Hardness is the main indicator of tool quality


Rockwell method

Among all existing methods for determining the hardness of steels and non-ferrous metals, the most common and most accurate is the Rockwell method.


Rockwell method - determination of metal hardness

Carrying out measurements and determining the Rockwell hardness number is regulated by the relevant documents of GOST 9013-59

. This method is implemented by pressing indenters—a diamond cone or a carbide ball—into the material being tested. Diamond indenters are used for testing hardened steels and carbide alloys, while carbide balls are used for testing less hard and relatively soft metals. Measurements are carried out using mechanical or electronic hardness testers.

The Rockwell method provides for the possibility of using a number of hardness scales A, B, C, D, E, F, G, H (54 in total), each of which provides the greatest accuracy only in its own relatively narrow measurement range.

To measure high hardness values ​​with a diamond cone, the “A” and “C” scales are most often used. They are used to test samples made of hardened tool steels and other hard steel alloys. And comparatively softer materials, such as aluminum, copper, brass, and annealed steel are tested with ball indenters on the “B” scale.

Example of Rockwell hardness designation: 58 HRC or 42 HRB.

The numbers in front indicate a number or a conventional unit of measurement. The two letters after them are the Rockwell hardness symbol, the third letter is the scale on which the tests were carried out.

(!)

Two identical values ​​from different scales are not the same thing, for example, 58 HRC ≠ 58 HRA. Rockwell numerical values ​​can only be compared if they belong to the same scale.

Rockwell scale ranges according to GOST 8.064-94:

A70-93 HR
B25-100 HR
C20-67 HR

Locksmith tool

Tools for manual metal processing (chopping, cutting, filing, branding, punching, marking) are made from carbon and alloy tool steels. Their working parts are subjected to hardening to a certain hardness, which should be within the following limits:

Hacksaw blades, files58 – 64 HRC
Chisels, crosspieces, bits, center punches, scribers54 – 60 HRC
Hammers (head, toe)50 – 57 HRC

Installation tool

This includes various wrenches, screwdrivers, and pliers. The hardness standard for their working parts is set by current standards. This is a very important indicator, which determines how wear-resistant the tool is and can resist crushing. Sufficient values ​​for some instruments are given below:

Wrenches with jaw size up to 36 mm45.5 – 51.5 HRC
Wrenches with jaw size from 36 mm40.5 – 46.5 HRC
Phillips, slotted screwdrivers47 – 52 HRC
Pliers, pliers, duckbills44 – 50 HRC
Nippers, side cutters, metal scissors56 – 61 HRC

Metal cutting tool

This category includes consumable equipment for metal cutting, used on machine tools or with hand tools. For its manufacture, high-speed steels or hard alloys are used, which retain hardness in cold and overheated states.

Taps, dies61 – 64 HRC
Countersinks, countersinks, counterbores61 – 65 HRC
Metal drills63 – 69 HRC
Titanium nitride coated drillsup to 80 HRC
HSS cutters62 – 66 HRC

Note:

Some milling cutter manufacturers indicate in the marking the hardness not of the cutter itself, but of the material that it can process.

Fasteners

There is a relationship between the strength class of a fastener and its hardness. For high-strength bolts, screws, and nuts, this relationship is reflected in the table:

Bolts and screwsNutsWashers
Strength classes 8.810.912.9 8 10 12Art.Zak.art.
d<16 mmd>16 mmd<16 mmd>16 mm
Rockwell hardness, HRCmin2323323911192629.220.328.5
max343439443036363623.140.8

If for bolts and nuts the main mechanical characteristic is the strength class, then for such fasteners as lock nuts, washers, set screws, hardness is no less important.

The following minimum/maximum Rockwell values ​​are established by the standards:

Retaining rings up to Ø 38 mm47 – 52 HRC
Retaining rings Ø 38 -200 mm44 – 49 HRC
Retaining rings from Ø 200 mm41 – 46 HRC
Lock toothed washers43.5 – 47.5 HRB
Spring steel washers (grover)41.5 – 51 HRC
Bronze spring washers (grover)90 HRB
Set screws of strength class 14H and 22H75 – 105 HRB
Set screws of strength class 33H and 45H33 – 53 HRC

Converting hardness units hb to hrc

Conversion table H B – HRC (Hardness Conversion)

(ratio of Brinell hardness to Rockwell hardness, determined by methods in accordance with GOST 8.064-79)

Hardness is the resistance of a body to the penetration of an indenter - another solid body. Hardness testing methods are divided into static and dynamic.

Static methods include methods for measuring hardness according to Brinell, Vickers, Rockwell, Knoop; to dynamic - methods of measuring hardness according to Shore, Schwartz, Bauman, Poldi, Morin, Grave.

Hardness measurements are carried out at 20±10°C.

