阅读说明：本技术 带有具有热塑性材料的内层的针织部件及相关方法 (Knitted component with inner layer having thermoplastic material and related method ) 是由 阿德里安·梅厄 于 2020-05-29 设计创作，主要内容包括：一种制造针织部件(100)的方法可以包括以下步骤中的一个或多个：在针织机上针织第一针织层(104)和第二针织层(112),其中第一针织层(104)和第二针织层(112)各自包括多个相互穿套的线圈,并且其中第一针织层(104)的至少一个线圈与第二针织层(112)的至少一个线圈相互穿套；在针织第一针织层(104)和第二针织层(112)期间,在第一针织层(104)与第二针织层(112)之间嵌入嵌入股线(120),其中嵌入股线(120)包括具有熔点的热塑性材料；以及将热施加到嵌入股线(120)的热塑性材料的至少一部分,使得热塑性材料的该部分升高到等于或高于熔点的温度。(A method of manufacturing a knitted component (100) may include one or more of the following steps: knitting a first layer of knitting (104) and a second layer of knitting (112) on a knitting machine, wherein the first layer of knitting (104) and the second layer of knitting (112) each include a plurality of loops that are interlooped, and wherein at least one loop of the first layer of knitting (104) is interlooped with at least one loop of the second layer of knitting (112); embedding an inlay strand (120) between the first knitted layer (104) and the second knitted layer (112) during knitting of the first knitted layer (104) and the second knitted layer (112), wherein the inlay strand (120) comprises a thermoplastic material having a melting point; and applying heat to at least a portion of the thermoplastic material of the embedded strands (120) such that the portion of the thermoplastic material is elevated to a temperature at or above the melting point.)

1. A method of manufacturing a knitted component, comprising:

knitting the first knitted layer and the second knitted layer on a knitting machine,

wherein the first knitted layer and the second knitted layer each comprise a plurality of loops that are interlooped, and wherein at least one loop of the first knitted layer is interlooped with at least one loop of the second knitted layer;

embedding an inlaid strand between the first knit layer and the second knit layer during knitting of the first knit layer and the second knit layer, wherein the inlaid strand comprises a thermoplastic material having a melting point;

applying heat to at least a portion of the thermoplastic material of the embedded strand such that the portion of the thermoplastic material is elevated to a temperature at or above the melting point;

applying pressure to at least one side of the knitted component with a die press to form a molded shape; and

during or after the application of the pressure, cooling the portion of the thermoplastic material to a temperature below the melting point such that the molded shape remains on at least one side of the knitted component.

2. The method of claim 1, wherein the step of cooling the portion of the thermoplastic material is performed at least in part by the die press.

3. The method of claim 1, wherein the step of applying heat to the portion of the thermoplastic material is performed before the step of applying the pressure to the at least one side of the knitted component.

4. The method recited in claim 1, wherein during the step of applying the pressure to the at least one side of the knitted component, the die press includes a temperature less than the melting point.

5. The method of claim 1, wherein the portion of the thermoplastic material forms a barrier between the first knitted layer and the second knitted layer once the portion of the thermoplastic material is cooled, and wherein the barrier is water resistant or waterproof.

6. The method of claim 1, wherein at least one of the first and second knitted layers comprises a yarn having a melting point higher than the melting point of the thermoplastic material.

7. The method of claim 1, wherein at least one of the first and second knitted layers comprises a polyester yarn.

8. A method of manufacturing a knitted component, comprising:

knitting the first knitted layer and the second knitted layer on a knitting machine,

wherein the first knitted layer and the second knitted layer each comprise a plurality of loops that are interlooped, and wherein at least one loop of the first knitted layer is interlooped with at least one loop of the second knitted layer;

embedding an inlaid strand between the first knit layer and the second knit layer during knitting of the first knit layer and the second knit layer, wherein the inlaid strand comprises a thermoplastic material having a melting point;

applying heat to at least a portion of the thermoplastic material of the embedded strand such that the portion of the thermoplastic material is elevated to a temperature at or above the melting point; and

cooling the portion of the thermoplastic material to a temperature below the melting point such that a barrier is formed between the first and second knitted layers, the barrier being water resistant or waterproof.

