APPLYING METAL CONTAINING COATINGS CARBON CONTAINING

Brand Owner Address Description
EF OERLIKON SURFACE SOLUTIONS AG, PFÄFFIKON Churerstrasse 120 Pfäffikon 8808 Switzerland Applying metal-containing coatings and carbon-containing linings to work pieces;Machine parts for use in drive chains of vehicles, namely manual and automatic transmissions, axles and parts thereof, transfer cases, clutch plates, torque converters, synchronizers, limited slip differentials, shift forks, shifting elements, and wet running clutches; and machine parts, namely manual and automatic transmissions, axles and parts thereof, transfer cases, clutch plates, torque converters, synchronizers, limited slip differentials, shift forks, shifting elements, and wet running clutches with coatings and/or linings made of metal, carbon,carbon fiber, carbon sheet and/or friction linings;[ Lining materials of metal applied to work pieces; metal linings for use as protection of sliding parts from wear; and metal linings for use as protection from wear ];Reinforcing lining materials made of carbon fiber; linings for protection of sliding parts from wear; reinforcing linings for protection from wear made of carbon fiber materials; reinforcing linings made of carbon fiber materials; and friction linings for use with vehicles;Friction linings for use in the drive chain of a vehicle; friction linings for use with synchronizers, gearboxes and clutch forks; and vehicle brakes;
 

Where the owner name is not linked, that owner no longer owns the brand

   
Technical Examples
  1. Coatings for implantable electrodes consisting of single- or multi-walled nanotubes, nanotube ropes, carbon whiskers, and a combination of these are described. The nanotubes can be carbon or other conductive nanotube-forming materials such as a carbon-doped boron nitride. The nanotube coatings are grown "in situ" on a catalytic substrate surface from thermal decomposition, or they are bonded to the substrate using a metal or conductive metal oxide thin film binder deposited by means of a metal compound precursor in liquid form. In the latter case, the precursor/nanotube coating is then converted to a pure metal or conductive metal oxide, resulting in the desired surface coating with imbedded nanotubes.