A wearable article such as an article of athletic gear (e.g., a skate, an article of protective athletic equipment such as a helmet, etc.) wearable by a user and comprising an expandable user-engaging structure that is configured to be expanded (e.g., by heat or another stimulus) after manufacturing of the wearable article to conform it to the user or otherwise improve a fit of the wearable article on the user.

Products related to the field of protective guards for practicing combat sports are disclosed herein. One training gear set for combat sports can include a shin guard and a concave calf pad. The calf pad can be detachably attached to the shin guard. The shin guard and calf pad can include attachment means and can be detachably attached to each other via the attachment means. The Shing guard and calf pad can be prepared so that the attachment means are not exposed when the calf pad and the shin guard are in an attached position.

A shin guard includes a protective plate having a front face and a rear face. The rear face is contoured to fit around a shin of a wearer of the shin guard. Further, the shin guard includes a three dimensional image element carried on the front face. This image element projects an image outline through a sock worn over the shin guard.

A leg pad (e.g., a hockey leg pad) for protecting a leg of a user, in which the leg pad is designed to enhance protection and freedom of movement (e.g., during skating strides), such as by providing flexibility of the leg pad proximate to a knee and optionally an ankle of the user (e.g., for extension and optional retraction of one or more parts of the leg pad) to better follow natural movements of the user's leg (e.g., bending of the knee and optional flexion of the ankle of the user).

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).

A training system, kit, and method including a weighted wearable equipment, e.g. gloves, having a sensor (e.g. accelerometers, gyroscopes, photoelectric sensors, position sensors, tilt sensors, pressure sensors, temperature sensors, blood pressure sensors, heart rate monitors, and SpO2 sensors) and including a weight enhancement (e.g. weight bodies in closed pockets); a non-weighted wearable equipment of the same type as the weighted wearable equipment, the non-weighted wearable equipment having a sensor and. not including a weight enhancement; and a training application in functional communication with each of the weighted wearable equipment and the non-weighted wearable equipment and having a data processor that includes instructions for: analyzing data received from the sensor of each of the weighted wearable equipment and the non-weighted wearable equipment and generating predictive information derived from exercise training data from the sensors.

In one embodiment, a particular state of a body is sensed. In response to the sensing, at least one action is taken to modulate a projected adverse interaction between the body or a portion thereof and at least one object in the environment of the body.

An apparatus, methods and computer program product, and system are described that enable a first subset of actuatable cushioning elements for a first time period, enable a second subset of actuatable cushioning elements for a second time period, determine an event, and actuate, based on a time the event is determined, at least one of the first and the second subsets of actuatable cushioning elements to provide cushioning support for an object. Other example embodiments are also provided relating to actuatable cushioning elements.

An apparatus, methods and computer program product, and system are described that enable a first subset of actuatable cushioning elements for a first time period, enable a second subset of actuatable cushioning elements for a second time period, determine an event, and actuate, based on a time the event is determined, at least one of the first and the second subsets of actuatable cushioning elements to provide cushioning support for an object. Other example embodiments are also provided relating to actuatable cushioning elements.

An apparatus, method, computer program product, and/or system are described that determine an event, actuate a cushioning element in response to the determining the event, the cushioning element including one or more tension-bearing members, and dissipate at least some of an energy associated with a collision based on deforming at least one of the tension-bearing members during the collision, the deforming including substantially inelastically stretching the at least one of the tension-bearing members. Other example embodiments are also provided relating to actuatable cushioning elements.

An apparatus, method, computer program product, and/or system are described that determine an event, actuate a cushioning element in response to the determining the event, the cushioning element including one or more tension-bearing members, and dissipate at least some of an energy associated with a collision based on deforming at least one of the tension-bearing members during the collision, the deforming including substantially inelastically stretching the at least one of the tension-bearing members. Other example embodiments are also provided relating to actuatable cushioning elements.

An apparatus, method, computer program product, and/or system are described that determine an event, actuate a cushioning element in response to the determining

A lower leg guard device is disclosed allowing a full range of ankle motion, while at the same time preventing impact injuries to the lower leg, including the Achilles area, the ankle, and the shin. The lower leg guard device includes two substantially rigid exterior shells each with a cushioned interior liner. The lower leg guard device can be securely attached to the lower leg with one or more attachment straps, and with at least one floating attachment pad that attaches to the wearer's footwear. A floating attachment pad can be positioned over both the inner side and outer side of the ankle, preferably attached to footwear that covers the ankle. The floating attachment pads are attached to the footwear using removable fasteners, located on the exterior surface of the footwear worn by the wearer, so that the guard device can be quickly and easily put on and removed.

The invention comprises an elastomeric athletic or orthopedic brace, support for a joint complex and is a network of interlinking elastomeric bands that extend radially from a hub member to support a joint in tension but provide for controlled hinging about an axis defined through the hub member. In particular, the brace is provided for an ankle.

An article made from an auxetic material, the auxetic material having a plurality of unit structures joined together, is provided. The unit structure includes a first strut element, and a second strut element joined to the first strut element. Each of the first strut element and the second strut element have a predetermined thickness and width, wherein the first strut element being connected to the second strut element at a predetermined re-entrant angle (Θ). Further, the first strut element includes a top first strut element, and a bottom first strut element, and the second strut element includes a set of top second strut elements and a set of bottom second strut elements and wherein the strut element of the set of top second strut elements being connected to respective strut member of the set of bottom second strut elements.