A comprehensive guide to CNC machining materials
At its core, CNC machining involves the automated control of machining tools and systems, including milling machines, CNC lathes, and grinders, through computers. This manufacturing process transforms a digital model into a final part through a continuous material removal technique. The importance of CNC machine tools lies in their ability to produce complex parts with high precision and repeatability, which is critical to industries ranging from aerospace to automotive.
Despite the advancements in CNC machining, defects are inevitable. These defects range from surface unevenness to tool breakage, each of which affects the final quality of the machined part. Addressing these defects is more than just correcting errors, it requires a comprehensive understanding of the machining process, tool materials, and workpiece materials.
1.Metals
Different metals react uniquely to CNC machining processes, and each metal has its own specific challenges and common defects.
①Aluminum
- Burrs: Due to its softness, aluminum often forms burrs, which are small raised edges or fragments of material that remain attached to the workpiece after the modification process.
- Adhesion to cutting tools: Aluminum can adhere to cutting tools, adversely affecting surface finish and even causing more serious defects.
- Thermal expansion: Aluminum is very sensitive to heat, which causes it to expand during machining. This expansion can result in inaccurate dimensions in the final product.
②Stainless steel
- Work hardening: Stainless steel hardens when subjected to heat and pressure during machining, which makes it more difficult to machine.
- Tool wear: The hardness and abrasiveness of stainless steel can cause tools to wear quickly, requiring more frequent tool replacement and maintenance.
- Chatter: The toughness of stainless steel can cause vibration and chatter during machining, which can reduce the quality of the workpiece.
③Titanium
- Heat generation: Excessive heat is often generated when machining titanium, resulting in potential tool damage and material deformation.
- Chemical reactivity: Titanium can chemically react with certain cutting fluids used during machining, which may require special consideration in the choice of cutting fluid.
④Brass
- Ease of machining: Brass is generally easier to machine with fewer defects. However, maintaining sharp cutting tools is essential to maintaining accuracy in the final product.
2.Plastics
①Acrylic
- Cracking: This material is prone to cracking, especially if it is not properly supported or the cutting tool is not sharp enough.
- Melting: Acrylic can also melt or deform due to the heat generated during machining.
②Nylon
- Warping: Nylon tends to warp due to heat.
- Hygroscopicity: Nylon has a tendency to absorb moisture, so its dimensions change.
③Polycarbonate
- Chip wrapping: Chips tend to wrap around the tool, causing surface finish issues.
- Heat sensitivity: Polycarbonate can deform or discolor due to the heat generated during machining.
3.Composites
①Carbon Fiber Reinforced Plastic (CFRP)
- Delamination: The layers of this composite can separate during machining.
- Abrasion to tools: The hardness of carbon fiber can cause tools to wear quickly.
②Fiberglass
- Wear: The edges of fiberglass can fray, resulting in a poor finish.
- Tool wear: Its abrasive nature can cause increased tool wear.
4.Wood
①Hardwood (e.g., oak, maple)
- Burning: Hardwood can burn if the tool is dull or the speed is too high, which is a common problem in CNC machining.
- Chipping: There is a risk of chipping or splitting along the grain, especially with hardwoods.
②Softwoods (e.g. pine, cedar)
- Compression: These woods compress rather than cut cleanly, affecting detail and accuracy.
- Fuzzing: Surface fuzzing or tearing, especially along the grain, is a common defect in softwoods