Device for coating turbine components

What is claimed is: 1. A coating device, comprising: electro-spark deposition (ESD) equipment including a power supply and an ESD torch electrically connected to the ESD equipment, the ESD torch including: an inert gas source; a vibration source; a housing defining a cavity; a spring positioned within the housing cavity and operably coupled to the vibration source to create a linear vibration in a controlled direction along an axis of the housing cavity; an electrode disk holder contained within the housing cavity defining a disk holder cavity and formed from a conductive material, the electrode disk holder operably coupled to the vibration source; an electrode disk including a conductive material, the electrode disk at least partially disposed within the electrode disk holder cavity and removably attached to the electrode disk holder by a pin, the electrode disk operably coupled with the electrode disk holder; a torch cup extended from the housing and encloses the electrode disk; and an inert gas lens surrounding the spring and at least a portion of the electrode disk holder within the housing cavity so at least a portion of the housing cavity defining an inert gas cavity between the electrode disk holder and the torch cup; wherein during operation of the coating device, the vibration source linearly vibrates the electrode disk holder and the electrode disk along the axis, creating an air gap between the electrode disk and a surface of the work piece; wherein in response to the housing following a contour of the work piece surface, the electrode disk rolls along the work piece surface; and wherein the inert gas source is configured to provide the inert gas to the housing cavity. 2. The coating device of claim 1 , wherein the coating device is portable. 3. The coating device of claim 1 , wherein the electrode disk is selected from nitinol, conductive cobalt based alloys, and conductive carbides. 4. The coating device of claim 1 , wherein the electrode disk includes approximately 50.2 to approximately 50.8 atomic percent nickel and balance titanium. 5. The coating device of claim 1 , wherein the electrode disk intermittently contacts the work piece surface during operation of the coating device. 6. The coating device of claim 1 , wherein the pin is rotatable. 7. The coating device of claim 1 , wherein the inert gas is helium, argon or a combination thereof. 8. The coating device of claim 3 , wherein the electrode disk is nitinol.