Plastic & Metal industry knowledge

CNC machining of Polypropylene (PP) presents unique challenges that manufacturers often struggle with. Its low rigidity and flexibility can lead to workpiece deflection during machining, making it difficult to achieve...

CNC machining has revolutionized manufacturing, and the integration of PCs into this process brings both opportunities and challenges. Users often struggle with seamless PC integration with CNC systems, facing issues...

CNC machining of Acrylic (PMMA) presents unique challenges that set it apart from machining reinforced plastics or metals. Its exceptional transparency and optical clarity mean even minor surface defects like...

CNC machining of Nylon 15%GF (15% glass fiber reinforced nylon) presents a unique set of challenges, even for experienced manufacturers. Its lower glass fiber content compared to higher-grade reinforced nylons...

CNC machining of Nylon 20%GF (20% glass fiber reinforced nylon) strikes a unique balance between performance and processability, but it still presents distinct challenges. Compared to unfilled nylon, the glass...

CNC machining of Nylon 30%GF (30% glass fiber reinforced nylon) presents unique challenges that set it apart from machining unfilled nylons. The glass fibers significantly increase the material’s abrasiveness, leading...

CNC machining of Nylon MC901 comes with distinct challenges that manufacturers often struggle with. Its higher moisture absorption compared to some other nylons can lead to unexpected dimensional changes during...

CNC machining of Nylon PA12 presents a unique set of challenges, even for experienced manufacturers. Its lower moisture absorption compared to other nylons affects dimensional stability during machining, while its...

CNC machining of Nylon PA66 is a critical process in manufacturing high-performance parts, yet it presents unique challenges. Manufacturers often struggle with managing its higher melting point compared to Nylon...

CNC machining of Nylon PA6 is a widely used process in manufacturing, but it comes with unique challenges. Manufacturers often struggle with dimensional changes due to Nylon PA6’s moisture absorption,...

CNC machining of Acetal (Delrin) is a staple in manufacturing high-performance parts, yet it comes with its own set of hurdles. Manufacturers often grapple with achieving consistent surface finishes due...

CNC machining of POM-H + PTFE composites combines the best of both materials but introduces unique challenges. Manufacturers often struggle with uneven tool wear due to PTFE’s abrasive nature, maintaining...

CNC machining of POM-H (Polyoxymethylene Homopolymer) is a go-to process for crafting high-precision components, yet it presents distinct challenges. Manufacturers often struggle with balancing its high mechanical strength against machining...

CNC machining of POM-C (Polyoxymethylene Copolymer) is a critical process in manufacturing high-precision components, but it comes with unique challenges. Manufacturers often struggle with excessive tool wear due to POM-C’s...

CNC machining of ABS (Acrylonitrile Butadiene Styrene) is widely used across various industries, but it comes with its own set of challenges. Many manufacturers struggle with achieving consistent surface finishes,...

In the realm of modern manufacturing, CNC machining of plastics has emerged as a crucial process, offering versatility, precision, and efficiency. However, like any manufacturing process, it comes with its...

Steel is one of the most widely used materials in manufacturing, but working with it has never been easy. Traditional steel machining often struggles with precision—parts might have inconsistent dimensions,...

Manufacturing small, complex parts—like medical device components or aerospace fasteners—has long been a challenge. Traditional lathes often struggle with long, slender workpieces, which can flex or vibrate during machining, leading...

Traditional machinery has long been a staple in manufacturing, but it comes with a host of challenges. Manual operation often leads to inconsistent results, with parts varying slightly from one...

Traditional bending methods often leave manufacturers frustrated. Manual bending can result in inconsistent angles, parts that don’t fit together, and wasted materials—especially when working with complex shapes or high-volume orders....