Patent Description:
Sporting good components often have a three-dimensional shape. For example, a sports shoe comprises a shoe upper and a sole. The shoe upper generally comprises a three-dimensional shape for receiving and covering a human foot. Another example is the shape of sports apparel which follows the human anatomy.

A three-dimensional shape of a sporting goods component is often obtained by joining together two-dimensional pieces. For example, a shoe upper often comprises different components like vamp, toe cap, heel counter, etc. which are stitched or glued together in a three-dimensional shape. Additionally, the shoe upper is often pulled over a last having the shape of a human foot.

This conventional method of forming a sporting goods component is time-consuming and costly due to the comparatively large number of manufacturing steps. Furthermore, sporting goods components manufactured in this way, comprise visible seams which are often detrimental to the optical appearance of the sporting good.

According to <CIT> lasting piece of shrinkable, preferably oriented thermoplastic polymeric material is attached, preferably by stitching, to a shoe upper lasting margin and is shrunk by being heated, if it is thermoplastic, to between its glass transition temperature and melting point. Shrinkage of the lasting piece lasts the shoe upper to the last. The lasting piece can be a lasting string, endless band or strip, or a sheet, web, net or welt.

However, <CIT> does not address the general problem of how to obtain a three-dimensional sporting goods component from two-dimensional pieces. Furthermore, <CIT> is directed to general footwear and does not address the specific needs of the sports industry.

Further prior art is disclosed in <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT> and <CIT>. <CIT> discloses a method wherein a three-dimensional shape of a shoe upper is obtained through a shrinking condition applied to an endless knitted band.

Therefore, the technical problem underlying the present invention is to provide a method for the manufacture of a sporting goods component, which is time- and cost-efficient, and allows for the manufacture of optically appealing shoe uppers.

This problem is solved by a method for the manufacture of a sporting goods component, wherein the sporting goods component is a shoe upper, comprising the steps of: selecting a first textile, wherein the first textile comprises a first shrinkage ratio under a predetermined shrinking condition; forming a first portion of the component using the first textile; Selecting a second textile, wherein the second textile comprises a second shrinkage ratio under the predetermined shrinking condition, wherein the second shrinkage ratio is higher than the first shrinkage ratio; forming a second portion of the component using the second textile; and attaching the first textile and the second textile together.

According to the invention, a sporting goods component is provided with a first textile and a second textile. Both textiles differ at least by their shrinkage ratio if a predetermined shrinking condition is applied as further defined in claim <NUM>. Examples of shrinking conditions will be given below. If the shrinking condition is applied, the second textile having a higher shrinking condition will shrink more than the first textile. As both textiles are attached to each other, the different shrinkage of both textiles will lead to a deformation of the sporting goods component. If the size, shape, arrangement and shrinkage ratio of both textiles are appropriately chosen, the deformation will result in a desired shape of the sporting goods component.

Thus, the sporting goods component may be provided with a rather complex three-dimensional shape without the need to join different pieces together.

The invention also allows to pull less appealing seams in a different location where they may be covered by another piece of the sporting goods component. Examples will be given below. In this way, more appealing sporting goods components can be manufactured.

"Shrinkage ratio" in the context of the present invention is understood as the ratio of the length of a certain portion of a respective textile before and after application of the shrinking condition. For example, if a certain portion of the first textile or the second textile comprises a length of <NUM> before shrinking and <NUM> after shrinking, the shrinkage ratio is <NUM>. Alternatively, the shrinkage ratio may be expressed as a percent value denoting by how much the portion is shrunk. For example, if the length of the portion is <NUM> before shrinking and <NUM> after shrinking, the shrinkage ratio is said to be <NUM>%. A shrinkage ratio of <NUM> (or <NUM>%) is possible according to the invention, i.e. the textile may not shrink at all.

The method further comprises the step of applying the shrinking condition. This causes the second textile to shrink more than the first textile, because its shrinkage ratio is higher. As both textiles are attached to each other, a tension force is created within the sporting goods component resulting in a deformation.

The application of the shrinking condition provides the sporting goods component with a three-dimensional shape. In this way, a three-dimensional sporting goods component is obtained from a flat two-dimensional shape simply by applying the shrinking condition. In other not claimed exemplary configurations, a three-dimensional sporting goods component may be modified from a three-dimensional shape to another different three-dimensional shape simply by applying the shrinking condition.

