Joining Technologies

CLADDING/ADDITIVE

Joining Technologies Additive uses laser cladding of metal powder alloys to enhance, repair or free-form material for applications in power generation, oil & gas exploration, industrial heavy equipment, petrochemical and aerospace. Our new facility enables us to find solutions for components weighing over seven tons and up to 40 feet in length. Some items JTAD currently specializes in include IGT component repair, boiler/superheater overlays and valve hardfacings.

Our new Laser Additive facility in East Granby Connecticut now offers our clients the ability to perform robotic and Cartesian laser cladding and direct manufacturing for components from the very small up to 40ft and 7.5 tons.

Our precision laser cladding processes allow us to accomplish virtually unlimited build-up heights in complex geometric dimensions, all while achieving full metallurgical bonds. Scott Poeppel Additive Processes Manager

WHY LASER ADDITIVE
Laser Additive Manufacturing, Joining Technologies

The unprecedented precision and reliability of our laser cladding processes is now available to private industry. As a leading provider of LAM (Laser Additive Manufacturing) surface restoration technology, we’re able to create true metallurgical bonds between virtually unlimited metal types. Precisely focused lasers enable us to create an extraordinarily small heat affected zone and dilution zone for superior strength, hardness and performance.

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APPLICATIONS
Joining Technologies uses laser cladding of metal powder alloys to enhance, repair or free-form material for applications in aerospace, power-generation, valve and OEM-supplied components. Our laser additive processes offer positional accuracy while maintaining material quality and metallurgical bonding.

LAM ADVANTAGES

4140 repair of a shaft - Heavy Manufacturing Equipment

The laser additive manufacturing process is used to laser clad metal powder alloys when enhancing or repairing parts. Using a laser to create a melt-pool on the workpiece, powdered metal is fed through a nozzle into the weld puddle, creating a clad layer. Unlike HVOF, the LAM process achieves a full metallurgical bond by fully melting the surface of the substrate while applying powder. The precisely targeted heat of the laser allows for lower penetrations of the parent material, resulting in a smaller Heat Affected Zone (HAZ) and a lower dilution rate. This translates to an enhanced grain structure and lower minimum clad thickness required to achieve desired hardness, as compared to PTA applied clads. Parametric accuracy of the system allows for clad layers as thin as 0.004”, with maximum clad thicknesses ranging over 3”.

alloys being deposited

• Inconel 625
• Inconel 718
• Stellite 6
• Stellite 21
• Waspaloy
• IN100
• 17-4 PH
• 347 SS
• 316 SS
• 304 SS

• 410 SS
• 420 SS
• H-13
• Tungsten Carbide
• Nickel Chrome Carbide
• 4047 Aluminum
• 4140 steel
• Titanium
• Various proprietary alloys

Feature Project - Connecticut Corsair Restoration Project

features

• Minimal surface prep
• Permanent metallurgical bond
• Small heat affected zone
• Less chipping, peeling or cracking
• Reduced corrosion
• Lower dilution
• Reduced retooling
• Unlimited surface heights
• Unprecedented reliability
• Long-term cost savings

downloads

Laser Additive Manufacturing Brochure
PDF - 728 KB

LAP® for Manufacturing and Aerospace Applications
PDF - 244 KB

Reduce, Reuse, Resurface
Remanufacturing with Laser Cladding. Click to listen

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