- Analysis & Instrumentation
- Cleaning, Polishing & Grinding
- Coating & Surface Treatment
- Controlled & Modified Atmospheres
- Freezing & Cooling
- Fumigation & Pestcontrol
- Heat Treatment
- Inerting, Blanketing & Sparging
- Melting & Heating
- Petrochemical Processing
- Pharma & Biotechnology
- Plastic Molding, Foaming, Forming & Extrusion
- Process Chemistry
- Rubber Deflashing & Vulcanization
- Thermal Cutting
- Water & Soil Treatment
Plasma cutting uses the heat and pressure generated by a constricted electric arc to cut material. This cutting method relies on electrical power units and requires high open circuit voltage.
Plasma cutting uses the 'transferred arc' mode, where the arc is maintained between the electrode and the material to be cut. A pilot arc is struck between the electrode and the constricting orifice. This cutting process uses high plasma gas flows and active gases. Blowing in a secondary gas, which flows around the plasma arc as a gas sheath, further constricts the arc, causing the energy flow density and the temperature of the plasma jet to rise even further.
This method is associated with a high energy density heat source as this is required to melt and eject molten material in the high velocity plasma jet. It is suited to a wide range of ferrous and non-ferrous alloys and is particularly suited to aluminum alloys and stainless steel.
Key to the success of the plasma cutting process are the right plasma gases. Depending on the individual application, argon/hydrogen mixtures, nitrogen, air or even oxygen and water-cooled electrodes with tungsten tips may be suitable. Secondary gases include carbon dioxide, nitrogen and air.
We can support your cutting process with a range of pure gases and gas
mixtures tailored to the needs of plasma arc cutting. In addition, our
application experts can advise you on the mixture best suited to your
needs. They can also help you select the correct operating parameters
for optimum results and support you with the equipment and gas management services you