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Product Overview

ALD Managementpolitik Stand Juli. 2019Corporate Policy

Corporate Policy for the Correct Handling of Conflict Minerals EN

Vacuum Induction Melting & Remelting

Vacuum Induction Melting (VIM 02 - 100)

Vacuum Induction Melting (VIM 100 - 4000)

Vacuum Induction Degassing (VID 400 - 4000)

Laboratory Remelting Systems

Vacuum Arc Melting (VAR)

Electro Slag Remelting (ESR)

Electron Beam Melting (EB)

Plasma Arc Melting (PAM)

Vacuum Investment Casting

Vacuum Induction Melting (VIM-IC)

Titanium (Leicomelt, VAR Scull Melter)

Thermal Barrier Coating

Turbine Blade Coating (TBC, Smart Coater)

Metal Powder

Metal Additive Manufacturing (VIGA)

Silicon Melting & Crystallization

Silicon Melting & Crystallization (SCU)

Other Furnaces

High Vacuum Resistance Furnace (WI)

Induction Heated Quartz Tube (IWQ)

Additive Manufacturing

EBuild – Additive Manufacturing of Metals at Industrial Scale

DualTherm

VKP

ModulTherm

MonoTherm

SyncroTherm

ALD Expert Strategy Produkt Portfolio

General Terms and Conditions of ALD Vacuum Technologies GmbH:


PAM – Plasma Arc Melting furnace


SyncroTherm


ModulTherm 2.0


Heat Treatment Service


Plasma Arc Melting furnace
For the melting and remelting of Alloys (e.g. Titanium Alloys, Titanium Aluminides) which contain larger amounts of alloying elements with high vapor pressure that would evaporate under deep vacuum conditions, the plasma arc melting process (PAM) is the first choice. Using plasma arc melting, the metal is melted under inert gas atmosphere (usually Helium or Argon) in a pressure range between 400 – 1,200 mbar abs. The plasma arc torch column provides the heat source with maximum temperatures well above 15,000 K. Under these process conditions evaporation of alloying elements can be suppressed and complex alloy compositions can be produced.


Plasma Arc Melting furnace
For the melting and remelting of Alloys (e.g. Titanium Alloys, Titanium Aluminides) which contain larger amounts of alloying elements with high vapor pressure that would evaporate under deep vacuum conditions, the plasma arc melting process (PAM) is the first choice. Using plasma arc melting, the metal is melted under inert gas atmosphere (usually Helium or Argon) in a pressure range between 400 – 1,200 mbar abs. The plasma arc torch column provides the heat source with maximum temperatures well above 15,000 K. Under these process conditions evaporation of alloying elements can be suppressed and complex alloy compositions can be produced.


SyncroTherm


SyncroTherm


ModulTherm


ModulTherm


Heat Treatment Service


Heat Treatment Service