Diffusion bonding of steels with a homogeneous microstructure throughout the joint

Diffusion bonding of steels with a homogeneous microstructure throughout the joint

Cold-finished carbon steel bars were bonded by means of the transient liquid phase bonding (TLPB) process using amorphous metallic foils of the eutectic Fe-B composition as filler material. A homogeneous microstructure throughout the joint was obtained. Traces of borides in the middle of the joint w...

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Bibliographic Details
Published in:Journal of materials science Vol. 59; no. 43; pp. 20400 - 20417
Main Authors: Di Luozzo, Nicolás, Schulz, Michael, Boudard, Michel, Limandri, Silvina, Garbarino, Gastón, Fontana, Marcelo
Format: Journal Article
Language:English
Published: New York Springer US 01-11-2024
Springer Nature B.V
Springer Verlag
Subjects:
Amorphous materials
Base metal
Bonded joints
Bonding strength
Borides
Carbon steels
Characterization and Evaluation of Materials
Chemical Sciences
Chemistry and Materials Science
Classical Mechanics
Crystallography and Scattering Methods
Engineering Sciences
Eutectic composition
Fracture surfaces
Grain growth
Iron
Liquid phases
Materials Science
Metals & Corrosion
Microstructure
Neutron radiography
Polymer Sciences
Recrystallization
Room temperature
Solid Mechanics
Tension tests
Transient liquid phase bonding
Ultimate tensile strength
Neutron radiography
Metallic glasses
Transient liquid phase bonding
Steels
Synchrotron microfocused X-ray diffraction
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Summary:Cold-finished carbon steel bars were bonded by means of the transient liquid phase bonding (TLPB) process using amorphous metallic foils of the eutectic Fe-B composition as filler material. A homogeneous microstructure throughout the joint was obtained. Traces of borides in the middle of the joint were the only distinguishable microconstituent from the base metal due to the TLPB process. The B concentration profile across the joint was measured by neutron radiography and was found to be composed of a central sharp peak with a maximum concentration of 15.9 ppm B superimposed over a broad peak (base width of ≈ 5 mm) with a maximum concentration of 13.3 ppm B. Owing to this low range of B concentrations, boride precipitation was almost suppressed, and only a scarce number of borides were observed at the joint. The resulting boride structure was identified as Fe 23 B 6 by synchrotron microfocused X-ray diffraction, and its stabilization at room temperature is discussed. The bonded samples were subjected to a bend test, with a bending angle of 180°, and no cracks were observed. In tension tests, the bonded samples attained an ultimate tensile strength (UTS) of 434 MPa, an elongation of 32.3% and a reduction area q of 51.2%—78.6%, 165.6% and 75.4%, respectively, of the base metal. The fracture of the bonded samples occurred at the joint. It was determined that the decrease in UTS compared with that of the base metal was due to the recovery, recrystallization and grain growth that occurred during the TLPB thermal cycle. In addition, from fracture surface observation, it was found that the decrease in q in bonded samples was caused by the presence of traces of borides at the joint, which were the result of the liquid phase that solidified during the cooling stage. Graphical abstract
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-024-10343-x