Edelstahl-CNC-Bearbeitung: Leitfaden 2026 (303, 304, 316L, 17-4PH)
Ingenieur-Leitfaden zur CNC-Bearbeitung von Edelstahl: 303 vs 304 vs 316L vs 17-4PH, Lebensmittel-/Medizin-/Marinegrade, Bearbeitbarkeit, Passivierung.
Edelstahl ist die Antwort, wenn Korrosion, Sterilisation, Lebensmittelkontakt oder anhaltende Festigkeit zählen — aber er ist auch eines der schwieriger zu bearbeitenden Materialien. Dieser Leitfaden behandelt die Sorten, die JLYPT täglich bearbeitet.
Why and when to choose stainless steel
Stainless steel earns its name from chromium (≥10.5%) forming a self-healing chromium-oxide passive layer that resists rust. Beyond corrosion resistance, the family offers:
- Strength — most grades yield at 200–500 MPa, with PH grades reaching 1100+ MPa.
- Hygiene — non-porous, easy to clean, autoclavable. Standard for food, medical, pharma.
- Heat tolerance — useful service to 400–800°C depending on grade.
- Aesthetic durability — keeps appearance for decades without coating.
- Recyclable — 100% recyclable, scrap value supports lifecycle costs.
Grade comparison — pick the right family
Austenitic (300 series)
- Most common stainless family.
- Non-magnetic (mostly), excellent corrosion.
- Includes 303, 304, 316, 316L, 321.
- Good weldability and formability.
- Cannot be hardened by heat treatment.
Precipitation Hardening (PH)
- Heat-treatable for high strength + corrosion resistance.
- Includes 17-4PH, 15-5PH, 13-8Mo.
- Yields 1100+ MPa after H900 treatment.
- Used in aerospace, pumps, downhole tools.
- More expensive than 300 series.
| Grade | Yield (MPa) | Corrosion | Machinability | Best for | Cost |
|---|---|---|---|---|---|
| 303 | 240 | Good | Excellent (free-machining) | Shafts, fasteners, valve parts | 1.0× |
| 304 | 215 | Excellent | Moderate | General food, marine, industrial | 1.05× |
| 316L | 170 | Superior | Moderate | Medical implants, marine, chemical | 1.3× |
| 321 | 205 | Excellent | Moderate | Heat exchangers, exhaust (high temp) | 1.4× |
| 17-4PH (H900) | 1170 | Good | Difficult (4-rated) | Aerospace pumps, oil & gas | 1.7× |
| 15-5PH | 1170 | Good | Difficult | Similar to 17-4 with better transverse | 1.8× |
| 2205 duplex | 450 | Superior | Very difficult | Chemical & offshore, chloride env. | 2.0× |
| 440C (martensitic) | 690 | Moderate | Difficult | Bearings, knives, hardened tools | 1.4× |
Machinability differences (this is where stainless gets tricky)
Unlike aluminium, stainless steel work-hardens during cutting — meaning a dull tool leaves the surface harder than the bulk material, making the next cut even harder. This drives several rules:
- Sharp tools always. Worn tools cause work hardening and surface damage. Replace at half the wear interval used for steel.
- Constant chip load. Stop-start motion (intermittent cutting) work-hardens the surface. Use trochoidal toolpaths for pockets.
- Slower than aluminium, faster than titanium. Surface speed: 60–90 m/min vs aluminium 300+ m/min vs titanium 30 m/min.
- Aggressive coolant. Heat builds fast in the cutting zone. Flood coolant minimum, high-pressure ideal.
- Carbide tooling preferred. HSS works for low-volume, but carbide lasts longer and cuts cleaner.
- 303 is dramatically easier than 304. The added sulphur in 303 acts as a chip-breaker and lubricant — but at the cost of corrosion resistance.
Achievable tolerances on stainless
| Feature | Standard CNC | Precision CNC | High-end (with care) |
|---|---|---|---|
| External dimensions | ±0.10 mm | ±0.025 mm | ±0.010 mm |
| Hole diameter (drilled) | ±0.05 mm | ±0.013 mm | ±0.005 mm |
| Hole diameter (reamed) | ±0.013 mm | ±0.005 mm | ±0.0025 mm |
| Surface finish (Ra) | 1.6 µm | 0.8 µm | 0.4 µm |
| Flatness (over 100 mm) | 0.05 mm | 0.020 mm | 0.010 mm |
For ±0.005 mm or tighter on stainless — typically aerospace pumps, medical implants — JLYPT uses dedicated 5-axis cells with thermal compensation and CMM verification. See our tolerances and GD&T guide.
Passivation and finishes (don't skip passivation)
CNC machining exposes free iron from the underlying material. This iron will rust in saline or moist environments, even on "stainless" parts. Passivation removes this iron and restores the chromium-oxide passive layer.
Degrease
Remove cutting fluid, oils and machining residues with appropriate cleaning chemistry.
Citric or nitric acid bath
Citric acid (gentler, environmentally friendly) or nitric acid (aggressive, faster) — typically 30–60 minutes per ASTM A967 or AMS 2700.
Rinse and neutralise
Multiple deionised-water rinses to remove all acid residue.
Dry and inspect
Visual inspection + optional copper sulphate test to confirm passive layer is present.
