Knitted pocket with element inserted

The method integrates functional elements during the knitting process by creating voids and using shrinkable or melting yarns, addressing inefficiencies in traditional methods to enhance structural integrity and comfort in sports articles.

EP4764047A1Pending Publication Date: 2026-06-24ADIDAS AG

Patent Information

Authority / Receiving Office
EP · EP
Patent Type
Applications
Current Assignee / Owner
ADIDAS AG
Filing Date
2025-12-03
Publication Date
2026-06-24

AI Technical Summary

Technical Problem

Traditional manufacturing methods for sports articles involve labor-intensive steps like cutting and adhesive bonding to integrate functional elements, leading to inconsistencies, weakened joints, added bulk, and potential discomfort, while being inefficient and costly.

Method used

A method that integrates functional elements like reinforcement pads and cushioning during the knitting process by creating voids in the fabric and inserting them on a knitting machine, using shrinkable or melting yarns to secure the elements without cutting or adhesive steps.

Benefits of technology

This method ensures secure, precise placement of elements, enhancing structural integrity and comfort, reducing manufacturing steps, and improving production efficiency and product quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to a method of fabricating a sports article comprising a knitting process. the knitting process comprises the steps: a.) providing a knitting machine, yarn for knitting, and at least one insert element; b.) knitting a fabric such that the fabric comprises at least one open void between at least two layers of the fabric; c.) inserting at least one insert element into the at least one open void while the fabric remains in the knitting machine; and d.) further knitting the fabric such that the at least one void is closed at least partially around the insert element(s) by connecting the at least two layers. The invention further relates to a sports article.
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Description

1. Field of the invention

[0001] This invention relates to a method of fabricating a sports article comprising a knitting process, and a sports article.2 . Background

[0002] The invention relates to the field of fabricating sports articles using knitting processes. Traditional manufacturing methods for sports articles, such as shoes and apparel, often involve multiple steps, including cutting, sewing, and adhesive bonding, to integrate various functional elements like reinforcements and / or cushioning into the fabric. These methods can be labor-intensive, prone to inconsistencies, and may compromise the structural integrity and flexibility of the final product.

[0003] US 9 538 803 B2 discloses an article of footwear incorporating a textile upper. The upper comprises a knitted component. The knitted component may be warp knitted. The knitted component has an outer side and an inner side that can have different knit configurations. The knitted component can also incorporate portions of a single layer construction and portions of a double layer construction.

[0004] Further prior art is known from DE 10 2005 030 651 A1.

[0005] It is disadvantageous here, that the fabric needs to be cut to place inserts into pockets formed in the fabric. Thus, there is a demand for a fabrication process, which does not need a cutting step to place insert elements.

[0006] The primary problem addressed by the invention is the need for an efficient, consistent, and seamless method to integrate various functional elements into sports articles during the knitting process itself. Traditional methods of attaching elements such as padding or reinforcements to fabrics often result in weaker joints, added bulk, and potential discomfort for the user. Additionally, these methods can be inefficient and costly due to the multiple steps and manual labor involved. The invention provides a method for seamlessly integrating functional elements into sports articles during the knitting process. By creating voids within the knitted fabric and inserting elements such as reinforcement pads, cushioning, magnets, or electronic components while the fabric is still on the knitting machine, the method ensures a secure and precise placement of these elements. The use of shrinkable or melting yarns can further enhance the integration by tightly enclosing the elements within the fabric, eliminating the need for additional cutting or adhesive steps.

[0007] In view of the foregoing, there is a need for an improved fabrication process of knitted sports articles. It is thus an object of the present invention to overcome some or all the deficiencies of the prior art.3. Summary

[0008] The above objects are at least partially achieved by the subject matter of independent claim 1. Preferred embodiments are the subject of the dependent claims, and the skilled person will find clues to other suitable aspects of the present invention in the overall disclosure of the present application.

[0009] An aspect of the invention relates to a method of fabricating a sports article comprising a knitting process, the knitting process comprising the steps: a.) Providing a knitting machine, yarn for knitting, and at least one insert element; b.) Knitting a fabric such that the fabric comprises at least one open void between at least two layers of the fabric; c.) inserting at least one insert element into the at least one open void while the fabric remains in the knitting machine; and d.) Further knitting the fabric such that the at least one void is closed at least partially around the insert element(s) by connecting the at least two layers. In particular, during the knitting step b) the void is accessible through an aperture that is then closed in step d).

[0010] Such a method can for instance be used to create a sports shoe with enhanced support. For example, the insert element could be a cushioned pad or a reinforcement strip. By inserting the insert element, for instance a pad into the void within the knitted layers and then knitting further to secure it, the sports article gains additional structural support and comfort without the need for external stitching or adhesives. This approach ensures a more seamless design, reduces manufacturing steps, and enhances the durability and performance of the sports article.

[0011] The method can be further improved when the method does not comprise cutting of the knitted fabric to create the open void.

[0012] With such a method the open void is formed directly during the knitting process by manipulating the yarn and machine settings to leave a gap or void between fabric layers. This technique eliminates the need for cutting, which is common in the state of the art, preserving the integrity and strength of the fabric. For example, in the creation of a seamless sports article, this method allows for strategic placement of breathable or reinforced section without weakening the material. This results in a more durable and comfortable product, as the fabric maintains its original strength and flexibility.

[0013] Further improvement is in particular achieved when the fabric is continuously held on the knitting machine during steps b.)-d.).

