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Multi-material compatibility, available in stainless steel and light metal customization, to meet the demands of high-end industries.

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Technological Strength

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Camera Trim

  • Material: 316L
  • Process: MIM + PVD
  • Applications: Mobile phones, tablets

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Hinge

  • Material: 17-4PH / 440L
  • Process: MIM + PVD
  • Applications: Mobile phones, tablets

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Bracket

  • Material: 17-4PH
  • Process: MIM + PVD
  • Applications: Mobile phones, tablets

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Side Buttons

  • Material: 316L
  • Process: MIM + PVD
  • Applications: Mobile phones, tablets

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MaterialPerformanceFeatures & Applications
316LStandard 316L density ≥7.8g/cm³; High-polish 316L density ≥7.93g/cm³; Tensile strength ≥480MPa; Yield strength ≥160MPa; Elongation ≥50%; Hardness 120-180HV1. Features: Non-magnetic, outstanding corrosion resistance and polishing performance2. Applications: 3C structural & cosmetic parts, watch cases
17-4PHDensity ≥7.6g/cm³; Tensile strength ≥1200MPa; Yield strength ≥1000MPa; Elongation ≥5%; Hardness 36-40HRC1. Features: High strength, high hardness, decent corrosion resistance2. Applications: 3C structural parts
PANACEADensity ≥7.5g/cm³; Tensile strength ≥900MPa; Yield strength ≥600MPa; Elongation ≥35%; Hardness 280-350HV1. Features: Nickel-free, non-magnetic, superior corrosion resistance2. Applications: 3C structural & cosmetic parts
Ultra-high Strength SteelDensity ≥7.6g/cm³; Tensile strength ≥1800MPa; Yield strength ≥1500MPa; Elongation ≥5%; Hardness 46-52HRC1. Features: Ultra-high yield strength, high hardness2. Applications: 3C structural parts, rotating shafts
TC4 Titanium AlloyDensity 4.3-4.4g/cm³; Tensile strength ≥1000MPa; Yield strength ≥900MPa; Elongation ≥20%; Hardness 300-370HV1. Features: Non-magnetic, low density, excellent corrosion resistance, good biocompatibility2. Applications: 3C structural & cosmetic parts, watch cases
Low-density SteelDensity ≤6.5g/cm³; Tensile strength ≥1100MPa; Yield strength ≥900MPa; Elongation ≥5%; Hardness 390-420HV1. Features: Low density, high strength2. Applications: 3C structural parts, rotating shafts
IN713CDensity ≥7.8g/cm³; Tensile strength ≥1350MPa; Yield strength ≥950MPa; Elongation ≥10%; Hardness 40-42HRC1. Features: Non-magnetic, high strength, great high-temperature performance and corrosion resistance2. Applications: 3C structural parts, rotating shafts
420WDensity ≥7.6g/cm³; Tensile strength ≥1800MPa; Yield strength ≥1300MPa; Elongation ≥8%; Hardness 50-52HRC1. Features: Moderate wear & corrosion resistance, high hardness2. Applications: 3C structural parts, rotating shafts
F75Density ≥8.0g/cm³; Tensile strength ≥880MPa; Yield strength ≥500MPa; Elongation ≥15%; Hardness 270-310HV1. Features: Non-magnetic, high strength, good corrosion resistance, biocompatible2. Applications: 3C structural parts
ProcessDetailed StepsMain AdvantagesMain DisadvantagesApplicable MaterialsTypical Applications
TumblingPut parts, abrasives and polishing agents into rotary barrels; remove burrs and flash via friction & collision to boost surface finishLow cost, mass-production compatible, works for complex geometries, great deburring effectLimited precision, unable to reach mirror finish, tiny features prone to abrasionStainless steel, iron-based alloys, cemented carbide and most MIM materialsSmall structural components, gears, hardware deburring & rough polishing
SandblastingHigh-speed blast abrasives (glass beads, ceramic grit, steel shot) onto workpieces via compressed air to form uniform matte textureUniform matte surface, removes scale, improves coating adhesion, adjustable roughnessNo dimensional accuracy improvement, thin-walled parts easy to deform, dust treatment requiredAll MIM metalsCosmetic parts, pre-treatment for coating/plating, eliminate machining marks
Mechanical PolishingMulti-stage grinding with abrasive wheels, cloth wheels and polishing paste from coarse to fine for smoother surfaceMirror finish achievable, controllable precision, fits flat & outer circular surfacesHigh labor cost, hard to polish complex inner cavities, low efficiencyStainless steel, titanium alloy, cemented carbideHigh-end cosmetic parts, mirror decorative pieces, sealing surface polishing
Vibratory FinishingParts vibrate at high frequency with abrasives in vibratory tanks for deburring, chamfering and polishingMass-production friendly, fits complex shapes, uniform finish, moderate costMedium polishing precision, cannot achieve ultra-mirror surfaceAll MIM metalsHardware, jewelry, small precision mass polishing
Chemical PolishingImmerse parts in acidic solution to level surface via chemical dissolution and boost glossWorks for complex inner cavities, simple equipment, high efficiencyHeavy pollution, high environmental cost, poor dimensional control, lower gloss than electropolishingStainless steel, copper alloy, aluminum alloyStainless decorative parts, bright finishing for complex inner cavity components
ElectropolishingTreat workpieces as anodes in electrolyte; electrochemically dissolve micro-protrusions to get mirror finishUltra-high surface smoothness, burr removal, enhanced corrosion resistance, fits complex shapesRelatively high cost, complicated waste liquid treatment, slight dimensional loss304/316 stainless steel, titanium alloyMedical devices, food-grade parts, semiconductor components, premium cosmetic parts
PassivationTreat stainless steel with nitric/citric acid passivating solution to form dense anti-rust oxide filmSimple process, low cost, greatly improves corrosion resistance, no change to dimension & appearanceOnly boosts rust resistance, no roughness or hardness improvementAustenitic stainless steel like 304/316Medical components, food equipment, chemical part anti-rust treatment
