What is the difference between abrasive, erosive, and adhesive wear, and which hardfacing alloy suits each?

Abrasive wear involves hard particles cutting or ploughing the surface — use high-hardness chromium carbide (55–65 HRC) or WC-based overlays. Erosive wear involves particle-impact material removal at oblique angles — use tough, moderate-hardness alloys (Stellite 6, 38–43 HRC) or WC cermet coatings for high-angle erosion. Adhesive wear (metal-to-metal sliding) involves plastic deformation and junction shearing — use Stellite grades with their low coefficient of friction and galling resistance. Cavitation erosion (collapse of vapour bubbles at surfaces) is best resisted by tough, strain-hardening alloys such as Stellite 6 or 21 rather than high-carbide, brittle deposits.

29 March 2026 18 min read Welding Metallurgy Alloy Design

Hardfacing Alloys: Stellite, Chromium Carbide, and Tungsten Carbide Overlay

Q: How does chromium carbide overlay plate resist abrasion?

Chromium carbide overlay (CCO) plate consists of a dense network of hypereutectic Cr7C3 and Cr3C2 carbides (typically 60–70 vol%) embedded in an austenitic or martensitic iron matrix. The angular, hard carbides (1400–1800 HV) act as individual wear-resistant islands that intercept abrasive particles, while the matrix provides toughness to prevent brittle spallation. CCO plates typically reach 55–65 HRC. The microstructure is controlled by C and Cr content: the eutectic point in the Fe-Cr-C system is near 4%C, 25%Cr, and hardfacing compositions are deliberately hypereutectic (4–6%C, 25–35%Cr) to maximise primary carbide volume.

Q: Why do chromium carbide hardfacing deposits crack, and is this acceptable?

Chromium carbide overlays applied by FCAW-O or SAW develop a network of transverse stress-relief cracks perpendicular to the welding direction during cooling. These cracks form because the hard, low-ductility deposit cannot accommodate the thermal contraction stress of cooling. They are a normal, expected feature of most CCO plates and do not propagate into the base plate if a buffer layer is used. Crack spacing is typically 25–50 mm. Longitudinal cracks or spallation, however, indicate excessive dilution, base plate contamination, or insufficient preheat and must be investigated. Check ASTM A484/A484M for acceptance criteria in CCO plate products.

Q: What preheat and interpass temperatures are required for hardfacing steels?

Preheat requirements depend on substrate carbon equivalent (CE) and hardfacing alloy type. For CE < 0.40 (mild steel), preheat is typically 20–50 °C minimum. For CE 0.40–0.60, preheat 100–200 °C is required. For CE > 0.60 (high-carbon, high-alloy substrates), 200–350 °C preheat may be needed. Cobalt-base hardfacings (Stellite) require lower preheat than iron-base carbide grades because they are less prone to HAZ hydrogen cracking in the substrate. Interpass temperature should not exceed 300 °C for most applications to prevent excessive dilution and carbide dissolution. Post-weld heat treatment (PWHT) of hardfaced components is generally avoided because it can dissolve fine carbides and reduce deposit hardness.

Q: How are WC-based hardfacing deposits different from sintered WC-Co cutting inserts?

Sintered WC-Co cutting inserts are manufactured by powder metallurgy at 1380–1430 °C with full densification; the WC grains are uniform and the microstructure is designed for predictable tool life. WC hardfacing deposits (applied by PTA, GMAW, or PTAW) embed cast WC or macro-crystalline WC particles (0.1–3 mm) in a Co, Ni, or Fe matrix applied by welding. The WC particles partially dissolve during deposition, releasing W and C into the matrix and forming complex W-containing carbides at the particle periphery. This dissolution is controlled by limiting heat input. As-deposited WC hardfacings can reach matrix hardness of 55–65 HRC with WC particles at 2000–2500 HV, but the deposit is not as dimensionally uniform as sintered carbide.

Q: What are iron-base hardfacing alloys and when are they preferred over cobalt-base?

