An overhead climb strength trainer apparatus comprises a frame bisected by at least one vertical frame portion, forming first and second climbing areas. First and second climbing panels are slideably mounted within the respective climbing areas and each include climbing holds and a panel hook. A line connects the first and second panel hooks, running through line guides and around a friction cylinder. The frame is configured for mounting at a predetermined angle of inversion for simulating an overhead climb as users manually raise and lower the first and second climbing panels in a reciprocating fashion within the first and second climbing areas respectively.

Systems and methods for providing climbing walls are discussed. While such systems and methods can include any suitable component, in some cases, they include a climbing wall that has a base member and a climbing surface that includes at least one climbing hold. In some cases, the climbing surface is pivotally connected to the base member. Additionally, in some cases, the system includes an anchor that is configured to adjustably retain the climbing surface at an angle with respect to the base member. In some cases, the system further includes a camera, microphone, and/or display that are configured to allow a climber to have audio and/or visual interactions with another person in a remote location (e.g., for training, competition, etc.). In some cases, at least one climbing hold on the climbing surface comprises a sensor that is configured to indicate when a climber has used that hold. Other implementations are described.

Embodiments of the present invention are directed to an adjustable-incline climbing wall. The climbing wall comprises one or more climbing panels supported by a frame and a system for adjusting the incline of the frame to provide a climbing wall of a desired incline. The incline of the climbing wall may be adjusted by activating an actuator, which extends the upper portion of the frame a distance from a support wall, tilting the climbing wall to a desired incline. When the climbing wall is substantially vertically oriented, the system for adjusting the incline of the climbing wall may extend only a small distance from the support wall so that the adjustable-incline climbing wall has a relatively small footprint. In some embodiments, the climbing wall may also comprise one or more fitness accessories that can brought to an optimal height for a particular user through adjustment of the climbing wall incline.

A climbing structure includes a support frame and a wall assembly. The wall assembly comprises a chain arranged as a loop with an array of climbing panels attached to the chain so as to maintain a configuration that rotates the climbing panels downward as the user climbs to achieve a continuous climbing experience. A lower shaft assembly includes a shaft that rotates based on an angle of the wall assembly. A sprocket is mounted to the shaft such that the shaft and the sprocket rotate independently to maintain tension on the chain as the climbing panels rotate downward. A cable hub assembly is rigidly attached to the shaft and secures a cable that is attached to the support frame. A disc braking system includes a disc rigidly attached to the shaft and a caliper mounted on bearing bolts such that the disc braking system fixes the angle of the wall assembly without affecting the continuous climbing experience.

Adjustable climbing walls for crack climbing at various gap sizes are provided. The adjustable climbing wall may have two panels and a slide for positioning one panel relative to another. An actuator may adjustably position each of the two panels along the slide. Aspects contemplated methods and systems for the adjustable climbing wall.

A climbing action structure includes a support structure having a plurality of columns configured to be fixed relative to an underlying surface and support at least one header of a plurality of headers above the underlying surface. A climbing action space is defined between the columns, the headers, and the underlying surface that is devoid of intruding structure. The headers define a plurality of action element mounts, each defining a longitudinal axis substantially parallel to the underlying surface. At least one action element is removably coupled to the support structure at a respective action element mount. The action element includes a top end having a header connection member. The header connection member being coupled to the respective action element mount and adjustably positionable along the longitudinal axis, and the action element is disposed within the climbing action space and a participant has 360° access to the action element therein.

A tower may support a horizontal track and a vertical climbing wall therebelow. A trolley, movable along the track, may be selectively driven toward and away from the tower by belay lines, line and capstan, positive drive, or some combination. Belay lines reeved over pulleys on the trolley may be taken up and paid out independently from the trolley, while fixed or moving. A rider may climb, be lifted, or both to near the intersection of the tower and track, from there to fall or jump into a controllable trajectory such as swinging or simulating a parachute landing. Swinging may be rapidly attenuated almost entirely by “bumps,” lifting a rider to remove momentum and kinetic energy as a rider moves toward a pivot point overhead. Control may be simplified based on sensing and using timing past bottom dead center (BDC).

A virtual reality (VR) system includes a VR display and a VR movement apparatus that includes hand interfaces and foot interfaces that can support the hands and feet of a system user. The VR movement apparatus allow the user's limbs to move in 3-dimensional space that include vertical, lateral, and fore-aft direction movements. A computer running VR software coordinate and synchronizes the VR movement apparatus and the VR display to provide system users with simulated activities in a VR environment.

System for physical mobility activity of a person, comprising at least one fixed support member and at least one contact member to be worn by the person In motion, wherein the support member and the contact member comprise at least one support surface and at least one contact surface, respectively, wherein the support surface and the contact surface constitute the respective components of a hook-and-loop fastening connection consisting of hooks and loops, wherein the hooks have hook stems and hook openings, wherein the hook openings on the support surface or contact surface in question are at least substantially all situated at the same side of the hook stems in question, when considered in a first direction parallel to the support surface or contact surface in question.

An amusement attraction features a wall structure, a respective set of illuminable handholds distributed over a wall surface of at least one upright wall of the structure, a floor surface residing adjacent to the upright wall on a side thereof faced by the wall surface, and one or more detection devices operable to detect landing of a participant on the floor surface during attempted traversal of the wall surface. A controller is operable to illuminate the handholds in different colour-coded patterns. Each pattern includes illumination of “authorized” handholds in a first colour, illumination of “prohibited” handholds in a second colour, and illumination of “targeted” handholds in a third colour. In a game-play session, participants are tasked with grasping of the targeted handholds while traversing the wall structure, with penalties applied for detected landing of participants on the floor surface and gripping of prohibited handholds.