Brinell hardness measurement

Brinell method

Brinell method [named after the Swedish engineer J.A. Brinell] – a method of determining the hardness of materials by pressing a hardened steel ball with a diameter of 2.5 into the test surface; 5 and 10 mm with load P from 625 N to 30 kN. Brinell hardness number HB is the ratio of load (kgf) to the area (mm 2 ) of the print surface. To obtain comparable results of relative hardness, materials (HB over 130) are tested at a ratio P:D 2 = 30, materials of medium hardness (HB 30-130) - at P: D 2 = 10, soft (HB 2 = 2.5. Tests according to the Brinell method, they are carried out on stationary hardness testers - Brinell presses , which ensure smooth application of a given load to the ball and its constancy when held for a set time (usually 30 seconds).

The Brinell method for measuring the hardness of metals is regulated by GOST 9012-59 “ Metals. Brinell hardness method : The standard establishes a method for measuring the Brinell hardness of metals with a hardness of not more than 650 units. The essence of the method is to press a ball (steel or hard alloy) into a sample (product) under the influence of a force applied perpendicular to the surface of the sample for a certain time, and measure the diameter of the indent after removing the force. GOST 9012-59, in particular, defines the requirements for the selection of metal samples for measuring Brinell hardness - sample size, surface roughness, etc.

Rockwell hardness measurement

material provided by SIDOROV Alexander Vladimirovich

Hardness

– the property of a material to resist the penetration of another, harder body into it – an indenter.

There are several scales (measurement methods) for measuring hardness, the most common of which are [1]:

  • Brinell method
    (HB) - hardness is determined by the diameter of the imprint left by a metal ball pressed into the surface. Hardness is calculated as the ratio of the force applied to the ball to the area of ​​the indentation. The dimension of Brinell hardness units is MPa. The method is not applicable to thin materials and materials with high hardness;
  • Rockwell method
    (HRA, HRB, HRC) - hardness is determined by the relative depth of indentation of a metal ball or diamond cone into the surface of the material being tested.
    Hardness is calculated using the formula [2]: HR = HRmax – (H – h) / 0.002
    , where
    HRmax
    is the maximum Rockwell hardness (on scales A and C it is 100 units, and on scale B – 130 units),
    (H – h )
    is the difference between the indenter immersion depths (in millimeters) after removing the main load and before its application (with pre-loading). Hardness determined by this method is a dimensionless quantity. The Rockwell method is easier to implement, but has less accuracy compared to the Brinell and Vickers methods. Testing of samples with a thickness less than ten times the tip penetration depth is not permitted;
  • Vickers method
    (HV) - hardness is determined by the area of ​​the imprint left by a tetrahedral diamond pyramid pressed into the surface. Hardness is calculated as the ratio of the load applied to the pyramid to the area of ​​the indentation. The dimension of Vickers hardness units is MPa. Allows you to determine the hardness of nitrided and cemented surfaces, as well as thin sheet materials [3]:, but has reduced accuracy in the lower range (for soft materials).

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The results of hardness measurements using the Rockwell and Vickers methods can be converted using tables into hardness units using the Brinell method (Table 1) [4]. Knowing the Brinell hardness, it is possible to calculate the tensile strength and yield of the material, which is important for applied engineering problems [5]:

for aluminum alloys:

for copper alloys:

where σв

– ultimate strength, MPa;
σт
– yield strength, MPa.

Table 1 – Translation of hardness measurement results
Brinell scale, HBRockwell scale, HRB (HRC)Vickers scale, HV
10052,4100
10557,5105
11060,9110
11564,1115
12067,0120
12569,8125
13072,4130
13574,7135
14076,6140
14578,3145
15079,9150
15581,4155
16082,8160
16584,2165
17085,6170
17587,0175
18088,3180
18589,5185
19090,6190
19591,7195
20092,8200
20593,8205
21094,8210
21595,7215
22096,6220
22597,5225
23098,4230
23599,2235
240100,0240
245(21,2)245
250(22,1)250
255(23,0)255
260(23,9)260
265(24,8)265
270(25,6)270
275(26,4)275
280(27,2)280
285(28,0)285
290(28,8)290
295(29,5)295
300(30,2)300
310(31,6)310
319(33,0)320
328(34,2)330
336(35,3)340
344(36,3)350
352(37,2)360
360(38,1)370
368(38,9)380
376(39,7)390
384(40,5)400
392(41,3)410
400(42,1)420
408(42,9)430
416(43,7)440
425(44,5)450
434(45,3)460
443(46,1)470
(47,5)490
(48,2)500
(49,6)520
(50,8)540
(52,0)560
(53,1)580
(54,2)600
(55,4)620
(56,5)640
(57,5)660
(58,4)680
(59,3)700
(60,2)720
(61,1)740
(62,0)760
(62,8)780
(63,6)800
(64,3)820
(65,1)840
(65,8)860
(66,4)880
(67,0)900
(69,0)1114
(72,0)1220

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Conversion of hardness values ​​should only be used in cases where it is impossible to test the material under the specified conditions. The resulting hardness conversion numbers are only approximate and may not be accurate for specific cases. Strictly speaking, such a comparison of hardness numbers obtained by different methods and having different dimensions is devoid of any physical meaning, but, nevertheless, has a definite practical value.

