A custom-fitted helmet and a method of making the same can comprise, at a first location, obtaining head data for a customer's head comprising a length, a width, and at least one head contour. With at least one processor, generating a computerized three-dimensional (3D) headform matching the customer's head length, width, and head contour from the head data. The 3D headform can be compared to a helmet safety standard. At a second location different from the first location, a custom-fitted helmet based on the 3D headform can be formed, wherein the custom-fitted helmet satisfies the safety standard and comprises an inner surface comprising a topography that conforms to the length, width, and at least one contour of the customer's head. The first location can be a home or a store. Obtaining the head data from photographic images of a deformable interface member disposed on the customer's head.

Disclosed are devices and methods for optimizing a protective helmet or other item of protective clothing with one or more enhanced principal impact zones and/or impact elements that incorporate protective features that can be particularized to a specific player-position and/or the individual behavior of a specific player or wearer.

A bespoke protective sports equipment to be worn by a player engaged in a sporting activity is provided. The bespoke sports equipment system includes methods for acquiring, storing and processing a player's unique data, namely the anatomical features of the body part against which the bespoke equipment is worn. The systems also includes methods of using the player's unique data to manufacture the bespoke protective equipment with a custom formed internal padding assembly that substantially corresponds to the player's unique data. The system and method allows for the design and manufacture of bespoke protective sports equipment that is purposely designed and manufactured to match the anatomical specifications of the player's body part.

A bespoke protective sports equipment to be worn by a player engaged in a sporting activity is provided. The bespoke sports equipment system includes methods for acquiring, storing and processing a player's unique data, namely the anatomical features of the body part against which the bespoke equipment is worn. The systems also includes methods of using the player's unique data to manufacture the bespoke protective equipment with a custom formed internal padding assembly that substantially corresponds to the player's unique data. The system and method allows for the design and manufacture of bespoke protective sports equipment that is purposely designed and manufactured to match the anatomical specifications of the player's body part.

A device (e.g., an article of athletic gear) comprising a post-molded expandable component, which is a part of the device that is configured to be expanded or has been expanded after being molded. This may allow the post-molded expandable component to have enhanced characteristics (e.g., be more shock-absorbent, lighter, etc.), to be cost-effectively manufactured (e.g., by using less material and/or making it in various sizes), and/or to be customized for a user (e.g., by custom-fitting it to the user).

The invention relates to a multi-step method with a number of processes and sub-processes that interact to allow for the selection, design and/or manufacture of a protective sports helmet for a specific player, or a recreational sports helmet for a specific person wearing the helmet. Once the desired protective sports helmet or recreational sports helmet is selected, information is collected from the individual player or wearer regarding the shape of his/her head and information about the impacts he/she has received while participating in the sport or activity. The collected information is processed to develop a bespoke energy attenuation assembly for use in the protective helmet. The energy attenuation assembly includes at least one energy attenuation member with a unique structural makeup and/or chemical composition. The energy attenuation assembly is purposely engineered to improve comfort and fit, as well as how the helmet responds when an impact or series of impacts are received by the helmet.

Apparatus is provided for point of service manufacture of custom headwear for a subject. The apparatus comprises capture apparatus disposed at a physical location for capturing three dimensional digital data of the head of the subject and generating a three-dimensional digital data file representative of said head; an additive manufacture device located at the physical location; and a processor. The processor operates to process the three-dimensional digital data file to produce a device file comprising the shape for the custom headwear and to provide the device file to the additive manufacture device. The additive manufacture device operates to utilize the device file to manufacture the custom headwear at the physical location.

A helmet may be worn on a head of a wearer having a shape and a contour. The helmet may have a plurality of layers coupled together including an energy management layer and an outer shell layer disposed over the energy management layer. The plurality of layers are integrally formed with one another, and the energy management layer is configured to absorb and dissipate energy received by the helmet during an impact by an external force. The outer shell layer is configured to disperse and dissipate impact energy from the external force. Each of the plurality of layers has a density and a geometry, and the density or geometry of at least one layer differs from the density or geometry of at least another layer.

The invention relates to a protective sports helmet purposely designed for a selected group of helmet wearers from amongst a larger population of helmet wearers. A multi-step method for helmet design starts by collecting information from a population of players that may include information about the shape of a player's head and the impacts the player has sustained. This information is then processed to create player population information that is sorted to create categories. Advanced mathematical techniques are utilized to further sort these categories into player groups or data sets based on player attributes. Once the player groups are identified, another multi-step process is utilized to design optimized helmet prototype models for each player group. These optimized helmet prototype models are then further processed into complete helmet models by determining a structural design and chemical composition that is manufacturable and has mechanical properties that are substantially similar to the optimized helmet prototype model. Physical helmet prototypes are then created and tested using a unique helmet standard derived from information associated with each player group. Once the prototypes pass testing, the complete helmet models can be manufactured to create actual stock helmets or stock helmet components for future players whose characteristics and attributes place them within the selected player group.

A total contact helmet, including a body that is customizable to contact surface contours of an individual's head and is made of a rigid material. A total contact helmet insert, including a body that is customizable to contact surface contours of an individual's head and is made of a rigid material, the total contact helmet insert being insertable under an existing helmet or as an inner shell as part of an existing helmet. A method of protecting the head of a user by the user wearing the total contact helmet, and when receiving an outside impacting force to the total contact helmet, distributing the force of impact over the surface area of the total contact helmet, wherein the total contact helmet remains undeformed after receiving the force.