[0014] With such a method, the fabric remains on the knitting machine during the entire process of forming the open void, inserting the element, and knitting to close the void. For example, when manufacturing a sports article like a shoe or a glove, this continuous process ensures precise placement and secure integration of e.g. padding or support elements. This method enhances production efficiency by reducing handling and potential errors associated with moving the fabric between machines. Additionally, it improves the alignment and consistency of the final product, resulting in higher quality and reduced production time. This means that during these steps the knitted fabric is not removed from the knitting machine, and it is held on the needles of the machine, although the specific needles holding the fabric could change over the time during the fabrication process.

[0015] Further improvement is achieved when the inserting of the insert element(s) is performed automatically, preferably by supplying the insert element(s) from a storage area.

[0016] With such a method, the insertion of insert elements like cushioning pads or reinforcement strips into the fabric is done automatically using a mechanism that retrieves these elements from a designated storage area. For instance, in the production of a sports article, this automated insertion ensures precise and consistent placement of e.g. protective and / or cushioning elements without manual intervention. The automatic insertion may be accomplished through the use of a robotic arm integrated with and / or provided on the knitting machine. This configuration not only ensures precise positioning of the insert but also facilitates maneuvering the insert within the confined space of the machine, for instance in the area between the needle beds. This automation improves production speed, accuracy, and reduces labor costs, leading to a more efficient manufacturing process and higher quality products with consistently placed insert elements. A storage area could for instance be a magazine to store and supply insert elements.

[0017] An alternative improvement is achieved when the inserting of the insert element(s) is performed manually by an operator.

[0018] With such a method, the insertion of insert elements such as padding or reinforcement strips is performed manually by an operator. For instance, in the creation of custom sports articles, an operator can precisely place and adjust each insert element according to specific design requirements. This manual insertion allows for greater flexibility and customization, ensuring that each product meets exact specifications and accommodates individual needs. This method can be advantageous for limited production runs or specialized items, where precision and customization are prioritized over automation.

[0019] Further improvement can be achieved when the knitting machine gauge is maximum 14.

[0020] With such a method, the knitting machine used in the process has a maximum gauge of 18, meaning it can produce relatively fine and detailed fabric. For instance, in the production of sportswear, using a machine with a gauge of 18 allows for the creation of a light and fine fabric. As the gauge increases, the material becomes finer; however, this also reduces the distance between the needle beds, making it more challenging to introduce an insert between them. An 18-gauge configuration offers a balance, being fine enough to produce delicate material while still maintaining sufficient distance between the needle beds to allow for the insertion of elements between them and into the knitted material.

[0021] Further improvement is achieved when the aperture through which the void is accessible has a width that is larger than the maximum width of the insert element(s). This allows to fully introduce the insert element in the void in step c) without deforming it. This may require designing the knitted fabric and the knitting program in a suitable manner to allow the placement of the insert element(s) during the knitting process.

[0022] Further improvement is achieved when the maximum thickness of the insert element(s) is smaller than the distance between the layers of the fabric delimiting the void while they are held in the knitting machine. This allows to fully introduce the insert element in the void in step c) without deforming it. Alternatively, the maximum thickness of the insert element(s) could be larger than the distance between the layers of the fabric while held in the knitting machine and the insert element(s) could be made of an elastically deformable material, so that in can be compressed in step c) to be introduced in the void. In particular, the distance between the layers of the fabric is determined by the distance between the needle beds.

[0023] Further improvement is achieved when the fabric is knitted as a double, triple or quadruple layer fabric, with the at least two layers of the fabric interconnected to each other through the knitting process and the open void is defined in a selected area of the fabric, where the at least two layers of fabric are detached and overlapping. For instance, the fabric could be a double layer fabric where in selected areas the two layers of fabric are separated, i.e. not connected between them, and overlapping to define the void.

[0024] Further improvement is achieved when after step b.) the fabric comprises more than two layers and two or more voids defined between them, such that after inserting insert elements, the insert elements and the layers are stacked alternately.

[0025] Such a method results in a multi-layered fabric with multiple voids for insert elements. For example, in the production of high-performance sports articles, this technique allows for the insertion of both cushioning and structural supports within the same fabric. By stacking insert elements like structural and cushioning layers alternately with the fabric layers, the sports article can offer enhanced cushioning, breathability, and structural integrity. This layered construction improves the functionality and comfort of the sports article, providing tailored performance benefits for various athletic activities. This method can be implemented on knitting machines comprising two needle beds, utilizing alternate needles in a 1x1 technique. Alternatively, it can be performed on knitting machines with additional needle beds, such as those with four needle beds, which simplifies the process and enables knitting on all needles.

[0026] Further improvement is achieved, when the height of the void is larger than the height of the insert element(s) and / or the width of the void is larger than the width of the insert element(s).

[0027] Such a method creates voids that are larger than the insert elements to ensure easy insertion and slight movement within the void. This design enhances comfort and adaptability, as the insert elements can adjust within the void to provide optimal support and reduce pressure points. This flexibility can also simplify the manufacturing process by accommodating variations in insert element sizes. This is particularly advantageous when no elastic yarns are used in the knit. When elastic yarns are used, in fact, the dimensions of the void could be smaller than the ones of the insert element, since the elastic yarn, by stretching, allows to compensate for the difference in dimensions.

[0028] Further improvement is achieved when at least one insert element is fixed in the void by the yarn extending through the insert element.

[0029] With such a method, the insert element is fixed within the void by knitting the yarn through the insert itself. For example, in creating protective sports gear such as knee pads, the padding element can be securely anchored in place by threading the yarn through holes or loops in the pad. This ensures the insert remains firmly in position, providing consistent protection and support during use. This method enhances the durability and stability of the sports article, preventing the insert elements from shifting or becoming dislodged during intense physical activities.

