Metal die casting prototype parts are the backbone of product development—they let teams test designs, Funktionalität validieren, and iterate fast before mass production. But with so many material options (Aluminium, Magnesium, Zink), casting processes (HPDC, vacuum-assisted), and design rules to follow, Es ist leicht, sich überwältigt zu fühlen. How to choose the right approach for your prototype? This guide breaks down everything from material selection to testing, with practical tips to create high-quality, cost-effective metal die casting prototypes.
1. Rapid Die-Casting Prototyping: Get Samples Fast Without Sacrificing Quality
In der Produktentwicklung, speed matters.Rapid die casting prototype solutions cut lead times to get you testing sooner—critical for staying ahead of competitors.
Key Rapid Prototyping Options
| Lösung | Vorlaufzeit | Ideal für | Beispiel Anwendungsfall |
|---|---|---|---|
| Quick-turn casting parts | 3–5 Tage | Einfache Prototypen (Z.B., grundlegende Gehäuse) | A startup needing to test a new electronic device’s shell |
| Fast metal prototype casting | 5–7 Tage | Parts with moderate complexity (Z.B., Klammern) | An automotive supplier validating a new sensor mount |
| 24-hour casting samples | <1 Tag | Emergency fixes or urgent design checks | A manufacturer needing to replace a broken prototype part for a client meeting |
| Express aluminum prototype | 2–4 Tage | Aluminiumteile (the most common prototype material) | A consumer goods brand testing a new kitchen tool’s handle |
The secret to rapid prototyping? Prioritize “good enough” for initial tests. Zum Beispiel, if you’re just checking fit (not cosmetic finish), skip expensive anodizing—focus on getting the part in hand to validate dimensions.
2. Aluminum Die-Cast Prototypes: The Go-To for Balance of Strength & Kosten
Aluminum is the most popular material for die casting prototypes—it’s lightweight, stark, und erschwinglich.Aluminum prototype casting works for nearly every industry, from electronics to automotive.
Top Aluminum Alloys for Prototypes
| Legierung | Schlüsseleigenschaften | Ideal Prototype Use |
|---|---|---|
| ADC12 prototype parts | Niedrige Kosten, Ausgezeichnete Gussbarkeit, glatte Oberfläche | Kosmetische Teile (Z.B., Telefonkoffer, Fernbedienungen) |
| A380 aluminum prototype | Hohe Stärke, gute maschinabilität, Wärmewiderstand | Struktureile (Z.B., Motorhalterungen, power tool housings) |
Why choose aluminum? Alightweight AL casting sample weighs 30–50% less than steel, making it perfect for portable devices or automotive parts where weight matters. Plus, aluminum rapid casting is fast—most suppliers can deliver parts in 3–7 days.
3. Magnesium Die-Cast Prototypes: The Lightest Option for High-Performance
If weight is your top priority (Z.B., aerospace or high-end electronics), magnesium prototype casting ist der richtige Weg. Magnesium ist 33% lighter than aluminum—ideal for parts where every gram counts.
Key Magnesium Alloy for Prototypes
- AZ91D prototype parts: The most common magnesium alloy for die casting. It has good strength and castability, es perfekt für:
- Light Mg casting sample (Z.B., Laptop -Rahmen, drone bodies)
- Thin-wall Mg casting (runter zu 0.5 mm—great for slim devices like tablets)
Magnesium prototypes do have tradeoffs: they’re more expensive than aluminum, and they corrode easily (so you’ll need a protective coating like chemical conversion). But for high-performance products, the weight savings are worth it.
4. Zinc Die-Cast Prototypes: Perfect for Small, Detaillierte Teile
Zinc prototype casting shines for small, intricate parts—zinc flows easily into tight spaces, making it ideal for prototypes with fine details (Z.B., Getriebe, Hardware).
Top Zinc Alloys for Prototypes
| Legierung | Schlüsseleigenschaften | Ideal Prototype Use |
|---|---|---|
| Lädt 3 Prototypteile | Niedriger Schmelzpunkt, Gute dimensionale Genauigkeit | Klein, Präzisionsteile (Z.B., Beobachten Sie Komponenten, Stecknadeln) |
| Lasten 5 casting sample | Higher strength than ZAMAK 3 | Parts needing durability (Z.B., Türgriffe, kleine Zahnräder) |
Zinc’s benefits:
- Miniature zinc prototype: Can cast parts as small as 5 mm × 5 mm with sharp details.
