MIM 304 stainless steel, also searched as SUS304 MIM or 304 stainless steel metal injection molding, is a practical material option for small, complex stainless steel parts that need general corrosion resistance, clean appearance, and moderate mechanical performance. It is commonly reviewed for precision hardware, small housings, levers, buttons, brackets, clips, and clean-environment components when the application does not require high hardness, high wear resistance, heat-treatable strength, or strong chloride resistance. For a MIM project, the key question is not whether 304 is a familiar stainless steel. The key question is whether MIM 304 can meet the part’s corrosion environment, surface expectation, tolerance requirement, and production volume after molding, debinding, sintering, finishing, and inspection. If the part will face sweat, salt spray, marine exposure, cleaning chemicals, sliding wear, or high load, 316L, 17-4 PH, 420, or 440C should be reviewed before tooling.
What Is MIM 304 Stainless Steel / SUS304?
304, SUS304, 1.4301, and UNS S30400 Material Identity
304 stainless steel is a common austenitic stainless steel grade. In international project communication, engineers may see several related names, including 304, SUS304, AISI 304, UNS S30400, and EN 1.4301. These names are often used to refer to broadly similar 18/8 austenitic stainless steel material families, but the exact specification should always be checked against the customer drawing, material standard, purchase specification, and supplier data sheet.
A common sourcing mistake is assuming that “SUS304” on a drawing is enough for manufacturing approval. In practice, the supplier still needs to confirm the applicable standard, required surface condition, corrosion environment, critical dimensions, and whether the part is expected to behave like wrought, machined, cast, or MIM stainless steel. General 304 / 1.4301 references can support material identification, but they should not be used alone to define final MIM part performance.
How MIM 304 Differs From Wrought or Machined 304
MIM 304 is not produced in the same way as bar stock, sheet, or CNC-machined 304. In Metallpulverspritzguss, fine stainless steel powder is mixed with a binder system to form feedstock. The feedstock is injection molded into a green part, debound to remove binder, and then sintered to achieve final density and mechanical performance.
This matters because final MIM properties depend on powder chemistry, feedstock consistency, molding conditions, debinding control, Sintern atmosphere, shrinkage compensation, density, and secondary operations. A 304 material callout alone does not define every manufacturing outcome. For MIM parts, the material decision should be reviewed together with part geometry, wall thickness, gate location, critical dimensions, post-processing needs, and inspection requirements.
Chemical Composition and Material Identity of MIM 304
304 stainless steel is generally understood as an austenitic chromium-nickel stainless steel. Chromium supports the passive corrosion-resistant surface film, while nickel helps stabilize the austenitic structure and supports ductility. Carbon control matters because excessive carbon-related effects can influence corrosion behavior in certain conditions, especially when parts are exposed to heat histories or corrosive environments.
The table below should be used as an engineering explanation, not as a final purchasing specification. Final approval should be aligned with the drawing, customer specification, MIM material standard, powder/feedstock route, and supplier data sheet.
| Element | Typical Role in 304 Stainless Steel | Why It Matters in MIM Parts |
|---|---|---|
| Chrom | Supports passive film formation and general corrosion resistance. | Important for corrosion behavior after sintering and finishing. |
| Nickel | Supports austenitic structure and ductility. | Helps material toughness and formability-related behavior. |
| Carbon | Must be controlled within the applicable material specification. | Can affect corrosion considerations in certain thermal or service conditions. |
| Manganese / Silicon | Support alloy balance and processing behavior. | Can influence material consistency and processing response. |
| Iron | Base metal balance. | Defines the stainless steel matrix. |
MIM 304 vs 304L: When the Low-Carbon Version Should Be Reviewed
304L is the low-carbon version of the 304 stainless steel family. In MIM sourcing, 304 and 304L should not be treated as automatically interchangeable unless the drawing, applicable standard, customer specification, and supplier material data sheet allow it. If the part has corrosion-sensitive service conditions, welding-related legacy requirements, heat history concerns, or a customer drawing that explicitly calls out 304L, the low-carbon version should be reviewed before confirming material approval.
