Fracture toughness is the ability of a component containing a flow to resist fracture. In the current study, the Ball indentation (BI) test technique, which is well acknowledged as an alternative approach to evaluate mechanical properties of materials due to its semi-nondestructive, fast, and high accurate qualities is used to estimate damage and the fracture toughness for copper samples subjected to varying levels of creep and fatigue. The indentation fracture toughness shows the degradation of Cu samples when they are subjected to different creep conditions. Axial fatigue cycling increases the strength at the mid-gauge section compared to other regions of the samples due to initial strain hardening. The advancement of indentation depth with indentation fatigue cycles experiences transient stage, i.e., jump in indentation depth has been observed, which may be an indication of failure and followed by a steady state with almost constant depth propagation with indentation cycles. © 2012 The Minerals, Metals & Materials Society and ASM International.

Raghu V. Prakash

Department of Mechanical Engineering

Alternative approach

AXIAL FATIGUE

BALL INDENTATION TESTS

CREEP AND FATIGUE

CREEP CONDITIONS

CYCLIC INDENTATION

FATIGUE CYCLES

INDENTATION DEPTH

INDENTATION FRACTURE TOUGHNESS

MECHANICAL PROPERTIES OF MATERIALS

PURE COPPER

steady state

TRANSIENT STAGE

Copper

Creep

Mechanical properties

Strain hardening

Fatigue damage

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IIT Madras

Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science

An experimental investigation of cyclic indentation testing to characterize the fatigue response of three different metallic materials: two aluminum alloys (2014-T651 and 7175-T7351) and a duplex stainless steel (2205), was carried out. The force-displacement response during cyclic loading was logged continuously throughout the entire duration of the test and the data were analyzed to identify parameters such as change in total depth of penetration, change in loading and unloading slopes, change in unloading intercept as a function of number of cycles, and change in displacement range as a function of number of cycles. From the results, one could identify the transient response of the material during cyclic loading, and identify some specific points relating to fatigue failure life, such as knee-point response in depth of penetration as a function of number of cycles of loading. It was observed that data on unloading slope plotted as a function of number of cycles also provide an indication of specimen failure in compression-compression fatigue. The responses were found to be similar for all the three materials tested at different maximum compressive force levels. Failure life data in the low cycle fatigue (LCF) region was evaluated for Al-Cu-Mg alloy 7175-T7351 and the data compared with the failure indicators (knee point) during cyclic indentation testing. A reasonable correlation was established between failure life, as indicated by LCF testing and knee point indicated by cyclic indentation. Experiments were also carried out on virgin material of 7175-T7351 alloy and plastically deformed material of the same alloy. Both static and cyclic indentation tests show a difference in material behavior before and after residual plastic deformation. Further work is required to correlate failure life data as obtained from cyclic indentation with specimens having controlled damage levels, before this technique can be used for residual life estimation purposes. Copyright © 2008 by ASTM International.

ASTM Special Technical Publication

Investigation of material fatigue behavior through cyclic ball indentation testing

Chemical Engineering & Technology

Editorial Board: Chem. Eng. Technol. 10/2019

Engineering Fracture Mechanics

Effect of pre-strain on the indentation fracture toughness of high strength low alloy steel by means of continuum damage mechanics

Philosophical Magazine Letters

An indentation fatigue strength law

Scripta Materialia

An indentation fatigue depth propagation law

Study of damage and fracture toughness due to influence of creep and fatigue of commercially pure copper by monotonic and cyclic indentation

Journal	Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science
ISSN	10735623
Open Access	No