- Zinc rapid casting: Schnelles Abkühlen (zinc solidifies quickly) means shorter cycle times—suppliers can make small batches in 2–4 days.
5. Hochdruckguss (HPDC) Prototypen: For Production-Ready Parts
Hochdruckguss (HPDC) Prototypen use the same process as mass production—making them perfect for validating how parts will perform in full-scale manufacturing.
Key HPDC Prototype Features
- HPDC prototype parts: Made with high pressure (100–150 MPA) to ensure dense, Starke Teile.
- Thin-wall HPDC casting: Can produce walls as thin as 0.4 mm (ideal for lightweight parts like smartphone frames).
- Multi-slide HPDC prototype: Uses multiple slides to cast complex shapes (Z.B., Teile mit Unterschnitten) without extra machining.
When to choose HPDC? If you’re close to mass production and want a prototype that matches the final product’s properties. AHPDC aluminum prototype, Zum Beispiel, will have the same strength and surface finish as production parts.
6. Vacuum-Assisted Die Casting Prototypes: For Low-Porosity Parts
Porosität (winzige Luftbläschen) is a common issue in die casting—especially for parts that need to hold fluids (Z.B., Pumps) or withstand high pressure.Vacuum die casting prototype solves this by removing air from the mold before casting.
Benefits of Vacuum-Assisted Prototypes
- Reduced-porosity casting: Cuts porosity by 70–80% compared to standard die casting.
- High-integrity vac casting: Ideal for parts like hydraulic components or medical devices where strength and leak resistance matter.
- Vac-cast aluminum parts: The most common vacuum-assisted prototype—aluminum’s fluidity pairs well with vacuum to fill thin walls and complex shapes.
7. Dünnwandig & Micro Die-Cast Prototypes: For Slim, Tiny Parts
Modern products are getting slimmer and smaller—so prototypes need to keep up.Thin-wall casting prototype Undmicro die casting parts let you test designs for the latest devices.
Key Capabilities
| Typ | Mindestwanddicke | Idealer Anwendungsfall |
|---|---|---|
| Thin-wall casting prototype | 0.3 mm (aluminum/magnesium) | Slim devices (Z.B., wireless earbud cases, Smartwatch -Bands) |
| Micro die casting parts | 0.2 mm (Zink) | Tiny components (Z.B., microchip connectors, medical needles) |
| Ultra-thin aluminum prototype | 0.3 mm | Leicht, slim parts (Z.B., tablet back covers) |
| Mini zinc die casting | 0.2 mm | Klein, detaillierte Teile (Z.B., Schmuckverschlüsse, micro-gears) |
Tipp: For thin walls, use vacuum-assisted casting (to ensure full filling) and conformal cooling (to prevent warpage).
8. Nach dem Maschinieren & Finishing for Cast Prototypes: Make Parts Look and Work Like Final Products
Casting alone rarely gives you a finished prototype—Nach dem Maschinieren & fertig are key to getting parts ready for testing or client presentations.
Häufige Nachbearbeitungsschritte
| Schritt | Zweck | Ideal für |
|---|---|---|
| CNC machining casting prototype | Adds precision features (Z.B., Löcher, Themen) that can’t be cast | Parts needing tight tolerances (Z.B., Sensorhalterungen) |
| Trim & drill die casting | Removes excess metal (Blitz) and adds simple holes | Basic prototypes where fit is more important than finish |
| Anodized casting sample | Fügt einen Schutz hinzu, farbige Schicht (Type II for cosmetic, Type III for wear) | Aluminum prototypes (Z.B., Konsumgüter, Kfz -Trim) |
| Powder-coat prototype parts | Fügt einen langlebigen hinzu, mattes Finish (available in any color) | Parts needing corrosion resistance (Z.B., Außenausrüstung) |
| Vibratory finish casting | Smooths edges and removes small burrs | Kleine Teile (Z.B., zinc hardware, magnesium brackets) |
Für die Spitze: For rapid prototypes, skip unnecessary steps. If you’re just testing functionality, trimmen & drill may be enough—save anodizing for final presentations.
9. Dimensional & Mechanical Testing of Cast Prototypes: Prove Parts Meet Specs
You can’t trust a prototype until you test it.Dimensional & mechanical testing ensures your parts meet design goals and will perform in real use.