For RFQ communication, write the exact material requirement shown on the drawing, such as 304, SUS304, 304L, or a customer-specific stainless steel specification. If the drawing only says “304 stainless steel,” confirm whether the customer accepts a MIM supplier’s standard 304 / 304L stainless feedstock route before tooling.
Key Properties to Review Before Choosing MIM 304
Corrosion Resistance in Normal Service Conditions
MIM 304 can be a good candidate when the part requires general stainless steel corrosion resistance in relatively mild service environments. Examples may include indoor equipment hardware, instrument components, consumer device parts, decorative or functional metal features, and clean-environment components where the corrosion exposure is controlled.
The important boundary is service condition. “Stainless” does not mean corrosion-proof. Stainless steels rely on a passive surface film, and that passive film can be challenged by chlorides, low oxygen crevices, deposits, heat, or aggressive chemicals. In practice, the environment and geometry often matter as much as the grade name.
Chloride, Sweat, Salt Spray, and Marine Exposure Risks
This is one of the most important review points for 304. If the part will face sweat, salt spray, seawater, de-icing salt, hot water, cleaning agents, or chloride-containing environments, 304 should not be approved only because it is stainless steel.
Localized corrosion such as pitting and crevice corrosion is often associated with chloride ions in aqueous environments. From a project review perspective, the supplier should ask whether the part will contact sweat, salt spray, marine air, chloride cleaning chemicals, trapped moisture, tight assembly gaps, blind holes, or crevice-prone geometry. If these answers are unclear, material selection should remain open until MIM 316L Edelstahl or another material option is reviewed.
| Exposure Condition | 304 Review Risk | Recommended Engineering Action |
|---|---|---|
| Indoor dry use | Generally suitable | Confirm cosmetic surface, tolerance, and finishing requirements. |
| Intermittent hand contact | Überprüfung erforderlich | Check sweat exposure, cleaning method, surface finish, and passivation needs. |
| Salt spray or marine air | Higher risk | Compare with 316L or another corrosion-focused stainless material before tooling. |
| Blind holes, narrow gaps, or crevices | Higher localized corrosion risk | Review trapped moisture, oxygen limitation, cleaning access, and geometry modification. |
| Cleaning chemicals or unknown fluid contact | Application-dependent | Define chemical composition, temperature, exposure time, and acceptance criteria. |
Strength, Hardness, and Wear Limitation
MIM 304 should not be selected when the main requirement is high hardness, high wear resistance, or precipitation-hardening strength. For parts exposed to high sliding wear, repeated mechanical friction, locking surfaces, bearing-like contact, or high structural load, 304 may be the wrong starting point.
A common mistake is choosing 304 because it is familiar, then discovering that the part requires a hardened martensitic stainless steel or precipitation-hardening stainless steel. In these cases, 17-4 PH, 420, oder 440C may be more suitable depending on strength, hardness, corrosion, and toughness requirements.
Surface Finish, Passivation, and Cosmetic Requirements
304 is often considered for parts that require a stainless appearance or a cleaner surface than low-alloy steel. However, the final surface condition of a MIM 304 part depends on tooling, molding, sintering, media finishing, polishing, passivation, and inspection criteria. If the part has a visible cosmetic surface, the drawing should define acceptable gate mark location, polishing direction, surface roughness expectation, burr limits, stain acceptance, and packaging requirements.
Dimensional Stability and Sintering Shrinkage
MIM parts shrink significantly during sintering. For MIM 304, dimensional stability depends on feedstock consistency, mold compensation, sintering support, part geometry, wall thickness balance, and critical dimension strategy. This does not mean 304 is dimensionally unstable by itself; it means that material and geometry cannot be separated in MIM production.
If a 304 part has long thin walls, asymmetric sections, unsupported flatness requirements, tight coaxiality, or thin features near gates, the drawing should go through MIM-DFM-Prüfung und MIM tolerance review before tooling. For deeper dimensional planning, see MIM-Schwindungskompensation.