The shrinking condition may comprise the application of heat and/or water. Water may include water in liquid form, as steam or as vapor. Heat and water are readily available and their application is rather simple.

The first textile may be a knit and/or the second textile may be a knit. Knitted fabrics are well suitable for sporting goods components such as shoe uppers, but also for sports apparel. Moreover, yarns with different shrinkage ratios can be used by knitting machines to obtain the first and second textiles in a fully automated manner. The method may further comprise the step of forming the first portion and the second portion of the component during the same knitting process. Thus, a one-piece seamless knit fabric is obtained, thereby providing a simple cost-efficient manufacturing, and also a good looking finished product. Besides, such knit component may be obtained on a flat-knitting machine and may be provided with a three-dimensional shape when subjected to the application of the shrinking condition.

The method may further comprise the step of attaching the first portion and the second portion to each other by loops of knitting during the knitting process. As mentioned above, this technique avoids seams between the two portions. Nonetheless and according to the invention other methods of attaching the first and the second portion may be used such as stitching, gluing, melting, etc..

The method may further comprise the steps of forming the first portion at least partially by a first knitting row and forming the second portion at least partially by a second knitting row. In this way, the two different textiles can be incorporated into the sporting goods component for example by changing the yarn on a knitting machine after the first row has been knitted.

The first portion of the component may be obtained by using a first selection of yarn or yarns on a first needle and the second portion of the component may be obtained by using a second selection of yarn or yarns on a second needle, wherein the second needle forms loops side by side with loops formed by the first needle, and the second selection of yarn or yarns comprises a higher shrinkage ratio than the first selection of yarn or yarns. Such a setup decreases production time because both textiles can be incorporated into the sporting goods component at the same time.

In exemplary configurations, the method may further comprise the step of forming the first textile and the second textile by small circular knitting. Small circular knitting is a technique which allows to manufacture a single circular knit portion with a diameter adapted to the final shape of the component. Compared to conventional circular knitting or flat knitting, no additional cutting step is needed. Furthermore, but unlike the claimed invention, as the result is a three-dimensional circular knit portion, no additional sewing step is needed to form a two-dimensional flat component into a three-dimensional component. In addition, by application of the shrinking condition, the circular knit portion may further be formed into the desired shape.

In exemplary configurations, the first textile and the second textile may be knitted in a single small circular knitting process to obtain a tube comprising the first portion and the second portion. The shape of the tube may then be locally modified by the method according to the invention.

The second shrinkage ratio may be higher than the first shrinkage ratio by at least <NUM>%. In particular, the shrinkage ratio may be at least <NUM>%.

The sporting goods component manufactured according to the method described herein is a shoe upper for a sports shoe. As mentioned above, shoe uppers are usually made from two-dimensional pieces sewn or glued together. These steps can be omitted when using the method according to the invention.

This description further relates to a sporting goods component comprising: a first portion with a first shrinkage ratio under a predetermined condition; and a second portion with a second shrinkage ratio under the predetermined condition. As described above, such a sporting goods component may be have a rather complex three-dimensional shape without the need to join different pieces together. The invention also allows to pull less appealing seams in a different location where they may be covered by another piece of the sporting goods component. Examples will be given below.

The sporting goods component comprises a three-dimensional shape caused at least in part by a difference of the first shrinkage ratio and the second shrinkage ratio. In this way, a three-dimensional sporting goods component can be obtained from a flat two-dimensional shape.

The Sporting goods component is a shoe upper. As mentioned above, shoe uppers are usually made from two-dimensional pieces sewn or glued together. These steps can be omitted when manufacturing a shoe upper according to the invention which may therefore be manufactured with less time, effort and costs.

The shrinking condition may comprise the application of heat and/or water. Heat and water are readily available and their application is rather simple.

The first portion may comprise a knit textile and/or the second portion may comprise a knit textile. Knitted fabrics are well suitable for sporting goods components such as shoe uppers, but also for sports apparel. Moreover, yarns with different shrinkage ratios can be used by knitting machines to obtain the first and second textiles in a fully automated manner.

The first knit textile and the second knit textile may be portions of a one-piece knit. Thus, the sporting goods component comprises a one-piece seamless knit fabric which is originally flat, but which is provided with a three-dimensional shape subject to the application of the shrinking condition.

The first portion and the second portion may have been attached to each other by loops of knitting during a knitting process. As mentioned above, this technique avoids seams between the two portions.