Key Tests for Cast Prototypes
| Prüfen | Zweck | Worauf man suchen sollte |
|---|---|---|
| CT scan casting inspection | Finds hidden defects (Z.B., Porosität, Risse) | Total porosity <1% (für strukturelle Teile) |
| X-ray die casting check | Erkennt interne Mängel (simpler than CT for basic checks) | No large pores (>0.5 mm) in kritischen Bereichen |
| CMM prototype measurement | Verifies dimensions (Z.B., Lochdurchmesser, Teillänge) | Dimensions within ±0.05 mm of design specs |
| Tensile test casting bar | Misst die Stärke (how much force the part can take before breaking) | Tensile strength ≥80% of the final production part |
| Porosity analysis report | Documents the amount and location of porosity | No porosity in high-stress areas (Z.B., Bolzenlöcher) |
Prioritize tests based on your prototype’s use. Zum Beispiel, a magnesium drone frame needs a tensile test and CT scan (to check for weak spots), while a zinc jewelry clasp just needs a CMM check (to ensure it fits).
10. Niedrigvolumme & Bridge-Tooling Strategies: From Prototype to Production
Once your prototype is validated, you may need small batches (10–500 Teile) before mass production.Low-volume die casting Undbridge tooling casting fill this gap.
Key Strategies
- Soft-tool casting prototype: Uses low-cost tools (Z.B., Aluminiumformen) for small batches—cheaper than production tooling and fast to make (1–2 Wochen).
- Insert die casting mold: Swaps inserts in a standard mold base to make different parts—ideal if you need multiple prototype variants (Z.B., 3 different lid designs).
- Quick-change casting inserts: Changes inserts in 30 minutes or less—cuts setup time for low-volume runs.
Bridge tooling is perfect for:
- Testing market demand (make 100 parts to sell and get feedback)
- Filling gaps between prototype and mass production (if production tooling is delayed)
11. Design for Die Casting (DfDC) Guidelines: Avoid Common Prototype Mistakes
Bad design leads to bad prototypes—Design for Die Casting (DfDC) Richtlinien help you create parts that cast easily and perform well.
Top DfDC Rules for Prototypes
- Draft angle casting design: Add 1–3° of draft to all vertical surfaces. No draft = parts stick in the mold = wasted time and money.
- Fillet radii prototype: Filets hinzufügen (abgerundete Kanten) to all corners. Sharp corners cause stress cracks and make casting harder.
- Uniform wall casting rule: Keep wall thickness consistent (± 0,2 mm). Thick spots cool slowly and cause shrinkage; thin spots may not fill.
- Undercut avoidance casting: Avoid undercuts (features that hang over and prevent the part from being pulled out of the mold). If you need an undercut, use a slide (but this adds cost to the prototype).
- Gate & runner optimization: Position gates (where metal enters the mold) to fill the part evenly. Für kleine Prototypen, use a pinpoint gate (small and easy to remove).
Beispiel: A client once designed an aluminum prototype with 0° draft and sharp corners—every part stuck in the mold, doubling their lead time. Adding 2° draft and fillets fixed the issue.
Yigu Technology’s Perspective on Metal Die Casting Prototype Parts
Bei Yigu Technology, we tailor metal die casting prototypes to clients’ needs. We offer rapid options (24-hour samples) for urgent tests, and HPDC/vacuum casting for production-ready parts. We guide material choice—aluminum for balance, magnesium for weight, zinc for details—and use DfDC to avoid flaws. Our post-processing and testing ensure prototypes meet specs. This holistic approach delivers fast, high-quality prototypes that speed up product development.
FAQs About Metal Die Casting Prototype Parts
- Wann sollte ich wählen magnesium prototype casting über aluminum prototype casting?Choose magnesium if weight is critical (Z.B., Luft- und Raumfahrt, high-end electronics)-es ist 33% leichter als Aluminium. Pick aluminum for most other cases (better cost, Korrosionsbeständigkeit, and availability). Magnesium works best for parts where every gram saves fuel or improves performance.
- Was ist der Unterschied zwischen HPDC prototype parts and standard die casting prototypes?HPDC verwendet Hochdruck (100–150 MPA) to make dense, strong parts—matching mass production processes. Standard die casting uses lower pressure (50–80 MPa) and is cheaper/faster for initial tests. Use HPDC if you want a prototype that behaves like the final production part.
- How can Design for Die Casting (DfDC) Richtlinien save time on prototypes?DfDC rules (Z.B., Entwurfswinkel, uniform walls) prevent common issues like stuck parts or incomplete filling. Zum Beispiel, adding 1–3° draft avoids mold sticking—cutting rework time by 50%. Skipping DfDC often leads to multiple prototype iterations, delaying your project.