Iron-base hardfacing alloys — including martensitic, austenitic, pearlitic, and carbide-reinforced grades — are significantly cheaper than cobalt-base Stellites and are preferred when cost-per-tonne of material processed is the primary driver. High-chromium iron (Fe-Cr-C, 25–35%Cr, 3–6%C) overlays at 55–65 HRC for low-stress abrasion in slurry pumps and bucket lips. Martensitic iron grades (Fe-Cr-C, 10–18%Cr, 0.5–2%C) reach 45–60 HRC and offer better impact resistance. Cobalt-base grades are specified where elevated temperature properties (>500 °C), corrosion-wear, or metal-to-metal galling resistance is required — applications where iron-base alloys fail rapidly due to oxidation or phase instability.

Hardfacing — the deposition of a wear-resistant alloy onto a substrate by welding or thermal spray — is one of the most cost-effective strategies in materials engineering for extending component service life against abrasion, erosion, cavitation, and metal-to-metal wear. This article examines the three principal hardfacing alloy families (cobalt-base Stellites, iron-base chromium carbide overlays, and tungsten carbide composites), the deposition processes that control deposit quality and dilution, the metallurgical relationships between microstructure and wear performance, and the selection logic that matching alloy to wear mechanism demands.

Key Takeaways

Hardfacing alloy selection is driven by wear mechanism first: abrasion demands high carbide hardness (CCO, WC), adhesive and cavitation wear demands toughness and low galling tendency (Stellite), and erosion demands a balance of hardness and impact resistance.
Stellite grades (Co-Cr-W-C) resist wear at elevated temperatures (>500 °C) and in corrosive environments where iron-base overlays oxidise or corrode; Stellite 6 (38–43 HRC) is the global benchmark valve seat alloy.
Chromium carbide overlay (CCO) plate achieves 55–65 HRC by depositing a hypereutectic Fe-Cr-C microstructure; transverse stress-relief cracks are a normal, acceptable feature.
Dilution is the critical process variable in hardfacing: PTA achieves 5–15% dilution versus 20–40% for GMAW/SMAW; second-layer deposits are essentially unaffected by substrate composition.
WC composite overlays embed 2000–2500 HV tungsten carbide particles in a Co or Ni matrix for extreme abrasion; partial WC dissolution during deposition creates a hardened transition zone.
Post-weld heat treatment is generally avoided for hardfacing deposits because it can dissolve fine carbides; controlled preheat (based on substrate CE) and slow post-weld cooling are the primary thermal management tools.

Hardfacing Alloy Selector & Dilution Calculator

Estimate deposit hardness after dilution and receive an alloy family recommendation based on your wear conditions.

Undiluted deposit hardness (HRC)

Deposition process

Number of layers

Primary wear mechanism

Service temperature (°C)

Substrate base metal HRC (approx.)

Please check your inputs — hardness 25–75 HRC, temperature 20–900 °C, substrate HRC 0–60.

Layer 1 hardness

—

HRC (diluted)

Layer 2 hardness

—

HRC (diluted)

Layer 3 hardness

—

HRC

Hardness drop (L1)

—

HRC lost vs undiluted

Fig. 1 — Schematic microstructure comparison of the three principal hardfacing alloy families: Stellite (Co-Cr-W carbides), chromium carbide overlay (hypereutectic Cr₇C₃), and WC composite (spherical WC particles with dissolution halo in Ni/Co matrix). © metallurgyzone.com

Wear Mechanisms and Alloy Selection Logic

The first step in hardfacing alloy selection is identifying the dominant wear mechanism. Applying the wrong alloy family — even a more expensive one — will consistently underperform the correct cheaper option. The four primary wear modes relevant to hardfacing are abrasion, erosion, adhesion, and cavitation; industrial applications frequently involve combinations.

Abrasion

Hard particles cut, plough, or scratch the surface. Severity depends on particle hardness vs deposit hardness ratio. Demands: maximum surface hardness; CCO (55–65 HRC) or WC overlays. Sub-modes: low-stress (sliding) vs high-stress (crushing/gouging) — high-stress requires toughness alongside hardness.