Document
Issue passivation certificate referencing ASTM/AMS standard for traceability.
Common stainless finishes
- Bead blasted — uniform matte; hides tool marks.
- Brushed (#3, #4) — directional grain, appliance look.
- Mirror polished (#8) — Ra ≤ 0.05 µm, sanitary applications.
- Electropolished — bright + smooth + corrosion-improved.
- PVD coated — TiN (gold), DLC (black) for wear/cosmetic.
Always passivate when
- Part will see saline, chlorides or chemicals.
- Medical or food-contact applications.
- Welded assemblies (welding contaminates with iron).
- After heat treatment of PH grades.
- Outdoor architectural or marine use.
Industry applications by grade
- 304 — kitchen equipment, brewery tanks, automotive trim, indoor industrial. The default "good stainless".
- 316L — surgical instruments, marine fittings, chemical processing, swimming pool components, off-shore. The default "premium stainless".
- 303 — non-critical machined parts: shafts, custom fasteners, valve internals where slight corrosion compromise is OK.
- 17-4PH — aerospace pump shafts, downhole oil tools, high-strength fasteners. See oil & gas components.
- 440C — bearings, ball valves, knife blades, hardened wear surfaces.
- 2205 duplex — chemical processing, offshore platforms, desalination — anywhere stainless commonly fails to chloride pitting.
- 321 — exhaust manifolds, heat exchangers, jet engine hot-section parts.
Real cost ranges
Indicative pricing for a typical 50×50×25 mm stainless bracket, passivated, batch quantities:
| Quantity | 303 unit cost | 304 unit cost | 316L unit cost | 17-4PH unit cost |
|---|---|---|---|---|
| 1 (prototype) | $110 | $135 | $165 | $210 |
| 10 | $32 | $40 | $48 | $70 |
| 100 | $13 | $17 | $22 | $32 |
| 1000 | $7.20 | $9.50 | $13 | $20 |
Stainless parts are typically 2–3× the cost of equivalent aluminium parts because: material is more expensive (×3), machining is slower (×2), and inspection takes longer (×1.5). For 100+ unit batches the gap narrows but stainless never matches aluminium on price.
Design tips for stainless parts
- Use 303 when corrosion isn't critical. Saves 20–30% in machining time over 304.
- Don't mix grades in one assembly. Galvanic corrosion at the interface; use the same grade throughout, or insulate.
- Specify passivation on the drawing. "Passivate per ASTM A967" — tells the shop to include it and certify.
- Avoid sharp internal corners. 1 mm minimum radius reduces stress concentration and tool breakage.
- Allow extra material for stress relief. For PH grades, plan rough → heat treat → finish; aging shifts dimensions slightly.
- Use larger thread engagements. Stainless galls easily; spec full thread depth + anti-seize for assembly.
- Specify surface finish where it matters. Default Ra 1.6 µm is fine for most. Demand Ra 0.4 only on sealing/sliding surfaces.
- Mark food/medical parts for traceability — alloy + lot number etched per regulations.
Häufig gestellte Fragen
- 316L fügt 2–3% Molybdän hinzu, verbessert dramatisch die Beständigkeit gegen Chlorid-Lochfraß (Meerwasser, Chemikalien). Kostet ~25% mehr — nur wählen wenn Chlorid oder Schweißbarkeit zählt.
- CNC-Bearbeitung legt freies Eisen aus dem Material an die Oberfläche frei. Ohne Passivierung rostet dieses Eisen in feuchten Umgebungen — selbst auf "Edelstahl"-Teilen.
- 300er austenitische Sorten können nicht durch Wärmebehandlung gehärtet werden. Martensitische Sorten (440C) und PH-Sorten (17-4PH) können gehärtet werden.
- 300er Sorten sind im Wesentlichen nicht magnetisch. 400er Sorten sind stark magnetisch. Für MRI-Räume: 316L spezifizieren.
- 303 Freibearbeitungs-Edelstahl — 30–50% schneller zu bearbeiten als 304 wegen Schwefelzusatz. Kompromiss: leicht schlechtere Korrosionsbeständigkeit.
- Ja, einschließlich H900-Zustand. Materialzertifikate (MTRs) und vollständige Rückverfolgbarkeit standardmäßig.
- Ja — Standard für ISO 13485 Medizinarbeit. Glattere Oberfläche (~Ra 0,1 µm erreichbar), bessere Korrosionsbeständigkeit.
- 316L ist in Ordnung für chirurgische Instrumente und kurzfristige Implantate. Langfristige Implantate verwenden typischerweise Ti-6Al-4V ELI.
Was ist der Unterschied zwischen 304 und 316L?
Warum ist Passivierung wichtig?
Kann Edelstahl gehärtet werden?
Ist Edelstahl magnetisch?
Was ist die billigste Edelstahlsorte?
Kann JLYPT 17-4PH bearbeiten?
Bieten Sie Elektropolieren an?
Wie vergleicht sich Edelstahl mit Titan für medizinische Implantate?
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JLYPT Engineering Team
Senior CNC Application Engineers
Our application engineering team brings 15+ years of combined experience producing precision components for aerospace, medical, robotics and industrial automation customers.
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