Wenn Sie Produktingenieur oder Beschaffungsspezialist sind, Die Wahl des falschen Materials für die CNC-Bearbeitung kann Ihr Projekt zum Scheitern bringen: Teile können unter Belastung reißen, mehr kosten als budgetiert, oder nicht den Industriestandards entsprechen. Die gute Nachricht? Dieser Leitfaden vereinfacht die Auswahl von CNC-Bearbeitungsmaterialien mit klaren Kategorien, Beispiele aus der Praxis, and data-driven tips to help you pick the right material—every time.
What Is CNC Machining Material Selection?
CNC machining material selection is the process of picking the best material (Metall, Polymer, or alloy) for your part based on its purpose, Leistungsbedarf, und Kosten. Im Gegensatz zum Spritzgießen (which uses molten materials), CNC machining is a subtractive process—it cuts away material from a solid block to shape your part. This means the material’s strength, Bearbeitbarkeit, and cost directly impact your project’s success.
The most common CNC machining materials fall into five categories: aluminium alloys, Stahl, Edelstahl, copper and brass, Titan, Und Polymere. Each has unique pros, Nachteile, and ideal use cases—let’s break them down.
1. Key CNC Machining Material Categories (With Pros, Nachteile, and Use Cases)
Not all materials work for every CNC project. Below is a detailed breakdown of each category, including critical specs like tensile strength and cost, to help you narrow down your options.
Aluminium Alloys: Lightweight and Cost-Effective
Aluminium alloys are the most popular choice for CNC machining—they’re lightweight, leicht zu schneiden, and affordable. They’re ideal for parts that need low weight but don’t face extreme stress.
Top Aluminium Alloys for CNC Machining
| Alloy Grade | Zugfestigkeit | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| EN AW-6061 / 3.3211 | 180 MPa | Hohe Festigkeit, gute Korrosionsbeständigkeit | Scaffolding, Luft- und Raumfahrtkomponenten | € |
| EN AW-6060 / 3.3206 | Niedrig | Good weldability, cold-forming ability | Beleuchtung, Möbel, flooring | € |
| EN AW-7075 / 3.4365 | 57 MPa | Hohe Festigkeit, Ermüdungsbeständigkeit | Aircraft structural parts | € |
| EN AW-5083 / 3.3547 | – | Ausgezeichnete Korrosionsbeständigkeit | Marineteile, offshore structures | € |
Real-World Example: A Drone Manufacturer’s Choice
A drone company needed a lightweight frame that could handle small impacts. They first tested EN AW-6060 (cheap but low strength)—the frames bent during flight tests. They switched to EN AW-6061, which had 180 MPa-Zugfestigkeit (enough to resist impacts) and was still 30% leichter als Stahl. The switch cost €0.50 more per frame but reduced crash-related failures by 80%.
Stahl: Strong and Durable for High-Stress Parts
Steel is a go-to for parts that need high strength and durability, like shafts or gears. It’s heavier than aluminium but offers better performance in high-load applications.
Top Steels for CNC Machining
| Steel Grade | Zugfestigkeit | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| 1.0503 / C45 (S45C) | 630 MPa | Hohe Festigkeit, good dimensional accuracy | Schrauben, Bohrer, Wellen | €€ |
| 1.0570 / St52-3 | 680 MPa | Hohe elektrische Leitfähigkeit | Strukturteile, Klammern | €€ |
| 1.7225 / 42CrMo4 | – | Hohe Zähigkeit, Schlagfestigkeit | Getriebewellen, large plastic molds | €€ |
| 1.7131 / 16MnCr5 | 600 MPa | High surface hardness, Verschleißfestigkeit | Getriebe, worms, Buchsen | €€ |
Edelstahl: Corrosion-Resistant for Harsh Environments
Stainless steel adds chromium (and often molybdenum) to steel, making it resistant to rust and chemicals. It’s perfect for parts that touch water, Essen, oder Chemikalien.
Top Stainless Steels for CNC Machining
| Stainless Steel Grade | Zugfestigkeit | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| 1.4301 / 304 (V2A) | 590 MPa | Gute Bearbeitbarkeit, easy to shape | Kitchen sinks, Rohre, pots | €€€ |
| 1.4404 / 316L (V4A) | – | Chlorine resistance, Hitzebeständigkeit | Ausrüstung für die Lebensmittelverarbeitung, boat parts | €€€ |
| 1.4571 / X6CrNiMoTi17-12-2 | – | Stable at 800°C+, marine resistance | Marinekomponenten, offshore parts | €€€€ |
Copper and Brass: High Conductivity for Electrical Parts
Copper and brass excel at conducting electricity and heat. They’re easy to machine and have good corrosion resistance—ideal for electrical components.
Top Copper/Brass Alloys for CNC Machining
| Alloy Grade | Zugfestigkeit | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| 2.0060 / E-Cu57 | 360 MPa | Hohe elektrische Leitfähigkeit | Sammelschienen, Motoren, windings | €€€ |
| CW004A / 2.0065 | – | Easy to shape into profiles/sheets | Electrical/electronics parts | €€€ |
| 2.0401 / CuZn39Pb3 (Ms58) | – | Good thermoformability, weldable | Hygienic industry parts, Motorkomponenten | €€ |
Titan: High Strength-to-Weight for Medical/Aerospace
Titanium is lightweight (half the weight of steel) but incredibly strong. It’s biocompatible (safe for the human body) and corrosion-resistant—perfect for medical implants and aerospace parts.
