Powder Metallurgy Sintering Methods

In powder metallurgy, the sintering method depends on the product type and required properties.

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1. Classification by Raw Material Composition

1. Single-component sintering
   • Conducted below the melting point of pure metals (e.g., refractory metals, pure iron for soft magnetic materials) or compounds (Al₂O₃, B₄C, BeO, MoSi₂, etc.)
   • Performed as solid-phase sintering
2. Multi-component solid-phase sintering
   • Involves two or more constituents
   • Sintered below the melting point of the lowest-melting component
   • Many powder sintered alloys belong to this category, e.g., Cu-Ni, Fe-Ni, Cu-Au, W-Mo, Ag-Au, Fe-Cu, W-Ni, Fe-C, Cu-C, Cu-W, Ag-W
3. Multi-component liquid-phase sintering
   • Conducted above the melting point of the lowest-melting component
   • Examples: W-Cu-Ni, W-C powder metallurgy, WC-Co, TiC-Ni, Fe-Cu (Cu>10%), Fe-Ni-Al, Cu-Pb, Cu-Sn, Fe-Cu (Cu<10%)

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2. Classification by Feeding Method

1. Continuous sintering
   • The furnace has sections for debinding, preheating, sintering, and cooling
   • Material passes continuously or in stages through each section
   • High production efficiency, suitable for mass production
   • Common feeding methods: push-rod, roller-bed, mesh-belt
2. Batch (intermittent) sintering
   • Parts remain stationary in the furnace
   • Temperature control devices perform preheating, heating, and cooling cycles
   • Allows customization of sintering schedules based on material performance
   • Lower efficiency, suitable for small batches or single pieces
   • Common furnaces: bell-type, box-type

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3. Other Classification Methods

• By sintering temperature and liquid phase presence: solid-phase vs. liquid-phase sintering
• By sintering temperature: medium-temperature (1100–1700°C) vs. high-temperature sintering
• By sintering atmosphere:
  • Air sintering
  • Hydrogen-protected sintering (e.g., molybdenum wire furnace, stainless steel tubes, hydrogen furnace)
  • Vacuum sintering
• Advanced techniques: ultra-high-pressure sintering, activated hot-press sintering

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Factors Affecting Sintered Product Quality

The performance of sintered parts depends on powder characteristics, forming conditions, and sintering conditions.

1. Sintering temperature and time
   • Temperature and duration affect porosity, density, strength, and hardness
   • Too high a temperature or too long a time can over-sinter and reduce performance
   • Too low a temperature or too short a time can cause under-sintering, lowering material properties
2. Sintering atmosphere
   • Common atmospheres: reducing gas, vacuum, hydrogen
   • Atmosphere affects sintered part properties:
     • Reducing atmosphere prevents oxidation and reduces surface oxides
       • E.g., iron- and copper-based products often use furnace gas or decomposed ammonia
       • Hard alloys and stainless steel often use pure hydrogen
     • Active metals, refractory metals (Be, Ti, Zr, Ta), TiC-containing hard alloys, and stainless steel can use vacuum sintering
       • Vacuum avoids harmful gas components (H₂O, O₂, H₂)
       • Can reduce sintering temperature by 100–150°C