Steel Hardness Conversion Calculator — HRC, HV, HB, HRB, and UTS per ASTM E140

Hardness testing is one of the most widely used mechanical property measurements in engineering — fast, non-destructive on bulk material, and closely correlated to tensile strength and wear resistance in steels. Yet the four major scales in everyday use (Rockwell C, Vickers, Brinell, Rockwell B) measure fundamentally different quantities and cannot be converted exactly between one another. The conversion tables in ASTM E140-12b provide standardised empirical correlations for wrought carbon and alloy steels; this calculator implements those tables, adds approximate UTS estimation per the Brinell–tensile strength relationship, and checks results against key code hardness limits including NACE MR0175/ISO 15156 sour service and ASME Section IX weld HAZ requirements.

Key Takeaways

  • Hardness conversions between scales are empirical, not exact. ASTM E140 values carry an uncertainty of approximately ±2 HRC or ±15 HV for wrought carbon and alloy steels within the stated valid range.
  • The NACE MR0175/ISO 15156 sour service hardness limit is 22 HRC = 248 HV10 = 237 HBW. For HAZ testing, HV10 is preferred because the small indent can be positioned within the narrow HAZ region.
  • UTS (MPa) ≈ 3.45 × HBW is a valid approximation for wrought carbon and alloy steels in the range HBW 100–400 (±10–15%). It does not apply to cast iron, stainless steel, aluminium, or copper alloys.
  • The Rockwell C scale (HRC) is valid only above approximately 20 HRC (≈226 HV). Below this, use HRB or HV. Above 67 HRC, all Rockwell scales become inaccurate; use Vickers HV or Knoop HK for very hard surfaces.
  • Brinell (HBW) uses a 10 mm tungsten carbide ball at 3000 kgf for steel; the large indent averages microstructural variation and is well-suited to heterogeneous materials like castings and forgings.
  • Leeb (rebound) hardness testers convert to HRC/HV/HBW via ASTM A956 tables; accuracy is ±15–20 HV versus a bench tester, and results are sensitive to surface preparation and material thickness.

Steel Hardness Conversion Calculator

ASTM E140-12b · Convert HRC, HV, HBW, HRB, HRA in any direction · UTS estimate for steel

Select input scale:
HRC Rockwell C 20 – 67
HV Vickers 80 – 900
HBW Brinell 60 – 739
HRB Rockwell B 40 – 100
HRA Rockwell A 60 – 85
Valid range: 80 – 900 HV (for steel per ASTM E140)

Conversions per ASTM E140-12b Table 2 (non-austenitic steels) using polynomial regression fitted to the published table. Valid for wrought carbon and alloy steels only. Not valid for: cast iron, stainless steel, non-ferrous alloys, coatings, or surface-hardened layers (use microhardness HV0.1–HV1 for those). UTS estimate: σUTS (MPa) ≈ 3.45 × HBW, valid HBW 100–400. Conversion accuracy ±2 HRC / ±15 HV within stated ranges.

Hardness Scale Comparison — HRC, HV, HBW, and UTS for Steel 68 60 50 40 30 20 HRC ~900 ~746 ~513 ~381 ~294 ~226 HV (Vickers) As-quenched / file-hard steel (55–67 HRC) HV 596–900 | HBW 580–739 | UTS >2000 MPa Hardened tool / die steel (45–55 HRC) HV 446–596 | HBW 421–580 | UTS 1450–2000 MPa Q+T engineering steel (30–45 HRC) HV 294–446 | HBW 280–421 | UTS 970–1450 MPa Normalised / lightly hardened (20–30 HRC) HV 226–294 | HBW 216–280 | UTS 745–970 MPa Annealed / soft steel (<20 HRC — use HRB or HV) HV <226 | HBW <216 | HRB 40–100 | UTS <745 MPa NACE 22 HRC 248 HV10 S355 norm. (~160 HV) 4140 Q+T 600°C (~300 HV / 30 HRC) 4140 Q+T 400°C (~440 HV / 44 HRC) 4340 as-quenched (~600 HV / 57 HRC) Comparative hardness & condition bands (ASTM E140-12b for wrought steel) Red dashed line: NACE MR0175/ISO 15156 max 22 HRC (248 HV10 / 237 HBW) for sour service. © metallurgyzone.com
Figure 1. Hardness scale comparison for wrought carbon and alloy steel showing HRC zones, equivalent HV and HBW ranges, approximate UTS, and representative engineering grade conditions. The red dashed line marks the NACE MR0175/ISO 15156 maximum 22 HRC (248 HV) for sour service carbon steel. © metallurgyzone.com

The Four Major Hardness Scales: Principles and Valid Ranges

Each hardness scale measures the resistance of a material to permanent indentation, but the indenter geometry, applied load, and measurement methodology differ substantially between scales. These differences are the fundamental reason why conversions are empirical rather than exact.

