Plastic & Metal industry knowledge
Transfer the value information of rapid prototypes, mold and injection molding industry
Die Casting A360: Corrosion-Resistant Aluminum Alloy for Demanding Environments
You’ve chosen A360 aluminum alloy for its reputation as a corrosion-resistant, high-performance material, expecting parts that can withstand harsh environments while maintaining strength. But your production is facing issues: the...
Die Casting A383 (ADC12): The Global Workhorse Aluminum Alloy
You’ve selected A383 (also known as ADC12 in Asian standards) for its reputation as a cost-effective, high-fluidity aluminum alloy, expecting parts that balance strength and production efficiency. But your operation...
Die Casting A380: The Workhorse Aluminum Alloy for Precision Parts
You’ve chosen A380 aluminum alloy for its reputation as a reliable, all-purpose die casting material, expecting parts with consistent flow, strength, and finish. But your production line is hitting snags:...
Die Casting Aluminum Alloys: Lightweight Strength for Modern Manufacturing
You’ve chosen aluminum alloys for their unbeatable combination of light weight and strength, expecting die cast parts that reduce weight without sacrificing durability. But your production is facing hurdles: the...
Die Casting ZA (Zinc-Aluminum): High-Strength Zinc Alloys for Demanding Applications
You’ve turned to zinc-aluminum alloys (ZA) for their promise of higher strength than standard ZAMAK, expecting parts that can handle heavier loads and higher temperatures. But your production is struggling:...
Die Casting ZAMAK (Zn-Al-Cu-Mg): The Gold Standard of Zinc Alloys
You’ve chosen ZAMAK for its reputation as a high-performance zinc alloy, expecting parts with consistent strength, smooth finishes, and easy castability. But your production line is struggling: some castings are...
Die Casting Zinc Alloys: Strength, Precision, and Affordability
You’ve chosen zinc alloys for die casting, drawn to their reputation for high precision and low cost. But your parts are falling short: the castings have unsightly pores that weaken...
3D Printing Ceramics (Zirconia): Combining Toughness and Precision
You’ve chosen zirconia ceramics for their unmatched toughness, hoping 3D printing will let you create parts that can withstand impacts while maintaining precision. But your prints are letting you down:...
3D Printing Ceramics (Alumina): Crafting High-Performance Ceramic Parts
You’ve turned to alumina ceramics for their unmatched combination of hardness, heat resistance, and chemical inertness—hoping 3D printing will let you create complex parts that traditional ceramic manufacturing can’t achieve....
3D Printing Graphene: Unleashing the Power of 2D Materials
You’ve turned to graphene for its extraordinary properties—hoping 3D printing will let you create parts with unmatched conductivity, strength, and flexibility. But your prints are underwhelming: the electrical conductivity is...
3D Printing Glass-Filled Nylon: Strength, Stability, and Versatility
You’ve turned to glass-filled nylon for its promise of strength, stiffness, and dimensional stability—hoping to print parts that outperform pure nylon. But your prints are falling short: the part warps...
3D Printing Carbon Fiber Reinforced (Nylon/PLA): Strength Meets Accessibility
You’ve invested in carbon fiber reinforced filaments—either nylon or PLA—hoping to print parts that are stronger, stiffer, and lighter than pure plastic. But your prints aren’t delivering: the part is...
3D Printing Composites: Strength, Customization, and Versatility
You’ve turned to composite materials for their unbeatable mix of strength, light weight, and durability—hoping 3D printing will let you create parts that outperform traditional composites. But your prints are...
3D Printing Aluminum (AlSi10Mg): Lightweight Strength for Modern Engineering
You’ve chosen AlSi10Mg for its unbeatable combination of light weight and strength, eager to create aerospace components, automotive parts, or lightweight tooling that outperforms plastic or steel. But your 3D...
3D Printing Titanium (Ti6Al4V): Strength, Lightness, and Biocompatibility
You’ve chosen Ti6Al4V for its unbeatable mix of strength, light weight, and biocompatibility—perfect for aerospace parts, medical implants, or high-performance components. But when you 3D print it, the results are...
3D Printing Stainless Steel: Combining Corrosion Resistance with Precision
You’ve chosen stainless steel for your 3D printing project, drawn to its unbeatable mix of strength and corrosion resistance. But when you print, the results fall short: the part rusts...
3D Printing Metals: Forging Precision in Industrial Manufacturing
You’ve heard 3D printed metals are revolutionizing manufacturing—creating lightweight aerospace parts, biocompatible medical implants, and intricate automotive components that traditional machining can’t match. But when you try it, the results...
3D Printing High-Temp Resin (Heat-resistant): Mastering Heat-Resistant Precision
You’ve invested in high-temp resin to create parts that can withstand the heat—engine components, industrial tooling, or electronics enclosures that face constant exposure to high temperatures. But your prints are...
3D Printing Flexible Resin (Rubber-like): Unlocking Elastic Precision
You’ve loaded flexible resin into your printer, eager to create parts that bend, stretch, and bounce back—perfect for grips, gaskets, or soft robotics. But your prints are a letdown: the...
3D Printing Tough Resin (ABS-like): The Resilient Choice for Functional Parts
You’ve switched to tough resin hoping to get the best of both worlds: resin’s high detail with ABS’s durability. But your prints aren’t living up to the hype—parts snap when...