Disclosed are a method of manufacturing sport protective equipment and sport protective equipment manufactured by the method. A thin casing is manufactured by a thin sheet material in a vacuum forming process; protrusions are formed apart from one another on a surface of the thin casing; a containing space is formed on an inner side of each protrusion for filling a filler; and a substrate is provided to seal the bottom of the thin casing, so that the filler in each of the containing spaces will not fall out, so as to improve the manufacturing efficiency and the product quality. The sport protective equipment manufactured by this method does not require any sewing manufacture or increase thickness, so that the flexibility of wearing and using is improved, and the thin casing and the filler are provided for absorbing shocks to improve the protective effect.

A two-part method for dye-sublimation printing a decorative design on a moldable orthotic substrate comprising a first digital printing step of printing a computer image file of a decorative design on a digital transfer paper substrate using dye-sublimation CMYK inks, and a second dye-sublimation printing step comprising the steps of heating an oven to a first temperature, placing a moldable orthotic substrate inside the oven, heating the moldable orthotic substrate to a second temperature, positioning the digital transfer paper substrate on the moldable orthotic substrate with the decorative design down and in contact with the moldable orthotic substrate, and sublimating the at least one color of dye-sublimation CMYK inks from the digital transfer paper substrate to the moldable orthotic substrate. A custom orthotic product may be manufactured by wrapping the dye-sublimation printed moldable orthotic substrate around an orthotic mold and applying a vacuum.

A two-part method for dye-sublimation printing a decorative design on a moldable orthotic substrate comprising a first digital printing step of printing a computer image file of a decorative design on a digital transfer paper substrate using dye-sublimation CMYK inks, and a second dye-sublimation printing step comprising the steps of heating an oven to a first temperature, placing a moldable orthotic substrate inside the oven, heating the moldable orthotic substrate to a second temperature, positioning the digital transfer paper substrate on the moldable orthotic substrate with the decorative design down and in contact with the moldable orthotic substrate, and sublimating the at least one color of dye-sublimation CMYK inks from the digital transfer paper substrate to the moldable orthotic substrate. A custom orthotic product may be manufactured by wrapping the dye-sublimation printed moldable orthotic substrate around an orthotic mold and applying a vacuum.

An apparatus including: a plurality of forming molds, each mold including: a leading edge; a trailing edge; a mold face; a plurality of first recesses in the mold face positioned across the mold face, each first recess in fluid communication with a first vacuum duct; a leading face extending from the leading edge in a direction away from the mold face; a trailing face extending from the trailing edge in a direction away from the mold face; wherein at least a portion of the leading face is recessed relative to the mold face proximal the leading edge or at least a portion of the trailing face is recessed relative to the mold face proximal the trailing edge; wherein the plurality of forming molds is arranged leading edge to trailing edge as a first mold belt.

Provided is a shaped article including a hardcoat layer, where the hardcoat layer has surface hardness, flexibility, and heat resistance at high levels and offers excellent workability. The shaped article according to the present invention is a shaped article including a hardcoat layer, a substrate layer, and a thermoplastic resin layer and having a curved shape. The hardcoat layer defines an outermost surface of the shaped article. The hardcoat layer includes a cure product of a curable composition. The curable composition includes a cationically curable silicone resin and a leveling agent. The cationically curable silicone resin includes a silsesquioxane unit. The cationically curable silicone resin includes an epoxy-containing monomeric unit in a proportion of 50 mole percent or more of the totality of all monomeric units and has a number-average molecular weight of 1000 to 3000.

A method and apparatus for manufacturing a composite structure having integrated electronics. A flexible electronic substrate is heated with the flexible electronic substrate positioned relative to a composite laminate. A vacuum is applied to cause the flexible electronic substrate to conform to and bond to the composite laminate, thereby forming an electronic composite panel.

A method and apparatus for manufacturing a composite structure having integrated electronics. A flexible electronic substrate is heated with the flexible electronic substrate positioned relative to a composite laminate. A vacuum is applied to cause the flexible electronic substrate to conform to and bond to the composite laminate, thereby forming an electronic composite panel.

A thermoforming device includes: a base configured to hold a substrate; a hot plate including a heating surface facing vertically downward; a sheet transport portion that supplies a sheet onto the heating surface of the hot plate; and a substrate supply portion configured to attach the substrate to the base and detach the substrate from the base, and to dispose the substrate at a substrate supply position positioned in a lower area of the sheet which is opposite to a side of the sheet in which the heating surface is provided. In the thermoforming device, heating of the sheet using the hot plate and attachment and detachment of the substrate with respect to the base are performable at the same time, and the sheet heated and softened by the hot plate is attached to the substrate at the substrate supply position.

Systems and methods for forming 3D plastic parts that are cost effective in low volume, have excellent fit and finish, and use many components from 2D construction are disclosed. The systems and methods involve selecting a design and modelling the design. The design comprises 2D and 3D components of plastic parts. A 3D forming buck corresponding to the 3D component is manufactured. At least one of a 2D part and the 3D forming buck may be heated. The 2D part may be loaded onto the 3D forming buck for a predefined period of time. The 3D part formed after the loading may be separated from the 3D forming buck. The 3D part is the 2D part generally having taken the shape of the 3D forming buck. The 3D part may be cooled to obtain an end product.

Systems and methods for forming 3D plastic parts that are cost effective in low volume, have excellent fit and finish, and use many components from 2D construction are disclosed. The systems and methods involve selecting a design and modelling the design. The design comprises 2D and 3D components of plastic parts. A 3D forming buck corresponding to the 3D component is manufactured. At least one of a 2D part and the 3D forming buck may be heated. The 2D part may be loaded onto the 3D forming buck for a predefined period of time. The 3D part formed after the loading may be separated from the 3D forming buck. The 3D part is the 2D part generally having taken the shape of the 3D forming buck. The 3D part may be cooled to obtain an end product.