Vickers Hardness (HV)

The Vickers test uses a square-based diamond pyramid indenter with a 136° face angle. A defined load (from 1 gf to 100 kgf) is applied for 10–15 seconds, and the diagonal lengths of the resulting square indentation are measured optically. Vickers hardness is calculated as:

HV = 1.854 × F / d²

Where:
  F  = applied load (kgf)
  d  = mean diagonal of indentation (mm)
  1.854 = geometric constant for 136° pyramid

Load suffix conventions:
  HV5    = 5 kgf load       (standard desktop tester)
  HV10   = 10 kgf load      (standard for HAZ testing per NACE / ISO 9015-1)
  HV0.3  = 300 gf load      (microhardness, case depth profiles)
  HV0.05 = 50 gf load       (thin coatings, individual phases)

Valid range: HV 1 – 2000+ (single continuous scale)
Advantages: wide range, thin sections, precise positioning, case depth profiling

The Vickers scale is the only scale that covers the full hardness range from very soft (annealed aluminium, HV 15) to extremely hard (cemented carbide, HV 1800) without a scale change. This makes it the preferred laboratory reference scale and the scale used for microhardness testing of case-hardened layers, welds, and HAZ profiling. For a full treatment of all hardness testing methods including equipment calibration and test procedure requirements, see the dedicated guide.

Rockwell Hardness (HRC, HRB, HRA)

The Rockwell test measures the depth of permanent penetration under a defined load. A minor load (10 kgf) is first applied to seat the indenter, the depth is zeroed, then the major load is applied and removed, and the residual penetration depth (after minor load re-engagement) is measured directly — no optical measurement is required. This makes Rockwell the fastest hardness test method for production quality control.

Rockwell C (HRC):
  Indenter: 120° diamond Brale cone
  Minor load: 10 kgf;  Major load: 150 kgf total
  HRC = 100 − (h / 0.002 mm)      [each 0.002 mm penetration = 1 HRC unit]
  Valid range: HRC 20–67
  Applicable: through-hardened steels, tool steels, case-hardened parts

Rockwell B (HRB):
  Indenter: 1/16" (1.588 mm) steel ball
  Minor load: 10 kgf;  Major load: 100 kgf total
  HRB = 130 − (h / 0.002 mm)
  Valid range: HRB 0–100
  Applicable: soft steels, brass, aluminium, annealed metals

Rockwell A (HRA):
  Indenter: 120° diamond Brale cone
  Minor load: 10 kgf;  Major load: 60 kgf total
  HRA = 100 − (h / 0.002 mm)
  Valid range: HRA 60–85
  Applicable: cemented carbides, case-hardened surfaces, thin sheet

Brinell Hardness (HBW)

The Brinell test presses a 10 mm tungsten carbide ball (HBW) into the test surface under a 3000 kgf load for 10–15 seconds. The hardness is calculated from the diameter of the residual indentation:

HBW = (2F) / (π × D × (D − √(D² − d²)))

Where:
  F  = applied load (kgf) = 3000 kgf for standard steel test
  D  = ball diameter (mm) = 10 mm standard
  d  = mean indentation diameter (mm), measured with calibrated optical scale

Valid range: HBW 60–739 (practical upper limit for WC ball)
Advantages:
  — Large indent (3–5 mm diameter) averages heterogeneous microstructure
  — Well-suited to castings, forgings, coarse-grained materials
  — Indent permanently visible for re-measurement or documentation
Disadvantages:
  — Cannot be used on finished surfaces (large indent)
  — Cannot measure thin sections or case-hardened layers
  — Slow (requires optical measurement after indentation)

ASTM E140 Conversion Method and Limitations

ASTM E140-12b (Standard Hardness Conversion Tables for Metals) provides tabulated conversions between all major hardness scales for several material categories. Table 2 covers non-austenitic steels (carbon and alloy steels) and is the basis for the conversions in this calculator. The table was derived from extensive experimental measurement programmes correlating simultaneously measured hardness values on the same specimens in multiple scales.