9. The method of claim 8, further comprising: applying pressure with a die press to at least one side of the knitted component to form a molded shape when the portion of the thermoplastic material is above the melting point.

10. The method of claim 9, wherein the step of cooling the portion of the thermoplastic material is performed at least in part by the die press.

11. The method of claim 9, wherein the step of applying heat to the portion of the thermoplastic material is performed before the step of applying the pressure to the at least one side of the knitted component.

12. The method recited in claim 9, wherein during the step of applying the pressure to the at least one side of the knitted component, the die press includes a temperature less than the melting point.

13. The method of claim 8, wherein at least one of the first and second knitted layers comprises a yarn having a melting point higher than the melting point of the thermoplastic material.

14. The method of claim 8, wherein at least one of the first and second knitted layers comprises a polyester yarn.

15. A knitted component comprising:

a first knitted layer on a first side of the knitted component;

a second knitted layer on a second side of the knitted component opposite the first side, wherein the first knitted layer includes at least one stitch that interlinings with at least one stitch of the second knitted layer; and

a third layer formed between the first knitted layer and the second knitted layer, wherein the third layer comprises a thermoplastic material substantially contained between the first knitted layer and the second knitted layer.

16. The knitted component of claim 15, further comprising a molded shape on at least one of the first side and the second side of the knitted component.

17. The knitted component of claim 15, wherein at least one of the first knitted layer and the second knitted layer includes a yarn having a melting point higher than a melting point of the thermoplastic material.

18. The knitted component of claim 15, wherein at least one of the first knitted layer and the second knitted layer includes a polyester yarn.

19. The knitted component of claim 15, wherein the third layer forms a water-resistant or waterproof barrier between the first knitted layer and the second knitted layer.

20. The knitted component of claim 15, wherein the thermoplastic material of the third layer is provided via at least one inlaid strand that is inlaid between the first knitted layer and the second knitted layer.

Technical Field

The present disclosure relates generally to knitted components and methods of manufacturing knitted components, such as knitted components for use in footwear applications, apparel applications, and the like.

Background

The present disclosure relates generally to a knitted component having selected areas of macro texture and a method for forming a knitted component having selected areas of macro texture. The present disclosure also relates to an article of footwear having an upper made according to the present disclosure.

A variety of material elements (e.g., textiles, polymer foams, polymer sheets, leather, synthetic leather) are conventionally utilized in the manufacture of knitted articles such as knitted uppers. For example, in athletic footwear, the upper may have multiple layers that each include various joined material elements. For example, the material elements may be selected to impart stretch-resistance, cushioning, low-friction, wear-resistance, flexibility, air-permeability, compression, comfort, water-resistance, and moisture-absorption properties to various areas of the upper. Furthermore, material elements are typically joined in a layered configuration to impart multiple properties to the same region.

A wearer of an article of footwear may desire that the article of footwear function durably, be precisely shaped for wearer comfort, be decorative or aerodynamic, and be soft in texture for wearer comfort. Such users may seek to maximize these properties and characteristics. A number of construction techniques have been employed to achieve this result. Examples of such constructions include the use of multiple layers of soft materials for comfort, the use of waterproof or high tensile strength materials for durability, and articles of use for shape and labeling.

However, as will be appreciated by those skilled in the art, combining disparate materials in this manner can create additional steps and waste in the manufacturing process. Furthermore, there may be assembly and maintenance burdens on the layers or joints of material between the different materials of construction.

Accordingly, there is a need in the art for a method for manufacturing an upper for an article of footwear that minimizes the number of manufacturing steps while reducing raw material waste.