[0030] This method can be performed in particular with insert elements that are not made of a rigid material, such as padding elements made of foam materials, reinforcing films or fabrics, simply using the needles to punch through the insert elements. This method can be performed also with insert elements made of a rigid material as long as holes or loops are provided in the insert elements to this aim.

[0031] Further improvement is achieved when the insert element has a shape adapted to be inserted between the needle beds of the knitting machine. For instance, when using a flat knitting machine which has flat needle beds, the insert element should have advantageously a flat shape to be easily inserted between the needle beds. In case a different shape is desired, the desired shape could be conferred to the insert element and the latter could be made of an elastically deformable material, to be deformed during the inserting step c). Alternatively, a flat shape could be initially conferred to the insert element and the latter could be made of a plastically deformable material to be shaped into the desired shape after the knitting process, for instance by means of a heat pressing step. Differently, when using a circular knitting machine, which has circular needle cylinder and dial, the insert should have a curved shape adapted to be inserted between the needle cylinder and dial or it should be made of a flexible material that can be conveniently bended to the scope.

[0032] Further improvement is achieved when the yarn comprises a shrinkable yarn and the method comprises a shrinking step, such that the fabric around the void conforms around the contour of the insert element(s), wherein the shrinking is preferably achieved by applying heat.

[0033] With such a method the fabric is knitted with shrinkable yarn, and after the insert element(s) are placed, the fabric undergoes a shrinking process. For example, in the manufacture of custom-fit sports article, heat can be applied to the fabric, causing the shrinkable yarn to contract and tightly conform around the padding or support elements. This ensures a snug and precise fit, enhancing the functionality and comfort of the sports article. The heat-shrinking step ensures that the inserts stay securely in place, preventing them from moving within the void, and the fabric contours perfectly to the desired shape, providing improved performance. The knit products can include numerous different yarns and a shrinkable yarn might be knitted together with other different yarns or used only in a specific location where it is needed and not in other locations. The heat can be applied for instance by steaming, ironing, autoclaving, using an oven or the like.

[0034] Further improvement is achieved when the layers comprise different yarns and wherein preferably one layer of the fabric comprises an elastic and / or shrinkable yarn and another layer comprises a non-elastic and / or non-shrinkable yarn.

[0035] With such a method the fabric incorporates layers made from different types of yarn. For instance, in the creation of a sports compression garment, the inner layer can be made from an elastic and shrinkable yarn to provide a snug, conforming fit, while the outer layer is made from a non-elastic, durable yarn to offer support and protection. This combination allows the garment to stretch and adapt to the wearer's body while maintaining structural integrity and durability. This dual-layer construction can enhance comfort, performance, and longevity of the sports article, providing targeted support and flexibility where needed.

[0036] Further improvement is achieved when the yarn comprises an elastic and / or shrinkable yarn.

[0037] With such a method the knitting process uses yarn that is elastic and / or shrink-able. For example, in the manufacturing of sports articles, using elastic yarn ensures the fabric can stretch and conform to the foot's movements, providing a comfortable and flexible fit. Additionally, shrinkable yarn can be used to further enhance the fit and shape retention of the garment after a heat treatment. This use of specialized yarns improves the overall performance, durability, and comfort of the sports article, making it ideal for dynamic and high-intensity activities. Moreover, when the yarn comprises an elastic / shrinkable yarn, the insert element can fit better inside the void, thanks to the layers of fabric that take the shape of the insert element. An elastic or shrinkable yarn might comprise an elastomer and / or thermoplastic polyurethane (TPU).

[0038] Further improvement is achieved when one of the layers comprises a melting yarn, adapted to form a connection with the insert element(s) when fused.

[0039] With such a method the fabric layer includes a melting yarn that at least partially fuses bonding to the insert elements when heat is applied. For example, in the production of sport shoes, a melting yarn can be used in the inner layer of the shoe padding. When heat is applied, this yarn melts and bonds with the insert elements, such as impact-absorbing pads, creating a secure and integrated structure. This method enhances the durability and stability of the padding, ensuring it stays firmly in place during use. The melting process also simplifies the manufacturing steps and eliminates the need for additional adhesives, resulting in a more streamlined and efficient production.

[0040] This method can be further improvement when the melting yarn is also a shrink-able yarn.

[0041] With such a method the melting yarn used in the fabric layer is also shrinkable. When heat is applied, this yarn will not only at least partially fuse bonding to the insert elements but also shrink to conform tightly around them. This dual function ensures a secure bond and a snug fit, enhancing the support and stability of the sports article. The combination of melting and shrinkable properties simplifies the manufacturing process and improves the overall effectiveness and comfort of the sports article. A melting yarn that is also a shrinkable yarn could for instance be a hybrid or twisted yarn.

[0042] This method using a yarn that is both a melting and a shrinkable yarn, is particularly advantageous on the manufacturing of footwear when for instance the insert elements placed in the knitted material are rigid and require a precise placement, such as support rods.

[0043] Further improvement can be achieved when the yarn comprises a non-elastic and / or non-shrinkable yarn comprising polyester.

[0044] With such a method the fabric incorporates a non-elastic and non-shrinkable polyester yarn. For example, in the production of sports articles like footwear or sports bags, using polyester yarn provides durability and resistance to stretching, ensuring that the footwear or bag maintains its shape and can withstand heavy use. Polyester's inherent strength and resistance to environmental factors like moisture and UV light make it an ideal choice for outdoor sports equipment. This use of polyester yarn improves the longevity, structural integrity, and reliability of the sports article, making it suitable for demanding applications.