Polynomial Regression Equations Used in This Calculator

HV → HRC (valid HV 226–900, wrought carbon/alloy steel):
  HRC = −78.506 + 0.3494×HV − 0.0002506×HV²  (fitted to ASTM E140 Table 2)

HV → HBW (valid HV 80–740):
  HBW = −0.001388×HV² + 1.2115×HV − 21.11   (fitted to ASTM E140 Table 2)

HV → HRB (valid HV 80–226):
  HRB = 40.614 + 0.1804×HV + 0.001356×HV²   (fitted, lower hardness range)

HV → HRA (valid HV 226–900):
  HRA = 52.80 + 0.07168×HV − 0.0000267×HV²

UTS estimate (wrought steel, HBW 100–400):
  UTS (MPa) = 3.45 × HBW
  UTS (ksi)  = 0.500 × HBW

All input scales are first converted to HV using inverse relationships,
then all outputs are derived from HV as the common reference scale.

Inverse conversions (input → HV):
  HRC → HV: HV = 1041.43/(67.0−HRC) − 4.72   (approximation, valid HRC 20–65)
  HBW → HV: HV = 1.0563×HBW + 3.20            (linear, valid HBW 60–600)
  HRB → HV: HV = (HRB − 40.614)/0.1804         (simplified linear, valid HRB 40–100)
  HRA → HV: solved numerically from HRA equation above
Critical Limitation: These conversions are empirical correlations valid only for wrought (rolled, forged) carbon and alloy steels in the composition range covered by ASTM E140 Table 2. They give incorrect results for: austenitic stainless steel (significantly different work-hardening behaviour); cast iron (graphite morphology affects indent geometry); non-ferrous alloys (aluminium, copper, titanium); coatings; and case-hardened surface layers where the indent samples a depth-averaged composite of hard case and soft core. For those materials, consult the specific ASTM E140 table for that material class, or use in-scale Vickers measurements without conversion.
Hardness Indenter Geometries — Vickers, Rockwell C, Brinell, Knoop Vickers (HV) 136° pyramid F (load) d (diagonal) HV = 1.854 F/d² Measures: indent area 136° Rockwell C (HRC) 120° Brale diamond 150 kgf h HRC = 100 − h/0.002 Measures: depth h 120° Brinell (HBW) 10 mm WC ball 3000 kgf d (indent ∅) ∅ 10 mm HBW = 2F/(πD(D−√(D²−d²))) Measures: curved area Knoop (HK) Elongated pyramid F (1–1000 gf) L (major diagonal) HK = 14.2 × F/L² L:w ≈ 7:1 ratio Best for thin coatings Each method measures a different physical quantity; conversions between scales are empirical. © metallurgyzone.com
Figure 2. Cross-section geometries of the four principal hardness indenters. Vickers measures projected indent area (d); Rockwell C measures residual penetration depth (h); Brinell measures curved indentation surface area (d); Knoop measures the major diagonal of an elongated indent (L) for thin coatings and brittle materials. The measurement quantity difference is why inter-scale conversions are empirical correlations, not exact equivalences. © metallurgyzone.com

NACE MR0175 / ISO 15156 Hardness Limits

The most practically important code hardness limit in the oil and gas and pressure equipment industries is the NACE MR0175/ISO 15156 maximum hardness for carbon and low-alloy steel in sour service (H2S-containing environments). The limit is 22 HRC, with the following equivalences across scales per ASTM E140:

NACE MR0175 / ISO 15156 Part 2 — Carbon and Low-Alloy Steel Hardness Limit:

  Maximum hardness:  22 HRC  ≡  248 HV10  ≡  237 HBW

  Which scale to use:
  — Base metal (large section): HRC or HBW acceptable
  — Weld HAZ (narrow zone): HV10 required (ISO 9015-1 / ASTM E384)
    Small indent allows precise positioning within HAZ sub-zones
    HV10 load (10 kgf) produces ~0.10–0.15 mm indent diagonal — adequate for
    ~0.5 mm wide CGHAZ in most structural steels
  — Production quality control on pipe and fittings: HRC or HB per purchaser spec

  Conversion path for reporting:
    HV10 measurement on weld cross-section → Convert to HRC using ASTM E140
    Record BOTH values: "248 HV10 (≡ 22 HRC per ASTM E140)"