Drawings

In order that the disclosure may be well understood, various forms thereof will now be described, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of an outer surface of a knitted component having an implicit insert yarn;

FIG. 2 is an exploded view of the embedded yarn in the kit component;

FIG. 3 is a close-up representation of one possible knit structure of a portion of a knitted component having an embedded yarn;

fig. 4A-4D are perspective views of an example of a pressure die in which a knitted component may be placed for forming;

FIG. 5 is a perspective view of an exemplary pressure die and a partially exploded view of a knitted component placed on the pressure die prior to forming;

FIG. 6 is a cross-sectional view of the knit article in the pressure mold of FIG. 5 when the pressure mold is engaged;

FIG. 7 is a cross-sectional view of the knitted component showing in detail the first and second knitted layers and the low melt thermoplastic inner yarn of the knitted component and the pressure mold prior to the knitted component being positioned in the pressure mold;

FIG. 8 is a cross-sectional and partially exploded view of the application of heat to a knitted component having two knitted layers and a low melt thermoplastic inner yarn;

FIG. 9A is a cross-sectional view of the knitted component showing in detail the first and second knitted layers and the low melt thermoplastic inner yarn of the knitted component, and the pressure mold after heat is applied to the knitted component but before the knitted component is disposed in the pressure mold;

FIG. 9B is a cross-sectional view of the knitted component of FIG. 9A after the knitted component is disposed in the first variation of the pressure die and the pressure die is engaged;

FIG. 9C is a cross-sectional view of the knitted component of FIG. 9A after the knitted component is disposed in a second variation of the pressure die and the pressure die is engaged;

figure 9D is a cross-sectional view of the knitted component of figures 9A-9C after the cooled knitted component is released from the compression mold of figure 9C;

FIG. 9E is a perspective and partially exploded view of the knitted component of FIGS. A-D showing various macro-textures after pressure molding;

FIG. 9F is a perspective and partially exploded view of the reverse side of the knitted component of FIG. 9E;

FIG. 9G is a close-up perspective view of a section of the knitted component of FIG. 9E;

FIG. 10A is a cross-sectional view of a knitted component having first and second knitted layers and a low melt inner yarn before the knitted component is disposed in a slump mold;

FIG. 10B is a cross-sectional view of the knitted component of FIG. 10A after the knitted component is disposed in the slump mold;

FIG. 10C is a cross-sectional view of the knitted component of FIGS. 10A and 10B after the knitted component is released from the slump mold;

figure 11A is a cross-sectional view of a section of the knitted component after heating and molding showing a knitted layer of a first low melt yarn, a re-solidified region of a low melt thermoplastic inlay strand, and a knitted layer of a second low melt yarn, wherein the knitted layer of high melt yarn is in contact with the re-solidified region;

figure 11B is a cross-sectional view of a section of the knitted component after heating and molding showing a knitted layer of the first low melt yarn, a re-solidified region of the low melt thermoplastic inlay strand, and a knitted layer of the second low melt yarn, wherein the knitted layer of the high melt yarn, the knitted layer of the low melt yarn penetrate the re-solidified region;

FIG. 11C is a cross-sectional view of a section of the knitted component after heating and molding, showing a knitted layer of a first low melt yarn, a re-solidified region of a low melt thermoplastic inlay strand, and a knitted layer of a second low melt yarn, wherein the knitted layer of heat resistant yarn is included by the re-solidified region;

FIG. 12 is a top view of a knitted component upper for a shoe including a plurality of macro-textured areas;

fig. 13 is a perspective view of a finished shoe including the textured upper of fig. 12.

Detailed Description

While various embodiments of the disclosure have been described, the disclosure is not to be restricted except in light of the attached claims and their equivalents. Moreover, the advantages described herein are not necessarily the only advantages of the disclosure, and it is not necessarily expected that every embodiment of the disclosure will achieve all of the described advantages.

The present disclosure will be described in detail as relating to one or more regions of structural rigidity. Structural stiffness can be described or characterized as resistance to permanent deformation, similar to more traditional measures of material properties (resilience measures such as young's modulus), but specifically the ability of a component to retain or recover a given morphology of its macroscopic texture after loading. In the present disclosure, regions may be described as providing or having different stiffness, resilience, structure, structural rigidity, or bending resistance, for example. These and other words or phrases have substantially the same meaning in this disclosure and are indicative of or describe similar phenomena.

