Effect of Laser Traverse Speed during Laser Hardening on Hardness Distribution and Microstructure of Hot Work Tool Steel H11

Effect of Laser Traverse Speed during Laser Hardening on Hardness Distribution and Microstructure of Hot Work Tool Steel H11

The paper describes the effect of laser traverse speed during laser hardening on hardness and microstructure. The experimental material is hot work tool steel AISI H11 with samples sized 100×100×35 mm. The initial state of the material before laser hardening is quenched and tempered. The laser harde...

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Bibliographic Details
Main Authors: Hodek, J. (Author), Hradil, D. (Author), Koukolíková, M. (Author), Nový, Z. (Author), Szyszko, A. (Author)
Format: Article
Language:English
Published: Jan-Evangelista-Purkyne-University 2023
Subjects:
Carbides
Computer software
EDS analysis
Energy dispersive spectroscopy
Energy dispersive spectroscopy analyse
Experimental materials
Hardened depth
Hardening
Hardness
Hardness distribution
Hardness drops
Heat affected zone
Heat-affected zones
Hot working
Hot-work tool steel
Initial state
Laser hardening
Microstructure
Numerical model
Numerical models
Scanning electron microscopy
Tool steel
Traverse speed
Online Access:View Fulltext in Publisher
Description
Summary:The paper describes the effect of laser traverse speed during laser hardening on hardness and microstructure. The experimental material is hot work tool steel AISI H11 with samples sized 100×100×35 mm. The initial state of the material before laser hardening is quenched and tempered. The laser hardening temperature is constant at 1100 °C, selected laser traverse speed was 1, 2, 4, and 6 mm/s. A numerical simulation performed in DEFORM-3D software before the experiment showed tendencies of temperature displacement and expected course of hardness. Increasing traverse speed leads to decreased laser-hardened depth and decreased hardness drop in the heat-affected zone (HAZ). The experimental program confirmed the results of the numerical model. The differences in the microstructure were investigated by light (LM) and scanning electron microscopes (SEM), which revealed an evident difference between the surface area and the locality with the lowest hardness. Local differences from the perspective of presence of carbides were analysed by energy dispersive spectroscopy (EDS). This investigation was performed to optimize laser traverse speed to improve the subsurface hardness profile, which is essential for the lifetime and reliability of forging dies. © 2023 Manufacturing Technology. All rights reserved.
Physical Description:8
ISBN:12132489 (ISSN)
ISSN:12132489 (ISSN)
DOI:10.21062/mft.2023.021

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