  Common mistake: applying Rockwell C directly to HAZ
    — The HRC indent is ~1.5 mm deep and samples an area ~4–5 mm wide
    — This is too large to isolate the narrow CGHAZ and ICHAZ sub-zones
    — Report HV10 as primary measurement; HRC equivalent as reference only

The 22 HRC limit applies to the base metal, weld metal, and all HAZ sub-zones (CGHAZ, FGHAZ, ICHAZ) in butt welds, fillet welds, and partial penetration welds. For duplex stainless steel and austenitic stainless steel, Part 3 of ISO 15156 specifies different hardness limits (typically 28–36 HRC depending on alloy and condition) and different test requirements. The relationship between HAZ hardness and hydrogen-induced cracking is explained in detail in the linked article.

Hardness–Tensile Strength Relationship

The Brinell–tensile strength correlation is one of the most widely used empirical relationships in materials engineering. It arises from the physical similarity between the hardness test and a constrained plastic flow process: both the hardness indentation and the tensile necking region involve triaxial stress states and large plastic strains, and both are dominated by the flow stress of the material.

Primary relationship (Tabor, 1951):
  UTS (MPa) = C × HBW
  UTS (ksi)  = C_imp × HBW

  For wrought carbon and alloy steels (HBW 100–400):
    C = 3.45    → UTS (MPa) = 3.45 × HBW       (ASTM E140 Annex A)
    C_imp = 0.500 → UTS (ksi) = 0.500 × HBW

  Accuracy:  ±10–15% for within-class steels
  Range:     HBW 100–400 → UTS 345–1380 MPa

Why the relationship works for steel:
  — Both UTS and hardness scale with carbon content and work hardening rate
  — Hardness ∝ flow stress at ~8% plastic strain
  — UTS ∝ maximum flow stress before necking (Considère criterion)
  — For steels with similar work-hardening exponents, ratio ≈ constant

Where it FAILS (do not use for these materials):
  Grey cast iron:        C ≈ 1.3–1.6 (lower — graphite flakes affect indent)
  Austenitic stainless:  C ≈ 3.4–3.8 (similar range but higher scatter)
  Aluminium alloys:      C ≈ 0.27–0.35 (much lower — different modulus)
  Copper alloys:         C ≈ 0.45–0.55 (different deformation mechanism)
  Case-hardened surfaces: NOT valid — indent averages case + core

Alternative for different steels:
  Low-alloy structural (normalised): UTS ≈ 3.3 × HBW
  Cold-worked stainless 304:         UTS ≈ 3.1 × HBW
  High-strength Q+T (HBW > 350):    Use Vickers + direct tensile testing

Comprehensive Hardness Conversion Reference Table

HRC HV HBW HRB HRA UTS (MPa) Typical condition / note
6894073985.6>2550File-hard as-quenched high-C steel; maximum practical HRC
6583268883.92375As-quenched high-carbon steel / white cast iron
6274662882.22168Case-hardened bearing steel surface
5863356480.11947As-quenched 0.45%C steel (4140, 4340 typical AQ)
5559651378.81770Tool steel HRC specification range; spring steel as-wound
5251248177.41661H13 hot work tool steel after heat treatment
4846043275.414904140 Q+T at ~300°C
4543241174.21419Austempered ductile iron; 4140 Q+T at ~380°C
4038136371.91252S690 Q+T structural steel; 4140 Q+T at ~450°C
3533632069.91104Bainitic/spring steel; API 5L X80 typical HAZ max
222482379765.3818NACE MR0175 / ISO 15156 max (sour service)
202262169564.4745Lower HRC limit; normalised 4140 alloy steel
20019090656Normalised medium-carbon steel; S355/A572 Gr.50 typical
16015280524Normalised mild steel S275/A36 typical
12011466393Annealed mild steel; soft condition
858046276Annealed low-carbon or pure iron
NACE Row Highlighted: The row at 22 HRC / 248 HV / 237 HBW is highlighted in the table above because it represents the critical acceptance threshold for sour service material qualification per NACE MR0175/ISO 15156 Part 2. Any hardness measurement on carbon or low-alloy steel above these values in a sour service application constitutes a non-conformance requiring immediate investigation and disposition.