The first portion may be formed at least partially by a first knitting row and the second portion may be formed at least partially by a second knitting row. In this way, the two different textiles can be incorporated into the sporting goods component for example by changing the yarn on a knitting machine after the first row has been knitted.

In exemplary configurations, the first textile and the second textile may have been formed by small circular knitting. As mentioned above, small circular knitting is a technique which allows to manufacture a single circular knit portion at a time with the correct size and shape. Compared to conventional circular knitting or flat knitting, which produce several components (i.e. shoe uppers or parts of it) at once, no additional cutting step is needed. Furthermore, and beyond the scope of the claimed invention, as the result is a three-dimensional circular knit portion, no additional sewing step is needed to form a two-dimensional flat component into a three-dimensional component. In addition, by using textiles with different shrinking conditions, the circular knit portion may further be formed into the desired shape of the final sporting goods component.

According to an aspect of the inventive idea of the present invention, a shrinking yarn is incorporated in a sporting goods component, such that when the sporting good is worn, the shrinking yarn surrounds a portion of a human body. For example, the shrinking yarn may be wrapped around a toe portion of a shoe upper, such that it surrounds a human foot when a shoe comprising the shoe upper is worn.

By the application of a shrinking condition, as described herein, the shrinking yarn may shrink and provide the sporting goods component with a desired shape. In the example above, the shoe upper may be provided with a smaller diameter at the toe portion compared for example to the midfoot portion.

The sporting goods component may comprise a base material and the shrinking yarn. The shrinking yarn may have a higher shrinkage ratio than the base material when applying the shrinking condition. For example, the base material may be a textile, leather or artificial leather.

The sporting goods component is a shoe upper. As described above, the shoe upper may be provided with the desired shape simply by the application of the shrinking condition.

The presently preferred embodiments of the method according to the invention as well as of a sporting goods component according to the invention are described in the following detailed description, with reference to the following drawings:.

<FIG> show an exemplary sporting goods component, namely an upper <NUM> for a sports shoe. According to the example of <FIG>, the shoe upper <NUM> is created by small circular knitting. Small circular knitting is a technique which allows to manufacture a single circular knit portion at a time with the correct size and shape. Compared to conventional circular knitting or flat knitting, in which several components (i.e. shoe uppers or parts of it) are produced at once, no additional cutting step is needed.

Thus, the shoe upper <NUM> is initially a small circular knit sock. The upper <NUM> comprises a shrinking zone <NUM> that will shrink more than the rest <NUM> of the sock when heat is applied to the knit. In particular, in an exemplary configuration, the shrinking portion <NUM> is placed at the bottom portion of the forefoot portion of the sock. That way some portions such as the seam <NUM> at the front of the sock may be pulled toward below the sock, so that it is hidden when the shoe upper is then joined with a sole (not shown in <FIG>).

After shrinking of the portion <NUM>, the shoe upper <NUM> will be deformed in the forefoot portion such that the front seam <NUM> is arranged below the shoe upper <NUM>. The joining line that separates the portion of the shoe upper <NUM> that will be visible on the final product and the portion of the upper <NUM> that will be joined to the sole unit is indicated by dashed lines <NUM>. After shrinking, the seam <NUM> is below the joining line such that it cannot be seen on the final product.

The method may be applied to any knit textile, in particular a flat knit textile, or to any other material. One or the other of the textiles may be a knit, mesh, woven, braid, or non-woven.

The area in which the higher shrinkage ratio is designed may be in a different place than in the above example of <FIG>. In particular, it may be in a plurality of portions with different sizes and shapes. Also, more than two areas may each have a different shrinkage ratio. The shrinkage ratio may also change gradually, for example by changing gradually the proportions of shrinking yarn in a knit. This way a small circular knit tube may be pre-formed to a shoe shape as illustrated in <FIG>.

In this example, a small circular knit tube <NUM> comprises four different zones <NUM>, <NUM>, <NUM> and <NUM>, each having a different shrinkage ratio. As illustrated in <FIG>, the toe zone <NUM> has the highest shrinkage ratio, whereas ankle zone <NUM> has the lowest shrinkage ratio. Of course, the number of zones, the arrangement of the zones, as well as the shrinkage ratios may vary.

