Relationship between Porosity and Interface Fracture on Aluminum Foam Sandwich with Dense Steel Face Sheets Fabricated by Friction Stir Processing Route

Utsunomiya, Takao; Ishii, Nobuyuki; Hangai, Yoshihiko; Koyama, Satoshi; Kuwazuru, Osamu; Yoshikawa, Nobuhiro

doi:10.2320/matertrans.maw201212

Cited by 12 publications

(3 citation statements)

References 16 publications

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“…(この方法を摩擦攪拌法と呼ぶ) 11,12) を提案した．この方法では，アルミニウム板中への添加剤粉末の攪拌・混合により作製するプリカーサと，表面材となる緻密板材の接合を同時に行うことが可能である 13,14) ．そこで，この利点を活用して，緻密鋼板とアルミニウムフォームのコアを接合したサンドイッチパネルの作製へ展開を図ってきた 15,16) ．しかしながら，構造体のより軽量化には，表面材はアルミニウム板材とするり 2400 番まで研磨後，粒径 1.0 mm のアルミナ粉末 ( a …”

Section: 緒言unclassified

Fabrication and Tensile Property of Sandwich Panel with ADC12 Foam Core by Friction Stir Processing Route

Utsunomiya¹,

Ishii²,

Hangai³

et al. 2013

J. Japan Inst. Metals and Materials

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An aluminum foam sandwich, which consists of an aluminum foam core and two dense metallic face sheets, is a lightweight structural component with good energy and vibration absorption properties. In this study, using aluminum alloy die casting ADC12 plates containing large amount of gases, sandwich panels with metallurgical bonding between ADC12 aluminum foam core and dense aluminum sheets, of which the thickness was 3 mm and 1 mm, were fabricated by friction stir processing route. Through the observations of the dense sheets and the pore structure of aluminum foam core, the foaming condition for obtaining high porosity and good pore structure, and keeping a dense aluminum plate as surface plate simultaneously was discussed. Moreover, tensile tests were carried out on the fabricated aluminum foam sandwiches and it was shown that the bonding strength of interface is higher than the tensile strength of aluminum foam core.

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Section: 緒言unclassified

Fabrication and Tensile Property of Sandwich Panel with ADC12 Foam Core by Friction Stir Processing Route

Utsunomiya¹,

Ishii²,

Hangai³

et al. 2013

J. Japan Inst. Metals and Materials

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“…26 The further publications on this subject have explained the process in detail and its pros and cons. [27][28][29][30][31][32][33][34][35][36] The various mechanical and structural characterizations of the metal foam produced through the FSP route, using advanced techniques such as X-Ray Computed tomography (XRCT), have been reported in a few publications. 26,29,34,[37][38][39] Images of solid aluminum foam obtained through various techniques are shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

A review of the compressive properties of closed-cell aluminum metal foams

Nisa

Pandey

2022

Proceedings of the Institution of Mechanical Engineers, Part E:

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Materials scientists and engineers have been trying to create porous metals and metal foams for many years. Naturally occurring porous materials such as bone, coral, cork, balsa wood, etc., are responsible for initiating research in the area of producing porous metals and metal foams. Metal foam is a cellular structure made up of a solid metal-containing a large volume fraction of gas-filled pores. These pores can either be sealed (closed-cell foam), or they can be an interconnected network (open-cell foam). The closed-cell foam is referred to as metal foams, while the open-cell foam is referred to simply as porous metal. Some of the key properties of the metal foam are, ultra-light material (75–95% of the volume consists of void spaces), very high porosity, and high compression strengths combined with good energy absorption characteristics. This paper provides a comprehensive review of mechanical characterizations of closed-cell aluminum metal foams (CCAFs) or porous aluminum alloys, the trends in their mechanical behavior specifically their compressive performance. The significant factors influencing this behavior are intricately studied in light of the available literature. The aim of this work is to facilitate a channelized development over the past few decades in the field of mechanical behavior of CCAF that may be of help to the researchers, academicians, and industries for the critical understanding of the failure criteria and mechanical properties of closed-cell aluminum metal foams.

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“…912) In this method, both the production of a foamable precursor by mixing blowing agent powder into Al sheets and metallurgical bonding between the foamable precursor and dense metallic face sheets can be conducted simultaneously; thus, high productivity of the foamable precursor can be realized. Moreover, using this fabrication method, we succeeded in fabricating an AFS comprising an A1050 Al foam core and SPCC low-carbon steel face sheets 9,10) and an AFS comprising an ADC12 Al alloy foam core and dense Al face sheets. 11,12) In the fabrication of the AFS, a foaming process, in which two foamable precursors with one face sheet placed face to face in a die are heated and the Al foam core is formed by bonding two foaming precursors, has been used.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Aluminum Foam Core Sandwich Using Sandwich-Type Foamable Precursor with Two Face Sheets by Friction Stir Welding Route

2018

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An aluminum foam sandwich (AFS), which consists of an aluminum (Al) foam core and two dense metallic face sheets, is a lightweight component material with good energy and sound insulation properties. A fabrication method for AFSs that can simultaneously fabricate a foamable precursor and realize metallurgical bonding between the precursor and a dense metallic sheet was proposed using the friction stir welding (FSW) route. In this study, we produced a sandwich-type foamable precursor with two Al face sheets using the FSW route and, by foaming this precursor, an AFS was fabricated. Through X-ray computed tomography inspection of the AFS and observation by an electron probe microanalyzer, it was confirmed that no cracklike pores existed in the Al foam core and that only few pores generated by the foaming entered the Al face sheet. Moreover, static tensile tests of the AFS were carried out, and it was shown that the tensile strength of the Al foam core was not decreased by the existence of an oxide film and that the bonding strength of the interface between the Al foam core and the Al face sheet was higher than the tensile strength of the Al foam core.

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Relationship between Porosity and Interface Fracture on Aluminum Foam Sandwich with Dense Steel Face Sheets Fabricated by Friction Stir Processing Route

Cited by 12 publications

References 16 publications

Fabrication and Tensile Property of Sandwich Panel with ADC12 Foam Core by Friction Stir Processing Route

Fabrication and Tensile Property of Sandwich Panel with ADC12 Foam Core by Friction Stir Processing Route

A review of the compressive properties of closed-cell aluminum metal foams

Fabrication of Aluminum Foam Core Sandwich Using Sandwich-Type Foamable Precursor with Two Face Sheets by Friction Stir Welding Route

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