The low-melt thermoplastic yarn imparts a segmental structural rigidity to the heat-or pressure-treated knitted component by anchoring a plurality of knitted layers on the region where the treated low-melt thermoplastic yarn is treated. The treated low melt thermoplastic layer imparts a new macro texture to the anchored knit layer by softening the thermoplastic yarns and reforming the thermoplastic yarns into a new morphology or "macro texture". By anchoring the layers together, the treated section of the knitted component exhibits increased structural rigidity as compared to an untreated knitted component. Thus, the knitted component sections stiffened with the treated low melt thermoplastic yarn will resist permanent deformation of the new macro texture.

One aspect of the present disclosure relates to a method for producing an integrally formed knitted component 100 having selected areas of the macro texture 900 after heat or pressure treatment and a method for producing such a knitted component 100. Herein, "macro-texture" may be referred to as a shape or texture that extends through multiple layers of a textile such that it is discernable from both sides of the textile (e.g., opposite textile faces), while "micro-texture" is generally isolated from one textile face. In knitted component 100, first knit layer 104 including first high melt yarn 108 is located on an opposite side of knitted component 100 from second knit layer 112 including second high melt yarn 116. The first yarn 108 and the second yarn 116 form an interlocking knit structure within the knitted component 100 (e.g., such that one or more stitches forming the first knit layer 110 are interwoven with at least one stitch forming the second knit layer 112). Thus, a majority of the yarns present in the first knitted layer 104 are the first high melting yarn 108 and a majority of the yarns present in the second knitted layer 112 are the second high melting yarn 116, although due to the nature of the knitting process, a small amount of the first yarn 108 will be present in the second layer 112 (forming an interlocking weave) and a small amount of the second yarn 116 will be present in the first layer 112. Although any particular yarn may be used as first yarn 108 and/or second yarn 116, in certain exemplary embodiments, first yarn 108 and/or second yarn 116 may be composed primarily of polyester. Low melting thermoplastic inlay strands (spacer strands) 120 (which may be formed partially or entirely of thermoplastic material) are embedded in the courses of the interlocking knit layer and may extend the entire length of the knit layer or may only embed courses over selected portions of the knit layer. Notably, when referring to the embedded strands 120. The number and direction of the strands of low melt thermoplastic yarns are selected to produce a controlled structural stiffness after heat or pressure treatment to maintain the macro-texture 900. The low melt thermoplastic strands 120 are softened by applying heat or pressure to the knitted component 100.

In one aspect, the present disclosure provides a method for producing a knitted component 100 having selected areas of controlled stiffness after heat or pressure treatment. One such knitted component is depicted in fig. 1 and 2. According to the method, a knitted component 100 including high melting polymer yarns 108 is knitted. The low melt thermoplastic strands 120 are embedded in selected regions 128 of the knitted component 100 in an amount and direction sufficient to produce a controlled stiffness after processing. In another aspect, the knitted component can be formed of three or more knit layers and two or more low melt thermoplastic insert yarn layers.

In another aspect depicted in fig. 1 and 2, the present disclosure provides a method for knitting a knitted component 100 having a first selected area 128 of a first controlled stiffness after treatment and a second selected area 130 of a second controlled stiffness after treatment. According to the method, a knitted component 100 comprising a high melting point yarn 108 is knitted. The first low melt thermoplastic strands 120 are embedded in the first selected regions 128 of the knitted component 100 in an amount and direction sufficient to produce a first controlled stiffness after processing. Second low melt thermoplastic yarns 122 are embedded in second selected regions 130 of knitted component 100 in an amount and orientation sufficient to produce a first controlled stiffness after processing.

In another aspect depicted in fig. 4A-10C, the present disclosure provides a method for producing a knitted component 100 having a macro-texture 900 and selected areas of controlled stiffness after heat or pressure treatment.

