 can also be provided with a suitable adhesive thereon.

  The inventors of the present invention normally collect moisture in the space at the end of the shaft region 23 between the shaft functional layer laminate 26 and the outer ply 24, and as a result, despite the waterproofness of the functional layer laminate. This creates a feeling of coldness in the feet in the shaft arrangement 100, impairs the function of transporting moisture from the inside to the outside, adversely affects the air permeability of the shaft arrangement 100 in this region, and causes moisture stains on the outer surface 24. It was found that this could happen.

  The suction member 102 sucks up such moisture and transports it to the area of the suction member 102, particularly outside the shaft arrangement 100 according to FIG. 4 and further outside the shaft arrangement 100 and below the shaft bottom functional layer stack 38. From there, the moisture is carried further down through the notch 12.

  This prevents the foot from feeling cold in the end region of the shaft functional layer laminate 26, ensures air permeability of the shaft arrangement 100 in this region, and prevents moisture stains from appearing on the outer surface 24. .

  As a result, the right side portion of the sole ply 6 which is located under the right end portion of the shaft bottom functional layer laminate 38 and is in contact with the comfort bar of the comfort bar ply 10 without using the adhesive ply 20 is used. Depending on the region, it is possible to further remove moisture from the suction member 102 in the downward direction through the notch 12.

  FIG. 5 shows a cross-sectional view of the forefoot region of a fourth shoe 104 according to an embodiment shown as a further illustration of the present invention.

  The fourth shoe 104 includes a shaft arrangement 100 of the third shoe 98 and a sole unit 54 of the second shoe 70, and the same members are denoted by the same reference numerals.

  In this configuration, the position and function of the suction member 102 are the same as those of the suction member 102 of the third shoe 98.

  In the case of the fourth shoe 104, the moisture is removed from the space between the shaft functional layer laminate 26 and the outer ply 24, particularly out of the region below the shaft bottom functional layer laminate 38 and further through the notch 60. To be carried to.

  In order to make the shaft arrangement 100 shown in FIGS. 4 and 5, before the sole side end region of the outer ply 24 is fixed inside the shaft functional layer laminate 26 together with the shaft bottom functional layer 38, the suction member 102 is The bottom functional layer laminate 38 is adhered from below with an adhesive (not shown).

  The durable adhesive does not interfere with the suction function of the suction member 102.

  FIG. 6 shows a cross-sectional view of the forefoot region of a fifth shoe 106 according to an embodiment of the present invention that is further illustrated.

  The fifth shoe 106 comprises a sole unit 54 of the second shoe 52 and a shaft arrangement 108 made in the same manner as the shaft arrangement 70 of the second shoe 52 in accordance with the booty principle.

  The shaft arrangement 108 corresponds to the shaft arrangement 70 of the second shoe 52 in FIG. 2, and the shaft functional layer laminate 116 has a three-layer structure, and from the outside to the inside, the net-like band 118, the shaft functional layer or the membrane 120 and a shaft liner 122.

  The shaft bottom functional layer laminate 128 has a three-layer structure over the entire region of the shaft bottom 124, and has a net-like band 118, a shaft bottom functional layer or membrane 130, and a supporting fabric ply 132 from the bottom to the top. The net band or mesh 118 is partially depicted in the figure.

  The shaft bottom functional layer laminate 128 is bonded to the upper side of the mounting sole 126 with a water vapor permeable layer of adhesive 134. A layer of adhesive extends from the left end region of the mounting sole 126 to the right end region. The layer of adhesive 134 penetrates through the net material 118 to the shaft bottom functional layer 130 where the layer of adhesive 134 is passed as a continuous layer of water vapor permeable adhesive or through which water vapor passes. It can be formed as a dotted layer of adhesive. The adhesive layer is intended to prevent friction between the mounting sole 126 and the shaft bottom functional layer 130. The shaft bottom functional layer laminate 128 and the fabric ply 132 in contact with the foot are secured to the mounting sole 126.

  The suction member 144 is accommodated in a space between the three functional layer laminates and the attachment sole 126, that is, the surface ply 114.

  The suction member 144 is preferably made of cotton material and is located in a region located slightly further to the right of the middle of the mounting sole 126 from the lower end of the right shaft region 112 and attached to the shaft bottom functional layer laminate 128. It extends into the space between the soles 126.