Tooling, Volume, and Secondary Operation Trade-Off
Before selecting MIM 304, the project should also be checked against production volume and secondary-operation needs. MIM tooling is usually justified when the part geometry is complex enough and the expected volume can absorb tooling development. If the design requires extensive post-machining, heavy polishing, unusually tight dimensions, or low-volume trial demand only, the cost advantage of MIM may be reduced. The review should compare material choice, geometry, tolerance strategy, finishing route, and annual volume together.
When MIM 304 Is a Good Fit
MIM 304 is most suitable when the project combines small complex geometry, general stainless corrosion resistance, moderate mechanical loading, and production volume that can justify tooling. It is one option within the wider MIM stainless steel material family, not the default answer for every stainless MIM part.
| Projektanforderung | MIM 304 Suitability | Technischer Grund |
|---|---|---|
| Kleines, komplexes Edelstahlteil | Gut geeignet | MIM supports small complex geometries that are costly to machine at volume. |
| Allgemeine Korrosionsbeständigkeit | Gut geeignet | 304 is a common austenitic stainless steel for many mild environments. |
| Cosmetic stainless surface | Möglicherweise geeignet | Surface finish, gate location, polishing, passivation, and packaging must be defined. |
| Moderate mechanical load | Möglicherweise geeignet | Suitable when high hardness or high strength is not the main requirement. |
| Chloride / sweat / salt exposure | Überprüfung erforderlich | 316L or another corrosion-focused material may be safer. |
| High hardness / wear resistance | Meist nicht ideal | 420 or 440C may fit better. |
| Hohe Festigkeit nach Wärmebehandlung | Meist nicht ideal | 17-4 PH should be reviewed. |
MIM 304 Material Decision Matrix
Use this matrix as a first-pass engineering filter before RFQ. It does not replace drawing review, supplier material data, prototype validation, or customer approval, but it helps clarify when 304 is a reasonable starting point and when another stainless steel grade should be compared.
| Wenn Ihr Bauteil Folgendes benötigt... | 304 Fit? | Better Material to Review | Grund |
|---|---|---|---|
| Clean stainless appearance with mild indoor corrosion exposure | Good starting point | 304 / SUS304 | 304 can be suitable when the environment is controlled and strength or wear is not the main driver. |
| Sweat, salt spray, marine air, or chloride cleaning exposure | Needs caution | 316L or corrosion-focused stainless review | Chloride and crevice conditions may create localized corrosion risk. |
| Höhere Festigkeit nach Wärmebehandlung | Meist nicht ideal | 17-4 PH | 17-4 PH is usually reviewed when precipitation-hardening strength is required. |
| High hardness or repeated sliding wear | Meist nicht ideal | 420 or 440C | Martensitic stainless grades may be more suitable for hardness and wear-focused features. |
| Explicit low-carbon stainless requirement on the drawing | Must confirm specification | 304L or customer-specified material | Do not substitute 304 for 304L unless the customer specification allows it. |
| Tight tolerance, thin wall, or cosmetic surface combined with MIM geometry | Möglich nach Prüfung | Material + DFM review | Gate position, shrinkage, sintering support, finishing, and inspection must be reviewed together. |
When MIM 304 Should Be Reconsidered
If the Part Will Face Chlorides, Sweat, or Salt Spray
Choose 304 carefully when the part will contact sweat, salt spray, marine atmosphere, outdoor moisture, or chloride cleaning agents. The risk is not only visible rust. Localized pitting can start in small crevices, blind holes, assembly gaps, deposits, or areas where oxygen access is limited. For more demanding corrosion exposure, compare with MIM 316L Edelstahl or review korrosionsbeständige MIM-Teile.
If the Part Needs High Strength After Heat Treatment
304 is not the first choice when the project requires high strength through precipitation hardening. If the part needs stronger mechanical performance after heat treatment, MIM 17-4 PH Edelstahl is often a more logical review candidate.