Generally, shrinking yarns may be used in the context of the present invention. A shrinking yarn may for example be based on polyamides, polyesters, polyacrylonitriles or vinyl polymers, olefin polymers, TPU, wool-felted, Lycra®, yarns comprising rubber in their content, and biomimetic yarn such as spider-silk yarn obtained by bio-engineering (e.g. produced by genetically modified bacteria).

In some embodiments, a PES yarn may be used in a portion that is to shrink only slightly (for example between <NUM>% and <NUM>%), and a mix of PES and Lycra yarn may be used in shrinking portions with a higher shrinkage ratio (for example between <NUM>% and <NUM>%, in particular between <NUM>% and <NUM>%).

One of the advantages of the invention is that a one size basic component may shrunk to different percentages so as to obtain different sizes of the final sporting good. This is particularly advantageous in small circular knitting where the number of needles is fixed, and therefore the diameter of the tube obtained is in principle also fixed. But varying the shrinkage ratio, and/or the size, and/or the shape, and/or the arrangement of the shrinking portion(s), and/or the shrinking conditions (in particular the duration of application), permits to obtain different sizes and shapes.

In an example, a sock obtained by small circular knitting is to be used as a sports shoe upper. The size of the sock as it is taken out of the small circular knitting machine corresponds to European shoe size <NUM>. By selectively adding a shrinking yarn during the knitting process and applying a shrinking condition, it is possible to shrink the sock, such that it corresponds to smaller shoe sizes, such as <NUM>, <NUM>, <NUM>, etc..

Generally, the shrinking portion may have a varying width over a dimension of the shoe upper, such that one portion will become smaller than other portions as illustrated in <FIG>. In this example, a tube <NUM> to be used for a shoe upper comprises a shrinking portion <NUM> which as a higher shrinkage ratio than other portions <NUM> of the tube <NUM>. The width of the shrinking portion <NUM> varies over its length. The middle section <NUM> of the shrinking portion <NUM> is rather large compared to its end portions 35a and 35b. Thus, when applying the shrinking condition, the tube <NUM> will obtain a smaller diameter in the area of the middle section <NUM> of the shrinking portion <NUM> compared to the areas of the end portions 35a and 35b of the shrinking portion <NUM>. Such middle section <NUM> may for example correspond to the foot arch portion of a sock or shoe upper.

A shrinking area, zone or portion according to the invention is understood as an area that shrinks more than another area of the sporting goods component (for example a shoe upper). For example, the shrinking area, zone or portion may be knit and comprises a higher proportion of a shrinking yarn. It may be that other areas have less percentage of shrinking yarn, or have no shrinking yarn at all.

In some embodiments, a sporting goods component may comprise two overlapping layers of textiles, wherein a first layer comprises a lower shrinkage ratio than a second layer. The two layers may be bonded to each other or only attached at some points (for example at their edges). The behavior of the portion will thus be different whether the two layers are bonded or not. The first (less shrinking) layer may be a stretch layer with a high degree of elasticity.

An example of overlapping layers with different shrinkage ratios is provided in <FIG>. In this example, the upper layer <NUM> comprises a lower shrinkage ratio than the lower layer <NUM>. Thus, when the shrinking condition is applied as illustrated in <FIG>, the lower layer <NUM> shrinks more than the upper layer <NUM> and "pulls" both layers into a bent shape.

Another example is provided in <FIG>. In this example, the upper layer <NUM> and the left portion 42a of the lower layer <NUM> are formed from a textile having a comparatively low shrinkage ratio. Both layers may for example for a spacer knit or the two layers may be attached by loose stitch for example. The right portion 42b of the lower layer <NUM> is formed from a textile having a comparatively high shrinkage ratio. As illustrated in <FIG>, after application of the shrinking condition, the portion 42b pulls a part of the upper layer <NUM> into a bent configuration.

A further example is illustrated in <FIG>. In this example, the upper layer <NUM>, the left portion 42a and the right portion 42c of the lower layer <NUM> are formed from a textile having a comparatively low shrinkage ratio. The middle portion 42b of the lower layer <NUM> is formed from a textile having a comparatively high shrinkage ratio. As illustrated in <FIG>, after application of the shrinking condition, the combination of the two layers <NUM> and <NUM> produces a texturing effect on the upper layer <NUM>. The upper layer <NUM> may for example be an outer layer of a shoe upper.

Generally, according to the invention, the activation of the shrinking may be provoked by different elements. The shrinking may be activated by heat, by water (liquid, vapor or steam), and/or any combination. The heat may be provided as electromagnetic waves in many different wavelengths: IR, microwave, radio-frequency, etc. so as to warm up the sporting goods component such as a shoe upper.