Erosion

Particles impinge at velocity. At low angle (<30°) resembles abrasion — use hard deposits. At high angle (70–90°) resembles impact — use tough, moderate-hardness alloys (Stellite). In slurry pumps both regimes co-exist depending on geometry.

Adhesion / Galling

Metal-to-metal contact causes plastic deformation and junction welding. Critical for valve seats, pump shafts, and die surfaces. Demands: low coefficient of friction, work-hardening matrix, corrosion resistance. Stellite 6 and 21 are the benchmark galling-resistant alloys.

Cobalt-Base Alloys: Stellite Family

The Stellite family of alloys — originally developed by Elwood Haynes in the early 1900s — are cobalt-chromium-tungsten-carbon alloys whose wear resistance arises from a combination of hard carbide phases, a work-hardening FCC cobalt matrix, and a tenacious Cr₂O₃ surface oxide that resists corrosion and adhesive transfer in corrosive environments. Unlike iron-base hardfacing alloys, Stellites retain their hardness at elevated temperatures (700–900 °C) and resist oxidation, making them the only commercially viable hardfacing choice for steam valve seats, gas turbine blade tip repair, and continuous casting rolls operating above 500 °C.

Stellite Alloy Compositions and Phases

The principal phase in high-carbon Stellite grades (Stellite 1, 6, 12) is M₇C₃ — a complex (Cr,Co,W)₇C₃ carbide that forms as hyper-eutectic primary dendrites and interdendrite eutectic product during solidification. In low-carbon grades (Stellite 21, 190), M₂₃C₆ is the dominant carbide, present in lower volume fractions, which reduces hardness but greatly increases ductility and impact toughness.

Grade	Co (bal.)	Cr (wt%)	W (wt%)	Mo (wt%)	C (wt%)	Hardness (HRC)	Primary Phase	Key Application
Stellite 1	bal.	30	12.5	—	2.4	51–58	M₇C₃	Severe abrasion, cutting blades
Stellite 6	bal.	28	4.5	—	1.1	38–43	M₇C₃	Valve seats, pump impellers, bearing surfaces
Stellite 12	bal.	29	8.3	—	1.4	45–50	M₇C₃	Abrasion + corrosion, intermediate grade
Stellite 21	bal.	27	—	5.5	0.25	28–35	M₂₃C₆	Impact, cavitation, biomedical applications
Stellite 190	bal.	26	14.0	—	3.3	60–65	M₇C₃	Maximum abrasion, not weldable directly
Stellite 694	bal.	28	19.0	—	1.5	45–52	M₇C₃	High-temperature turbine repair

Solidification Microstructure of Stellite 6

During PTA or GTAW deposition of Stellite 6, the weld pool solidifies with a dendritic Co-Cr-W solid solution primary phase, with M₇C₃ carbides segregating to interdendritic regions as the eutectic product. The carbide volume fraction in Stellite 6 is approximately 12–15 vol%, while in Stellite 1 it reaches 30–35 vol%. Rapid cooling (as occurs in GTAW) refines the carbide spacing and increases hardness slightly; slow cooling (as in furnace brazing) coarsens carbides and reduces hardness. This is directly analogous to solidification rate effects on carbide morphology in iron-carbon systems.

Hot Hardness Retention

The critical advantage of Stellite over iron-base hardfacing alloys is hot hardness. Stellite 6 retains approximately 28 HRC at 600 °C and 18 HRC at 800 °C. High-chromium iron (CCO) drops to approximately 15 HRC at 600 °C as the martensite tempers and M₇C₃ coarsens. For valve seat applications in power stations where seat temperatures can exceed 550 °C, this renders iron-base overlays inadequate and makes Stellite the default specification (ASTM A484, ASME PCC-1 supplementary requirements for power valves).

Iron-Base Chromium Carbide Overlays

Chromium carbide overlay (CCO) is the dominant hardfacing product by volume for bulk material handling in mining, cement, steel, and aggregate processing industries. Its principal advantage over Stellite is economics: iron-base consumables cost 5–15% of equivalent cobalt-base alloys per kilogram. CCO is deposited by FCAW-O (open-arc flux-cored wire), SAW, or PTA and reaches 55–65 HRC through a hypereutectic Fe-Cr-C microstructure in which the primary Cr₇C₃ carbides are harder than the abrasive particles typically encountered in bulk handling (silica sand: ~800 HV, Cr₇C₃: 1400–1800 HV).