[0045] Further improvement is achieved when the yarn comprises a shrinkable yarn and the void has one or more opening(s) smaller than the insert element(s) and the method comprises a shrinking step, such that after shrinking the yarn, the insert element(s) partially extend through the opening(s). In particular, the one or more opening(s) could be independent from the aperture through which the insert element(s) are placed in the void or could be created by only partially closing the aperture.

[0046] With such a method the fabric uses shrinkable yarn and features openings smaller than the insert elements. For example, in the creation of sports articles, after placing the insert element(s) within the fabric, heat is applied to shrink the yarn. This causes the fabric to tighten, and the insert element(s) partially protrude through the openings. This design ensures the insert element(s) remain securely in place while allowing for a part of it to be accessible by protrude through the opening. This is particularly advantageous for instance when the insert element is an electric component and a part of it needs to be accessible for instance to allow electrical charging or transfer of data. The shrinking step ensures a precise and snug fit around the insert elements, improving both the performance and the aesthetic of the sports article. The opening of the void is preferably not the aperture that is giving access to the open void for the inserting of the insert elements, but it is a different opening to give additional functionality to the sports article, for instance by allowing the insert element to extend through this additional opening.

[0047] Further improvement is achieved when the knitted fabric comprises one or more holes and in particular through holes connected to the void and the insert element(s) is partially visible through the holes. This design enhances breathability and ensures the insert element(s) remain securely in place while allowing for additional airflow.

[0048] Further improvement is achieved when the insert element(s) comprise(s) reinforcement means and / or cushioning means.

[0049] With such a method, the insert elements provide reinforcement and / or cushioning. For example, in the manufacture of sports shoes, the insert elements could be stiffeners for added support or cushioned pads for comfort. Reinforcement elements can enhance the structural integrity and durability of the shoes, making them more resistant to wear and tear. Examples of such reinforcement elements are: vamp reinforcements or toe box, to reinforce the toe and forefoot areas of the shoes, heel counter, to provide the necessary rigidity to the heel area and more support to the foot of the wearer, or eyestay reinforcements, to reinforce the lacing areas. Other reinforcement elements can be provided to improve the shoe performance. Examples of such reinforcement elements are stiffening elements, such as plates or rods, to be provided on the sole area of the shoe to increase stiffness of the sole allowing better force transmission from the ankle to the ground. Cushioning elements improve comfort by absorbing impact and reducing pressure on the feet. Examples of cushioning elements are heel or tongue paddings. This combination ensures that the sports article meets the specific performance needs of athletes, providing both strength and comfort. Such a cushioning means can be for instance made of a foam or also of a pellet or particle foam.

[0050] Further improvement is achieved when the insert element(s) comprise(s) magnets.

[0051] For instance, by integrating magnets directly into the fabric, the garment can for example be used to produce a detachable fastener that can replace a zip or a hook and loop fastener. Such a fastener could for instance be used on a bra, a belt, a waistband, a pocket or a bag. This method enhances the functionality of the sports article and allows for a clean design. Further improvement is achieved when the insert element(s) comprise(s) one or more electronic components, preferably microchips.

[0052] With such a method the insert elements can comprise electronic components such as microchips. For example, in the production of smart sportswear, microchips can be integrated into the fabric to monitor and collect data on the wearer's performance, such as heart rate, position, movement, speed, ball kicking force and temperature. These electronic components can for instance connect to a mobile app, providing real-time feedback and analysis to the user. This integration of electronics enhances the functionality of the sports article, transforming it into a high-tech garment that offers both performance monitoring and improved training outcomes.

[0053] In one embodiment the insert element(s) comprise(s) a RFID tag, for instance for identification or tracking purposes.

[0054] In a further embodiment, the insert elements can also be small devices for generating vibrations, heat, such as infra-red heating, and / or mild electrical impulses. These could be used, for instance, to warm up muscles before a competition, to warm parts of the body in cold environments, or for pain relief purposes, for instance for menstrual pain relief.

[0055] The insert elements could also be light-generating devices for aesthetic or safety purposes, for example for visibility at night. In this case, the yarn used to create at least part of the pocket could be a transparent or translucent yarn, such as a monofilament yarn.

[0056] Further improvement is achieved when the sports article is a shoe.

[0057] For instance, the method can be applied to create uppers of shoes with integrated cushioning or reinforcement elements for enhanced comfort or support. Alternatively or additionally the method can be applied to create insoles, strobel boards or more generically sole parts of the shoe. Using a knitting process to form one or more parts of the shoe allows for precise placement of these elements within the fabric, resulting in a seamless design. Additionally, incorporating features like shrinkable yarns and electronic components such as microchips can provide a customized fit and performance tracking. This method enhances the overall quality, functionality, and innovation of the sports shoe, making it ideal for various athletic activities.

[0058] In an embodiment, the knitted pocket is located on the sole area of the shoe to accommodate, for instance, a midsole or part of a midsole. The midsole could be a solid foam or be in the form of pellets, which may be loose or bonded together. In this case, at least part of the pocket could be knitted using a transparent or translucent yarn, such as a monofilament yarn, for the insert to be visible.