The activation may be applied on the whole sporting goods component (such as a shoe upper) or locally. For example, heat or steam may be applied very locally with a nozzle, either manually or automatically (e.g. with a robotic arm). Nonetheless the invention is particularly advantageous when the activation is applied to the entire sporting goods component (such as a shoe upper): the process is then more simple and cheaper as it may require less complex machines and less labor. Indeed, the entire shoe upper may be passed in an oven for example.

In case of a shoe upper, the shrinking is beneficially made when the shoe upper is lasted. Nonetheless it may be made when the shoe upper is not lasted. If the shoe upper is lasted, heat may be transferred to the shoe upper via the last to activate the shrinking process. To this end, the last may comprise a heating, such as heating wires or may allow the passage of a hot medium such as water or oil, or may comprise steam nozzles.

According to the invention, other portions with different characteristics may be integrated in a shoe upper for a sports shoe (or sports apparel). For example, a portion may have a higher elasticity than another one. This may be obtained by using a higher proportion of an elastic yarn (in a knit or a woven for example). More particularly, an elastic yarn may be integrated in the shrinking area, in combination with a shrinking yarn. By doing so, the elastic yarn may be able to pull on the shrinking area when the shrinking yarn is "activated" so as to accelerate the shrinkage and/or obtain shrinkage with a lighter activation (e.g. at a lower temperature) and/or with a lower proportion of shrinking yarn than would be needed without the elastic yarn.

The shrinking area may also be combined with a second different area made to be auxetic. Auxeticity may be obtained by the geometry and/or material of the second area. The shrinking area and the auxetic area may be placed on the shoe upper such that when the shrinking area shrinks it pulls the auxetic material in one direction. As a consequence of this pull along one direction the auxetic area also extends in a second direction.

The method not according to the invention may generally also be used for apparel. One other advantage of embedding shrinking areas is that these areas may become stiffer. Therefore, they can form a local reinforcement such as a heel counter or a toe cap. They may also improve abrasion resistance. It is particularly the case with knit textile whereby the shrunk knit portion has smaller and tighter loops. Besides, the shrunk portion may also be more water-repellant as the holes between the loops are smaller. Combined with a water-repellant yarn (e.g. water-repellant coated yarn), the holes may be small enough to stop water intake, even in a knit.

The shrinking portions or parts thereof, such as for example a shrinking yarn may be removed in a further manufacturing step. For example, it may be a shrinking patch or a shrinking yarn attached at intervals to a base layer so as to deform it when shrinking, and the base layer is then locked in place or set in its shape, and the shrinking portion is then removed. Also, the shrinking portion may be cut-off for example a shoe upper in a subsequent manufacturing step. More particularly an outer-periphery of the shoe upper that would be made more shrinking than other portions of the shoe upper may be cut-off in a subsequent step.

A specific shrinking yarn may comprise two different grades of material such that a portion of the yarn will shrink more than another portion of the yarn. An illustrative example of such a yarn <NUM> in provided in <FIG>. The yarn <NUM> comprises a first portion <NUM> with a comparatively high shrinkage ratio and a second portion <NUM> with a comparatively low shrinkage ratio. As illustrated in <FIG>, after the application of the shrinking condition, the yarn <NUM> is in a curled configuration.

The yarn <NUM> may be obtained by co-extrusion of two different materials - or two different grades of a same material - with different shrinkage ratio under the same predetermined conditions. Such yarn <NUM> would curl as illustrated in <FIG> and thereby exert a pulling force. If such yarn <NUM> is embedded in a textile such as a knit, it will exert its pulling force on the textile, thereby deforming the textile.

<FIG> illustrate a location where a shrinking portion <NUM> may be placed in a shoe upper <NUM>, namely in the toe area. As illustrated in <FIG>, after application of the shrinking condition, the toe area comprises a smaller diameter than the rest of the shoe upper which comprises a lower shrinking condition. Another possible location for a shrinking area is the outer periphery <NUM> of a shoe upper.

It is also possible to apply a shrinking condition more than once. For example, as illustrated in <FIG>, a second step may be applied after having obtained the shoe support of <FIG> by a first shrinking step, to shrink an area <NUM> below the toe portion. In an example, the area <NUM> may comprise a yarn with a higher activation temperature compared to the area <NUM>. In another example, the area <NUM> is activated by heat, whereas the area <NUM> is activated by water or vice versa.

