Sophisticated CNC machines and latest technology enable us to deliver custom parts with high precision. Our 3-, 4-, and 5-axis machines allow diverse projects across industries. Precise cuts and versatile materials make CNC machining ideal for prototyping and small-batch manufacturing.
Depending on your design ,we will choose a CNC turning or CNC milling machine to process your products. 4-Axis CNC Milling 4-Axis CNC Milling Think of a design, and 4-axis milling can probablymake it. Multi-sided machining just got a whole lotsimpler.
3-axis CNC milling machine should be the most basic, with three linear axes X Y、Z. The advantages are simple structure, easy operation and maintenance, and low cost
On the basis of the 3-axis, an additional rotation axis has been added, This way, the workpiece can rotate, allowing for the processing of multiple surfaces without the need for re clamping. The advantage may be to reduce the number of clamping times and improve the processing efficiency of complex parts
5-axis CNC milling is based on three linear axes and has two rotating axes to achieve more complex machining, such as simultaneous multi-faceted machining, reducing clamping times, suitable for complex parts such as aerospace, molds, etc
| Description | |
|---|---|
| Aluminum | AL6061/ AL5052/ AL2024/ AL7075/ AL5083/ ADC12/ AL6082 |
| Stainless Steel | SUS301/ SUS303/ SUS304/ SUS316/ SUS316L/ SUS420/ SUS430/ SUS630/17-4PH/ SUS321 |
| Alloy Steel | Q235(A3Steel/ C45/ Cr12/ 3Cr13/ GCr15/ 40Cr/ 65Mn/ SKD11/ Steel 1018/ Steel 1020/
High speed steel/ Cold rolled steel/ Bearing steel/ SPCC |
| Stainless Steel | SUS301/ SUS303/ SUS304/ SUS316/ SUS316L/ SUS420/ SUS430/ SUS630/17-4PH/ SUS321 |
| Copper Alloy | H59/ H62/ H68/ H80/ Tin Bronze/ C17200/ Aluminum Bronze |
| Titanium | TA1/ TC4 |
| Plastic | ABS/ PTFE/ POM/ Bakelite/ PMMA/ PP/ PPS/ FR4/ HDPE/ LDPE/ PA6/ PA66/ PC/ PVC/ PU/ PEEK/
|
| Special Materials and Others | Carbon Fiber /Glass Fiber |
Surface treatment of CNC-machined parts can enhance corrosion resistance, wear resistance, and appearance quality, endow functional properties, and improve assembly performance, comprehensively enhancing the quality and practicality of the parts.
Machined surface is directly from CNC machine and it is cost effective BUT coming with tooling marks
Anodizing can improve the corrosion resistance of parts and can also be dyed, making it the most suitable for aluminum alloy parts
Polishing smoothes metal surfaces, minimizing roughness to create a high - gloss look that boosts their visual allure.
Sandblasting propels pressurized sand or alternative media onto the surface. This action both cleans the surface and imparts a consistent, matte texture.
Electropolishing, a chemical treatment method, refines and brightens metal surfaces, concurrently enhancing their resistance to corrosion.
Heat treatment modifies the mechanical characteristics of metal, aiming to heighten its hardness, strength, or enhance its ductility.
A brushed finish produces a one - way satin - like texture, which diminishes the appearance of marks and scratches on the surface.
The powder coating process can form a strong and wear-resistant coating surface, with the significant advantage of providing rich color choices and texture expression, while also having a wide range of substrate adaptability.
Electroplating adheres a thin coating of metal layer to components. This process serves to enhance their wear resistance, safeguard against corrosion, and boost surface conductivity.
Black oxidizing, a conversion coating technique applied to ferrous metals, not only enhances their corrosion resistance but also reduces light reflection.
Choose us for your CNC machining needs! With advanced equipment, skilled technicians, and a commitment to precision and efficiency, we ensure high - quality results and on - time delivery for all your projects.
In every project, you'll encounter precision like never before. Our state - of - the - art milling techniques guarantee that components meet extremely strict tolerances, with an accuracy of up to ±0.01mm. This precision paves the way for flawless assembly and outstanding operational performance.
Boost your manufacturing speed significantly. our local workshops equipped with advanced machinery, we ensure quick production turnarounds. This enables businesses to keep their operations running smoothly and hit crucial deadlines without a hitch.
