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Common Misconceptions in Roller Surface Material Selection for Double Roll Crushers and How to Avoid Them

The material of the roller surface in the Double roller crusher is the most important, which determines the machine’s operating cost during the crushing process. Below, Huashengming Heavy Industry will explain to you: Common misconceptions and avoidance methods for selecting roller surface materials in roller crushers

Misconception 1: Harder Materials Are Always Better, Ignoring Impact Resistance

• Flawed Assumption: Blindly selecting ultra-hard materials (e.g., high-chromium cast iron, tungsten carbide) without considering impact loads.
• Consequences: Brittle materials crack or spall under high-impact conditions (e.g., large ore blocks, metal scraps).
  • Example: High-chromium rollers may fracture when crushing large, hard feed materials.
• Solution:
  • For high-impact workloads, prioritize high-manganese steel (e.g., Mn18) or bimetal composite rollers to balance wear and impact resistance.
  • Formula for assessment: Impact energy (J) = Material hardness (MPa) × Crushing force (kN). Use high-toughness materials if impact energy >200 J.

Misconception 2: Neglecting Material Stickiness/Humidity Causes Blockages or Corrosion

• Flawed Assumption: Selecting materials based solely on hardness, ignoring stickiness or corrosivity.
• Consequences: Sticky or wet materials (e.g., clay, gypsum) adhere to rollers; acidic/alkaline materials corrode metal surfaces.
• Solution:
  • For sticky materials: Use grooved rollers or ceramic-coated surfaces (roughness Ra ≤1.6 μm) to reduce adhesion.
  • For corrosive environments: Opt for stainless steel composite rollers or polyurethane-coated surfaces (resists pH 3–10).

Misconception 3: Prioritizing Initial Cost Over Long-Term Maintenance

• Flawed Assumption: Choosing low-cost materials (e.g., carbon steel) to reduce upfront expenses.
• Consequences: Short lifespan (e.g., carbon steel lasts ~500 hours vs. 3,000+ hours for high-chromium iron), leading to frequent downtime and replacements.
• Solution: Calculate total cost per ton based on annual throughput to prioritize lifecycle efficiency.

Key Steps for Scientific Material Selection

1. Material Analysis Sheet: Document hardness, moisture, impact resistance, and corrosion data.
2. Operational Classification: Rank factors (e.g., heat, impact, wear, corrosion) by priority.
3. Material Cross-Comparison: Use bimetal composites for mixed conditions.
4. Lifecycle Cost Analysis: Include procurement, maintenance, and downtime costs.

Recommendation: Collaborate with manufacturers to test materials with ≥10 batches of actual feedstock, ensuring optimal compatibility.