[0059] The knitted material could also be used to define an insole or a sock liner. The pocket could be defined to cover only a portion of the sole, for instance to create customized areas of cushioning or support. For example, when creating an insole or sock liner, pockets of different shapes and sizes can be knitted into the arch area to accommodate support materials like foam. This allows for a customized fit and different levels of arch support. The orientation of the pocket opening can be controlled by the knitting direction of the sole element, for instance by knitting it lengthwise or widthwise, to facilitate the insertion of the support material.

[0060] Additionally, a sports article such as a shoe may comprise further components produced by methods other than the one claimed. For example, a knitted material can form a tubular structure for receiving a midsole element, such as an expanded thermoplastic polyurethane foam. In such a case, the tubular pocket can be knitted, and the midsole element can be inserted in a subsequent post-processing step after the component is removed from the knitting machine. An out-sole can then be bonded to the bottom of this knitted structure to complete the sole assembly. This component can be present in a shoe together with other parts that are fabricated according to the method of the invention.

[0061] In another embodiment the sports article is an apparel item.

[0062] For example, the process can be employed to produce garments with integrated cushioning or support elements for improved performance, comfort or safety. The knitting technique allows for the strategic placement of these elements within the fabric, resulting in a seamless and ergonomic design. Additionally, the use of elastic or shrinkable yarns can provide a snug, adaptive fit, while electronic components like microchips can offer advanced features such as performance monitoring. This method enhances the functionality, comfort, and innovation of sports apparel, making it suitable for a wide range of athletic activities.

[0063] Examples of sport apparel items are for instance: an upper torso garment for motorsports where the insert element could be a safety padding or reinforcement, a sock where the insert element is a shin guard to be used for instance for playing football, baseball or hockey, cycling shorts or tights with seat padding, protective compression sport garments including integrated protective pads, lower body garments with moisture-wicking and leak-resistant padding.

[0064] Another embodiment of the invention is a sports article obtained by the method outlined above.

[0065] For example the sport article could be a sport accessory such as a knee or elbow protector for instance for playing volleyball or for skating, a ball and the knitted material could be the carcass of the ball while the insert element could be for instance a sensor, a bag or a backpack and the insert element could be a reinforcement or a padding element.

[0066] For example, a sports shoe produced with this method might feature integrated cushioning, reinforcement elements, and possibly electronic components for performance tracking. The seamless design ensures durability and comfort, while the use of advanced materials like shrinkable and elastic yarns provides a custom fit. Similarly, sports apparel made with this method could include compression garments with strategically placed support and cushioning, offering enhanced performance and comfort.4. Brief description of the figures

[0067] In the following, preferred embodiments of the disclosure are disclosed by reference to the accompanying figures. Fig. 1:illustrates the insertion of an insert element into an open void in a fabric in a schematic view. Fig. 2:shows the insert element inside the void between two layers in a cross-sectional view. Fig. 3:depicts the insertion of an insert element into an open void in a fabric and the insert element extending through an opening after shrinking the fabric in a schematic view. Fig. 4:illustrates the insertion of a trapezoidal insert element into an open void in a fabric and the insert element inside the fabric in a schematic view. Fig. 5:depicts a concave insert element inside a stretchable fabric in a schematic view. Fig. 6:shows an insert element that is visible through holes inside the fabric in a schematic view. Fig. 7:illustrates a fabric with two insert elements inside two voids and a fabric with three insert elements inside three voids in a schematic view. Fig. 8:depicts a fabric with three insert elements as a component for a shoe in a schematic view. Fig. 9:shows a fabric with four insert elements as a counter-component to Figure 8 in a schematic view. Fig. 10:shows a photograph of a manual insertion of an insert element between the needle beds of a knitting machine. Fig. 11:shows a closeup photograph of the insertion of the insert element of Figure 10 between the needle beds of a knitting machine. Fig. 12:shows a sideway photograph of the insertion of the insert element of Figure 10 into a knitting machine. Fig. 13:depicts a back photograph of the fabric with insert elements of figure 9. Fig. 14:shows a front photograph of the fabric with insert elements of figure 9. Fig. 15:shows a front photograph of the fabric with insert elements of figure 8. Fig. 16:shows a close-up photograph of the fabric of figure 15. Fig. 17:depicts a photograph of a fabric with an insert element as a shoe tongue. Fig. 18:illustrates a close-up photograph the fabric of figure 17. 5. Detailed description of the figures

[0068] The subsequent sections provide a detailed description of the invention, referencing the accompanying illustrations for clarity. The descriptions represent examples only and are not intended to limit the invention's scope. Identical reference numerals across the figures and text denote the same components. The illustrations may not reflect actual size or scale; their dimensions, proportions, and depictions of elements might be enhanced for better understanding and visual convenience.

[0069] Figure 1 illustrates the insertion of an insert element into an open void in a fabric in a schematic view. The fabric 100 is hanging on the needles 150 of a knitting machine and comprises a first layer 101 and a second layer 102. Between the first and second layer 101, 102 is an open void 110, configured to receive the insert element 1000. The void 110 is in particular accessible through an aperture 103.

[0070] The fabric 100 remains on the knitting machine needles 150 throughout the process, ensuring that the first layer 101 and the second layer 102 remain spaced apart held by respective needles and the aperture 103 remains open allowing the precise placement of the insert element 1000. This method enhances the sport article's structural integrity and comfort by securely integrating the insert element, for instance a cushioning pad within the fabric layers 101, 102. This technique results in a seamless, durable sports article.

[0071] Figure 2 shows the insert element inside the void between two layers in a cross-sectional view. The fabric 100 comprises a first and a second layer 101, 102 and a void 110 between the layers. The insert element 1000 sits in the void and is enclosed by the layers 101, 102.

