The present invention is a system and method for creating a customized protective equipment item having improved fit. A measuring device takes measurements of a person. The measurements are sent to a computer, which has software for translating the measurements into a custom selection of standard sized components used to assemble the custom protective equipment item. An assembly process builds the completed protective equipment item which is customized to the wearer's size requirements.

A safety helmet includes an outer shell configured for surrounding a head of a user, and an infrared reflective layer disposed in an interior of the outer shell. The infrared reflective layer is configured for reflecting at a least a portion of incident infrared radiation transmitted through the outer shell. The infrared reflective layer has infrared reflectivity of at least 40%. The safety helmet further may have an evaporative cooling pad positioned within a cavity defined by the inner surface of the outer shell. A method of manufacturing a safety helmet is also disclosed.

A safety helmet includes an outer shell configured for surrounding a head of a user, and an infrared reflective layer disposed in an interior of the outer shell. The infrared reflective layer is configured for reflecting at a least a portion of incident infrared radiation transmitted through the outer shell. The infrared reflective layer has infrared reflectivity of at least 40%. The safety helmet further may have an evaporative cooling pad positioned within a cavity defined by the inner surface of the outer shell. A method of manufacturing a safety helmet is also disclosed.

A method of forming a dual cure three-dimensional object by additive manufacturing may be carried out by mixing a first precursor liquid and a second precursor liquid to produce a polymerizable liquid comprising a mixture of (i) a light polymerizable liquid first component, and (ii) a second solidifiable component (e.g., a second reactive component) that is different from the first component (e.g., that does not contain a cationic photoinitiator, or is further solidified by a different physical mechanism, or further reacted, polymerized or chain extended by a different chemical reaction). In the foregoing: (i) at least one reactant of the second solidifiable component is contained in the first precursor liquid, and (ii) at least one reactant or catalyst of the second solidifiable component is contained in the second precursor liquid. Once mixed, the three-dimensional object may be formed from the resin by a dual cure additive manufacturing process.

A helmet body includes an outer shell and an energy management liner with an outer shell lower edge extending between the inner surface and the outer surface of the outer shell. At least two shoulder pad recesses are positioned at a lower edge of the outer shell on a respective left and right sides of the helmet. The energy management liner is adjacent to the inner surface of the outer shell and includes at least two shoulder pads formed of a foamed energy management material. Each of the at least two shoulder pads is received into one of the at least two shoulder pad recesses on the respective left or right side of the helmet, each shoulder pad extending from inside of the outer shell to across at least a majority of a width of the lower edge of the outer shell.

The present invention is applicable to the field of bicycle motion protection and safeguard equipment. The present invention discloses a luminous helmet, including an outer shell and an inner shell in joint connection with the outer shell, a light emitting band is arranged between the inner shell and the outer shell, the outer shell is provided with a strip-shaped fixing hole at the position of the light emitting band, a light transmission groove for accommodating the light emitting band is formed in the fixing hole, and an extension part extending toward the outer side is arranged at the opening of the light transmission groove. During blister forming of the outer shell, the blister forming is carried out after the whole PC sheet is colored, the area requiring light transmission is cut to form the fixing hole, and the light transmission groove and the fixing hole are fixed to form a light transmission structure. No light transmission blank area needs to be arranged on the PC sheet, thereby preventing the deviation between an uncolored blank area of a light transmission position and a light emission position of the formed outer shell from affecting the beautiful appearance and quality of a product in a production process, improving the production efficiency of the luminous helmet and reducing the production cost.

A garment worn by a wearer has an impact absorbing material comprising arrays of various hexagonal or other deformable polygonal-shaped structures positioned between an exterior surface and an interior surface. When force is applied to the exterior surface, the structures of the impact absorbing materials deform (e.g., buckle) in a desired manner, reducing the force received by the interior surface.

A lightweight helmet according to an embodiment of the present invention may have a fiber sheet layer formed of a reinforced fiber, and a porous foamed plastic layer thermally bonded and formed on one surface or both surfaces of the fiber sheet layer, and the fiber sheet layer and the porous foamed plastic layer may be alternatingly formed in duplicate or more.

A method is providing for manufacturing an integrally formed cap, the method comprising: in step 1, providing a shell fabric B and a thermoplastic lining fabric C, superposing the shell fabric on a surface of the lining fabric and tightly attaching the shell fabric to the lining fabric, to obtain the fabric A needed, and providing the shaping mold matched with the shape of a cap; in step 2, cutting the fabric A obtained in Step 1 into set dimensions; and in step 3, tightly attaching the fabric A cut in Step 2 onto the shaping mold obtained in Step 1, thermally shaping the fabric A by a container, so as to integrally shape the fabric A into the cap. With the method of the invention, the production speed and quality stability can be increased, the production cost reduced, and the production process is energy-saving and environment-friendly.

A helmet and method for forming a helmet having a multi-density impact liner may include forming a puck with an interface surface and at least one side. The interface surface of the puck is placed in direct contact with a receiving surface of a cap located in an impact liner mold. Next, the interface surface of the puck is thermally fused directly to the receiving surface of the cap while contemporaneously an impact liner body is formed inside the mold. The impact liner body is fused to the at least one side of the puck, and to a majority of the receiving surface of the cap. The density of the puck may be greater than the density of the impact liner body. The puck and the impact liner body may be EPS, and the cap may be PC.