If the Part Needs High Hardness or Wear Resistance
For sliding contact, rotating contact, locking features, abrasive exposure, or repeated metal-to-metal contact, 304 may wear too quickly. In these cases, MIM 420 Edelstahl oder MIM 440C Edelstahl may be better candidates, depending on corrosion and toughness requirements.
If the Part Has Tight Critical Dimensions
Tight dimensions do not automatically exclude MIM 304, but they must be reviewed carefully. Critical dimensions near gates, thin walls, unsupported spans, deep holes, long flat surfaces, or asymmetric geometry may need mold compensation, Sinterunterstützung, or secondary machining.
MIM 304 vs 316L, 17-4 PH, 420, and 440C
This section is a quick material selection boundary, not a full comparison guide. For a broader selection path, use the dedicated MIM-Werkstoffvergleiche Seite.
| Material | Besser geeignet für | Nicht ideal für | Next Review Direction |
|---|---|---|---|
| 304 / SUS304 | General corrosion resistance, cosmetic stainless parts, moderate-load hardware. | Chloride-heavy environments, high hardness, high strength. | Use this page for 304-specific review. |
| 304L | Projects that explicitly require low-carbon 304-family stainless steel. | Unapproved substitution where the drawing specifies standard 304 or another grade. | Confirm customer specification and supplier material data sheet. |
| 316L | More demanding corrosion environments where molybdenum-bearing stainless is preferred. | High hardness or high strength applications. | Review 316L page. |
| 17-4 PH | Higher strength after heat treatment. | Maximum corrosion resistance or high ductility requirements. | Review 17-4 PH page. |
| 420 | Higher hardness and wear resistance than 304. | Corrosion-critical applications. | Review 420 page. |
| 440C | High hardness and wear-focused stainless applications. | Ductility-sensitive or corrosion-critical parts. | Review 440C page. |
Typical MIM 304 Parts and Application Scenarios
MIM 304 can be suitable for selected small stainless steel parts when the design requires clean appearance, moderate load capacity, general corrosion resistance, and complex geometry. Part type alone does not approve 304. Each component still needs review for application environment, load, wear, surface finish, tolerance, and inspection requirements.
Small Housings and Covers
MIM 304 can be suitable for small stainless housings, covers, and protective shells when the part requires complex geometry, clean appearance, and moderate functional loading. If the housing includes snap-fit features, thin walls, threaded inserts, or cosmetic surfaces, DFM review should confirm gate position, parting line, shrinkage risk, and finishing method.
Buttons, Levers, and Functional Hardware
Buttons, levers, small control features, and user-contact hardware may fit MIM 304 when surface feel, appearance, corrosion resistance, and dimensional repeatability matter. If the part will contact sweat daily, 316L or finishing requirements should be reviewed.
Brackets, Clips, and Small Structural Components
304 may work for small brackets, clips, retainers, and support components under moderate loads. If the part has spring-like requirements, repeated flexing, high stress concentration, or load-bearing safety relevance, material strength and fatigue assumptions should be reviewed carefully.
Fluid or Clean-Environment Components
304 can be considered for some clean-environment or light fluid-contact components, but the medium must be defined. Water, cleaning chemicals, chloride concentration, pH, temperature, and trapped fluid areas can change the material decision.
For broader part-category navigation, see MIM-Teile, MIM-Teile für Unterhaltungselektronik, industrial equipment MIM parts, und medizinische MIM-Teile. Medical or dental use should be reviewed carefully and should not be assumed from material name alone.
Processing and Quality Review Notes for MIM 304 Projects
Feedstock- und Pulverkonsistenz
MIM 304 begins with stainless steel powder and binder feedstock. Powder chemistry, powder size distribution, binder behavior, and feedstock consistency can influence molding stability, sintering response, density, surface condition, and dimensional repeatability.
Entbindern und Sintersteuerung
During Entbindern, binder must be removed without damaging the green part. During sintering, the part shrinks and densifies. Poor process control can contribute to distortion, cracks, dimensional drift, surface defects, or inconsistent mechanical performance. This is why a MIM 304 project should not be evaluated from material grade alone.
