Abstract: The exemplified systems and methods provide an extension cord system having a cord that is configured to slidably guide a movable plug carriage having conventional plug receptacle. In some embodiments, the movable plug carriage is configured with pierce-able conductors that can be inserted and retracted from a sealed skin of the cord. In other embodiments, the sealed skin can be fastened and unfastened by the movable plug carriage as the movable plug carriage moves over the cord. In yet other embodiments, the movable plug carriage is attachable and detachable from the cord.

Abstract: The invention discloses a method for adhering a metal layer to a polymer substrate and device manufacture therefrom. The metal layer is deposited on a sacrificial substrate of a mold to form part of an interior surface of the mold, and a solution of monomers is deposited on the metal layer. The monomers are then polymerized together to form the polymer substrate on the metal layer. Then the polymer substrate is removed from the mold such that the metal layer is removed from the mold and adhered to the polymer substrate.

Abstract: The invention discloses a method for adhering a metal layer to a polymer substrate. The metal layer is deposited on a sacrificial substrate of a mold to form part of an interior surface of the mold, and a solution of monomers is deposited on the metal layer. The monomers are then polymerized together to form the polymer substrate on the metal layer. Then the polymer substrate is removed from the mold such that the metal layer is removed from the mold and adhered to the polymer substrate.

Abstract: The exemplified systems and methods provide an extension cord system having a cord that is configured to slidably guide a movable plug carriage having conventional plug receptacle. In some embodiments, the movable plug carriage is configured with pierce-able conductors that can be inserted and retracted from a sealed skin of the cord. In other embodiments, the sealed skin can be fastened and unfastened by the movable plug carriage as the movable plug carriage moves over the cord. In yet other embodiments, the movable plug carriage is attachable and detachable from the cord.

Abstract: Embodiments of the invention are directed to softening amorphous polymeric materials based on a combination of thiol, acrylate, ene and epoxy monomers. These materials can soften to the modulus of tissue, have a sharp transition and are highly tunable. The materials have a glassy modulus of 1-7 GPa and exhibit a rubbery plateau in modulus that can range from 100 MPa down to as low as 0.03 MPa, which is at or below the modulus of tissue. They have potential uses as materials for near net shape processing such as casting, stereolithography, reaction injection molding, fused deposition molding and various other forms of 3D printing.

Abstract: The invention described herein consists of a process that enables increased adhesion of thin film materials (such as metals, metal oxides, carbon nanotubes or other materials) to solvent and temperature sensitive, and non-planar, polymer substrates and the fabrication of softening electronics. Importantly, this process can be used to create exceptional embodiments of the disclosed flexible electronic devices having dynamic properties that make them suitable for implantation in the human body.

Abstract: Embodiments of the invention is directed to a manufacturing process to mold and cast custom softening polymers into complex shaped devices, said process comprising the steps of: creating a 3D mold or shell; injecting the shell with a polymer or pre-polymer; cooling or curing the polymer in a short period of time; and forming a device.

Abstract: Embodiments of the invention are directed to softening amorphous polymeric materials based on a combination of thiol, acrylate, ene and epoxy monomers. These materials can soften to the modulus of tissue, have a sharp transition and are highly tunable. The materials have a glassy modulus of 1-7 GPa and exhibit a rubbery plateau in modulus that can range from 100 MPa down to as low as 0.03 MPa, which is at or below the modulus of tissue. They have potential uses as materials for near net shape processing such as casting, stereolithography, reaction injection molding, fused deposition molding and various other forms of 3D printing.

Abstract: Disclosed herein are tunable shape memory polymers (SMP's) and methods for manufacturing the disclosed SMP's.

Abstract: The invention is directed to shape memory polymer compositions, articles of manufacture thereof, and methods of preparation and use thereof. The invention is further directed to methods of controlling the nature of the interaction of a shape memory device with the environment in which it is operating.

Abstract: Disclosed herein are tunable shape memory polymers (SMP's) and methods for manufacturing the disclosed SMP's.