ISO 14577-1:2026

International Standard   Current Edition · Approved on 16 June 2026

Metallic materials — Instrumented indentation test for hardness and materials parameters — Part 1: Test method

ISO 14577-1:2026 Files

English 44 Pages
Current Edition
USD 225.18

ISO 14577-1:2026 Scope

This document specifies the method of instrumented indentation test for determination of hardness and other materials parameters for the following three ranges:

  • macro range: 2 N ≤ F ≤ 30 kN;
  • micro range: 2 N > F; h > 0,2 µm;
  • nano range: h ≤ 0,2 µm.

For the nano range, the mechanical deformation strongly depends on the real shape of indenter tip and the calculated material parameters are significantly influenced by the contact area function of the indenter used in the testing machine. Therefore, careful calibration of both instrument and indenter shape is required in order to achieve an acceptable reproducibility of the materials parameters determined with different machines.

The macro and micro ranges are distinguished by the test forces in relation to the indentation depth.

Attention is drawn to the fact that the micro range has an upper limit given by the test force (2 N) and a lower limit given by the indentation depth of 0,2 µm.

The determination of hardness and other material parameters is given in the normative Annex A.

At high contact pressures, damage to the indenter is possible. For test pieces with very high hardness and modulus of elasticity, permanent indenter deformation can occur and can be detected using suitable reference materials. Indentations that result in damage or permanent deformation of the indenter are excluded from the scope of this test method.

This test method can also be applied to thin metallic and non-metallic coatings and non-metallic materials. In this case, it is recommended that the specifications in the relevant standards be taken into account (see also 7.3 and ISO 14577-4).

The analysis methods of this standard assume that materials behave like ideal materials. Any deviation (internal stress, pile-up, sink-in, densification, phase transitions, cracks) will result in additional uncertainties. This becomes especially important if comparisons shall be done to material parameters, obtained with other methods.

Best Sellers

GSO 150-2:2013
 
Gulf Standard
Expiration dates for food products - Part 2 : Voluntary expiration dates
YSMO GSO 150-2:2020
GSO 150-2:2013 
Yemeni Technical Regulation
Expiration dates for food products - Part 2 : Voluntary expiration dates
GSO 9:2022
 
Gulf Technical Regulation
Labeling of prepackaged food stuffs
YSMO GSO 2055-1:2020
GSO 2055-1:2015 
Yemeni Standard
HALAL FOOD - Part 1 : General Requirements

Recently Published

ISO/IEC TR 23888-1:2026
 
International Standard
Information technology — Artificial intelligence for multimedia — Part 1: Vision and scenarios
ISO 8715-1:2026
 
International Standard
Electric road vehicles — Road operating characteristics — Part 1: Passenger cars and light duty vehicles
ISO 4306-1:2026
 
International Standard
Cranes — Vocabulary — Part 1: General
ISO 21316:2026
 
International Standard
Traditional Chinese medicine — Isatis indigotica root