Abstract: An exoskeleton to support and move a large character costume and to transfer weight of the costume away from a performer's body. The exoskeleton includes a spine including an elongated and rigid vertical member and also includes a waist ring configured to extend about a waist of a performer using the exoskeleton in a spaced apart manner. A lower end of the spine is attached to a rear center portion of the waist ring. The exoskeleton includes a pair of leg assemblies each pivotally coupled on opposite sides of the waist ring. Each of the leg assemblies is spaced apart from a leg of the performer and extends below a foot of the performer, whereby weight is transmitted to a support surface. Each of the leg assemblies may include at least one passive assist mechanism configured to assist the performer in moving the exoskeleton with bipedal locomotion.

Abstract: Rebar-based support assemblies that can be fabricated without the need for on-site welding. The assemblies include a number of differing sized and shaped crimps used in place of welds to provide rebar assembly-to-rebar assembly connections. Each crimp mechanically couples two or three pieces of rebar together, such as a border bar of one rebar assembly to a border bar of an adjacent rebar assembly. Each crimp includes a body with two or more arcuate recessed surfaces each for receiving a piece of rebar. In a first configuration of the crimp, a pair of spaced-apart arms (or extending members) extend from the body and define an opening through which the rebar is passed and set into the recessed surfaces. A deformation force is applied upon the two arms to deform the body into a second configuration with the arms in abutting contact or nearly so at an outer tip or end.

Abstract: A method for fabricating an artificial skin system such as skin for use with a robotics assembly. The method includes forming or accessing a digital three dimensional (3D) model of an object. The digital 3D model defines a topography of an exterior surface of the object. The method includes processing the 3D model to generate a 3D model of a core, including defining an exterior surface of the core with a topography that is an inverse copy of the topography of the exterior surface of the object. The method includes fabricating the core based on the core model, whereby the core has an exterior surface corresponding to the exterior surface of the core model. The core is used in dipping processes or injection molding processes to form a skin in which the exterior surface is formed of material that abutted the inverse topography of the exterior surface of the core.

Abstract: A method for fabricating an artificial skin system such as skin for use with a robotics assembly. The method includes forming or accessing a digital three dimensional (3D) model of an object. The digital 3D model defines a topography of an exterior surface of the object. The method includes processing the 3D model to generate a 3D model of a core, including defining an exterior surface of the core with a topography that is an inverse copy of the topography of the exterior surface of the object. The method includes fabricating the core based on the core model, whereby the core has an exterior surface corresponding to the exterior surface of the core model. The core is used in dipping processes or injection molding processes to form a skin in which the exterior surface is formed of material that abutted the inverse topography of the exterior surface of the core.