Fe-Cr-C Alloy Design

The wear-optimal composition lies in the hypereutectic region of the Fe-Cr-C ternary phase diagram at approximately 4–6 wt%C and 25–35 wt%Cr. In this regime, primary Cr₇C₃ dendrites solidify first, growing to 50–200 μm in length, followed by the ledeburite eutectic (Cr₇C₃ + austenite). The austenite matrix transforms to martensite on cooling, contributing additional hardness. The total carbide volume fraction is 50–70 vol%, which is why CCO is so effective against low-stress abrasion but relatively brittle and unsuitable for impact.

Carbon equivalent for CCO composition:

Cr7C3 stability requires:
  Cr/C ratio (wt/wt) ≈ 4.0 to 7.5
  
For Fe-30Cr-5C (representative CCO composition):
  Cr/C = 30/5 = 6.0  → predominantly Cr7C3

Below Cr/C ≈ 4.0 → Cr3C2 + Cr7C3 mixture
Above Cr/C ≈ 8.0 → M23C6 becomes dominant (lower hardness)

Primary carbide hardness: Cr7C3 → 1400–1800 HV
                          Cr3C2 → 2100–2300 HV (but more brittle)
                          M23C6 → 1000–1200 HV

Transverse Stress-Relief Cracking

All commercial CCO plates develop a network of transverse cracks perpendicular to the rolling direction at 25–50 mm spacing during cooling from the deposition temperature. These cracks are a thermodynamic inevitability: the hard, brittle deposit (<1% elongation) cannot accommodate the 200–300 MPa tensile residual stress that builds on cooling. Transverse cracks are a design-accepted feature of CCO plate, provided:

Cracks do not penetrate the buffer layer into the base plate.
No longitudinal cracks or spallation are present.
Crack edges are tight (no gap >0.5 mm for slurry applications).

A 3–6 mm austenitic stainless steel (309L or 307) buffer layer between the base plate and CCO deposit prevents crack propagation and allows the brittle overlay to flex slightly relative to the tough substrate.

CCO Plate Standards and Designations

Commercial CCO plates are typically specified as Cr content + C content + minimum hardness, e.g. a “25+5 / 62 HRC” plate (25 wt%Cr, 5 wt%C, 62 HRC minimum). ASTM G65 (dry rubber wheel abrasion) is the standard comparative wear test, with CCO showing mass loss of 0.02–0.08 g versus 0.3–1.2 g for mild steel in the same test. Overlay thickness ranges from 3 mm to 25 mm; total plate thickness includes base plate (typically 6–25 mm mild steel).

Tungsten Carbide Composite Overlays

Tungsten carbide composite hardfacing embeds WC particles — either cast WC (spherical, containing W₂C dendrites) or macro-crystalline WC (blocky, single-phase hexagonal) — in a metallic matrix of Co, Ni, or NiCr applied by PTA, PTAW, or thermal spray. WC particles bring extreme hardness (2000–2500 HV) for maximum resistance to coarse abrasive particles, while the metal matrix provides cohesion and toughness. Applications include oilfield drill bit inserts, centrifugal pump wear plates in dredging, coal pulveriser grinding rings, and sugar cane chopper blades.

WC Particle Dissolution During Deposition

The critical challenge in WC composite hardfacing is controlling WC dissolution into the melt pool. Above approximately 1300 °C WC dissolves rapidly, releasing W and C into the matrix. The dissolved W forms W-containing carbides (W₂C, (W,Co)₆C) at the WC surface during cooling, creating a brittle dissolution halo that reduces particle-matrix adhesion and can cause delamination. Control strategies include:

Minimising heat input and arc energy per unit length (critical for PTA current and travel speed).
Using WC powders with a protective NiCr or CoCr coating to inhibit surface dissolution.
Limiting powder preheating time in the plasma jet.
Selecting cast WC (higher melting point due to W₂C dendrites) over pure WC for high-dilution processes.

