Brinell hardness test

 ( Hardness Tests ) 

The Brinell hardness test (pronounced /brəˈnɛl/) measures the indentation hardness of materials. It determines hardness through the scale of penetration of an indenter, loaded on a material test-piece. It is one of several definitions of hardness in materials science. The hardness scale is expressed in terms of a Brinell hardness value, sometimes referred to as the Brinell hardness number but formally expressed as HBW (Hardness Brinell Wolfram – Wolfram being an alternative name for the tungsten carbide ball indenter used during the test).

The test was named after Johan August Brinell (1849-1925) who developed the method at the end of the 19th century.

---

History Premiered by Sweden engineer Johan August Brinell at the 1900 Paris Exposition, it was the first widely used and standardised hardness test in engineering and metallurgy. The large size of indentation and thus possible damage to test-pieces limits its usefulness. However, it also had the useful feature that the hardness value divided by two gave the approximate UTS in ksi for steels. This feature contributed to its early adoption over competing hardness tests.

---

Test details The test uses a Tungsten Carbide ball indenter and a controlled force, the ratio of ball size to test force being a function of the material being tested. Most commonly the test is used for ferrous metals and uses a 10mm ball and a 3000 Kgf test force, although it can go as low as 1mm and 1 Kgf (HBW 1/1).

Although the maximum test force is 3000 kgf, there are hand-pumped, hydraulic, portable Brinell testers less than 58cm / 23 inches in height that can develop this force and hold it for sufficient time to perform a Brinell test. One such is pictured.

The advantage of the Brinell test over other measurement systems is that the indentation diameters usually range between 2.4mm and 6mm. This means that the indentation is unaffected by the grain structure of the metal under test, so Brinell testing is especially useful in testing materials such as rough castings with coarse grains. However, measurement of the indentation is normally carried out by a technician using a low-powered microscope, and it can be difficult to judge exactly where an indentation begins and ends. Three experienced technicians could obtain three slightly different readings using the same microscope - and an error of 0.2mm can equal 20 hardness points. The problem of operator interpretation errors was overcome in the 1980s in a collaboration between Birmingham University and the British company Foundrax Engineering Products. They developed a system which harnessed an optical microscope to a computer and which was able to measure indentations across multiple axes in under a second. Automatic measurement systems are now used in many production environments where accuracy is critical.

Brinell hardness is sometimes quoted in megapascals; the Brinell hardness value (expressed as HBW (see above)) is multiplied by the acceleration due to gravity, 9.80665 m/s², to convert it to megapascals.

The Brinell hardness value can be correlated with the ultimate tensile strength (UTS), although the relationship is dependent on the material, and therefore determined empirically. The relationship is based on Meyer's index (n) from Meyer's law. If Meyer's index is less than 2.2 then the ratio of UTS to HBW is 0.36. If Meyer's index is greater than 2.2, then the ratio increases.

The Brinell hardness is designated by the most commonly used test standards (ASTM E10-14 and ISO 6506–1:2005) as HBW ( H from hardness, B from brinell and W from the material of the indenter, tungsten (wolfram) carbide). In former standards HB or HBS were used to refer to measurements made with steel indenters.

HBW is calculated in both standards using the SI units as

$\backslash operatorname\{HBW\}=0.102\; \backslash frac\{2F\}\{\backslash pi\; D\; \backslash left(D-\backslash sqrt\{D^2-d^2\}\backslash right)\}$

where:

F = applied load (newtons)

D = diameter of indenter (mm)

d = diameter of indentation (mm)

---

Common values When quoting a Brinell hardness value (HBW), the conditions of the test used to obtain the number must be specified. The standard format for specifying tests can be seen in the example "HBW 10/3000". "HBW" means that a tungsten carbide (from the chemical symbol for tungsten or from the Spanish/Swedish/German name for tungsten, "Wolfram") ball indenter was used, as opposed to "HBS", which (formerly) meant a hardened steel ball (these are no longer in use). The "10" is the ball diameter in millimeters. The "3000" is the force in kilograms force.

The hardness may also be shown as XXX HB YY D². The XXX is the force to apply (in kgf) on a material of type YY (5 for aluminum alloys, 10 for copper alloys, 30 for steels). Thus a typical steel hardness could be written: 250 HB 30 D². It could be a maximum or a minimum.

+Correspondent relations among scale, indenter and test force: !Hardness symbol !Diameter of Indenter mm !F/D2 !Test force N/kgf
HBW 10/3000	10	30	29420(3000)
HBW 10/1500	10	15	14710(1500)
HBW 10/1000	10	10	9807(1000)

+ Brinell hardness numbers !Material !! Hardness

1.6 HBS 10/100

2.6–7.0 HBS 10/100

5.0 HB (pure lead; alloyed lead typically can range from 5.0 HB to values in excess of 22.0 HB)

15 HB

35 HB

75 HB

120 HB

200 HB

400-700 HB

600–900 HB (HBW 10/3000)

1550 HB

4600 HB

Note: Standard test conditions unless otherwise stated

---

Standards

• International (ISO) and European (CEN) Standard
• US standard (ASTM International)

---

See also

• Brinelling
• Hardness comparison
• Knoop hardness test
• Leeb rebound hardness test
• Rockwell hardness test
• Vickers hardness test

• David Tabor (2025). 9780198507765, Oxford University Press. . ISBN 9780198507765

---

External links

• Brinell Hardness Test – Methods, advantages, disadvantages, applications
• Rockwell to Brinell conversion chart (Brinell, Rockwell A,B,C)
• Struers hardness conversion table (Vickers, Brinell, Rockwell B,C,D)
• Brinell Hardness HB conversion chart (MPa, Brinell, Vickers, Rockwell C)

Post Comment