One such knitted component 100 is depicted in fig. 9D and 9E. According to the method, a knitted component 100 including high melting polymer yarns 108 is knitted. The low melt thermoplastic strands 120 are embedded in selected regions 128 of the knitted component 100 in an amount and direction sufficient to produce a controlled stiffness after processing. The knitted component is treated to soften the low melt thermoplastic strands 120.

In one aspect, as depicted in fig. 8, the embedded strands 120 may be softened by applying heat to the knitted component 120. Knitted component 100 is heated to soften low melt thermoplastic strands 120. The knitted component may be heated by omnidirectional means (such as with steam, an oven, or equivalent), or by directional means (such as a hot surface, a heat gun, or equivalent). Depending on the crystallinity or general characteristics of the yarn, to soften the low-melt thermoplastic strands 120, the knitted component 100 may be heated to or above the melting point of the embedded yarn, to above the glass transition temperature of the embedded yarn, or to or above the softening point of the embedded yarn for a given processing pressure. When the softened embedded strands 120 are cooled to a temperature below their softening point, the material becomes set.

When the low melt thermoplastic yarn is softened, the knitted component is formed using a die press 400 (also referred to as a "die press") having macro-texture features 410. Notably, the die press 400 can be relatively cool (e.g., it can be maintained at room temperature) relative to the melting temperature of one or more yarns in the knitted component. The die press 400 generally has a top portion and a bottom portion. The die press may be of a clamshell design, where the top and bottom portions are hinged along one edge so that the knitted component can be inserted between the top and bottom portions, and the die press closes down on the knitted component 100. Alternatively, the top and bottom portions of the die press 400 may be two separate plates that are not otherwise connected. In this alternative design, the knitted component is positioned on top of the bottom portion of the die press 400, and then the top portion is positioned on top of the knitted component 100. The top portion may have similar dimensions as the bottom portion, or may be larger or smaller. Although the top and bottom portions are generally aligned such that the macro-texture features 410 on the bottom portion are aligned with the corresponding macro-texture features 410 on the top portion, there is no requirement. The top and bottom portions may have distinct macro-texture features 410, or the portions may be flat and therefore free of macro-texture features. As shown in fig. 4A-4D, the macro-texture features 410 on the die press 400 may be various shapes and patterns including, but not limited to, letters, words, phrases, numbers, logos, three-dimensional geometric designs, line drawings or sketches, signatures, or combinations of features.

As depicted in fig. 5 and 9B, after the knitted component 100 with softened low melt thermoplastic strands 120 is positioned in the molding press 400 and the molding press 400 is engaged, a sufficient amount of pressure is applied to the molding press 400 such that the softened low melt thermoplastic strands 120 deform and the knitted component 100 conforms to the macro-texture features 410 in the molding press 400. The amount of pressure will vary depending on the amount and temperature of the thermoplastic strands 120, the amount of penetration of the low melting thermoplastic strands 120 into the knit layers 204, 112, and like factors. In one embodiment, the inherent weight of the top portion of the die press will provide sufficient pressure to achieve the desired result, and no additional pressure is required. In another embodiment, additional pressure is applied to the stamp 410. As depicted in fig. 9C, the additional pressure may cause the low melt thermoplastic strands 120 to penetrate more into the knit layers 104, 112 than if only the inherent weight of the top portion of the die press were applied, as depicted in fig. 9C.

After knitted component 100 conforms to macro-texture feature 410, knitted component 100 is allowed to cool. This cooling allows the low melting thermoplastic strands 120 to transition from their softened state to their set state. Cooling may be achieved in a variety of ways, including but not limited to: allowing the knitted component to cool in the environment; cooling one of the two sections of the molding press 400 (and/or relying only on conduction through the molding press 400 when the molding press is below the melting temperature of the thermoplastic strands 120, such as at room temperature); exposing knitted component 100 to a fluid, including liquids and gases, having a temperature below the temperature of softened low melting thermoplastic strands 120; or otherwise. As depicted in fig. 9D, after the knitted component 100 with the low melting thermoplastic strands 120 has been set, the knitted component 100 is removed from the molding press 400.