  The suction member 144 carries moisture that collects in the space between the outer ply 114 and the shaft functional layer laminate 116 to a region below the shaft bottom functional layer laminate 128, and from there, the permeable mounting sole 126 and It is carried to the outside of the shoe through the barrier layer 64 and brings about the above effects.

  The position of the suction member 144 shown in FIG. 6 is shown as an example, and by its nature, the suction member 144 is arranged mirror-symmetrically with respect to the suction member 144 on the shaft arrangement 108.

  FIG. 7 shows a cross-sectional view of the forefoot region of a sixth shoe 146 according to a further illustrative embodiment of the present invention.

  The sixth shoe 146 includes the sole unit 54 and the shaft arrangement 147 of the second shoe 52.

  The shaft arrangement 147 includes a shaft bottom portion 160 and a shaft region 148 connected to the shaft bottom portion 160 at the former peripheral end, and FIG. 7 shows left and right shaft portions that are mirror-symmetric with respect to each other.

  The outer ply 150 in the shaft region 148 curves inward at the lower end and is joined to the mounting sole 162 with a durable adhesive 176.

  The shaft arrangement 147 is made by a booty method. That is, the lower end portion of the shaft functional layer 153 is sewn to the peripheral end portion of the shaft bottom functional layer 164 by, for example, zigzag sewing. In addition, the transition is sealed to the outside using a seam sealing tape 174 to provide water resistance. In the embodiment illustrated in FIG. 6, these seams are located at the curved transition between the longitudinal shaft region 148 and the transverse shaft bottom 160.

  Both shaft functional layer 152 and shaft bottom functional layer 164 are outer net band 154, shaft functional layer / shaft bottom functional layer or shaft membrane / shaft bottom membrane 156/166, and inwardly disposed fabric ply or shaft liner. 158 / supporting fabric ply 168 has a three-layer structure.

  Similar to the first shoe 2, in the sixth shoe 146, a space extends between the end region of the outer ply 150 and the shaft bottom functional layer laminate 164 or the shaft functional layer laminate 152. This space increases in size toward the end of the outer ply 150 and the mounting sole 162 extends to this space. A portion of this space is not occupied by the mounting sole 162 and is usually filled with air or water vapor or a mixture thereof.

  As in the case of the third shoe 98 shown in FIG. 4, the sixth shoe 146 also extends from the space between the shaft functional layer laminate 152 and the outer ply 150 to the lower side of the sealing adhesive 174, and the adhesive 176 A suction member 180 is provided that extends below the mounting sole 162 to the outside of the shaft arrangement 146 via the.

  The space-side end of the suction member 180 extends from the vertical portion of the shaft region that does not move through the sealing adhesive 174 to form a curve, and is placed on the bottom surface of the mounting sole 162. The outer region of the suction member 180 may be adhered to the bottom surface of the mounting sole 162 by, for example, an adhesive layer.

  The suction member 180 is embedded in the sealing adhesive without greatly impairing the suction effect.

  The suction member 180 carries moisture outward from the space. This moisture can be further removed from the bottom surface of the mounting sole 162 through the plurality of notches 60 of the sole unit 54.

  The shaft bottom functional layer laminate 164 is bonded to the mounting sole 162 by a layer of water vapor permeable adhesive 170. The layer of adhesive 170 may be made continuous or punctied in the embodiment shown as an example in FIG. 7, but covers most of the surface of the mounting sole 162 and through the net material 154 through the shaft. It penetrates to the bottom functional layer 166. The layer of adhesive 170 is water vapor permeable so as to ensure air permeability at this portion. This ensures that the shaft bottom functional layer laminate 164 is fixed to the mounting sole 162 at this portion.

  FIG. 8 shows a schematic view of the shaft arrangement 100 as viewed from below.

  The lower peripheral edge of the shaft arrangement 100 is formed and the end region of the outer surface 24 placed on the bottom surface of the mounting sole 42 can be easily seen. Similarly, the end of the suction member embodied as a suction tape 184 can be readily seen. The suction tape 184 carries moisture to the outside from the space between the shaft functional layer laminate and the surface ply.

  In the illustrated example, the ends of eight narrow width suction tapes 184 are shown and are positioned along the peripheral ends of the outer ply 24. By arranging the plurality of suction tapes 184 along the entire circumference of the outer ply 24, moisture can be reliably removed from the space between the shaft functional layer and the outer ply in the entire peripheral area of the shaft arrangement.

  Such an arrangement of suction tape 184 will find utility in all of the other shaft arrangements described above.