Surface Finishing and Passivation Review
For 304 parts, finishing may be required for appearance, corrosion performance, or assembly function. Common review points include polishing direction, tumbling marks, gate vestige, edge condition, passivation requirement, and acceptable discoloration. If corrosion resistance is a functional requirement, finishing should not be treated as a cosmetic afterthought.
Inspection Points for MIM 304 Parts
The inspection plan should connect the material requirement with geometry, surface condition, and end-use function. The table below summarizes common review items for MIM 304 projects.
| Prüfpunkt | Warum das wichtig ist |
|---|---|
| Kritische Maße | Confirms shrinkage compensation and functional fit. |
| Density / material condition | Supports review of mechanical and corrosion-related performance. |
| Oberflächenbeschaffenheit | Affects appearance, friction, cleaning, and corrosion behavior. |
| Gate mark location | Can affect cosmetic surfaces and assembly areas. For deeper review, see MIM-Angussdesign. |
| Burr / edge condition | Important for handling, mating parts, and safety. |
| Passivation requirement | Relevant when corrosion performance is part of the specification. |
| Packaging condition | Helps prevent surface contamination before assembly. |
Verbundene Fallszenarien für die technische Schulung
Scenario 1: 304 Part Used in a Sweat-Contact Application
- Welches Problem aufgetreten ist
- A small stainless MIM component was specified as SUS304 because the design team wanted a familiar stainless steel material and a clean appearance. After field exposure, cosmetic staining and localized corrosion appeared near a small crevice area.
- Warum es passiert ist
- The part was used in a sweat-contact environment, but the original material review treated “stainless steel” as enough information. The geometry included a tight gap where moisture and chlorides could remain after use.
- Was die eigentliche Systemursache war
- The failure was not simply a material problem. It came from incomplete environment definition, insufficient review of chloride exposure, crevice-sensitive geometry, and unclear finishing/passivation requirements.
- Wie es korrigiert wurde
- The project team reviewed the application environment, compared 304 with 316L, adjusted the crevice geometry where possible, and clarified surface finishing and acceptance requirements before the next tooling or production update.
- So verhindern Sie ein erneutes Auftreten
- For any 304 MIM part exposed to sweat, salt, cleaning chemicals, or trapped moisture, confirm the corrosion environment before material approval. Do not approve SUS304 only because it appears on an earlier drawing.
Scenario 2: 304 Selected for a Wear Feature
- Welches Problem aufgetreten ist
- A small MIM lever was designed in 304 stainless steel. During functional review, the contact area showed wear risk because the part repeatedly rubbed against a harder mating component.
- Warum es passiert ist
- The initial material choice focused on stainless appearance and general corrosion resistance, but the drawing did not clearly identify the contact surface as a wear-critical feature.
- Was die eigentliche Systemursache war
- The project mixed two different requirements: stainless appearance and wear resistance. 304 could address the first requirement, but it was not the best starting point for a high-wear contact area.
- Wie es korrigiert wurde
- The engineering team compared 304 with 420 and 440C, reviewed the mating material, contact pressure, surface finish, and lubrication condition, and then selected a material path based on the actual wear requirement.
- So verhindern Sie ein erneutes Auftreten
- Before selecting 304, mark contact surfaces, sliding areas, locking faces, and wear-critical edges on the drawing. Material selection should follow the function of the feature, not only the general part name.
