Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing

The Alumix 13 (wt.%) (Al-4.5 Cu 0.5 Mg 0.2 Si) powder with and without 5 wt.% Saffil short fibers specimens were hot pressed in the range 580-620. °C. The densification during pressure increase was fitted using the Konopicky model and an agreement with the associated linear plot P vs. ln(1/(1 - D) w...

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Autores principales: Moreno, M.F., González Oliver, C.J.R.
Formato: JOUR
Materias:
Ceramic short fibers
Hot pressing
Liquid phase sintering
Metal matrix composites
Power Law Creep
Super plastic deformation
Hot pressing pressure
Hot-pressed composites
Newtonian viscous flow
Power law creep
Power-law creep model
Short Fiber
Transient liquid phase
Aluminum
Creep
Densification
Fibers
Metallic matrix composites
Porous materials
Reinforced plastics
Liquids
aluminum
aluminum derivative
copper
saffil
silicon
unclassified drug
article
chemical parameters
composite material
controlled study
deformation
density
flow
Konopicky model
liquid phase densification
mathematical model
physical parameters
powder
Power Law Creep model
pressure
solid
stress strain relationship
temperature
viscosity
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_00325910_v245_n_p13_Moreno
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
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spelling todo:paper_00325910_v245_n_p13_Moreno2023-10-03T14:45:17Z Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing Moreno, M.F. González Oliver, C.J.R. Ceramic short fibers Hot pressing Liquid phase sintering Metal matrix composites Power Law Creep Super plastic deformation Hot pressing pressure Hot-pressed composites Metal matrix composites Newtonian viscous flow Power law creep Power-law creep model Short Fiber Transient liquid phase Aluminum Creep Densification Fibers Hot pressing Liquid phase sintering Metallic matrix composites Porous materials Reinforced plastics Liquids aluminum aluminum derivative copper saffil silicon unclassified drug article chemical parameters composite material controlled study deformation density flow Konopicky model liquid phase densification mathematical model physical parameters powder Power Law Creep model pressure solid stress strain relationship temperature viscosity The Alumix 13 (wt.%) (Al-4.5 Cu 0.5 Mg 0.2 Si) powder with and without 5 wt.% Saffil short fibers specimens were hot pressed in the range 580-620. °C. The densification during pressure increase was fitted using the Konopicky model and an agreement with the associated linear plot P vs. ln(1/(1 - D) was found for both materials, where P is applied pressure and D is the relative density of the porous material.The transient liquid phase formed from the elemental Al and Cu powder particles above the eutectic temperature of 548. °C at low hot pressing pressures, allows to increase the densification due to the reduction in the yield stress of the porous material. The active liquid flow enhanced the deformation between Al particles in the beginning of the pressure ramp.For higher pressures, a sudden break to a higher slope in Konopicky plot was found. This hardening behavior was detected from 610 °C for pure Alumix 13 and it was systematically developed at 580, 600, 610 and 620 °C for the composites, and it can be assigned to diffusion of Cu into the Al grains.During the constant pressure stage the densification was well fitted using the Power Law Creep model with exponents of n = 1 and n = 2, which are related to Newtonian viscous flow and superplastic deformation, respectively. Besides, final hot pressed composites samples retained an important quantity of solidified liquid phase located in between the Saffil fibers agglomerates. © 2013 Elsevier B.V. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00325910_v245_n_p13_Moreno
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Ceramic short fibers
Hot pressing
Liquid phase sintering
Metal matrix composites
Power Law Creep
Super plastic deformation
Hot pressing pressure
Hot-pressed composites
Metal matrix composites
Newtonian viscous flow
Power law creep
Power-law creep model
Short Fiber
Transient liquid phase
Aluminum
Creep
Densification
Fibers
Hot pressing
Liquid phase sintering
Metallic matrix composites
Porous materials
Reinforced plastics
Liquids
aluminum
aluminum derivative
copper
saffil
silicon
unclassified drug
article
chemical parameters
composite material
controlled study
deformation
density
flow
Konopicky model
liquid phase densification
mathematical model
physical parameters
powder
Power Law Creep model
pressure
solid
stress strain relationship
temperature
viscosity
spellingShingle Ceramic short fibers
Hot pressing
Liquid phase sintering
Metal matrix composites
Power Law Creep
Super plastic deformation
Hot pressing pressure
Hot-pressed composites
Metal matrix composites
Newtonian viscous flow
Power law creep
Power-law creep model
Short Fiber
Transient liquid phase
Aluminum
Creep
Densification
Fibers
Hot pressing
Liquid phase sintering
Metallic matrix composites
Porous materials
Reinforced plastics
Liquids
aluminum
aluminum derivative
copper
saffil
silicon
unclassified drug
article
chemical parameters
composite material
controlled study
deformation
density
flow
Konopicky model
liquid phase densification
mathematical model
physical parameters
powder
Power Law Creep model
pressure
solid
stress strain relationship
temperature
viscosity
Moreno, M.F.