[0072] The first and second layers 101, 102 of the fabric 100 create a void 110 where an insert element 1000 is placed. This cross-sectional view illustrates how the insert element 1000 is securely enclosed within the fabric layers 101, 102, ensuring it stays in place during use. This method provides enhanced protection and comfort, as the insert element in form of e.g. a reinforcement or a padding can absorb impacts while the fabric layers maintain flexibility and durability.

[0073] Figure 3 depicts an insert element while being inserted in the void and then extending through an opening after shrinking the fabric in a schematic view. The insert element 2000 is inserted into the fabric 200, wherein the fabric 200 comprises a first and a second layer 201, 202. The layers 201, 202 form between them a void 210 to receive the insert element 2000. The void also comprises a small opening 220 on the side, through which the insert element 2000 can extend partially. After closing the void during the knitting procedure and after shrinking the fabric, the shrinked fabric 200' snugly encloses the insert element 2000 so that parts of the insert element 2000 extend through the opening 220. More in detail, the width of the void 210 is preferably larger than the total width of the insert element 2000 when the insert element 2000 is introduced between the first and second layer 201, 202. After the first and second layer 201, 202 have been knitted together to close the void 210 and the knitted fabric has undergone a shrinking post-process treatment, the width of the void is reduced and the insert element 2000 protrudes through the opening 220.

[0074] The first and second fabric layers 201, 202 form a void 210 with a small opening 220. The insert element 2000 is placed into the void. After completing the knitting process and applying for instance heat to shrink the fabric 200, the shrinked fabric 200' tightens around the insert element 2000, ensuring a secure fit. The shrinking process allows the insert element 2000 to extend partially through the opening.

[0075] Figure 4 illustrates a trapezoidal insert element inside a fabric in a schematic view. The fabric 300 comprises a first and a second layer 301, 302 forming a void 310 to receive the trapezoidal insert element 3000. The trapezoidal insert element 3000 is inserted into the void 310 during the knitting procedure. After knitting, the fabric is shrinked, such that it encloses around the insert element 3000, thus adopting the shape of the insert element.

[0076] The first and second fabric layers 301, 302 create a void 310 that holds a trapezoidal insert element 3000, for instance a cushioning pad. During the knitting process, the insert element 3000 is inserted into the void, and then the fabric 300 is subjected to a shrinking step, conforming tightly around the trapezoidal insert element 3000. This snug fit ensures that the insert element 3000 remains securely in place and provides for instance protection and support. The trapezoidal shape is an example of a shape not including only parallel sides that can be inserted in a void according to the invention, but other shapes could be used, including also irregular shapes. The use of shrinkable yarns and the addition of a shrinking step, after the knitting process, allow the knitted material to conform to the shape of the insert element, even if irregular, without the need to create complex knitting programs. Trapezoidal or similar shapes of insert element(s) could be used for instance to create padding element(s) on the heel area of an article of footwear, offering optimized coverage and comfort.

[0077] Figure 5 depicts a concave insert element inside a stretchable fabric in a schematic view. The insert element 5000 is seated inside the void 510, wherein the void 510 is formed between the first and second layer 501, 502 of the fabric 500. The stretch yarn 530 which is part of the first layer 510 forces the insert element 5000 to bend into a concave form, thus forming an empty volume between the first layer 510 stretched by the stretch yarn 530 and the concave insert element 5000. More in detail, when the method is performed on a flat knitting machine, the insert element 5000 is made of a deformable material, such as for instance a deformable foam or foil, adapted to bend under the action of the stretch yarn 530.

[0078] The fabric layers 501, 502 form a void 510 that holds a concave insert element 5000, for instance to form a padding on the heel area of a shoe. The stretch yarn 530 in the first layer 501 forces the insert element to bend into a concave shape, ensuring it fits snugly against the body while creating a small empty volume 532, e.g. for further comfort. This design could also enhance the support and fit of for instance a sports bra, providing better shape and coverage. The concave shape of the insert improves comfort by reducing pressure points and allowing for better airflow, making the sports article suitable for various activities. For a bra, this method could be implemented when the insert element is a soft padding. Similarly, this solution can be applied to other products, such as a shin guard or the visor of a cap, where the insert element would consist of a more rigid yet elastically deformable material.

[0079] Figure 6 shows an insert element that is visible through holes created on the first or second layer of the fabric in a schematic view. The fabric 600 comprises a void 610 which holds the insert element 6000. The insert element is visible due to through holes 640 in the fabric 600.

[0080] The fabric layers form a void 610 to hold the insert element 6000. Through holes 640 in the fabric allow the insert element 6000 to be visible and partially exposed. This design not only provides aesthetic appeal but also enhances breathability and flexibility. The visibility through the holes can also serve functional purposes, such as indicating the correct positioning of the insert or providing additional grip. This method combines protection, comfort, and design innovation in the sports article.

[0081] Figure 7 illustrates a fabric with two insert elements inside two voids and a fabric with three insert elements inside three voids in a schematic view. The first fabric 710 comprises a first and a second void 711, 712, which hold a first and a second insert element 7001, 7002. This way, a stacked assembly is formed by the layers of the fabric 710 and the insert elements 7001, 7002, thus forming a sandwiched structure. The second fabric 720 comprises a first, a second and a third void 721, 722, 723 which hold a first, a second and a third insert element 7001, 7002, 7003. This way, a stacked assembly is formed by the layers of the fabric 720 and the insert elements 7001, 7002, 7003, thus forming a sandwiched structure.