PicklingRemove oxide scale, rust and sinter discoloration with acid to expose bare metalEffective scale removal, mass-production feasible, low costMatte gray-white surface, corrosion risk, strict environmental compliance requiredStainless steel, iron-based alloy, copper alloyPost-sintering scale removal, pre-treatment for plating & coating
Electroplating (Nickel/Chrome/Zinc)Deposit metal coating on parts via electrolysis for wear resistance, anti-corrosion and decorationUniform coating, multiple metal options, strong decoration & wear resistanceMIM pores may cause blistering, sealing pre-treatment needed, strict environmental rulesIron-based alloy, stainless steel, copper alloy and most MIM materialsHardware fasteners, decorative parts anti-corrosion & finishing
Electroless NickelDeposit nickel-phosphorus alloy coating via chemical reaction without power supply, excellent uniformityConsistent coating thickness, great throwing power, superior wear & corrosion resistance, high hardnessHigher cost than electroplating, slow deposition, brittle coatingAll MIM metalsComplex components, valve bodies, pump parts, mold inserts wear & corrosion protection
PVD (Physical Vapor Deposition)Ionize metals like titanium/chromium under vacuum and deposit hard coating on workpieceUltra-high hardness (HV2000+), outstanding wear resistance, eco-friendly, various colors (gold/black/blue)Thin coating (1-5μm), strict requirement on substrate roughness, high costStainless steel, titanium alloy, cemented carbide, mold steelCutting tools, molds, wear-resistant components, premium decorative parts
DLC (Diamond-Like Carbon Coating)DLC film with extreme hardness and self-lubricating propertyHigh hardness, ultra-low friction coefficient, self-lubricating, anti-corrosionBonding force control required, thin coating, high cost, poor high-temperature resistanceStainless steel, titanium alloy, bearing steelPrecision bearings, gears, valve spools, medical wear-resistant parts
AnodizingForm dense oxide film on titanium/aluminum via electrolytic oxidation for wear resistance, anti-corrosion and coloringExcellent corrosion resistance, customizable decorative colors, high hardness, eco-friendlyOnly applicable to valve metals (Ti/Al), complicated process, relatively high costTC4 titanium alloy, aluminum alloyTitanium medical implants, aerospace components, premium cosmetic parts
Vacuum QuenchingHeat parts in vacuum furnace then rapid cooling; martensitic transformation boosts hardness & strengthOxidation-free, minimal deformation, uniform hardness, good surface qualityHigh equipment cost, only for hardenable materials, dimensional shift control requiredMartensitic stainless steel (420/440C), low-alloy steel, mold steelCutting tools, bearings, gears, structural part strengthening heat treatment
Age HardeningPrecipitation-hardened stainless steel low-temperature aging; precipitate intermetallic compounds to strengthen substrateMinimal heat treatment deformation, stable dimension, adjustable high strengthLong process cycle, high cost, only for precipitation-hardening materials17-4PH, 17-7PH precipitation hardening stainless steelAerospace parts, high-pressure valve bodies, precision structural components
Carburizing / NitridingInfuse carbon/nitrogen atoms into workpiece surface at high temperature to form hard surface layerUltra-high surface hardness, wear resistance, tough core substrate, suitable for heavy loadsHigh processing temperature, obvious deformation, long cycle, environmental requirementsLow-carbon steel, low-alloy steel, partial stainless steelGears, shafts, molds, surface strengthening for wear-resistant parts
CarbonitridingCo-infiltrate carbon & nitrogen, combine advantages of carburizing and nitriding for high hard wear-resistant surfaceHigh hardness, great wear resistance, lower processing temperature & less deformation than carburizingModerate deformation, complicated process, higher costLow-carbon alloy steel, structural steelGears, pin shafts, valves and medium-load wear-resistant parts
Black Oxide TreatmentAlkaline oxidation forms black Fe₃O₄ protective film on steel for decoration & mild anti-rustUltra-low cost, uniform black appearance, nearly zero dimensional change, limited rust preventionWeak anti-corrosion performance, oil sealing required, only for ferrous metalsIron-based alloy, carbon steel, low-alloy steelFasteners, mechanical parts, black decorative hardware
Impregnation & SealingFill internal pores of MIM parts with resin/inorganic sealant to improve density & air tightnessCloses pores, improves plating/coating quality, prevents leakage, boosts strengthExtra process cost, possible dimensional tolerance shift, infiltration depth control neededAll sintered MIM parts (especially low-density grades)Air-tight components, hydraulic parts, pre-plating pore sealing
Powder Coating & Spray PaintingSpray plastic powder or paint on workpieces, cure to form organic anti-corrosion decorative coatingRich color options, good decoration & anti-corrosion, covers minor surface defectsCoating thickness affects precision dimensions, pre-treatment required for adhesion, poor high-temperature resistanceAll MIM metalsCosmetic housings, outdoor equipment anti-corrosion finishing
Laser MarkingEtch texts, patterns & QR codes on surface via laser beam for permanent identificationPermanent & clear marking, high precision, non-contact processing, eco-friendly without consumablesHigh equipment cost, surface marking only, better effect on dark materialsAll MIM metalsPart serial numbers, QR codes, LOGO, specification marking
Brushed FinishingPull uniform linear textures on surface with abrasive belts/nylon wheels for metallic textureStrong metallic texture, covers minor scratches, premium decorative effectFingerprint prone, slightly reduced anti-corrosion performance, only for flat/curved surfacesStainless steel, copper alloy, aluminum alloyHigh-end cosmetic parts, consumer electronics, decorative hardware