WC-Based Hardfacing Matrix Alloys

Matrix Alloy	Typical WC Loading (wt%)	Matrix Hardness (HRC)	Key Feature	Primary Application
Co-Cr (Stellite-type)	35–50	55–65	Best toughness-hardness balance	Drill bits, pump impellers
NiCrBSi (self-fluxing)	40–60	58–68	Low deposition temp; HVOF compatible	Valve plugs, agitator blades
Fe-Cr-C matrix	30–45	55–62	Lowest cost; adequate toughness	Mining wear plates, bucket lips
Ni-base (Inconel type)	20–40	45–55	Corrosion resistance in acids/brine	Sour-service pump components

Fig. 2 — Plasma transferred arc (PTA) hardfacing process schematic: alloy powder is fed into the constricted plasma arc, melts, and solidifies as a metallurgically bonded deposit. Dilution of 5–15% is the lowest achievable in arc-based hardfacing processes. © metallurgyzone.com

Deposition Processes and Dilution Control

Dilution is the single most important process variable in hardfacing because it directly determines the chemical composition — and thus hardness and wear resistance — of the first deposited layer. Dilution is defined as:

Dilution (%) = (A_base / (A_base + A_deposit)) × 100

where:
  A_base    = cross-sectional area of base metal melted into the pool
  A_deposit = cross-sectional area of filler metal added

Deposit hardness (approximate, first layer):
  HRC_deposit = HRC_filler − (HRC_filler − HRC_substrate) × (D/100)

Example — Stellite 6 (42 HRC) on mild steel (15 HRC), 30% dilution (GMAW):
  HRC_deposit = 42 − (42 − 15) × 0.30 = 42 − 8.1 = 33.9 HRC

Same deposit, 10% dilution (PTA):
  HRC_deposit = 42 − (42 − 15) × 0.10 = 42 − 2.7 = 39.3 HRC

Process	Typical Dilution (%)	Deposition Rate (kg/h)	Heat Input (kJ/mm)	Alloy Forms	Strengths / Limitations
PTA (Plasma Transferred Arc)	5–15	0.5–5	0.3–1.5	Powder	Lowest dilution; excellent quality; expensive equipment; slow for large areas
GTAW (TIG)	10–20	0.5–1.5	0.5–2.0	Rod, wire	Precise heat control; low dilution; very slow; best for small complex geometry
GMAW (MIG)	20–35	2–8	0.5–1.5	Wire	High productivity; moderate dilution; good for large flat surfaces
SMAW (Stick)	25–40	1–3	1.0–3.0	Electrode	Portable; versatile; high dilution; Stellite rods available (E-CoCr-A, -B, -C)
FCAW-O (Open arc)	15–30	4–12	0.8–2.5	Flux-cored wire	Dominant CCO process; high deposition rate; flat/horizontal positions only
SAW (Submerged arc)	35–50	5–20	2.0–5.0	Wire + flux	Highest deposition rate; highest dilution (2 layers essential); flat only
HVOF thermal spray	0 (no fusion)	3–8	—	Powder	No dilution, no HAZ; bond strength limited; not suitable for impact

Multi-Layer Strategies

The standard engineering practice for high-performance hardfacing is a two-layer system: a buffer layer (first pass) absorbs dilution and provides a transition zone, while the second layer achieves near-nominal alloy composition and properties. For Stellite on carbon steel, the first layer at 30% dilution (GMAW) might give 33 HRC versus the nominal 42 HRC; the second layer, diluted primarily by first-layer Stellite, will approach 40–42 HRC. For critical valve seats, a third layer may be specified to ensure a minimum 2 mm of full-composition deposit after final machining.

