Structure and Microhardness of Constructional Steel after Ultrasonic Impact Treatment at Negative Air Temperatures

Michael M. Sidorov; Nikolay  I. Golikov; Susanna N. Makharova; Ruslan P. Tikhonov; Marina A. Ivanova

doi:10.4028/p-24xz15

Paper Titles

Investigation of the Gradient Properties of Samples Obtained by Direct Laser Deposition from a Mixture of Ni/Ti Elemental Powders
p.3

Effect of Selective Laser Melting Parameters on Physicomechanical Properties of Ferromagnetic Shape Memory Ni₃₆Al₂₇Co₃₇ Alloy
p.11

Properties Investigation of Steel-TiC Composite Material Formed during Selective Laser Melting Process
p.19

Structure and Microhardness of Constructional Steel after Ultrasonic Impact Treatment at Negative Air Temperatures
p.29

Forming of Briquettes from Iron and Plastic Waste
p.35

Welding at Low Temperatures of Structural Steels
p.41

Surface Modification of Nickel Oxide (II) Thin Films Obtained by Gas-Phase Deposition
p.49

Influence of Crystallization Conditions on the As-Cast Structure of Fe-Mn-Si Alloy with a Shape Memory Effect
p.55

HomeKey Engineering MaterialsKey Engineering Materials Vol. 942Structure and Microhardness of Constructional...

Structure and Microhardness of Constructional Steel after Ultrasonic Impact Treatment at Negative Air Temperatures

Abstract:

The paper investigates the effect of ultrasonic impact treatment on the structure and microhardness of constructional steel 10G2FBYu (GOST). Ultrasonic impact treatment of these steel was carried out an air temperature of -30 °C.

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Periodical:

Key Engineering Materials (Volume 942)

Pages:

29-34

DOI:

https://doi.org/10.4028/p-24xz15

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Online since:

March 2023

Authors:

Michael M. Sidorov, Nikolay I. Golikov, Susanna N. Makharova, Ruslan P. Tikhonov, Marina A. Ivanova*

Keywords:

Constructional Steel, Negative Air Temperature, Pipeline System, Residual Welding Stress, Ultrasonic Impact Treatment

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References

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