In another aspect depicted in fig. 9E-9G, the present disclosure provides a method for producing a knitted component 100 having a macro-texture 900 and multiple selected areas of controlled stiffness after heat or pressure treatment. According to the method, a knitted component 100 including high melting polymer yarns 108 is knitted. The low melt thermoplastic strands 120 are embedded in selected regions 128 of the knitted component 100 in an amount and direction sufficient to produce a controlled stiffness after processing. Knitted component 100 is treated to soften low melt thermoplastic strands 120. When the low melt thermoplastic yarn is softened, the knitted component is formed using a die press 400 having a plurality of macro-texture features 410. A sufficient amount of pressure is applied to the molding press 400 such that the softened low melt thermoplastic strands 120 deform and the knitted component 100 conforms to the macro-texture features 410 in the molding press 400. After the low melt thermoplastic strands 120 of knitted component 10 have been set, knitted component 100 is removed from mold press 400.

In another aspect depicted in fig. 10A, knitted component 100 is heated to soften low melt thermoplastic strands 120 and positioned over a slump mold 1000 having macro-texture 1010. As depicted in fig. 10B, when the low melt thermoplastic strands 120 are softened, the knitted component is placed on the slump mold 1000. After the knitted component 100 cools such that the low melting thermoplastic strands 120 have set, the knitted component 100 is removed from the slump mold 1000, as shown in figure 10C.

In another aspect depicted in fig. 11A-11C, different amounts of low melt thermoplastic strands 120 or different amounts of pressure may be applied to the heated knitted component 100 in the joining die press 400 to achieve different levels of penetration of the low melt thermoplastic yarns into the knit layers 104, 112. Additional pressure applied to the cold press will allow the low melt thermoplastic strands 120 to penetrate the knit layer to a greater depth. This may result in negligible penetration of fig. 11A, significant penetration of fig. 11B, or complete penetration of fig. 11C as the amount of pressure is increased or the amount of time the pressure is applied is increased. Similarly, using a higher volume ratio of low-melt thermoplastic yarns to high-melt thermoplastic yarns will allow the low-melt thermoplastic yarns to penetrate into the knit layer at a greater depth, as depicted in fig. 11B and 11C. As the volumetric ratio of the materials increases, the low melt thermoplastic yarns may occupy a greater percentage of the empty space around the high melt yarns of the knit layer, allowing greater penetration.

When the thermoplastic strand 120 melts between the first layer 112 and the second layer 112, it may form a "third layer" consisting essentially of thermoplastic material, as shown in fig. 11B. When sufficiently melted, the third layer may form a water-resistant and/or water-resistant barrier between the first layer 112 and the second layer. Advantageously, the knitted component may include an outer surface having a knit texture (e.g., as is often desired in footwear due to its soft/comfortable surface characteristics and aesthetics) while also having desirable water-resistant properties. Further, it is contemplated that the thermoplastic material of the third layer may be primarily contained between the first layer 112 and the second layer 112 such that it is substantially absent from the outer surface of the knitted component.

The yarns used in the examples may be selected from monofilament and multifilament yarns formed of synthetic materials. The high melt polymer yarns 108, 116 may also be made of natural materials. Natural materials are not practical for low melt polymer yarns, as low melt polymer yarns must at least partially soften in order to be perfectly molded. Natural materials generally do not soften as do synthetic thermoplastics, but rather char; thus, the use of natural materials may limit the range of processing temperatures that may be used to ensure that knitted components are processed below the scorch temperature of the natural material. However, natural materials may be combined with the low melt thermoplastic yarns and used as the layer of low melt thermoplastic strands 120.

The low melt thermoplastic yarns 120 are typically synthetic polymeric materials formed from polymers that melt at relatively low temperatures (typically less than 150 ℃). The melting temperature of the low melt thermoplastic strands 120 may be sufficiently different from the melting temperature of the high melt polymer yarns 108, 116 such that the low melt polymer strands 120 may substantially completely melt without melting the high melt polymer yarns 108, 116 or adversely affecting the properties of the high melt polymer yarns 108, 116.