RFQ Checklist for MIM 304 Stainless Steel Parts
Before requesting a quote for a MIM 304 / SUS304 part, prepare the following information. These inputs help the engineering team review whether 304 is suitable before tooling, and whether material, DFM, tolerance, finishing, or inspection risks need to be clarified.
| RFQ-Eingabe | Warum XTMIM dies benötigt |
|---|---|
| 2D-Zeichnung | Defines dimensions, tolerances, datum structure, and inspection requirements. |
| 3D-CAD-Datei | Supports geometry, tooling, gate, shrinkage, and DFM review. |
| Material callout | Confirms whether the requirement is 304, SUS304, 304L, 1.4301, or customer-specific. |
| Anwendungsumgebung | Determines whether 304 is suitable or whether 316L / other alloys should be reviewed. |
| Korrosionsbelastung | Identifies sweat, salt spray, marine air, cleaning chemicals, or fluid contact. |
| Oberflächengüteanforderung | Affects polishing, tumbling, passivation, cosmetic review, and cost. |
| Kritische Maße | Helps define as-sintered vs secondary machining strategy. |
| Mechanical load | Supports review of strength, wear, and material alternatives. |
| Jahresvolumen | Bestimmt, ob ein MIM-Werkzeug wirtschaftlich vertretbar ist. |
| Aktueller Fertigungsprozess | Helps compare MIM with CNC machining, casting, stamping, PM, prototype routes, or the existing production method. |
| Current issue or project pain point | Clarifies whether the project is driven by cost, machining difficulty, corrosion failure, dimensional instability, surface defects, or assembly problems. |
| Prototype or production schedule | Supports project planning, sample review, trial run preparation, and production risk control. |
Standards and Technical References for MIM 304 Review
MIM 304 material review should be based on the customer drawing, application environment, supplier material data, and relevant MIM material standards. Standards and technical references can support material communication, but they do not replace project-specific DFM review, supplier process review, prototype validation, or final customer approval.
- MPIF Standard 35-MIM: relevant because it covers materials standards for metal injection molded parts and helps align MIM material communication.
- MIMA-Werkstoffpalette: relevant because it explains available MIM material families and helps place 304 within the broader MIM stainless steel selection context.
- BSSA crevice corrosion guidance: relevant for understanding localized corrosion mechanisms and chloride-related risk.
- ASSDA stainless steel corrosion resistance FAQ: relevant for explaining passive film behavior and why excessive chlorides can cause pitting.
- SSINA pitting and crevice corrosion resource: relevant for explaining why halide ions, typically chlorides, are associated with pitting and crevice corrosion in stainless steels.
Reference note: external technical resources are used to support material and corrosion review logic. MIM material properties can vary with powder chemistry, feedstock route, sintered density, impurity control, surface condition, heat history, and post-processing. Final acceptance should follow the customer drawing, applicable standard, project environment, supplier material data, inspection requirements, and engineering validation.
FAQ About MIM 304 / SUS304 Stainless Steel
Ist SUS304 dasselbe wie Edelstahl 304?
SUS304 wird häufig in JIS-basierten Werkstoffbeschreibungen verwendet, während 304 in der AISI-/ASTM-Kommunikation üblich ist. In vielen technischen Diskussionen werden sie als gleichwertig betrachtet, die genaue Anforderung sollte jedoch anhand der Kundenzeichnung, der geltenden Norm und des werkstoffbezogenen Datenblatts des Lieferanten bestätigt werden.
Ist MIM 304 dasselbe wie MIM 304L?
Nein. 304L ist die kohlenstoffarme Variante der Edelstahlfamilie 304. In MIM-Projekten sollten 304 und 304L nicht als austauschbar betrachtet werden, es sei denn, die Zeichnung, die geltende Norm, die Kundenspezifikation und das Materialdatenblatt des Lieferanten lassen dies zu.
Ist MIM-Edelstahl 304 korrosionsbeständig?
MIM 304 bietet in vielen milden Umgebungen eine allgemeine Edelstahl-Korrosionsbeständigkeit. Bei Chloridexposition, Schweiß, Salzsprühnebel, Meeresatmosphäre, Reinigungschemikalien, eingeschlossener Feuchtigkeit oder spaltanfälliger Geometrie sollte jedoch sorgfältig geprüft werden. In diesen Fällen ist 316L oder ein anderer Werkstoff möglicherweise besser geeignet.
Ist 304 besser als 316L für MIM-Teile?
