Computer-programmed milling machines enable high-precision, high-efficiency machining of metal and plastic components. Capable of machining complex contours, surfaces, holes, and slots, CNC milling is widely used in mold making, aerospace, and precision instrumentation. It supports multi-axis simultaneous machining, achieving micron-level accuracy.
View More ›Computer-controlled lathes automatically and precisely machine rotational parts such as shafts and disks. Efficiently performs external and internal turning, threading, grooving, and other complex features, with machining accuracy up to ±0.01 mm. Widely applied in mass production of precision parts for industries including automotive, aerospace, and medical.
View More ›Utilizes a high-speed moving metal wire (molybdenum or copper) to perform electrical discharge machining on conductive materials, enabling ultra-precise profile cutting. Specialized in cutting complex, irregular shapes from high-hardness metals (such as hardened steel and hard alloys), with machining precision up to ±0.005 mm and surface roughness Ra 0.4 μm, with no risk of deformation due to cutting forces.
View More ›Uses high-energy laser beams for precision cutting, welding, marking, or surface treatment of both metals and non-metals, all as non-contact processes. Features high precision (±0.1 mm), no mechanical stress, and strong flexibility, making it especially suitable for machining complex shapes and for precision processing of thin materials.
View More ›Utilizes the high temperatures generated by pulsed discharges between an electrode and the workpiece to precisely shape high-hardness, conductive materials. Divided into two main types: Wire EDM and Die-Sinking EDM. Particularly effective for machining ultra-hard alloys and complex cavities that are difficult to process using traditional cutting methods.
View More ›Employs processes such as laser cutting and CNC bending to accurately form metal sheets into complex structural components, with tolerances up to ±0.1 mm. Widely used in the manufacturing of enclosures, brackets, and other precision metal products.
View More ›Rapidly manufactures complex structural components by layer-by-layer deposition of materials (metal/plastic/resin), overcoming the limitations of traditional machining, enabling lightweight, integrated designs, and reducing product development cycles by up to 70%.
View More ›Uses high-precision grinding machines for micron-level material removal, achieving surface roughness as low as Ra 0.01 μm and ultra-high accuracy up to ±0.001 mm, making it ideal for the final finishing of high-hardness materials such as ceramics and hard alloys.
View More ›Achieves mirror-like surface finish (Ra ≤ 0.01 μm) through mechanical grinding or chemical treatment, enhancing corrosion resistance, sealing performance, and aesthetics. This is crucial for medical devices, optical components, and high-end molds.
View More ›Utilizes specialized drilling technologies (gun drilling/BTA drilling) to achieve high-precision deep holes with diameters ranging from Φ0.5 to 300 mm and depth-to-diameter ratios up to 100:1, ensuring straightness ≤ 0.1/1000 mm. Especially suited for machining internal channels in critical parts such as hydraulic valve bodies and aircraft landing gear.
View More ›Employs precisely controlled chemical etching to selectively dissolve metallic or non-metallic materials at the micron level, enabling stress-free fabrication of complex, precise components (such as ultra-thin filters and microchannel plates) with accuracy up to ±0.02 mm. Especially suitable for precision forming of ultra-thin or ultra-hard materials that are difficult to process by conventional machining.
View More ›Enhances corrosion resistance, hardness, or appearance of parts through processes such as electroplating, spraying, and anodizing, extending service life and meeting stringent industry standards in fields like medical and automotive. Customizable coating and plating combinations available.
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