Ferrous Fibre Network Materials for Jet Noise Reduction in Aeroengines Part I: Acoustic Effects

Golosnoy, Igor O.; Tan, Jin‐Chong; Clyne, T.W.

doi:10.1002/adem.200700302

Cited by 25 publications

(14 citation statements)

References 25 publications

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“…They may be used as energy absorbing elements in cars [1], to absorb noise in architectural or aerospace applications [2][3][4] or for phase separation purposes [1,5], for example. A multitude of manufacturing processes have emerged in the past.…”

Section: Introductionmentioning

confidence: 99%

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Mechanical behaviour of nanoporous superalloy membranes

Rösler

Näth

2010

Acta Materialia

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Section: Introductionmentioning

confidence: 99%

“…Cellular metals are of interest for many applications because of their attractive functional properties [1][2][3][4][5]. They may be used as energy absorbing elements in cars [1], to absorb noise in architectural or aerospace applications [2][3][4] or for phase separation purposes [1,5], for example.…”

Section: Introductionmentioning

confidence: 99%

Mechanical behaviour of nanoporous superalloy membranes

Rösler

Näth

2010

Acta Materialia

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“…These materials are mainly produced by sintering of powders or fibers [3], coating of polymer sponges [4] or melt infiltration techniques [5]. Resulting pore sizes of these "conventional" porous metals are typically in a range between 10 μm and 100 μm.…”

Section: Introductionmentioning

confidence: 99%

A Concept for the Control of Pore Size in Superalloy Membranes

Rösler

Krause

Hinze

2014

Metals

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Abstract:A new method to adjust the pore size in superalloy membranes is shown, utilizing controlled cooling from solution heat treatment of the solid superalloy. Hereby, the nucleation rate and, thus, the size of the γ'-precipitates can be varied to a large extent. This leads to a corresponding variation in the pore size once the membrane material is produced by directional coarsening of the γ'-phase to an interconnected network and subsequent selective extraction of the γ-phase. Furthermore, it was found that coherent and incoherent γ'-precipitates can be used alike to fabricate superalloy membranes, and yet, result in vastly different pore morphologies. The findings widen the application range of this novel material class.

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“…In recent years, porous metal materials have been widely used in aerospace, metallurgic, mechanic, petrochemical, energy, pharmaceutical, architectural, and transportation fields [1][2][3][4][5]. Porous metal fiber sintered felts (PMFSFs), made from metal fibers, attract increasing attention, because of their three-dimensional reticulated structure, interconnected pores, high porosity, and large specific surface area [6][7][8]. These structural characteristics create potential to overcome the shortfalls of other porous materials.…”

Section: Introductionmentioning

confidence: 99%

An Innovative Fabrication Process of Porous Metal Fiber Sintered Felts with Three-Dimensional Reticulated Structure

Tang

Zhou

Xiang

et al. 2010

Materials and Manufacturing Processes

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A novel porous metal fiber sintered felt (PMFSF) with a three-dimensional reticulated structure has been produced by the solid-state sintering of copper fibers. The copper fibers, with several microstructures distributed onto the surface, were fabricated using the cutting method. The Scanning Electron Microscope (SEM) results revealed that there were two kinds of sintering joints present in the PMFSFs: fiber-to-fiber surface contact and crossing fiber meshing. In the sintering process, the surface microstructures of the fibers helped to improve the forming process of the PMFSFs, as a result of high surface energy. Furthermore, the effect of different sintering parameters on the forming process of the PMFSFs was studied in detail, including the sintering temperature and holding time. The sintering temperatures had a significant influence on the surface microstructures of single fiber and specific surface area of the PMFSFs, but the holding time did not. The optimal PMFSF with a three-dimensional reticulated structure and larger specific surface area was produced by sintering copper fibers at 800 C for 30 minutes in the reduction atmosphere.Keywords Copper fiber; Metal fiber sintered felt; Porous metal; Sintering. IntroductionPorous metal material, an interesting engineering material with excellent performances, is being explored due to its porous structure and unique properties. In recent years, porous metal materials have been widely used in aerospace, metallurgic, mechanic, petrochemical, energy, pharmaceutical, architectural, and transportation fields [1][2][3][4][5]. Porous metal fiber sintered felts (PMFSFs), made from metal fibers, attract increasing attention, because of their three-dimensional reticulated structure, interconnected pores, high porosity, and large specific surface area [6][7][8]. These structural characteristics create potential to overcome the shortfalls of other porous materials. For example, porous organic polymer materials have low intensity and cannot withstand high temperature; porous ceramics have poor brittleness and bad thermal shock resistance; metal wire mesh are easily destroyed and plugged; sintered powder materials are fragile, and often fail to allow a sufficient amount of liquid to pass through. Therefore, the research related to the new type of PMFSF helps to enrich the entire system of porous metal materials. As part of a new generation of high-performance structural and functional materials, the PMFSFs have been widely used in many fields, including catalyst supports [9][10][11]

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Ferrous Fibre Network Materials for Jet Noise Reduction in Aeroengines Part I: Acoustic Effects

Cited by 25 publications

References 25 publications

Mechanical behaviour of nanoporous superalloy membranes

Mechanical behaviour of nanoporous superalloy membranes

A Concept for the Control of Pore Size in Superalloy Membranes

An Innovative Fabrication Process of Porous Metal Fiber Sintered Felts with Three-Dimensional Reticulated Structure

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