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ATF Crusher Parts
Martensitischer Stahl | Schlagleisten und Prallauskleidungen | ATF

Werkstofftechnologie

Martensitischer Stahl | Schlagleisten und Prallauskleidungen | ATF

Martensitischer Stahl für Schlagleisten und Prallauskleidungen. 450-550 BHN, Charpy-Werte und Vergleich mit Mangan- und Hochchromguss.

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Technische Eckdaten

Hardness Range
450–550 BHN (45–55 HRC)
Charpy Impact Energy
15–30 J at 20 C (unnotched 10x10 mm)
Alloy System
NiCrMo low-alloy, NiCrMoV medium-alloy
Heat Treatment
Austenitise 850–900 C, oil/air quench, temper 180–400 C
Through-Hardening
Full martensitic to 200 mm section thickness
Wear Life vs. Mn Steel
1.5–2.5x in abrasive applications
Applications
Blow bars, impact plates, hammers, side liners
Key Advantage
Rebar and tramp-metal tolerant (recycling, demolition)

Martensitic Grade Comparison

ATF supplies martensitic blow bars in three standard alloy grades, each optimised for a different point on the hardness-toughness curve. The table below compares these grades alongside high-chrome white iron to illustrate the trade-offs. Grade selection depends on the severity of tramp metal contamination versus the abrasiveness of the primary feed material.

Standard Martensitic (NiCrMo Low-Alloy)

Härte:450 BHN (45 HRC)
Anwendung:Recycling, demolition, C&D waste with frequent rebar and heavy tramp metal
Hinweise:Charpy 25-30 J. Maximum toughness, best tramp metal survival. Preferred for recycling operations.

Medium-Alloy Martensitic (NiCrMo+V)

Härte:500 BHN (50 HRC)
Anwendung:Mixed feed operations with moderate contamination and abrasive rock components
Hinweise:Charpy 18-22 J. Balanced grade for operations processing both rock and demolition waste.

High-Alloy Martensitic (NiCrMoV High-C)

Härte:550 BHN (55 HRC)
Anwendung:Abrasive limestone, granite, and aggregate with occasional tramp metal risk
Hinweise:Charpy 15-18 J. Approaches chrome iron abrasion resistance while retaining meaningful toughness.

High-Chrome White Iron (Cr26-28%)

Härte:600-640 BHN (60-63 HRC)
Anwendung:Clean, abrasive aggregate with no tramp metal contamination
Hinweise:Charpy 2-5 J. Maximum abrasion resistance but shatters on rebar impact. Requires clean feed.

Charpy values are at room temperature (20°C) on standard 10x10 mm unnotched specimens. Actual performance depends on section thickness, heat treatment parameters, and operating temperature.

Martensitic

Martensitic Steel: Balancing Hardness and Impact Toughness in Blow Bars

Martensitic steels are low-alloy NiCrMo and NiCrMoV grades heat-treated to a fully martensitic microstructure through austenitising at 850–900 degrees C, oil or air quenching, and controlled tempering at 180–400 degrees C to deliver hardness in the 450–550 BHN (45–55 HRC) range while retaining meaningful impact toughness of 15–30 J Charpy at room temperature on unnotched 10x10 mm specimens. In blow bar and impact liner applications, this combination fills the critical performance gap between work-hardening manganese steels (high toughness exceeding 100 J but moderate hardness of 200–550 BHN requiring sustained impact to activate) and high-chrome white irons (extreme hardness of 600–700 BHN but brittle under shock loading with Charpy values below 5 J). NiCrMo alloying provides sufficient hardenability for full through-hardening in blow bar cross-sections up to 200 mm, ensuring consistent hardness from surface to core with no soft zones that would wear preferentially.