In some embodiments, the low melting polymer yarn has a melting temperature of less than about 115 ℃, typically less than about 110 ℃, and more typically less than about 100 ℃. Synthetic polymer yarns that may be suitable as low melting polymer yarns include TPU yarns, low melting temperature PET or low melting temperature nylon yarns. For example, a low melting temperature nylon, which may be nylon-6, nylon-11, or nylon-12, may have a melting point of about 85 ℃. In some embodiments, polyurethane and polypropylene yarns may be used. In some embodiments, Thermoplastic Polyurethane (TPU) yarns may be used.

By definition, high melting polymer yarns have a higher melting temperature than low melting thermoplastic yarns. The melting point of the high melting polymer yarn is typically greater than about 185 ℃, more typically greater than about 200 ℃, and even more typically greater than about 210 ℃. For example, nylon-6/11 has a melting point of at least about 195 ℃; nylon-6/10 has a melting point of about 220 ℃ and nylon-6/6 has a melting point of at least about 255 ℃. These and other high melting polymer yarns may be used.

The yarns may be of any color and may be transparent, translucent or opaque. These color and light properties and characteristics can be used to provide pleasing designs and color combinations. When the low-melt polymer yarn is softened, the softened yarn may partially or completely surround the high-melt polymer yarn. Thus, the colors of the yarns may be combined where the yarns overlap. Thus, examples of articles of footwear of the present disclosure may be transparent, translucent, or opaque, depending most strongly on the properties and characteristics of the low-melt polymer yarn. Softening the yarns generally does not change the color or light transmission properties of the resulting solid layer. In some embodiments, the color and light transmission properties may be selected to provide a selected effect.

For example, the yarns may be selected from yarns that meet design criteria, and may be made of different denier and substance compositions. Further, typically, the high-melt polymer yarns 108, 116 comprise a different polymer than the low-melt polymer yarns 120. More typically, the high melt polymer yarns 108, 116 will have a different material composition than the low melt polymer yarns 120. However, low melt polymer yarns made from low melt nylon may be used with high melt nylon yarns with a difference in melting temperature sufficient to ensure that only the low melt polymer yarns are melted when the knitted component is heated. In some embodiments, the composite material may be incorporated into knitted component 100 in one of the high melting point yarns 108, 116 or in the low melting point thermoplastic strands 120. Such composites typically include fibers in a binder.

Additionally, embedded strands 120 may be a composite material to provide additional properties to knitted component 100, such as strength, rigidity, elasticity, water resistance, and the like. The embedded strands 120 may comprise a material that is not a low melting thermoplastic. However, to maintain the properties of the knit layers 104, 112 (including the micro-texture of the knit layer 300), the knitted component 100 should not be heated above the scorch or softening temperature of either of the high melting polymer yarns 108, 116 making up the knit layer. The inlaid strand 120 may also include a plurality of strands and/or yarns 132. These multiple embedded strands 132 may have similar or different properties, although at least one of the strands may comprise a low melt thermoplastic material.

In another aspect depicted in fig. 12 and 13, a knitted component may be incorporated into an upper of a shoe or other wearable article. An article of footwear is depicted in fig. 13 as including a sole structure 1300 and an upper 1200. Although the article of footwear is illustrated as having a general configuration suitable for running, concepts associated with the article of footwear may also be applied to a variety of other athletic footwear types, including baseball shoes, basketball shoes, cycling shoes, soccer shoes, tennis shoes, football shoes, training shoes, walking shoes, and hiking boots, for example. The concept may also be applied to footwear styles that are generally considered to be non-athletic, including dress shoes, loafers, sandals, and work shoes. Accordingly, the concepts disclosed with respect to footwear apply to a wide variety of footwear types.