Top Titanium Grades for CNC Machining
| Titanium Grade | Zugfestigkeit | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| Grad 2 / IN 3.7035 | – | Excellent strength-to-weight, biokompatibel | Medizinische Implantate, weight-reducing structures | €€€€€ |
| Grad 5 / 6Al-4V | – | Hohe Festigkeit, seawater resistance | Subsea oil/gas structures, Teile für die Luft- und Raumfahrt | €€€€€ |
Polymere: Affordable and Versatile for Low-Stress Parts
Polymere (Kunststoffe) are cheap, leicht, and easy to machine. They’re great for parts that don’t need extreme strength, like enclosures or electrical insulators.
Top Polymers for CNC Machining
| Polymer Type | Hauptvorteile | Ideale Anwendungsfälle | Price Range |
| ABS | Good chemical resistance, Dimensionsstabilität | Food processing parts, Gehäuse | € |
| Acryl (PMMA) | Transparent (like glass), ästhetisch | Beschilderung, face shields, zeigt an | € |
| POM (Acetal) | Verschleißfest, good in wet environments | Buchsen, clamps, elektrische Teile | € |
| SPÄHEN | Hochtemperaturbeständigkeit, chemische Beständigkeit | Medizinisch, Teile für die Luft- und Raumfahrt | €€€ |
| Teflon (PTFE) | Extreme Temperaturbeständigkeit, geringe Reibung | Getriebe, piston rings, skateboards | €€ |
2. 4 Critical Factors to Choose the Right CNC Material
Picking a material isn’t just about specs—you need to match it to your project’s unique needs. Ask yourself these four questions:
1. What Will the Part Do? (Performance Needs)
- Does it need to resist stress? Choose high-tensile materials like 1.0570 Stahl (680 MPa) oder titanium Grade 5.
- Will it touch water/chemicals? Go with Edelstahl 1.4404 (316L) oder Kupfer 2.0060.
- Does it need to be lightweight? Entscheiden Sie sich für aluminium 6061 oder titanium Grade 2.
- Is electrical conductivity key? Pick Kupfer 2.0060 oder Messing 2.0401.
2. What’s Your Budget? (Kosten vs. Wert)
Materials range from cheap (aluminium, ABS) to expensive (Titan, high-grade stainless steel). Zum Beispiel:
- A simple bracket: Verwenden ABS (€) oder aluminium 6060 (€) to save money.
- A medical implant: Invest in titanium Grade 2 (€€€€€)—it’s biocompatible and worth the cost to avoid failures.
3. How Easy Is It to Machine? (Bearbeitbarkeit)
Some materials are harder to cut than others, which adds time and cost. Zum Beispiel:
- POM (Acetal) is the easiest polymer to machine—fast and low-waste.
- Titanium Grade 5 is hard to machine—needs special tools, increasing lead time by 2–3 days.
4. What Industry Standards Apply? (Einhaltung)
- Food industry: Verwenden Edelstahl 1.4301 (304) oder 1.4404 (316L)—they’re food-safe.
- Medizinische Industrie: Wählen titanium Grade 2 (biokompatibel) oder SPÄHEN (chemikalienbeständig).
- Luft- und Raumfahrt: Go with aluminium 7075 oder titanium Grade 5—they meet aerospace strength standards.
3. Real-World Mistake to Avoid: Choosing Cost Over Performance
A automotive parts supplier once chose ABS (cheap polymer) for a fuel line bracket because it cost €1 less per part than Nylon. But ABS isn’t resistant to gasoline—after 6 Monate, the brackets cracked, leading to fuel leaks. They had to recall 10,000 Teile, costing $200,000.
The fix? Switching to Nylon (€€), which is hydrocarbon-resistant. The extra €1 per part saved them from a costly recall. The lesson: Don’t sacrifice performance for a lower price—choose the material that fits the part’s job.
Yigu Technology’s Perspective on CNC Machining Material Selection
Bei Yigu Technology, we believe CNC material selection is a balance of performance, kosten, und Bearbeitbarkeit. For clients, we start with the part’s purpose—never just cost. Zum Beispiel, we often guide procurement teams away from cheap aluminium for high-stress parts and toward 42CrMo4 steel instead. We also share material spec sheets early to avoid compliance issues. The best results come from collaboration: engineers share performance needs, we share material expertise, and together we pick a solution that works—on time and on budget.
FAQ About CNC Machining Material Selection
1. What’s the most cost-effective material for CNC machining?
For most low-stress parts (z.B., Klammern, Gehäuse), aluminium 6060 (Metalle) oder ABS (Polymere) are the cheapest and easiest to machine. They balance cost and basic performance.
2. Can I use stainless steel for medical parts?
Only specific grades—Edelstahl 1.4404 (316L) is often used for non-implant parts (z.B., Griffe für chirurgische Instrumente). For implants, titanium Grade 2 is better because it’s biocompatible (safe for long-term body contact).
3. Why is PEEK more expensive than other polymers?
PEEK is expensive because it can withstand high temperatures (works in hot water/steam) and has excellent chemical resistance—properties that make it ideal for medical and aerospace parts. Cheaper polymers like ABS can’t match this performance.