RockwellBrinellVicker sShoreTo break
HRAH.R.C.HB(3000H)Print diameter, mmH.V.HSDN/mm²
89727822.201220
86.5701076101
86697442.25100499
85.56894297
85677132.3089495
84.56685492
84656832.3582091
83.56478988
83636522.4076387
82.56273985
81.5616272.4571583
8160695812206
80.5596002.50675802137
80582.55655782069
79.557578636762000
79562.60617751944
78.555555598741889
78542.65580721834
77.553532562711772
77525122.70545691689
76.5514952.75528681648
7650513671607
75.5494772.80498661565
74.5484602.85485641524
74474482.89471631496
73.5464372.92458621462
73454262.96446601420
72.5444153.00435581379
71.5423933.08413561317
70.5403723.16393541255
383523.25373511193
363323.34353491138
343133.44334471076
322973.53317441014
302833.6130142965
282703.6928541917
262603.7627139869
242503.8325737834
222403.9124635793
202303.9923634752

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Rockwell hardness

Indentation of a diamond cone with an angle of 120° at the apex and measurement of the relative depth of immersion into the material under study.

Scale A – load 60 kgf, for tungsten carbide (VK)

Scale C – load 150 kgf, for hard steel HRB>100

The advantage is simplicity. Disadvantage: low accuracy.

Brinell hardness

The diameter of the imprint of a metal ball in the material.

Disadvantage: hardness up to 450HB.

Vickers hardness

The area of ​​the imprint from a diamond pyramid.

Shore hardness

Rebound of a ball from a surface in a scleroscope (rebound method). A very simple and convenient method.

Determining the hardness of a material is an important part of the technological process for manufacturing parts of any complexity.

Various methods for searching for the hardness of a metal are primarily associated with the difference in their structure and shape. Working with a regular blank in the form of a blank is not difficult, but sheet material requires a special approach, given its small thickness.

Only using the Vickers method is it most convenient to search for the hardness of nitrided and cemented surfaces.

Calculation of the service life of a metal-cutting tool, its durability, is always carried out primarily taking into account tabular indicators.

It is thanks to the increased hardness (about 71 HRC) that carbide drills and cutters made from VK8 alloy make it possible to process super-hard materials.

Relative hardness measurement using files

The cost of stationary and portable hardness testers is quite high, so their purchase is justified only by the need for frequent use. Many craftsmen, if necessary, practice measuring the hardness of metals and alloys relatively, using improvised means.


Measuring hardness using files

Filing a sample with a file is one of the most accessible, but far from the most objective, ways of checking the hardness of steel parts, tools, and equipment. The file must have a non-blunted double cut of medium size No. 3 or No. 4. The resistance to filing and the accompanying grinding noise makes it possible, even with little skill, to distinguish unhardened steel from moderately (40 HRC) or hard-hardened (55 HRC).

For testing with greater accuracy, there are sets of calibrated files, also called scratch hardness testers. They are used for testing saw teeth, milling cutters, and gears. Each such file carries a certain value on the Rockwell scale. Hardness is measured by briefly scratching the metal surface alternately with files from the kit. Then two close ones are selected - a harder one, which left a scratch, and a less hard one, which could not scratch the surface. The hardness of the metal being tested will be between the hardness values ​​of these two files.

Why are hardness tables needed?

However, let's return to the question posed: why do we need hardness tables?

In short, they are indispensable if different methods of hardness measurement are used. You can understand what we are talking about using specific examples.

Example: how to measure the hardness of a 65G steel wavy spring

You need to measure the hardness of a 65G steel wavy spring, but it is very thin, less than 0.5 mm thick, and cannot be tested with a conventional Rockwell apparatus at a load of 150 kgf or 60 kgf, since it will sag. However, the final values ​​must be obtained from HRC. You can get out of this situation if you use a Super-Rockwell apparatus, for example, at a load of 15 kgf (HR15N), in which case you will receive the correct hardness values, which you can convert into the required units using the table.

Example: how to determine the hardness of beryllium bronze BrB2

Or the following example. It is necessary to determine the hardness of beryllium bronze BrB2; after dispersion aging it should be at least 320 HV (Vickers). You can also “prick” it on a Super-Rockwell machine, and then convert the resulting values, for example, in HR15N to HV.

Vickers method

The Vickers method is characterized by low loads and, unlike other methods, where sometimes rough grinding on a sandpaper or a grinding and grinding machine is sufficient, it requires ideal preparation of the surface under study (to a mirror state). Hardness is determined by the diagonal of the indentation (pyramid), which is also converted to HV according to the table. No. 1. Vickers is indispensable when studying the results of chemical-thermal treatment. For example, the hardness of a nitrided layer, if it has a shallow depth, can only be determined by Vickers; Super-Rockwell will show incorrect results in such a situation.

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