Review: liquid phase sintering

German, Randall M.; Suri, Pavan; Park, Seong Jin

doi:10.1007/s10853-008-3008-0

Cited by 1,098 publications

(644 citation statements)

References 192 publications

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“…However, when sintered at 560 • C, the density was significantly decreased for all compaction pressures, attributed to the expansion of volume. At this temperature, Al-Zn and Cu elements form small amount of liquid phase with Al, and the diffusion from the liquid to solid phase expands interparticle distance forming unfilled skeleton of the powder body, resulting in the increase of volume [14][15][16][17]. When sintered at 615 • C, in which LPS actively occurs in addition to solid state sintering, the density increases compared to that achieved at 560 • C because of the volume shrinkage by dissolution of solid into the liquid phase.…”

Section: Resultsmentioning

confidence: 99%

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

Lee

Ahn

2015

Archives of Metallurgy and Materials

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The liquid phase sintering characteristics of Al-Cu-Zn alloy were investigated with respect to various powder metallurgy processing conditions. Powders of each alloying elements were blended to form Al-6Cu-5Zn composition and compacted with pressures of 200, 400, and 600 MPa. The sintering process was performed at various temperatures of 410, 560, and 615 • C in N 2 gas atmosphere. Density and micro-Vickers hardness measurements were conducted at different processing stages, and transverse rupture strength of sintered materials was examined for each condition, respectively. The microstructure was characterized using optical microscope and scanning electron microscopy. The effect of Zn addition on the liquid phase sintering behavior during P/M process of the Al-Cu-Zn alloy was also discussed in detail.

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Section: Resultsmentioning

confidence: 99%

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

Lee

Ahn

2015

Archives of Metallurgy and Materials

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“…Previous investigations [12 17] show that sintering contributes to the formation of secondary porosity during transient liquid phase sintering (LPS) the swelling presented seems to be related to the amount of liquid generated (the deeper information about the LPS phenomenon is presented in review [18] and concerning aluminium PM alloys in [19,20]). The mix of primary, secondary and residual porosity is revealed by the mean values of pores size decreasing with increasing pressing pressure.…”

Section: Resultsmentioning

confidence: 99%

The Porosity Evaluation during ECAP in Aluminium PM Alloy

et al. 2012

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The main aim of this paper is to show porosity evolution during application of various processing conditions including pressing, sintering and equal channel angular pressure. An aluminium based powder (Al Mg Si Cu Fe) was used as investigated material. After applying di erent pressing pressures (400 and 600 MPa), specimens were dewaxed in a ventilated furnace at 400 • C for 60 min. Sintering was carried out in a vacuum furnace at 610 • C for 30 min. The specimens were processed by single equal channel angular pressure pass. A signi cant disadvantage of powder metallurgy processing methods is the presence of porosity. Pores act as crack initiators and, due to their presence, the distribution of stress is inhomogeneous across the cross-section and leads to reduction of the e ective load bearing area. The equal channel angular pressure process, causing stress distribution in deformed specimens, made the powder particles to squeeze together to such an extent that the initially interconnected pores transform to small isolated pores. The proposed safety diagram includes the combined e ect of stress and strain behaviour during equal channel angular pressure. The safety line eliminates and quanti es the e ect of large pores as a potential fracture initiation sites with respect to the mechanical viewpoint.

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“…Generally there was no solubility between the liquid and solid, so the densification occurred at the rate associated with sintering the solid skeleton and the liquid is simply a pore filling agent [39,40].The amount of the liquid phase had a significant impact on the sintering trajectory. It seemed that liquid phase infiltrate into space between ceramic agglomerate, the more liquid amount was required to obtain the enhanced sinterability of composite materials [38].…”

Section: Liquid Phases Formationmentioning

confidence: 99%

“…So there was no longer persistence of liquid phase during sintering. To achieve persistent liquid phase sintering, the solid and liquid contents should converge to constant values while the pores was annihilated, giving densification [39].…”

Section: Liquid Phases Formationmentioning

confidence: 99%

Advance on Al₂O₃Particulates Reinforced Aluminum Metal Matrix Composites (Al-MMCs) Manufactured by the Power Metallurgy(PM) Methods- Improved PM Techniques

Zhang

Yue

et al. 2016

MATEC Web Conf.

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Abstract. Aluminum metal matrix composites (Al-MMCs) with Al 2 O 3 particulates as reinforcement fabricated by the power metallurgy (PM) methods have gained much attention due to their unique characteristics of the wide range of Al 2 O 3 particles addition, easy-operating process and effectiveness. The improved PM techniques, such as the high energy ball milling, powder extruder and high pressure torsion were applied to further strengthening the properties or/and diminishing the agglomeration of strength particles. The formation of liquid phase assisted densi¿cation of compacts to promote the sintering of composites. Complex design of Al 2 O 3 particles with other particles was another efficient method to tailor the properties of Al-MMCs.

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Review: liquid phase sintering

Cited by 1,098 publications

References 192 publications

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

The Porosity Evaluation during ECAP in Aluminium PM Alloy

Advance on Al₂O₃Particulates Reinforced Aluminum Metal Matrix Composites (Al-MMCs) Manufactured by the Power Metallurgy(PM) Methods- Improved PM Techniques

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Review: liquid phase sintering

Cited by 1,098 publications

References 192 publications

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

Effect Of Compaction Pressure And Sintering Temperature On The Liquid Phase Sintering Behavior Of Al-Cu-Zn Alloy

The Porosity Evaluation during ECAP in Aluminium PM Alloy

Advance on Al2O3Particulates Reinforced Aluminum Metal Matrix Composites (Al-MMCs) Manufactured by the Power Metallurgy(PM) Methods- Improved PM Techniques

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Product

Resources

About

Advance on Al₂O₃Particulates Reinforced Aluminum Metal Matrix Composites (Al-MMCs) Manufactured by the Power Metallurgy(PM) Methods- Improved PM Techniques