In an optional step of the invention, a mask may be applied to at least a portion of the sporting good component (such as a shoe upper), such that it does not receive the application of the shrinking condition. Such portion may thus remain un-shrunk or may be shrunk at a later stage. For example, a mask may protect at least one portion from heat application.

<FIG> show another example, namely a shoe upper <NUM> for a sports shoe. In this example, a TPU yarn has been used to create a shrinking zone <NUM>. The shrinking zone <NUM> has been created in the bottom portion of the forefoot (or "toe") area of a knitted, sock-like shoe upper <NUM> (for example obtained by small circular knitting). <FIG> shows a bottom view of the knitted sock-like upper <NUM> before shrinkage. <FIG> show the shrinking thus obtained. As can be seen, a portion <NUM> of the shoe upper <NUM> not comprising the shrinking TPU yarn is pulled under a portion of the toes.

More particularly, <FIG> shows the upper <NUM> after the application of steam, in a flat configuration. The zone <NUM> knitted with TPU yarn shrank from <NUM> to <NUM>, as indicated with the ruler. It can be seen that the seam lines <NUM> (between the zones <NUM> and <NUM>) have been pulled toward the bottom surface of the shoe upper <NUM>, such that if the shoe upper <NUM> is joined to a bottom unit, the seam lines will not be visible anymore.

<FIG> shows the upper <NUM> after the application of steam, with the shoe upper <NUM> having been placed on a last. Here again the seam lines <NUM> have been pulled towards the bottom surface of the shoe upper <NUM>.

The yarn proportions in this specific example are as follow: <NUM>% PES in the area <NUM> and <NUM>% TPU in the area <NUM>. However, similar behavior would be seen with material blends and especially using some materials which could be engineered with higher shrinkage levels. Additionally, material blends are advantageous to maintain a combination of properties in the shrinkage zones, for example to maintain bonding behavior or comfort.

<FIG> shows another example, namely a shoe upper <NUM> with a shrinking portion <NUM> in the lower midfoot (or arch) region. In this example, the shrinking portion <NUM> helps to form the upper <NUM> around the concave shape of the midfoot, thus providing support to a foot of a wearer of the final sports shoe and generally improving the shape and fitting to the foot.

According to a not claimed aspect of the inventive idea of the present invention, a shrinking yarn is incorporated in a sporting goods component, such that when the sporting good is worn, the shrinking yarn surrounds a portion of a human body. This principle is generally illustrated in <FIG> which show a cylindrical shape <NUM>. The cylindrical shape <NUM> is generally made from a first material <NUM>. The middle of the cylinder comprises a shrinking portion or zone which additionally comprises a second material <NUM> in form of a yarn which shrinks by the application of a certain shrinking condition, e.g. the application of heat above a certain temperature or the application of water. The first material <NUM> does generally not shrink by the application of the shrinking condition or does not shrink as much as the shrinking yarn. After the application of the shrinking condition, the middle of the cylindrical shape is constricted due to the yarn <NUM> which has become shorter as illustrated in <FIG>.

Claim 1:
Method for the manufacture of a sporting goods component (<NUM>), wherein the sporting goods component (<NUM>) is a shoe upper (<NUM>), the method comprising the steps of:
- Selecting a first textile (<NUM>), wherein the first textile (<NUM>) comprises a first shrinkage ratio under a predetermined shrinking condition;
- Forming a first portion of the component (<NUM>) using the first textile (<NUM>);
- Selecting a second textile (<NUM>, 42a, 42b, <NUM>, <NUM>), wherein the second textile (<NUM>, 42a, 42b, <NUM>, <NUM>) comprises a second shrinkage ratio under the predetermined shrinking condition, wherein the second shrinkage ratio is higher than the first shrinkage ratio;
- Forming a second portion (<NUM>, <NUM>) of the component (<NUM>) using the second textile (<NUM>, 42a, 42b, <NUM>, <NUM>);
- Attaching the first textile (<NUM>) and the second textile (<NUM>, 42a, 42b, <NUM>, <NUM>) together; and
- Applying the shrinking condition, wherein the application of the shrinking condition provides the sporting goods component (<NUM>) with a three-dimensional shape, characterised in that the three-dimensional shape is provided by the shrinking condition from a flat two-dimensional shape.