Using plasma arc cutting to clean-cut stainless steel sheet
To clean-cut stainless steel sheet and plate, fabricators first must choose the right CNC cutting equipment and then set the correct process-related variables. Precise machine motion controls, torch-to-material distance control, and the correct plasma and assist gases all are crucial to producing weld-ready plasma-cut edges on all stainless steel thicknesses.
To cut stainless steels and other metals with plasma successfully, fabricators need the following tools:
1. Precision machine motion controls
2. A smooth linear drive system
3. Software controls that automatically compensate and provide proper speed and acceleration and deceleration for various part features
Machine Motion Control
During the plasma cutting process, material is in the molten state inside the kerf zone. Mechanical problems such as motion irregularities cause vibrations, which transfer through the machine axis into the cut edge. These vibrations are solidified into the cut surface and can be easily mistaken for process problems. These motion irregularities and/or vibrations cause a rough-cut surface, nonlinear cut edges, and overall poor cut quality.
Torch Tip-to-Material Distance Control
To initiate the cutting process, a pneumatic probe locates the material position and provides an accurate and repeatable pierce height. After the pierce is made, the plasma arc cutting (PAC) voltage from the plasma power unit is used in a closed-loop process control system to maintain torch-to-material height while cutting.
Automatic voltage control precisely maintains the torch tip-to-material distance. This is vital when processing thin sheet and stainless steel plate.
Plasma Gases
Fabricators can process stainless steel with clean-cut surfaces by using nitrogen or a blend of oxygen and nitrogen as a plasma gas. These plasma gases provide a nonoxidizing plasma arc, which produces a clean-cut edge that is weld-ready without secondary operations.
Nitrogen also increases electrode life by preventing oxide formation on the tip of the halfnium electrode. Halfnium is used as the metallic element in the electrode, which also is compatible with oxygen as a plasma gas for steel cutting.
Pure oxygen is not recommended as a plasma gas for stainless steel cutting because of its oxidizing characteristics, which leave an oxidized, contaminated cut edge.
Compressed air is not used for cutting because it often is contaminated with water, oil, or other contaminants. These contaminants can cause regulator and solenoid valve breakdown, as well as plasma double-arcing.
Assist Gases
The type of stainless steel assist gas (or shield gas) to use varies according to the material thickness and the desired cleanliness of the cut edge. Based on each assist gas type and the material thickness, different conditions and chemical reactions result.
The five main assist gases are:
1. Compressed air.
2. Carbon dioxide.
3. Nitrogen plus hydrogen.
4. Nitrogen plus propane.
5. Nitrogen.
The assist gas serves multiple purposes:
-- It helps to prevent molten pierce metal from coming into contact with the nozzle and shield cap during piercing and cutting.
-- It protects the nozzle and shield cap from double-arcing.
-- It offers a method for high-speed flushing of the kerf during cutting with pure nitrogen.
-- It produces a chemical reaction with hydrocarbons or other reactive gases.
Advanced Piercing Controls
Advanced piercing controls used in clean-cutting stainless steel sheet and plate include:
1. Automatic pilot current control: This sets the proper pilot amperage needed for various cutting conditions and pierce heights. Pilot current relates directly to the plasma gas type, pressure, nozzle size, and piercing height.
As the material thickness increases, higher pierce heights are necessary to prevent shield cap and nozzle damage. This is achieved by using higher pilot current to connect the pilot arc to the workpiece. If pilot currents are set too high, however, premature nozzle or electrode failure can occur if the pilot arc current burns the nozzle.
2. Start gas pressure control: This minimizes the amount of pilot current necessary to generate the pilot arc. The higher the plasma gas pressure setting is, the more pilot current, high frequency, and start voltage are needed to create the pilot.
3. Two-step pierce height control: Piercing is initiated at 0.250 inch or less before the torch retracts to a programmed final height. After the main arc transfer has taken place, the torch automatically rises to the final height, away from pierce splatter, until the piercing is complete. The shield cap and nozzle are protected from damage even when piercing 0.750-inch stainless steel.
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