Key Characteristics of Laser Cutting
Key Characteristics of Laser Cutting:
Precision: Capable of cutting with tolerances as tight as ±0.1 mm.
Edge Quality: Produces smooth, clean edges that often require no further finishing.
Versatility: Suitable for cutting a wide range of materials, including metals, plastics, wood, and glass (depending on the laser type).
Minimal Heat-Affected Zone: The focused beam minimizes thermal distortion of the surrounding material.
Plasma Cutting Working Principle:
Plasma cutting is a process that cuts through electrically conductive materials using a jet of hot plasma. Here’s a step-by-step explanation of how plasma cutting works:
Power Supply and Gas: A plasma cutter uses a power supply to generate a direct current (DC) arc and a gas supply (usually compressed air, nitrogen, or oxygen) that will form the plasma.
Arc Initiation: The plasma cutter starts an arc between an electrode (situated in the torch) and the workpiece. This can be initiated by:
Contact Start: Touching the torch tip to the workpiece to complete the circuit.
High-Frequency Start: Using a high-voltage, high-frequency circuit to ionize the gas without contact.
Plasma Formation: The gas is forced through a narrow nozzle inside the torch at high speed. As the gas passes through the electrical arc, it becomes ionized, transforming into plasma—a hot, electrically conductive gas.
Material Melting and Removal:
Melting: The plasma reaches temperatures up to 30,000℃ (54,000℉), instantly melting the metal at the point of contact.
Blowing Away Molten Metal: The high-velocity plasma stream blows the molten metal away from the cut, creating a kerf.
Cutting Torch Movement: Similar to laser cutting, CNC systems control the movement of the plasma torch to follow the desired cutting path accurately.
For high-quality laser and plasma cutting systems, explore AccTek CNC.