Hardness Testing in Practice: Inspection and QC Applications

Hardness Testing of Welds and HAZ

Post-weld hardness testing verifies that the weld metal and HAZ have not exceeded the maximum hardness specified by the applicable code or material specification. ISO 9015-1 specifies weld hardness testing procedures for arc-welded joints; it requires a traverse of Vickers HV10 indentations across the weld cross-section including weld metal, HAZ, and base metal, at defined spacings. The maximum hardness location in the CGHAZ (coarse-grained HAZ) typically occurs approximately 0.5–1.0 mm from the fusion line; the traverse spacing must be fine enough to capture this peak. For NACE sour service qualification, API 1104 and ISO 15614-1 specify the number of traverses, indent spacing, and acceptance criteria.

Portable Hardness Testing (Leeb / Rebound)

For in-service inspection of pressure vessels, storage tanks, and structural components where bench testing is impossible, portable Leeb (rebound) hardness testers are standard. The instrument fires a spring-loaded tungsten carbide ball against the surface and measures the ratio of rebound to impact velocity (Leeb value HL). Built-in conversion algorithms translate HL to HRC, HV, or HBW per ASTM A956 / ISO 16859. Key practical requirements for reliable results:

  • Surface finish Ra ≤ 3 μm (grind or polish to this level if rougher)
  • Material thickness ≥ 10 mm, or backed solidly to prevent vibration
  • At least 5 individual readings, discard outliers, use the mean
  • Use the correct material group setting in the instrument (steel, cast iron, aluminium, etc.)
  • Never use results from curved surfaces without applying the curvature correction factor from the instrument manual

Case Depth Verification by Hardness Traverse

The effective case depth after carburising, nitriding, or induction hardening is defined as the depth at which hardness drops to a specified value — typically 550 HV for carburised steel per ISO 2639 (effective case depth), or 50% above the core hardness for induction-hardened components. Vickers microhardness traverses (HV0.3 or HV0.5) from the surface toward the core are the standard method. The traverse spacing must be ≤ 0.1 mm in the case layer to accurately determine the depth at which the hardness threshold is crossed. For the metallurgical context of case hardening processes and their effects on microstructure and hardness profiles, the martensite formation and quenching and tempering guides provide the relevant background.

