Abstract: Subject of the invention is a medical implant comprising a fiber reinforced silicone comprising (A) a silicone matrix and (B) fibers embedded in the silicone matrix, wherein the fibers comprise a comb polymer having a base polymer and side chains, wherein the base polymer is an organic polymer and the side chains comprise polysiloxanes. The invention also relates to outer shells of breast implants and uses and methods.

Abstract: Subject of the invention is a medical implant comprising a fiber reinforced silicone comprising (A) a silicone matrix and (B) fibers embedded in the silicone matrix, wherein the fibers comprise a comb polymer having a base polymer and side chains, wherein the base polymer is an organic polymer and the side chains comprise polysiloxanes. The invention also relates to outer shells of breast implants and uses and methods.

Abstract: A steering column assembly includes an outer jacket defining a through aperture and an inner jacket slidably disposed within the outer jacket. A plurality of steering shafts are movable relative to one another within the inner jacket. A frictional plate is disposed within the through aperture for selectively engaging the inner jacket. A radial force transmitting assembly is coupled to the frictional plate and applies a force on the frictional plate causing the frictional plate to engage the inner jacket. The radial force transmitting assembly includes a first cam member and a second cam each coupled to the frictional plate and each including a plurality of inclined surfaces facing one another. A lever is coupled to one of the cam members for rotating the other of the cam members for applying a force on the frictional plate to prevent movement of the steering shafts.

Abstract: A steering column assembly includes an outer jacket defining a through aperture and an inner jacket slidably disposed within the outer jacket. A plurality of steering shafts are movable relative to one another within the inner jacket. A frictional plate is disposed within the through aperture for selectively engaging the inner jacket. A radial force transmitting assembly is coupled to the frictional plate and applies a force on the frictional plate causing the frictional plate to engage the inner jacket. The radial force transmitting assembly includes a first cam member and a second cam each coupled to the frictional plate and each including a plurality of inclined surfaces facing one another. A lever is coupled to one of the cam members for rotating the other of the cam members for applying a force on the frictional plate to prevent movement of the steering shafts.

Abstract: Methods and systems using a numerical model to describe polymeric material properties are disclosed. FEM model of a product is defined. FEM model includes one or more solid elements of polymeric material. In a time-marching simulation of the product under loads, stress state of the solid elements is calculated from deformation gradient tensors. Stress state incorporates the Mullins effect and strain hardening effect, also includes elastic stress, viscoelastic stress and back stress. A yield surface is defined to determine whether the elements are under plastic deformation. Plastic strain is obtained to update the deformation gradient tensor, which is then used to recalculate the stress state. Calculations continue until updated stress state is within a tolerance of the yield surface, at which time the results of polymeric material elements are obtained. The numerical model takes into account all characteristics of a polymeric material.