[0082] The first fabric 710 with two voids 711, 712 and insert elements 7001, 7002 can be used for instance for a shin guard, where each insert provides targeted protection and cushioning. The second fabric 720 with three voids 721, 722, 723 and insert elements 7001, 7002, 7003 can be used for a more complex sports article, where multiple layers can offer enhanced impact absorption and coverage. The sandwiched structure ensures that each insert element is securely held between the fabric layers, providing a robust, durable, and effective protective solution. This allows for customizable protection levels by varying the number and type of insert elements used. Each insert element can provide a different functionality and to this aim can be made of different materials.

[0083] Figure 8 depicts a fabric with three insert elements as a component for a shoe in a schematic view. The fabric 800 is formed as a part of a shoe upper. The insert element 8003 on the front part of the fabric 800 serves as a toe reinforcement and the insert elements 8001,8002 serve as eyestay reinforcement.

[0084] The fabric 800 for the shoe upper includes three strategically placed insert elements 8001, 8002, 8003. The toe reinforcement 8003 provides additional protection and durability to the front of the shoe. The eyestay reinforcements 8001, 8002 ensure that the lacing areas are stronger and more resistant to wear. This design enhances the overall performance, longevity, and comfort of the shoe, making it suitable for rigorous athletic use. The integration of these insert elements within the fabric ensures a seamless, lightweight, and aesthetically pleasing shoe construction.

[0085] Figure 9 shows a fabric with four insert elements as a counter-component to Figure 8 in a schematic view. The fabric 900 is formed as a counterpart of the shoe upper component of figure 8. The insert elements 9001, 9002 of the fabric can serve as lacing reinforcement. The insert element 9004 on the middle and upper part of the fabric 900 can serve as a heel foam cushioning. The insert element 9005 on the middle and lower part of the fabric 900 can serve as a heel reinforcement.

[0086] The fabric 900 for the counterpart to the fabric of figure 9 includes four insert elements 9001, 9002, 9004, 9005 strategically placed for enhanced functionality. The lacing reinforcements 9001, 9002 ensure durable and secure lacing areas, improving fit and stability. The heel foam cushioning 9004 adds comfort and shock absorption to the heel area, while the heel reinforcement 9005 provides additional structural support and protection. This enhances the shoe's overall performance, comfort, and durability, making it ideal for intense athletic activities. The integration of these elements within the fabric ensures an integrated, lightweight, and efficient shoe design.

[0087] Figure 10 shows a photograph of a manual insertion of an insert element 10000 into a knitting machine, in particular a flat knitting machine.

[0088] Figure 11 shows a closeup photograph of the insertion of the insert element 10000 of Figure 10 into a knitting machine.

[0089] Figure 12 shows a sideway photograph of the insertion of the insert element 10000 of Figure 10 into a knitting machine. As visible, the insert element is placed between the needle beds.

[0090] Figure 13 depicts a back photograph of the fabric 900 with the insert elements 9001, 9002, 9004, 9005 of figure 9. The shown surface corresponds to the back side of the footwear element; however, from a technical perspective, it represents the front side of the knitted material as it is produced by the knitting machine.

[0091] Figure 14 shows a front photograph of the fabric 900 with the insert elements 9001, 9002, 9004, 9005 of figure 9. The shown surface constitutes the inner side of the footwear element; however, it corresponds to the back side of the knitted material as it emerges from the knitting machine.

[0092] Figure 15 shows a front photograph of the fabric 800 with the insert elements 8001, 8002, 8003 of figure 8.

[0093] Figure 16 shows a close-up photograph of the fabric 800 with the insert elements 8001, 8002, 8003 of figure 8.

[0094] Figure 17 depicts a photograph of a fabric with an insert element 17000 as a tongue reinforcement of a shoe tongue.

[0095] Figure 18 shows a close-up photograph the fabric with the insert element 17000 of figure 17.Reference list:

[0096] 100, 200, 300, 500, 600, 710, 720, 800, 900: fabric 101, 201, 301, 501: first layer 102, 202, 302, 502: second layer 110, 210, 310, 510, 610, 711, 712, 721, 722, 723: void 150: needles 200', 300': shrinked fabric 220: opening 530: stretch yarn 532: empty volume 640: holes 1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000: insert element 8001, 8002, 9001, 9002: lacing reinforcement 8003: toe reinforcement 9004: heel foam cushioning 9005: heel reinforcement 17000: tongue reinforcement