Hardfacing on Specific Substrate Materials

Carbon and Low-Alloy Steels

The most common substrate class. Carbon equivalent (CE) governs preheat requirement. Steels with CE > 0.45 require preheat of 100–200 °C to prevent hydrogen-induced cold cracking in the HAZ, as discussed in the hydrogen-induced cracking article. The heat-affected zone microstructure beneath a hardfacing deposit is typically a coarse-grained HAZ containing martensite, which can crack without adequate preheat and interpass temperature control.

Carbon equivalent (Ito-Bessyo PCM for crack susceptibility):

PCM = C + Si/30 + (Mn+Cu+Cr)/20 + Ni/60 + Mo/15 + V/10 + 5B

Preheat guidelines for hardfacing on carbon steels:
  PCM < 0.20  → No preheat required (T_min = 20 °C)
  PCM 0.20–0.25 → Preheat 50–100 °C
  PCM 0.25–0.30 → Preheat 100–150 °C
  PCM > 0.30  → Preheat 150–250 °C minimum

Austenitic Manganese Steel (Hadfield Steel)

13% Mn austenitic steels are used in crusher jaws, rail crossings, and dipper teeth — they work-harden in service from ~200 HV to 500+ HV. Hardfacing with austenitic Mn-based filler (AWS EFeMn-B) or chromium carbide is common for rebuilding worn surfaces. The critical constraint is heat input: above approximately 250–350 °C interpass temperature, Mn steel embrittles by carbide precipitation at austenite grain boundaries. Multi-pass hardfacing must use strict interpass temperature control with forced air or water cooling between passes.

High-Chromium Cast Iron Substrates

Hardfacing onto existing CCO plate for repair uses matching-composition FCAW-O wire or, for improved properties, WC-Ni PTA. Preheat of 150–200 °C is required. The existing CCO must be mechanically prepared (grinding or gouging) to remove the work-hardened surface layer before redeposition. Interpass temperature control is especially critical here due to the very low ductility of the substrate.

Quality Assurance and Testing

Post-deposition testing for hardfacing deposits follows a well-established sequence: visual inspection (ISO 17637 for surface integrity, crack pattern acceptability), hardness survey (Rockwell HRC or Brinell per ISO 6506, ASTM E18/E10), bead geometry measurement, and bond test (inclined plane shear test per AWS C2.25 or peel test). For critical applications (valve seats in power stations, oilfield components), the ASTM G65 dry rubber wheel test and ASTM G76 erosion test provide comparative wear data. Metallographic cross-sections etched in Murakami’s reagent (K₃[Fe(CN)₆] + KOH) reveal carbide distribution and dilution zone depth in Stellite and CCO deposits.

HAZ Microstructure

Understanding the coarse-grained and fine-grained HAZ zones formed beneath hardfacing deposits — critical for preheat selection and crack prevention.

Hydrogen-Induced Cracking

The mechanism behind cold cracking in the HAZ of hardfaced carbon steel components — prevention through preheat, low-hydrogen consumables, and PWHT.

Hardness Testing Methods

HRC, HV, and Brinell measurement of hardfacing deposits — load selection, surface preparation requirements, and cross-section microhardness traverses.

Martensite Formation in Steel

The hard, brittle phase that forms in the substrate HAZ when hardfacing high-CE steels without adequate preheat — and why it cracks under residual stress.

Alloy Family Comparison Summary

Property / Criterion	Stellite (Co-Cr-W)	Chromium Carbide (Fe-Cr-C)	WC Composite	Iron-Base Martensitic
Hardness (HRC)	28–58	55–65	55–68	45–62
Low-stress abrasion	Good	Excellent	Excellent	Good
High-stress abrasion / gouging	Fair	Good	Very Good	Very Good
Metal-to-metal galling	Excellent	Poor	Fair	Poor
Cavitation erosion	Very Good	Poor	Fair	Poor
Elevated temp. performance (>500 °C)	Excellent	Poor	Good	Poor
Corrosion resistance	Very Good	Moderate	Fair–Good (Ni matrix)	Poor–Moderate
Relative consumable cost	Very High	Low	High	Low–Medium
Machinability after deposit	Grind only	Grind only	Grind only	Grind only
Preferred deposition process	PTA, GTAW	FCAW-O, SAW	PTA, PTAW	FCAW-O, GMAW

Frequently Asked Questions

What is hardfacing and how does it differ from cladding?