304 ist nicht einfach besser oder schlechter als 316L. 304 kann für allgemeine Edelstahlteile geeignet sein, bei denen die Korrosionsbelastung moderat ist und Kosten oder Verfügbarkeit eine Rolle spielen. 316L wird oft in Betracht gezogen, wenn die Korrosionsbeständigkeit anspruchsvoller ist, insbesondere wenn ein chloridbedingtes Risiko besteht.
Ist MIM-Edelstahl 304 magnetisch?
304-Edelstahl wird allgemein als austenitischer Edelstahl mit geringer magnetischer Ansprechbarkeit betrachtet, aber MIM-Teile können je nach Chemie, Prozessführung, Dichte, Wärmebehandlung und Nachbearbeitung ein unterschiedliches magnetisches Verhalten aufweisen. Wenn die magnetische Ansprechbarkeit funktional wichtig ist, sollte sie spezifiziert und während der Musterprüfung verifiziert werden.
Kann MIM 304 zur Erhöhung der Festigkeit wärmebehandelt werden?
304 wird normalerweise nicht als ausscheidungshärtbarer Edelstahl ausgewählt. Wenn das Bauteil nach der Wärmebehandlung eine höhere Festigkeit erfordert, sollte in der Regel 17-4 PH geprüft werden. Wenn das Bauteil eine hohe Härte oder Verschleißfestigkeit erfordert, sind 420 oder 440C möglicherweise besser geeignet.
Kann MIM 304 bearbeitete 304-Teile ersetzen?
MIM 304 kann maschinell bearbeitete 304-Teile ersetzen, wenn die Geometrie klein und komplex ist, das Produktionsvolumen den Werkzeugbau rechtfertigt und die Anforderungen an Toleranz, Oberflächengüte, Korrosionsbelastung und Prüfung durch den MIM-Prozess erfüllt werden können. Es sollte nicht als direkter Ersatz ohne DFM-Prüfung und Musterfreigabe betrachtet werden.
Welche Teiletypen eignen sich für MIM 304?
MIM 304 eignet sich für kleine Gehäuse, Knöpfe, Hebel, Halterungen, Clips, dekorative Edelstahlbeschläge und Präzisionskomponenten mit moderater Belastung. Die endgültige Entscheidung hängt von der Korrosionsbelastung, Oberflächengüte, mechanischen Belastung, Toleranzanforderungen und Produktionsmenge ab.
Welche Informationen werden benötigt, um ein MIM-304-Teil anzufragen?
Ein aussagekräftiges RFQ sollte 2D-Zeichnungen, 3D-CAD-Dateien, Materialangaben, Anwendungsumgebung, Korrosionsbelastung, Oberflächengüteanforderungen, kritische Maße, Jahresstückzahl, aktuelles Fertigungsverfahren und aktuelle Projektschwachstellen enthalten. Diese Details helfen dem Entwicklungsteam, vor dem Werkzeugbau zu prüfen, ob 304 geeignet ist.
Wann sollte ich 420 oder 440C anstelle von 304 wählen?
Prüfen Sie 420 oder 440C, wenn das Teil höhere Härte, Verschleißfestigkeit, Gleitkontakteigenschaften, Verriegelungsflächen oder wiederholte Reibung erfordert. Diese Werkstoffe können für verschleißorientierte Anwendungen besser geeignet sein, jedoch müssen die Anforderungen an Korrosionsbeständigkeit und Zähigkeit weiterhin geprüft werden.
Need to Confirm Whether 304 / SUS304 Fits Your MIM Part?
Send your 2D drawing, 3D CAD file, material callout, corrosion environment, surface finish requirement, tolerance needs, current manufacturing process, current project issue, and estimated annual volume to XTMIM for a material suitability and DFM review. Our engineering team can help evaluate whether MIM 304 is appropriate, whether 304L / 316L / 17-4 PH / 420 / 440C should be compared, and which material, geometry, surface, tolerance, or inspection risks should be confirmed before tooling or production.