Thermo-mechanical Analysis of LENS [Trademark] Deposited Bimetallic (Steel-Copper) Parts

Talukdar, Tushar K

11 August 2012

A thermo-mechanical finite element model is developed to determine the temperature history and residual stresses in a Cu-H13 thin-walled plate deposited by the Laser Engineered Net Shaping (LENSTM) process. The same model is also applied to a H13-H13 sample to compare the results. The input laser power is adjusted to maintain a steady molten pool size and depth. For a constant scanning speed the laser power decreases with the addition of more layers, and with the increase of scanning speed the laser power needs to be increased. The Z-component of residual stresses is greater than the other components, and is compressive near the center of the wall and tensile at the free edges. The residual stress levels near the free edges are higher in the H13-H13 sample than in the Cu-H13 sample. In these regions, the use of unidirectional scanning results in a higher stress accumulation than the alternating scanning.

modeling

Cu-H13

residual stress

LENS

H13 tool steel

bimetallic parts

Design and LENS® Fabrication of Bi-metallic Cu-H13 Tooling for Die Casting

Jain, Akshay Ashok

January 2013

No description available.

Engineering

Industrial Engineering

Mechanical Engineering

Metallurgy

Die Casting

Bi-metallic tooling

Copper

H13

Die Casting Tooling

Ansys

Finite Element Analysis

FEA

Thermal Fatigue Die Casting

Laser Engineered Net Shaping

Laser Additive Manufacturing

Copper-H13

H13-Copper

Cu-H13

H13-Cu

Dunk Test