Laser cutting is a highly accurate and efficient method for processing ultra-thin steel sheets, such as 0.018mm thick materials. This process utilizes a high-energy laser beam to achieve clean, precise cuts with minimal heat-affected zones (HAZ). It is ideal for industries requiring extreme precision, such as electronics, medical devices, and micro-engineering.
High Precision Micro-Cutting
Laser cutting can achieve micron-level precision, ensuring that ultra-thin steel sheets are cut with minimal deviation.
Suitable for intricate and detailed patterns required in microelectronics and medical applications.
Minimal Heat-Affected Zone (HAZ)
Due to the high focus of the laser beam and controlled pulse duration, the heat input is minimized.
Prevents material warping, distortion, or microstructural changes, which are common issues when cutting ultra-thin steel.
Clean, Burr-Free Edges
Provides smooth and clean-cut edges, reducing the need for secondary processing such as deburring or polishing.
Enhances the quality and performance of components used in precision applications.
Non-Contact Processing
Unlike mechanical cutting methods, laser cutting does not exert physical force on the material, preventing deformation.
Ideal for delicate and thin steel sheets that may be easily damaged by mechanical tools.
Custom & Complex Shape Cutting
Laser cutting can create intricate shapes, fine patterns, and micro-perforations that would be difficult with traditional cutting methods.
Enables precise customization for specialized industrial applications.
High-Speed & Efficient Processing
Laser cutting is faster than conventional mechanical cutting, increasing productivity and reducing production time.
Suitable for mass production with consistent quality.
Used for manufacturing microelectronic components, including semiconductor parts, connectors, and circuit boards.
Enables precise cutting of ultra-thin metal shielding layers used in high-frequency electronics.
Used in the production of stainless steel medical components such as micro-surgical tools, biopsy blades, and implantable medical devices.
High precision ensures biocompatibility and reliable performance in medical applications.
Used for fabricating ultra-lightweight components in satellites and aerospace applications where every gram matters.
Enables precise cutting of steel foils used in aerospace sensors and instrumentation.
Used in the production of ultra-thin steel layers for lithium-ion battery electrodes, fuel cells, and energy storage devices.
Ensures high conductivity and precision in battery component manufacturing.
High-precision laser cutting is used for manufacturing intricate watch components such as dials, gears, and decorative steel elements.
Used in fine jewelry and custom engraving applications.
Used for micro-cutting of thin stainless steel components in automotive sensors and precision assemblies.
Supports the production of miniaturized parts for electric vehicle (EV) battery systems.
✔ Extreme Precision – Achieves micron-level accuracy, essential for high-tech applications.
✔ Minimal Heat Effect – Prevents warping and maintains material integrity.
✔ Burr-Free Cutting – Produces clean edges, eliminating post-processing needs.
✔ Non-Contact Processing – Protects ultra-thin materials from mechanical damage.
✔ Complex Shape Cutting – Enables intricate designs and micro-perforations.
✔ High Speed & Efficiency – Optimized for mass production with repeatable accuracy.
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