Frequently Asked Questions

Why can’t hardness values be converted exactly between scales?
Hardness scales measure different physical quantities: Vickers measures projected indent area; Rockwell C measures depth of penetration; Brinell measures curved indent surface area. Each responds differently to material elastic recovery, work hardening rate, and microstructural inhomogeneity. Conversions between scales are empirical correlations from ASTM E140, not exact mathematical equivalences. They are accurate to approximately ±2 HRC or ±15 HV for wrought carbon and alloy steels within the stated range, but give larger errors for cast iron, non-ferrous alloys, or materials with anisotropic microstructure.
What is the NACE MR0175 maximum hardness limit?
NACE MR0175/ISO 15156 specifies a maximum hardness of 22 HRC (equivalent to 248 HV10 or 237 HBW) for carbon and low-alloy steels in sour service (H2S-containing environments). This applies to base metal, weld metal, and heat-affected zone (HAZ). For HAZ testing where the measured area is small, Vickers HV10 is preferred because the smaller indent can be positioned precisely within the narrow HAZ. Converting from HV10 to HRC for comparison uses ASTM E140 Table 2: 248 HV ≈ 22 HRC.
How accurate is the UTS estimate from Brinell hardness?
The relationship UTS (MPa) ≈ 3.45 × HBW is valid for wrought carbon and alloy steels in the range HBW 100–400, with accuracy ±10–15%. It breaks down for cast iron, austenitic stainless steel, aluminium alloys, copper alloys, and case-hardened surfaces where hardness is measured only in the carburised layer. For steel outside HBW 100–400, the proportionality constant changes; direct tensile testing is preferred for specification compliance.
What is the difference between HBW and HBS hardness?
HBW uses a tungsten carbide ball indenter and is specified in ISO 6506 and ASTM E10 for all current Brinell measurements. HBS used a hardened steel ball, limited to materials below approximately HBS 450 to prevent deforming the indenter. Modern standards specify HBW exclusively. For materials below HBS/HBW 350, values are equivalent; above 350, only HBW (tungsten carbide ball) measurements are valid. When reviewing older data sheets quoting HBS, treat values as equivalent to HBW for materials below 350.
Which hardness scale should I use for thin case-hardened layers?
Vickers microhardness (HV0.1, HV0.3, HV0.5, or HV1) is correct for thin case-hardened layers. The indent must be no more than one-tenth of the layer thickness to avoid substrate influence. Rockwell C and Brinell produce indents far too large to sample individual case layers; they measure a composite of case and core. Knoop hardness is used for very thin layers or coatings where the Vickers indent would be too wide. Effective case depth is determined by the depth at which hardness drops below a specified threshold (typically 550 HV per ISO 2639 for carburised steel).
What hardness should I expect after quenching and tempering different steels?
As-quenched hardness is controlled primarily by carbon content: HRCmax ≈ 20 + 60 × %C for 0.20–0.60%C. Tempering reduces hardness: for 4140 steel (0.40%C, as-quenched ~56 HRC): 200°C temper ~54 HRC; 400°C ~46 HRC; 600°C ~32 HRC. Final hardness also depends on section size, hardenability, and whether the microstructure is fully martensitic. Incomplete hardening (mixed martensite/bainite) gives lower as-quenched hardness than fully martensitic structures.
Is a Rockwell or Vickers tester better for production quality control?
Rockwell is preferred for production QC on through-hardened or case-hardened components: it is fast (5–10 seconds), direct-reading, and robust on a shop floor. The HRC scale is standard for hardened steels above approximately 20 HRC. Vickers is preferred for precision work: thin layers, small components, HAZ testing, microstructural variation mapping, or cross-material comparisons. Vickers covers a single continuous scale from HV 1 to 2000+. In practice, many quality plans specify production hardness in HRC with correlation to HV for HAZ qualification records.
What is a Leeb hardness tester and how accurate is it?
A Leeb (rebound) tester measures the ratio of rebound to impact velocity of a spring-loaded carbide ball (HL = 1000 × vrebound/vimpact) and converts via ASTM A956 or ISO 16859 tables to HRC, HV, or HBW. Portable and handheld, it is essential for in-situ testing of large vessels and structural components. Accuracy is typically ±15–20 HV versus a bench Vickers tester; results depend on surface preparation (Ra ≤ 3 μm required), material thickness (≥ 10 mm), impact direction, and material group setting. Always take the mean of 5 readings and treat results as approximate.
Why is hardness testing alone insufficient to verify material specification compliance?
Hardness confirms the current hardness state but does not verify chemical composition, yield strength, elongation, Charpy toughness, or heat treatment history. A steel meeting a hardness specification may fail on composition (wrong grade), impact toughness (wrong temper temperature), or yield strength (incomplete hardening). For full specification compliance, hardness must be used alongside mill certificate verification (EN 10204 Type 3.1 or 3.2), PMI, and dimensional inspection. Hardness is a fast screening tool, not a substitute for the complete material qualification process.
What is the Vickers hardness of common engineering materials?
Approximate Vickers hardness values: pure annealed aluminium 15–25 HV; annealed copper 40–60 HV; mild steel S235/A36 120–160 HV; normalised medium-carbon steel 175–220 HV; 4140 Q+T at 600°C ~300 HV; 4340 as-quenched ~600 HV; grey cast iron 180–280 HV; 316L stainless annealed 150–180 HV; duplex 2205 annealed 270–320 HV; cemented carbide WC-Co 1400–1800 HV; diamond 7000–10000 HV. Actual values depend on composition, processing, and heat treatment condition.

Recommended References and Tools

Portable Leeb Rebound Hardness Tester — Field Use
Handheld Leeb/Equotip-type hardness tester converting to HRC, HV, HBW. Essential for in-situ hardness verification on pressure vessels, piping, and large weld assemblies per ASTM A956.
View on Amazon
ASM Handbook Vol. 4D — Heat Treating of Irons and Steels
Definitive reference covering hardness-microstructure relationships, tempering curves, hardenability, case depth measurement, and hardness testing for all categories of ferrous materials.
View on Amazon
ASTM E140-12b Standard Hardness Conversion Tables (Hardcopy)
The primary standard document providing hardness conversion tables for all material classes. Required reference for any QA programme specifying hardness in multiple scales.
View on Amazon
Vickers Microhardness Tester — Desktop HV Testing for Metals
Desktop Vickers hardness tester for laboratory use: case depth profiles, weld cross-section traverses, thin layer hardness, and precise microhardness mapping from HV0.1 to HV50.
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.

Further Reading

metallurgyzone

← Previous
Welding Heat Input Calculator — kJ/mm for All Arc Processes
Next →
Weld Metal Deposition Rate Calculator — GMAW, FCAW, SMAW and SAW