Numerical and experimental study on the effects of welding environment and input heat on properties of FSSWed TRIP steel

Numerical and experimental study on the effects of welding environment and input heat on properties of FSSWed TRIP steel

In this paper, the effect of input heat and welding environment on microstructure and mechanical properties of friction stir spot welded TRIP steel sheets were investigated. Six types of joints produced in both air and water environments and under rotational speeds of 900, 1350, and 1800 rpm. Then,...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology Vol. 90; no. 1-4; pp. 1131 - 1143
Main Authors: Mostafapour, Amir, Ebrahimpour, Ali, Saeid, Tohid
Format: Journal Article
Language:English
Published: London Springer London 01-04-2017
Springer Nature B.V
Subjects:
CAE) and Design
Computer-Aided Engineering (CAD
Cooling rate
Dimpling
Ductile fracture
Elongation
Engineering
Finite element method
Fracture surfaces
Friction stir welding
Grains
Heat affected zone
Heat treating
Industrial and Production Engineering
Low temperature
Mechanical Engineering
Mechanical properties
Media Management
Metal sheets
Microstructure
Original Article
Recrystallization
Strain distribution
Strain rate
TRIP steels
Underwater
Welded joints
TRIP steel
Finite element modeling
Friction stir spot welding
Underwater welding
Input heat
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Summary:In this paper, the effect of input heat and welding environment on microstructure and mechanical properties of friction stir spot welded TRIP steel sheets were investigated. Six types of joints produced in both air and water environments and under rotational speeds of 900, 1350, and 1800 rpm. Then, the microstructure and mechanical properties of them were studied. The thermal histories, strain, and strain rate distributions of cases obtained by finite element modeling. According to the temperature and strain distribution and microstructural observations, four different zones determined in welding region: stir zone, thermomechanically affected zone, and high and low temperature heat-affected zones. It is obtained at in-air welds by increasing the rotational speed, the strength of joints increase to a maximum value because of higher strain rate and more recrystallization of prior austenite grains. The strength then decreases due to high amount of heat input and growth of recrystallized grains. Thermal history of underwater welds showed lower peak temperature and rapid cooling rate. Also, by increasing rotational speed in underwater joints, the strength and hardness increased because of microstructure refinement. The fracture surfaces of joints showed a dimple pattern ductile fracture in all cases except 1800 rpm in-air joint that the fracture was less ductile which agrees with lower tensile elongation of it.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-016-9430-6