González Oliver, C.J.R.
Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
topic_facet Ceramic short fibers
Hot pressing
Liquid phase sintering
Metal matrix composites
Power Law Creep
Super plastic deformation
Hot pressing pressure
Hot-pressed composites
Metal matrix composites
Newtonian viscous flow
Power law creep
Power-law creep model
Short Fiber
Transient liquid phase
Aluminum
Creep
Densification
Fibers
Hot pressing
Liquid phase sintering
Metallic matrix composites
Porous materials
Reinforced plastics
Liquids
aluminum
aluminum derivative
copper
saffil
silicon
unclassified drug
article
chemical parameters
composite material
controlled study
deformation
density
flow
Konopicky model
liquid phase densification
mathematical model
physical parameters
powder
Power Law Creep model
pressure
solid
stress strain relationship
temperature
viscosity
description The Alumix 13 (wt.%) (Al-4.5 Cu 0.5 Mg 0.2 Si) powder with and without 5 wt.% Saffil short fibers specimens were hot pressed in the range 580-620. °C. The densification during pressure increase was fitted using the Konopicky model and an agreement with the associated linear plot P vs. ln(1/(1 - D) was found for both materials, where P is applied pressure and D is the relative density of the porous material.The transient liquid phase formed from the elemental Al and Cu powder particles above the eutectic temperature of 548. °C at low hot pressing pressures, allows to increase the densification due to the reduction in the yield stress of the porous material. The active liquid flow enhanced the deformation between Al particles in the beginning of the pressure ramp.For higher pressures, a sudden break to a higher slope in Konopicky plot was found. This hardening behavior was detected from 610 °C for pure Alumix 13 and it was systematically developed at 580, 600, 610 and 620 °C for the composites, and it can be assigned to diffusion of Cu into the Al grains.During the constant pressure stage the densification was well fitted using the Power Law Creep model with exponents of n = 1 and n = 2, which are related to Newtonian viscous flow and superplastic deformation, respectively. Besides, final hot pressed composites samples retained an important quantity of solidified liquid phase located in between the Saffil fibers agglomerates. © 2013 Elsevier B.V.
format JOUR
author Moreno, M.F.
González Oliver, C.J.R.
author_facet Moreno, M.F.
González Oliver, C.J.R.
author_sort Moreno, M.F.
title Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
title_short Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
title_full Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
title_fullStr Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
title_full_unstemmed Liquid phase densification of Al-4.5wt.% Cu powder reinforced with 5wt.% Saffil short fibers during hot pressing
title_sort liquid phase densification of al-4.5wt.% cu powder reinforced with 5wt.% saffil short fibers during hot pressing
url http://hdl.handle.net/20.500.12110/paper_00325910_v245_n_p13_Moreno
work_keys_str_mv AT morenomf liquidphasedensificationofal45wtcupowderreinforcedwith5wtsaffilshortfibersduringhotpressing
AT gonzalezolivercjr liquidphasedensificationofal45wtcupowderreinforcedwith5wtsaffilshortfibersduringhotpressing
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