Hardfacing is the deposition of a wear-resistant alloy layer onto a substrate to extend service life against abrasion, erosion, impact, or corrosion-wear. Cladding (weld overlay for corrosion protection) uses corrosion-resistant alloys such as Inconel 625 or 309L stainless and prioritises chemical resistance over surface hardness. Hardfacing deposits typically reach 30–70 HRC and are selected primarily on wear mechanism, while cladding deposits are typically 15–30 HRC and selected on electrochemical compatibility with the service environment.

What is dilution and why does it matter in hardfacing?

Dilution is the percentage of base metal that mixes into the deposit: Dilution (%) = (Base metal area melted / Total weld bead area) × 100. High dilution reduces the concentration of hardening alloying elements in the deposit, lowering hardness and wear resistance. PTA achieves 5–15% dilution, making it preferred for expensive alloys like Stellite. SMAW and GMAW give 20–40% dilution. A second layer (buffer coat + hardfacing layer) reduces effective dilution in the surface-active wear zone.

What are the Stellite alloy grades and how do they differ?

Stellite grades are cobalt-chromium-tungsten alloys with varying carbon content. Stellite 6 (Co-28Cr-4W-1.1C) is the benchmark general-purpose grade (38–43 HRC). Stellite 1 (Co-30Cr-12.5W-2.4C) has higher carbide volume fraction giving 51–58 HRC for severe abrasion. Stellite 12 (Co-29Cr-8.3W-1.4C) is intermediate. Stellite 21 (Co-27Cr-5.5Mo-0.25C) is a low-carbon, higher-toughness grade for impact and cavitation. The carbide phase is primarily M₇C₃ in higher-carbon grades and M₂₃C₆ in lower-carbon grades.

How does chromium carbide overlay plate resist abrasion?

CCO plate consists of a dense network of hypereutectic Cr₇C₃ carbides (60–70 vol%) in an austenitic or martensitic iron matrix. The angular, hard carbides (1400–1800 HV) intercept abrasive particles, while the matrix provides toughness to prevent spallation. CCO reaches 55–65 HRC. Compositions are deliberately hypereutectic (4–6 wt%C, 25–35 wt%Cr) to maximise primary carbide volume, as the hardness of Cr₇C₃ (1400–1800 HV) greatly exceeds that of silica (800 HV), the most common industrial abrasive.

What is PTA hardfacing and what are its advantages?

PTA is a powder-fed deposition process in which a constricted plasma arc melts alloy powder onto the substrate. Key advantages: dilution of 5–15% (lowest of arc processes), dense metallurgically bonded deposits, precise bead geometry, suitability for expensive alloy powders, minimal HAZ, and automation compatibility. Powder feed rate, plasma current, travel speed, and shielding gas composition are the primary variables. PTA is the dominant process for valve seats, pump components, and oilfield drill bit hardfacing.

What is the difference between abrasive, erosive, and adhesive wear for alloy selection?

Abrasive wear involves hard particles cutting or ploughing the surface — use high-hardness CCO or WC-based overlays. Erosive wear involves particle impingement at oblique angles — at low angles use hard deposits (CCO); at high angles use tough, moderate-hardness alloys (Stellite). Adhesive wear (metal-to-metal sliding/galling) requires Stellite grades with low friction and excellent galling resistance. Cavitation erosion is best resisted by tough, strain-hardening alloys such as Stellite 6 or 21 rather than high-carbide brittle deposits.

Why do chromium carbide hardfacing deposits crack, and is this acceptable?

CCO overlays develop transverse stress-relief cracks perpendicular to the welding direction during cooling, because the hard, low-ductility deposit cannot accommodate thermal contraction stress. These cracks (25–50 mm spacing) are a normal, expected, and accepted feature of CCO plates and do not propagate into the base plate when a buffer layer is used. Longitudinal cracks or spallation, however, indicate excessive dilution or poor base plate preparation and must be investigated. ASTM A484/A484M provides acceptance criteria.