Although the present disclosure is described in detail as it relates to a knitted component of upper 1200 for an article of footwear, the principles described herein may be applied to any textile element to provide areas of stiffness and macrostructure 900 to an object. For example, the principles may be applied to textiles, including but not limited to knitted textiles and woven textiles. Knitted textiles include textiles formed by warp knitting, weft knitting, flat knitting, circular knitting, and other suitable knitting operations. The knitted textile may have, for example, a plain knit construction, an open knit construction or a rib knit construction. Woven textiles include, but are not limited to, textiles formed by any of a variety of weave forms, for example, weave forms such as plain weave, twill weave, satin weave, dobby weave, double layer weave, and double layer weave.

Having described various aspects of the above subject matter, the following provides additional disclosure that may be consistent with the claims as originally presented in this disclosure. In describing this additional subject matter, reference may be made to the previously described figures.

One general aspect includes a method of manufacturing a knitted component, comprising: knitting a first knit layer and a second knit layer on a knitting machine, wherein the first knit layer and the second knit layer each include a plurality of interlooped loops, and wherein at least one loop of the first knit layer is interlooped with at least one loop of the second knit layer; during knitting the first knitted layer and the second knitted layer, embedding an embedded strand between the first knitted layer and the second knitted layer, wherein the embedded strand comprises a thermoplastic material having a melting point; applying heat to at least a portion of the thermoplastic material embedded in the strands such that the portion of the thermoplastic material is elevated to a temperature at or above the melting point; applying pressure to at least one side of the knitted component with a die press to form a molded shape; and cooling the portion of the thermoplastic material to a temperature below the melting point during or after the application of the pressure such that the molded shape remains on at least one side of the knitted component.

Optionally, the step of cooling the portion of thermoplastic material is performed at least in part by a die press. The step of applying heat to portions of the thermoplastic material may be performed before the step of applying pressure to at least one side of the knitted component. The molding press may include a temperature less than the melting point during the step of applying pressure to at least one side of the knitted component. Once the portion of the thermoplastic material is cooled, the portion of the thermoplastic material may form a barrier between the first knitted layer and the second knitted layer, and wherein the barrier is water resistant or waterproof. At least one of the first knitted layer and the second knitted layer may comprise yarns having a melting point higher than the melting point of the thermoplastic material. At least one of the first and second knitted layers may comprise a polyester yarn.

Another general aspect includes a method of manufacturing a knitted component, comprising: knitting a first knit layer and a second knit layer on a knitting machine, wherein the first knit layer and the second knit layer each include a plurality of interlooped loops, and wherein at least one loop of the first knit layer is interlooped with at least one loop of the second knit layer; during knitting the first knitted layer and the second knitted layer, embedding an embedded strand between the first knitted layer and the second knitted layer, wherein the embedded strand comprises a thermoplastic material having a melting point; applying heat to at least a portion of the thermoplastic material embedded in the strands such that the portion of the thermoplastic material is elevated to a temperature at or above the melting point; applying pressure to at least one side of the knitted component with a die press to form a molded shape; and cooling portions of the thermoplastic material to a temperature below the melting point such that a barrier is formed between the first knitted layer and the second knitted layer, the barrier being water resistant or waterproof (e.g., as tested in accordance with ISO-11092 (7.4)).

Another general aspect includes a knitted component comprising: a first knit layer on a first side of the knitted component; a second knitted layer on a second side of the knitted component opposite the first side, wherein the first knitted layer includes at least one stitch interlooped with the at least one stitch of the second knitted layer; and a third layer formed between the first knitted layer and the second knitted layer, wherein the third layer comprises a thermoplastic material substantially contained between the first knitted layer and the second knitted layer.

Optionally, the knitted component can also include a molded shape on at least one of the first side and the second side of the knitted component. At least one of the first knitted layer and the second knitted layer may comprise yarns having a melting point higher than the melting point of the thermoplastic material. At least one of the first and second knitted layers may comprise a polyester yarn. The third layer may form a water-resistant or waterproof barrier between the first and second knitted layers. The thermoplastic material of the third layer may be provided via at least one inlay strand which is embedded between the first knitted layer and the second knitted layer.

While various embodiments of the invention have been described, the description is intended to be exemplary, rather than limiting and it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible that are within the scope of the invention. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents. Also, various modifications and changes may be made within the scope of the appended claims.