Provided are an electrode structural body for a highly sensitive protrusion type pressure sensor and a method for manufacturing the same. According to the electrode structural body of the present invention, an electrode is formed along a protruding structure, so that deformation of the protruding structure may be sufficiently sensed to achieve high sensitivity even in a low pressure range and a polymer layer may be further introduced to the outside of the electrode to achieve excellent stability.

Provided is a method to form a thermoplastic composite with electrically and thermally conductive constituents. The method may include receiving a molten rod having a polymer composite core. The method may further include embedding the rod with at least one conductive wire. Embedding the rod with the at least one wire may include wrapping the at least one conductive wire around the rod and tensioning the wire thereby causing the wire to at least partially embed into the rod.

A wiring body includes a substrate, a mesh-like conductor layer provided on the substrate, and a resin layer covering the conductor layer, in which the resin layer includes a first resin layer and a second resin layer in order from the substrate side, and the conductor layer passes through the first resin layer.

A flexible electrode apparatus for bonding with a SEEG electrode includes: at least one wire electrode which is implantable and flexible, wherein each wire electrode includes: a wire located between a first insulating layer and a second insulating layer of the flexible electrode; and an electrode site located on the second insulating layer and electrically coupled to the wire via a through hole in the second insulating layer, wherein the at least one wire electrode is configured to be affixed to the SEEG electrode and is in contact with a biological tissue after the SEEG electrode is implanted.

A method of manufacturing a corrosion-resistant wireline cable includes embedding a first layer of armor wires onto a core cable using a heated carbon fiber reinforced polymer. A second layer of carbon fiber reinforced polymer is then extruded to envelop the first layer of armor wires. In one method, a layer of virgin or colored polymer is extruded over the second layer, and a second layer of armor wires is embedded through the virgin or colored polymer, displacing it to envelop the outer armor wires. In another method, each wire in the second armor layer is coated with virgin polymer before being embedded into the second carbon fiber reinforced polymer layer. The assembly is then heated to cause the virgin polymer to migrate outward, forming an outermost layer. In both methods, a final jacket layer is applied over the exterior to complete the cable. The resulting cable provides corrosion resistance and mechanical reinforcement.

A nanomembrane and a forming method thereof are provided. The nanomembrane according to embodiments of the present invention comprises an elastomer layer and nanostructures disposed on the elastomer layer. The method for forming a nanomembrane according to embodiments of the present invention comprises forming a nanocomposite solution comprising nanostructures and an elastomer solution, forming an elastomer solution layer by providing the nanocomposite solution on a first solvent, and forming an elastomer layer by drying the elastomer solution layer, and forming a nanomembrane comprising the elastomer layer and the nanostructures bonded to the elastomer layer. The nanocomposite solution is formed by mixing the nanostructures and the elastomer solution with a second solvent, and the elastomer solution is formed by mixing elastomer and a third solvent.