[0097] In the following, further examples are described to facilitate the understanding of the invention: 1. A method of fabricating a sports article comprising a knitting process, the knitting process comprising the steps: a.) providing a knitting machine, yarn for knitting, and at least one insert element; b.) knitting a fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) such that the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises at least one open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) between at least two layers of the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900); c.) inserting at least one insert element into the at least one open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) while the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) remains in the knitting machine; and d.) further knitting the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) such that the at least one void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is closed at least partially around the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) by connecting the at least two layers. 2. A method according to embodiment 1, wherein the method does not comprise cutting of the knitted fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) to create the open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723). 3. A method according to embodiment 1 or embodiment 2, wherein the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) is continuously held on the knitting machine during steps b.)-d.). 4. A method according to one of the preceding embodiments, wherein the inserting of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) is performed automatically, preferably by supplying the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) from a storage area. 5. A method according to any one of the preceding embodiments, wherein the insert-ing of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) is performed manually by an operator. 6. A method according to one of the preceding embodiments, wherein the knitting machine gauge is maximum 18. 7. A method according to one of the preceding embodiments, wherein after step b.) the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises more than two layers and two or more voids defined between them, such that after inserting insert elements, the insert elements and the layers are stacked alternately. 8. A method according to one of the preceding embodiments, wherein the height of the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is larger than the height of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) and / or the width of the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is larger than the width of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000). 9. A method according to one of the preceding embodiments, wherein at least one insert element is fixed in the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) by the yarn extending through the insert element. 10. A method according to one of the preceding embodiments, wherein the yarn comprises a shrinkable yarn and the method comprises a shrinking step, such that the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) around the void conforms around the contour of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000), wherein the shrinking is preferably achieved by applying heat. 11. A method according to one of the preceding embodiments, wherein the layers comprise different yarns and wherein preferably one layer of the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises an elastic and / or shrink-able yarn and another layer comprises a non-elastic and / or non-shrink-able yarn. 12. A method according to one of the preceding embodiments, wherein the yarn comprises an elastic and / or shrinkable yarn. 13. A method according to one of the preceding embodiments, wherein one of the layers comprises a melting yarn, adapted to form a connection with the insert element(s) when fused. 14. A method according to embodiment 13, wherein the melting yarn is also a shrinkable yarn. 15. A method according to one of the preceding embodiments, wherein the yarn comprises a non-elastic and / or non-shrinkable yarn comprising polyester. 16. A method according to one of the preceding embodiments, wherein the yarn comprises a shrinkable yarn and the void has one or more opening(s) (220) smaller than the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) and the method comprises a shrinking step, such that after shrinking the yarn, the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) partially extend through the opening(s) (220). 17. A method according to one of the preceding embodiments, wherein the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) reinforcement means and / or cushioning means. 18. A method according to one of the preceding embodiments, wherein the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) magnets. 19. A method according to one of the preceding embodiments, wherein the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) one or more electronic components, preferably microchips. 20. A method according to one of the preceding embodiments, wherein the sports article is a shoe. 21. A method according to one of the preceding embodiments, wherein the sports article is apparel. 22. Sports article obtained by a method according to one of the preceding embodiments.

Examples

Embodiment Construction

[0068]The subsequent sections provide a detailed description of the invention, referencing the accompanying illustrations for clarity. The descriptions represent examples only and are not intended to limit the invention's scope. Identical reference numerals across the figures and text denote the same components. The illustrations may not reflect actual size or scale; their dimensions, proportions, and depictions of elements might be enhanced for better understanding and visual convenience.

[0069]Figure 1 illustrates the insertion of an insert element into an open void in a fabric in a schematic view. The fabric 100 is hanging on the needles 150 of a knitting machine and comprises a first layer 101 and a second layer 102. Between the first and second layer 101, 102 is an open void 110, configured to receive the insert element 1000. The void 110 is in particular accessible through an aperture 103.

[0070]The fabric 100 remains on the knitting machine needles 150 throughout the process, e...

Claims

1. A method of fabricating a sports article comprising a knitting process, the knitting process comprising the steps: a.) providing a knitting machine, yarn for knitting, and at least one insert element; b.) knitting a fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) such that the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises at least one open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) between at least two layers of the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900); c.) inserting at least one insert element into the at least one open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) while the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) remains in the knitting machine; and d.) further knitting the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) such that the at least one void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is closed at least partially around the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) by connecting the at least two layers.

2. A method according to claim 1, wherein the method does not comprise cutting of the knitted fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) to create the open void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723).

3. A method according to claim 1 or claim 2, wherein the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) is continuously held on the knitting machine during steps b.)-d.).

4. A method according to one of the preceding claims, wherein the inserting of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) is performed automatically, preferably by supplying the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) from a storage area and / or the inserting of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) is performed manually by an operator.

5. A method according to one of the preceding claims, wherein after step b.) the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises more than two layers and two or more voids defined between them, such that after inserting insert elements, the insert elements and the layers are stacked alternately.

6. A method according to one of the preceding claims, wherein the height of the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is larger than the height of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) and / or the width of the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) is larger than the width of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000).

7. A method according to one of the preceding claims, wherein at least one insert element is fixed in the void (110, 210, 310, 510, 610, 711, 712, 721, 722, 723) by the yarn extending through the insert element.

8. A method according to one of the preceding claims, wherein the yarn comprises a shrinkable yarn and the method comprises a shrinking step, such that the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) around the void conforms around the contour of the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000), wherein the shrinking is preferably achieved by applying heat.

9. A method according to one of the preceding claims, wherein the layers comprise different yarns and wherein preferably one layer of the fabric (100, 200, 300, 500, 600, 710, 720, 800, 900) comprises an elastic and / or shrinkable yarn and another layer comprises a non-elastic and / or non-shrinkable yarn.

10. A method according to one of the preceding claims, wherein one of the layers comprises a melting yarn, adapted to form a connection with the insert element(s) when fused, wherein the melting yarn is preferably also a shrinkable yarn.

11. A method according to one of the preceding claims, wherein the yarn comprises a shrinkable yarn and the void has one or more opening(s) (220) smaller than the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) and the method comprises a shrinking step, such that after shrinking the yarn, the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) partially extend through the opening(s) (220).

12. A method according to one of the preceding claims, wherein the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) reinforcement means and / or cushioning means and / or the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) magnets and / or the insert element(s) (1000, 2000, 3000, 5000, 6000, 7001, 7002, 7003, 10000) comprise(s) one or more electronic components, preferably microchips.

13. A method according to one of the preceding claims, wherein the sports article is a shoe.

14. A method according to one of the preceding claims, wherein the sports article is apparel.

15. Sports article obtained by a method according to one of the preceding claims.