  FIG. 9 shows another embodiment illustrating the shaft arrangement 100 of the third shoe 98 as viewed from below.

  Here, only one suction tape 186 is provided in the forefoot region of the shaft arrangement 100 and extends slightly below the mounting sole 42. This suction tape 186 carries moisture from the space between the outer ply and the shaft functional layer laminate to the outside, and one such suction tape 186 is sufficient to sufficiently remove moisture.

  FIG. 10 shows another embodiment, shown by way of example, of the shaft arrangement 100 of the third shoe 98 viewed from below.

  Here, instead of a suction tape having a relatively narrow width, a sheet-like suction member 188 surrounding the half of the side is provided, and the surface ply and the shaft functional layer laminate are formed in the entire region and the center region of the front foot of the shoe. Moisture is carried from the space between the bottom of the mounting sole 42, and the moisture exits from the shoe downward from there.

  FIG. 11 shows an embodiment showing the shaft arrangement 100 of the third shoe 98 as an example viewed from below.

  Here, a total of four suction tapes 190 are provided, extending across the entire bottom surface of the mounting sole 42 in the direction of crossing the shoe, and the left and right end portions of the outer ply and the shaft functional layer laminate, respectively. It extends into the space between. In the present embodiment shown as an example, four suction tapes 190 are arranged at equal intervals in the length direction of the shaft arrangement 100.

  By the arrangement of the suction tape, moisture can be reliably removed from the space between the outer ply and the shaft functional layer laminate in the same manner.

  FIG. 12 is a cross-sectional view of the suction member 102 according to the embodiment shown as an example of the present invention.

  The suction member 102 is made of, for example, a liquid sucking material layer 192 made of a cotton material, and reliably moves the liquid from the space to the outside. The suction layer has an adhesive material 194 applied to the top surface thereof, so that the suction member 102 can be adhered to, for example, the bottom surface of the mounting sole 42 and the inside of the shaft functional layer laminate. This adhesive need not be applied to the entire top surface of the suction layer 192. It is sufficient to apply this adhesive in some places.

Claims (10)

A shaft bottom (34) having a water vapor permeable mounting sole (36) and a shaft bottom functional layer laminate (38);
A shaft arrangement (22) for footwear (2) comprising a surface region ply (24) and a shaft region (23) having a shaft functional layer laminate (26),
The sole shaft end region is connected to the shaft bottom (34);
Shaft arrangement (22) for footwear (2), characterized in that the shaft bottom functional layer laminate (38) has a two-ply structure.   The shaft arrangement (22) of claim 1, wherein the two-ply shaft bottom functional layer laminate (38) comprises a shaft bottom functional layer (40) and a supporting fabric ply (42).   3. Shaft arrangement (22) according to claim 2, characterized in that the shaft bottom functional layer (40) is arranged between the supporting fabric ply (42) and the water vapor permeable mounting sole (36).   The shaft arrangement (22) according to any one of claims 1 to 3, wherein the shaft functional layer laminate (26) has a three-ply structure.   The water vapor permeable mounting sole (36) is sewn to the sole side end region (26) of the shaft functional layer laminate and / or the inside of the sole side end region of the outer ply (24) is the shaft bottom function. The shaft arrangement (22) according to any one of claims 1 to 4, characterized in that it is supported by a layer stack (38).   6. Shaft arrangement (22) according to claim 5, characterized in that the water vapor permeable mounting sole (36) is arranged on the shaft bottom functional layer stack (38).   The sole side end region (74) of the shaft functional layer laminate is connected to the shaft bottom functional layer laminate (84) with waterproofness, and the mounting sole (82) is connected to the shaft bottom functional layer laminate (84). The shaft arrangement (70) according to any one of claims 1 to 4, characterized in that it is arranged at the lower part of the shaft.   8. Shaft arrangement (70) according to claim 7, characterized in that the sole side end region of the outer ply (72) is sewn to a water vapor permeable mounting sole (82).   The shaft arrangement according to claim 7, wherein an inner side of a sole side end region of the outer ply is supported by a mounting sole.   It has at least one shaft arrangement (22) according to any one of claims 1 to 9, a sole unit (4) fixed to the bottom surface, and at least one through-hole opening or porosity. In particular, the footwear (2) is characterized in that the sole unit (4) is bonded or sandwiched between the bottom surfaces of the shaft arrangement (22).

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