摘要:
The present disclosure provides a core protective pad formed of rigid or semi-rigid filaments having been fused together by melting, thereby eliminating the risk of skin injury by splintered fibres. The pad is easy to manufacture by 3D printing, allowing for custom built protective pads to be provided for various areas of an individual athlete's body. Thus, also provided by the present disclosure is a method of manufacture of a protective pad including the 3D printing of the pad to custom specifications and subsequently applying heat to bond the fibres together. Related systems for implementing the method are also provided.
权利要求:
Claims
What is claimed is:
1. A method of manufacturing a protective pad, the method comprising: receiving, by a processor, one or more body parameters for a target area of a body; based on the one or more body parameters, constructing a 3-dimensional model of a protective pad for the target area; receiving, by a 3D printer, the 3-dimensional model and printing a protective pad according to the 3-dimensional model from one or more rigid and/or semi-rigid filament materials; and applying, by one or more heating elements, a heat above the melting temperature of the one or more rigid and/or semi-rigid filament materials to the protective pad to fuse the filaments together.
2. A method of manufacturing a protective pad according to claim 1, wherein the method further comprises: cutting to a sheet of a second material according to the shape and dimensions of the protective pad; encapsulating the protective pad in the cut-out of the second material to form an outer layer on the protective pad; and securing the outer layer to the protective pad.
3. A method of manufacturing a protective pad according to claim 2, wherein securing the outer layer to the protective pad comprises applying an adhesive between the outer layer and the protective pad and applying compression to the encapsulated protective pad until the adhesive has set.
4. A method of manufacturing a protective pad according to claim 2, wherein securing the outer layer to the protective pad comprises applying stitches to the outer layer.
5. A method of manufacturing a protective pad according to claim 2, wherein the method further comprises, after securing the outer layer to the protective pad, applying a heat press to the encapsulated protective pad.
6. A method of manufacturing a protective pad according to claim 2, wherein the outer layer is formed of one or more of: polymer rubber, polymer foam material, neoprene rubber,
EVA foam, synthetic rubber, elastomers (TPE, TPR-thermoplastic rubbers), natural latex rubber, styrene butadiene (SBR) and natural gum rubbers.
7. A method of manufacturing a protective pad according to claim 1, wherein the protective pad is placed inside a material pocket pouch on the inside of a material sleeve made from one of from a combination of EVA foam, rubber, spandex and/or neoprene rubber.
8. A method of manufacturing a protective pad according to claim 1, wherein the protective pad is secured on an inner surface of a piece of clothing so as to be positioned adjacent to the target body area when the piece of clothing is worn.
9. A method of manufacturing a protective pad according to claim 1, wherein the heating element is a component of the 3D printer.
10. A method of manufacturing a protective pad according to claim 1, wherein the one or more body parameters of the target area are acquired by a scanning operation, performed by a scanning module, on the target area of the body of an individual.
11. A method of manufacturing a protective pad according to claim 10, wherein the scanning module generates point cloud data file containing the one or more body parameters.
12. A method of manufacturing a protective pad according to claim 10, wherein the one or more body parameters include one or more dimensions and one or more 3-dimensional contours for the target area.
13. A method of manufacturing a protective pad according to claim 10, wherein the method further comprises converting the data generated by the scan for compatibility with a computer aided design, CAD, program.
14. A method of manufacturing a protective pad according to claim 1, wherein the step of constructing a 3-dimensional model of a protective pad for the target area comprises operations by the processor, including: constructing a 3-dimensional model of the target body area; constructing a shape having a first inner surface with contours designed to match the contours of the target body area and an outer surface having contours defining the thickness of the protective pad based on a desired level of impact protection for each point.
15. A method of manufacturing a protective pad according to claim 1, wherein the filament material for constructing the protective pad is formed of one or more of: Kevlar filaments, Onyx filaments, carbon fibre filaments, nylon filaments, and Polymer thermoplastic filaments.
16. A protective pad formed according to the method of any one of claims 1 to 15.
17. A 3D-printed protective sports pad shaped to fit a target body area of an individual, the
protective sports pad being formed of a melted rigid or semi-rigid filament material.
18. A BD-printed protective sports pad according to claim 17, wherein the melted rigid or semi rigid filament material is encapsulated in an outer layer.
19. A 3D-printed protective sports pad according to claim 18, wherein the outer layer is secured to the melted filament material by stitching or adhesive.
20. A 3D-printed protective sports pad according to claim 17, wherein the melted rigid or semi rigid filament material is encapsulated in a soft pouch.
21. A 3D-printed protective sports pad according to claim 17, wherein the protective pad is secured to an inner surface of a piece of clothing by adhesive or stitching.
22. A protective glove comprising one or more protective pads formed according to the method of any one of claims 1 to 15.