The MIM Injection Molding Process

Our high-performance materials and technologies set new standards in numerous industries such as the automotive industry, mechanical engineering, the energy sector and many more.

Step 1

Mold Design and Fabrication

Precision molds are designed with shrinkage compensation and optimized structures to ensure stable molding, high accuracy, and long service life for mass production.

Step 2

Material Preparation

Fine metal powders are mixed with polymer binders to form a homogeneous feedstock with excellent flowability and consistent composition.

Step 3

Injection Molding

The prepared feedstock is injected into precision molds under high pressure to form green parts with complex geometries and high dimensional consistency.

Step 4

Debinding

Binder materials are carefully removed through thermal or solvent processes to produce a porous brown part while maintaining structural integrity.

Step 5

Sintering

Parts are sintered at high temperatures in a controlled atmosphere, achieving densification, shrinkage control, and mechanical properties close to forged metals.

Step 6

Post-Processing

Secondary processes such as CNC machining, polishing, and surface treatment are applied to achieve final precision, appearance, and functional performance.

Why Choose Us?

Real-world project demonstrations showcase our technological capabilities and achievements across multiple industries.

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Frequently Asked Questions

Here are some of the questions we get asked often. If yours isn’t answered, don’t hesitate to contact us, we’re happy to help!

  • What is the first step in the MIM process?

  • What materials are used in MIM feedstock?

  • How does injection molding work in MIM?

  • Why is debinding important in MIM?

  • What happens during the sintering process?

  • What is included in post-processing?

Let's Talk About Your Project

With its ability to create complex shapes, use a variety of alloys, and enable rapid production, our die casting service is unmatched. If you’re ready to get started, choosing a material and an experienced injection molding partner becomes crucial.

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