The defining advantage of martensitic blow bars is their tolerance of mixed and contaminated feed streams—a capability that neither manganese steel nor high-chrome white iron can match as effectively. In recycling, demolition, and construction-and-demolition (C&D) waste processing, rebar, bolts, wire mesh, and other tramp metal are unavoidable realities of the feed material. High-chrome white iron blow bars, with Charpy values typically under 5 J, shatter catastrophically on rebar impact, sending large fragments through the crusher that damage the rotor, housing, conveyor belts, and downstream equipment at a cost that far exceeds the price of the blow bar itself. Martensitic grades, with Charpy impact energy of 15–30 J at room temperature, deform locally—producing a dent or gouge at the impact point—rather than fracturing catastrophically, allowing the blow bar to continue in service. This makes martensitic steel the default material choice for horizontal shaft impact (HSI) crusher blow bars wherever feed contamination with metallic objects is a realistic operational risk.

Martensitic Steel
450-550 BHN Range
Rebar-Tolerant

Key Properties of Martensitic Steel Blow Bars

Controlled Hardness Range (450-550 BHN)

Through-hardened martensitic microstructure provides consistent hardness from surface to core. Unlike manganese steel that requires impact energy to work-harden, martensitic grades deliver full hardness as-supplied, ensuring wear resistance from the first tonne of feed.

Tramp Metal Tolerance

Charpy impact values of 15-30 J at room temperature allow martensitic blow bars to absorb rebar and tramp metal impacts without catastrophic fracture. Local deformation and surface damage occur, but the blow bar remains in service — a critical advantage over high-chrome white iron in contaminated feeds.

Heat Treatment Optimisation

Austenitizing, oil or air quenching, and controlled tempering allow precise tuning of the hardness-toughness balance. Lower tempering temperatures push hardness toward 550 BHN for abrasive feeds; higher tempering temperatures increase toughness toward 30 J for heavy tramp metal exposure.

Uniform Through-Section Properties

NiCrMo alloying provides sufficient hardenability for full through-hardening in blow bar cross-sections up to 200 mm. No soft core or hardness gradient means consistent performance as the blow bar wears through its usable thickness.

Weldable for Field Repair

Unlike high-chrome white iron, martensitic steel can be pre-heated and welded using low-hydrogen electrodes for field repair of localised damage. This extends service life in remote operations where replacement logistics are difficult.

Cost-Effective Wear Life

Martensitic blow bars typically deliver 1.5-2.5x the wear life of manganese in abrasive applications, at a lower unit cost than high-chrome or ceramic composite alternatives. In recycling and demolition operations, the combination of longer life and tramp metal survival produces the lowest cost per tonne.

Need Help Selecting a Martensitic Grade?

Provide your crusher model, feed material, and tramp metal exposure. ATF engineering will recommend the optimal hardness-toughness balance for your operation.

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Applications by Duty

Martensitic blow bars are specified across a range of impact crushing applications. The operating environment — particularly tramp metal frequency, feed abrasiveness, and required product shape — determines the optimal grade and hardness target.

Recycling & Demolition

  • C&D waste processing with rebar and reinforcing mesh
  • Concrete recycling with embedded steel
  • Asphalt reclamation with wire and bolt contamination
  • Scrap-heavy mixed demolition waste streams

Primary Impact Crushing

  • Quarry primary HSI crushing of run-of-mine limestone
  • First-stage reduction of blasted rock with drill steel risk
  • Portable plant operations with variable feed quality
  • High-throughput primary reduction where blow bar life is critical

Limestone & Aggregate

  • Cement-grade limestone processing requiring tight gradation
  • Aggregate production where product shape is a specification
  • Medium-abrasive sedimentary rock with occasional hard inclusions
  • Single-pass crushing to finished product in low-abrasion feeds

Mixed Feed Operations

  • Transfer stations processing unknown or variable waste streams
  • Mining operations with mixed ore and waste rock
  • Multi-source aggregate plants with inconsistent feed quality
  • Operators switching between clean rock and demolition contracts
FAQ

Martensitic FAQ

Finden Sie Antworten auf häufige Fragen zu martensitic Werkstoffen, Auswahl, Wartung und Bestellung. Nicht gefunden, was Sie suchen?

