Vacuum Induction Melting

Description: Consarc offers Induction Skull Melting (ISM) furnaces which is a method of melting metals in a segmented water-cooled copper vessel while under vacuum or controlled atmosphere using an induction coil. Consarc’s single chamber design is for low volume prototype

• Application: Foundry / Melting
• Atmosphere: Vacuum
• Heat Source / Transfer: Induction

Description: Consarc offers Induction Skull Melting (ISM) furnaces which is a method of melting metals in a segmented water-cooled copper vessel while under vacuum or controlled atmosphere using an induction coil. Consarc’s two chamber horizontal furnaces are excellent for the

• Application: Foundry / Melting
• Atmosphere: Vacuum
• Heat Source / Transfer: Induction

Description: Consarc offers Induction Skull Melting (ISM) furnaces which is a method of melting metals in a segmented water-cooled copper vessel while under vacuum or controlled atmosphere using an induction coil. Consarc’s two chamber vertical furnaces are excellent for the

• Application: Foundry / Melting
• Atmosphere: Vacuum
• Heat Source / Transfer: Induction

Description: Consarc offers Induction Skull Melting (ISM) furnaces which is a method of melting metals in a segmented water-cooled copper vessel while under vacuum or controlled atmosphere using an induction coil. Consarc’s tandem chamber design is designed for the production

• Application: Foundry / Melting
• Atmosphere: Vacuum
• Heat Source / Transfer: Induction

Description: Water cooled copper hearths hold reactive alloys during refining & melting

• Application / Industry: Nickel Base / Superalloys, Precious / Red Metals, Titanium / Reactive Metals
• Atmosphere Type: Inert, Reducing, Vacuum
• Bottom Type / Pour Method: Flat Bottom, Pouring Spout, Other
• Crucible Products: Melting Hearth / Tundish Liner, Other

Description: Water cooled copper hearths hold reactive alloys during refining & melting

• Application / Industry: Nickel Base / Superalloys, Precious / Red Metals, Titanium / Reactive Metals
• Atmosphere Type: Inert, Reducing, Vacuum
• Bottom Type / Pour Method: Flat Bottom, Round Bottom, Pouring Spout, Other
• Crucible Products: Melting Hearth / Tundish Liner

Description: For static melting or ingot withdrawal, adjustable slab width or thickness

• Application / Industry: Nickel Base / Superalloys, Precious / Red Metals, Titanium / Reactive Metals
• Atmosphere Type: Inert, Reducing, Vacuum
• Bottom Type / Pour Method: Flat Bottom, Pouring / Metering Hole
• Crucible Products: Melting Hearth / Tundish Liner, Other

Description: Modular construction through assembly welding or forged designs

• Application / Industry: Nickel Base / Superalloys, Precious / Red Metals, Titanium / Reactive Metals
• Atmosphere Type: Inert, Reducing, Vacuum
• Crucible Products: Melting Hearth / Tundish Liner, Other
• Furnace Type: Arc / Plasma Melting, Electron Beam Melting, Evaporator / CVD Furnace, Induction

Description: Carpenter VIM VAR Core Iron is a low carbon magnetic iron produced using vacuum induction melting plus vacuum arc re-melting practices. Other elements commonly found in low carbon irons are held as low as possible to ensure good DC magnetic properties. This double

• Applications: Other
• Elongation: 40 %
• Features: Cold Finished / Rolled / Drawn, Wrought
• Low Alloy / HSLA: Yes

Description: Carpenter VIM VAR Core Iron is a low carbon magnetic iron produced using vacuum induction melting plus vacuum arc re-melting practices. Other elements commonly found in low carbon irons are held as low as possible to ensure good DC magnetic properties. This double

• Applications: Other
• Features: Cold Finished / Rolled / Drawn, Wrought
• Low Alloy / HSLA: Yes
• Metal / Alloy Types: Other / Miscellaneous Ferrous Alloy (UNS K)

Description: , steel manufactured by vacuum-induction melting or consumable-electrode vacuum melting process; Class II, air-melted steel manufactured by electric-furnace vacuum degassing process; Class III, air-melted steel manufactured by electric-furnace ladle refining and

Description: , steel manufactured by vacuum-induction melting or consumable-electrode vacuum melting process; Class II, air-melted steel manufactured by electric-furnace vacuum degassing process; Class III, air-melted steel manufactured by electric-furnace ladle refining and

Description: This specification covers a group of common requirements that, unless covered by the individual product specification in another ASTM document, applies to steel forgings for general use. Materials shall be produced primarily by either electric-furnace, basic oxygen, vacuum-induction (VIM), or

Description: Tight tolerance capability Trade as Cerox® in USA Typically, these fired shapes are for the Vacuum Induction Melting (VIM) of Super Alloys and Nickel-based Steel Alloys. Designs would include crucibles, tundishes and launder systems. Thermal Ceramics is a World

• Type: Specialty / Other

Description: design is a key for achieving the required performance levels. Several medium carbon steels containing 0.07 wt pct P, 0.06 wt pct S and various amounts of Mn, Si, V, and N were produced by vacuum induction melting laboratory heats and hot working the cast ingots into plates. The

Description: operating temperatures, vibration, shock, and corrosive atmospheres. Assembled to heater by torch or induction brazing. the most common braze material for customer assembly is ASTM # Bag-1 (MP-1125/1145 Degree F.) Braze materials with melting points up to 1500 Degree F have been used

Description: Advantages Of Beryllium Oxide Ceramic Substrate Beryllium oxide ceramic substrate has the characteristics of high thermal conductivity, high melting, strength, high insulation, low dielectric constant, low dielectric loss and good packaging process adaptability. It is used in

• Applications: Electrical / HV Parts
• Density: 3.02 g/cc
• Material Type: Beryllia / Beryllium Oxide, Specialty Ceramic
• Thermal Conductivity: 200 to 250 W/m-K

Description: , austenitic, age hardening, and austenitic-ferritic stainless steels. Compacts shall be manufactured by placing a single powder blend into a can, evacuating the can, and sealing it. The powder shall be prealloyed and made by a melting method (such as but not limited to air or vacuum

Description: brittle materials, their melting point is higher than that of metals, and their linear expansion coefficient is quite different from that of metals, resulting in high residual stress in the welded joint between Ti (C, n) - based ceramic blades and tool rods, and poor compatibility with metals

• Material Type: Alumina / Aluminum Oxide