Regardless of the time or location, approach your CNC milling projects with full assurance. Our experienced experts are by your side throughout the entire process, providing valuable advice. This ensures that your designs are optimized to the fullest and the output quality is top
We offer a one - stop service that encompasses every step from design verification, machining production, surface treatment, to packaging and shipping. In addition, we also provide assembly services to make your project process more convenient and efficient.
| 3-Axis CNC | 4-Axis CNC | 5-Axis CNC | |
|---|---|---|---|
| Suitable Parts | Disk - shaped parts (e.g., simple planar and slot - milling parts | Box - shaped parts requiring multi - surface machining or cylindrical side engraving | Complex curved - surface parts (e.g., aerospace components, impellers, and molds) |
| Machining Characteristics | Only one plane can be machined in a single clamping, and the workpiece direction needs to be adjusted multiple times | With the addition of rotation around the X - axis (A - axis), it can machine cylindrical sides and curved features | It can rotate around the X and Y axes (A and B axes) simultaneously, enabling continuous multi - angle machining and reducing the number of clampings |
| Size Range | Minimum: approximately 0.1mm Maximum: Limited by machine tool travel (usually ≤ 3m) | Similar to three - axis, but can handle longer cylinders (e.g., diameter ≤ 500mm) | High flexibility, capable of machining extremely small precision parts (e.g., 0.05mm) to large and complex parts (such as aerospace structural components up to 5m) |
| Typical Tolerances | General tolerance: ±0.05 - 0.1mm (ISO 2768 - m) High precision: ±0.01mm (requires special processes) | General tolerance: ±0.03 - 0.05mm Cylindrical surface machining: ±0.02mm | General tolerance: ±0.01 - 0.02mm Complex curved surfaces: ±0.005mm (synchronous five - axis machining) |
| Surface Roughness | Ra 1.6 - 6.3μm (affected by tool overhang vibration) | Ra 0.8 - 3.2μm (rotation axis improves cutting conditions) | Ra 0.4 - 1.6μm (short tool overhang + multi - axis linkage) |
| Cost and Efficiency | Low cost, suitable for mass production of simple parts | Medium cost, suitable for medium - complexity parts requiring multi - surface machining | High cost, but high efficiency in a single clamping, suitable for high - value - added parts |
CNC machining has a wide range of applications across industries. In the automotive and aerospace sectors, it is used to fabricate precise engine components, structural parts, and other intricate elements. The medical industry leverages CNC for manufacturing devices, implants, and surgical instruments. CNC is also crucial in electronics, enabling the production of electronic housings, circuit boards, and connectors. Machine tool makers rely on CNC to create complex molds, dies, and machine components. Additionally, CNC is valuable for general custom part production, prototyping, woodworking, and more, allowing for consistent quality and high precision.
Manufacturing Process: 3D printing is an additive process, building parts layer by layer from materials like plastic or metal. In contrast, CNC machining is subtractive, cutting away material from a solid block to shape the final product. Material Efficiency: 3D printing minimizes waste by using only the material needed to form the part, whereas CNC machining can produce more waste due to its subtractive nature. Speed and Cost: For small batches and complex geometries, 3D printing can be faster and more cost-effective. CNC machining is preferable for larger volumes and materials requiring high precision and strength. Surface Finish and Tolerances: CNC machining typically achieves better surface finishes and tighter tolerances compared to 3D printing.
Advantages of CNC Machining Precision and Repeatability: CNC machining ensures high precision and consistent replication of parts, crucial for complex designs with tight tolerances. Reduced Human Error: The automated nature of CNC machining minimizes human error, enhancing the overall quality of production. Efficiency and Speed: Automation allows for faster production cycles, enabling quicker turnaround times than manual processes. Material Flexibility: CNC machines can work with a diverse range of materials, including metals, plastics, and composites, offering versatility across various applications. Software Integration: Advanced CNC software supports quick design changes and updates, facilitating rapid prototyping and easy customization. Cost-Effective for Large Runs: While setup costs are higher, per-unit costs decrease significantly with larger production volumes, making it cost-effective for mass production.Disadvantages of CNC Machining High Initial Costs: CNC machinery and its maintenance represent significant investments, making initial setup expensive, especially for small-scale operations. Skill Requirements: Operating CNC machines requires highly skilled personnel, which can increase training costs and limit accessibility. Less Cost-Effective for Small Runs: Due to setup and programming time, CNC machining may not be economical for producing small quantities of parts. Material Waste: CNC machining often involves subtractive processes, leading to more material waste compared to additive manufacturing. Limited to Material Hardness: Extremely hard materials can wear out CNC tools quickly, potentially increasing operational costs and downtime.
G and M codes are the programming languages used in CNC machining to control CNC machine tools. G-codes are primarily used for specifying the movements of the machine, such as linear interpolation, circular movements, and other specific functions related to the actual path of the tool. M-codes, on the other hand, handle machine functions that are not directly related to the path of the tool, such as turning the machine on or off, starting or stopping the spindle, and controlling coolant. Together, G and M codes provide a comprehensive set of instructions that CNC machines follow to produce parts accurately and efficiently.
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