What preheat and interpass temperatures are required for hardfacing steels?

Preheat depends on substrate carbon equivalent. For PCM < 0.20 (mild steel), no preheat is required. For PCM 0.20–0.25, preheat 50–100 °C. For PCM 0.25–0.30, preheat 100–150 °C. For PCM > 0.30, preheat 150–250 °C minimum. Cobalt-base hardfacings require lower preheat than iron-base carbide grades. Interpass temperature should not exceed 300 °C. Post-weld heat treatment is generally avoided because it can dissolve fine carbides and reduce deposit hardness.

How are WC hardfacing deposits different from sintered WC-Co cutting inserts?

Sintered WC-Co inserts are manufactured by powder metallurgy with full densification; the WC grains are uniform and the microstructure is engineered for tool life. WC hardfacing deposits embed cast or macro-crystalline WC particles (0.1–3 mm) in a Co or Ni matrix by welding. WC particles partially dissolve during deposition, releasing W and C into the matrix and forming complex carbides at particle peripheries. As-deposited WC hardfacings reach matrix hardness of 55–65 HRC with WC particles at 2000–2500 HV, but the deposit is not as dimensionally uniform as sintered carbide.

What are iron-base hardfacing alloys and when are they preferred over cobalt-base?

Iron-base hardfacing alloys (high-Cr iron, martensitic grades, austenitic Mn-steel) are significantly cheaper than cobalt-base Stellites and are preferred when cost per tonne of processed material is the primary driver. High-chromium iron overlays at 55–65 HRC suit bulk abrasion in mining and cement. Cobalt-base grades are specified where elevated temperature (>500 °C), corrosion-wear, or galling resistance is required — applications where iron-base alloys fail rapidly due to oxidation or phase instability.

Recommended Books and References

Handbook of Thermal Spray Technology — ASM International

Covers all thermal spray and weld overlay processes including PTA and HVOF, with coating property data and application case studies. Essential reference for hardfacing engineers.

View on Amazon

Engineering Tribology — Gwidon Stachowiak & Andrew Batchelor

Comprehensive treatment of friction, wear mechanisms, lubrication, and surface engineering. Provides the tribological foundation for rational hardfacing alloy selection.

View on Amazon

Welding Metallurgy — Sindo Kou (2nd Ed.)

Rigorous metallurgical treatment of weld pool solidification, HAZ microstructure, and hot cracking — directly applicable to hardfacing deposit quality and dilution effects.

View on Amazon

Wear of Materials — ASM International (Selected Works)

Curated collection from the biennial Wear of Materials conference — peer-reviewed data on abrasive, erosive, and adhesive wear of hardfacing alloys and coatings.

View on Amazon

Disclosure: MetallurgyZone participates in the Amazon Associates programme. If you purchase through these links, we may earn a small commission at no extra cost to you. This helps support free technical content on this site.

Hardfacing Alloys: Stellite, Chromium Carbide, and Tungsten Carbide Overlay

Hardfacing Alloys: Stellite, Chromium Carbide, and Tungsten Carbide Overlay

Key Takeaways

Hardfacing Alloy Selector & Dilution Calculator

Wear Mechanisms and Alloy Selection Logic

Cobalt-Base Alloys: Stellite Family

Stellite Alloy Compositions and Phases

Solidification Microstructure of Stellite 6

Hot Hardness Retention

Iron-Base Chromium Carbide Overlays

Fe-Cr-C Alloy Design

Transverse Stress-Relief Cracking

CCO Plate Standards and Designations

Tungsten Carbide Composite Overlays

WC Particle Dissolution During Deposition

WC-Based Hardfacing Matrix Alloys

Deposition Processes and Dilution Control

Multi-Layer Strategies

Hardfacing on Specific Substrate Materials

Carbon and Low-Alloy Steels

Austenitic Manganese Steel (Hadfield Steel)

High-Chromium Cast Iron Substrates

Quality Assurance and Testing

Alloy Family Comparison Summary

Frequently Asked Questions

Recommended Books and References

Further Reading