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When should I choose martensitic steel over high-chrome white iron blow bars?
Choose martensitic when your feed contains tramp metal, rebar, or any unscreened contamination. High-chrome white iron delivers superior abrasion resistance but has Charpy impact energy under 5 J — a single rebar strike can shatter the blow bar and cause cascading damage to the rotor and housing. Martensitic grades at 450-500 BHN absorb these impacts with localised deformation rather than fracture. If your operation processes clean, pre-screened aggregate with zero tramp metal risk, high-chrome may be the better choice for pure abrasion resistance.
How does martensitic steel handle rebar impacts?
When a martensitic blow bar strikes rebar or tramp metal, the impact causes localised plastic deformation — a dent or gouge on the working face. The blow bar remains intact and continues operating. By contrast, high-chrome white iron is a brittle material that fractures on impact, often breaking into large fragments that damage the rotor, housing, and discharge conveyor. The 15-30 J Charpy impact energy of martensitic grades provides the ductility margin needed to survive these events.
What is the cost-per-tonne difference between martensitic and manganese blow bars?
Martensitic blow bars cost approximately 30-50% more per unit than equivalent manganese blow bars. However, in abrasive applications, martensitic grades deliver 1.5-2.5x longer wear life due to their higher as-supplied hardness. The net cost per tonne of processed material is typically 15-30% lower with martensitic bars. In low-abrasion applications where manganese work-hardening is effective, the cost advantage narrows. A cost-per-tonne analysis based on your specific throughput and wear rates provides the most accurate comparison.
What tempering temperature is used for martensitic blow bars?
After austenitizing at 850-900°C and oil or air quenching, martensitic blow bars are tempered to control the hardness-toughness balance. Tempering at 180-220°C retains maximum hardness (530-550 BHN) for abrasive feeds with low tramp metal risk. Tempering at 250-300°C reduces hardness to 480-500 BHN while increasing Charpy impact energy to 20-25 J for moderate contamination. Tempering at 350-400°C produces 450-470 BHN with maximum toughness (25-30 J) for heavy recycling duty. ATF selects the tempering range based on your specific application requirements.
Can martensitic blow bars be used in all impact crusher models?
Yes. Martensitic blow bars are available for all major HSI crusher models from Metso, Sandvik, Hazemag, Terex, Kleemann, McCloskey, and other manufacturers. The material does not affect dimensional compatibility — ATF machines martensitic blow bars to the same OEM profiles, mounting geometry, and weight tolerances as the original parts. The only consideration is that martensitic steel is approximately 5% less dense than high-chrome white iron, so a direct replacement may weigh slightly less.
How does wear life of 550 BHN martensitic compare to high-chrome white iron?
In clean abrasive feeds (limestone, granite, basalt), 550 BHN martensitic blow bars achieve approximately 60-75% of the wear life of high-chrome white iron (600-640 BHN). The gap narrows in less abrasive feeds. However, this comparison only holds in clean feed conditions. In operations with any tramp metal, a single impact event can destroy a chrome blow bar, making martensitic the better value even with shorter theoretical abrasion life. Total cost of ownership must include unplanned downtime and collateral damage costs from chrome bar fracture.

Related Materials Technology

High-Chrome White Iron

Maximum abrasion resistance for clean feed applications. 600-640 BHN hardness with 60-63 HRC. Ideal where tramp metal is excluded and pure wear life is the priority.

Mehr erfahren

Manganese Steel Alloys

Work-hardening austenitic manganese steels (Mn14-Mn22) for extreme impact applications. Maximum toughness with surface hardening under repeated impact loading.

Mehr erfahren

Ceramic Insert Technology

Ceramic-metal composite wear surfaces combining alumina or zirconia inserts with metallic matrices. 2-4x wear life extension in high-abrasion, clean-feed conditions.

Mehr erfahren

Technischer Inhalt geprüft vom ATF-Ingenieurteam | Metallurgische Spezifikationen verifiziert nach ASTM/ISO-Normen

Get a Quote for Martensitic Blow Bars

Specify your crusher model, feed material, and tramp metal exposure. ATF will recommend the right martensitic grade and tempering specification for your operation.

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450-550
BHN Hardness Range
15-30 J
Charpy Impact Energy
1.5-2.5x
Wear Life vs Manganese

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