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agglomeration
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Image
Published: 01 August 2013
Fig. 10 Yttria-stabilized zirconia-base abradable SM 2395 with agglomeration and plasma densification/spheroidizing-processed ceramic powder showing smooth and spherical particle appearance
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Image
Published: 01 December 2008
Fig. 7 (a) AlP 3 inclusion on a machined surface. (b) Agglomeration of tiny AlP 3 particles. The phosphide reacts with atmospheric moisture to become the phosphate, which then protrudes from the machined surface. Original magnification: 1000×
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Image
Published: 01 December 1998
Fig. 19 Agglomeration of γ′ in Udimet 700 resulting from creep testing. Left, as heat treated. Right, after 91.2 h at 252.3 MPa (36.6 ksi) and 893 °C (1640 °F). 4000×
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Image
in In Situ X-Ray Imaging of Metal Additive Manufacturing Processes
> Additive Manufacturing Design and Applications
Published: 30 June 2023
Fig. 12 Binder jetting process showing agglomeration effects, represented by black circular shapes in air and on stainless steel powder bed. Reprinted from Ref 50 with permission from Springer Nature Limited under a Creative Commons Attribution 4.0 International License, http
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in Part-Scale Process Modeling for Metal Additive Manufacturing
> Additive Manufacturing Design and Applications
Published: 30 June 2023
Fig. 6 Inherent strain, layer agglomeration methods for additive manufacturing. CPU, central processing unit. Source: Ref 22
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Image
in Nondestructive Evaluation of Pressed and Sintered Powder Metallurgy Parts[1]
> Nondestructive Evaluation of Materials
Published: 01 August 2018
Fig. 3 Large void in a sintered PM part—the result of a lubricant agglomerate in the green compact that burnt out during sintering. Unetched
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Image
Published: 01 November 1995
Fig. 2 Compaction rate diagram of powder agglomerates. A, soft, binder, low density; B, hard binder, low density; C, soft binder, high density. TD, theoretical density; P, pressure
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in Metallography and Microstructures of Powder Metallurgy Alloys
> Metallography and Microstructures
Published: 01 December 2004
Fig. 11 Water-atomized iron (−80 mesh), Arrows indicate fine particles agglomerated to coarser ones during annealing. As-polished. 960×
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Image
Published: 01 December 2004
Fig. 10 Secondary electron images of a diesel soot agglomerate from a heavy-duty engine. (a) Environmental scanning electron microscopy at elevated pressures (600 Pa). Volatile components are preserved. 4000×. (b) Conventional scanning electron microscopy at high vacuum (10 −3 Pa). Volatile
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Image
Published: 15 May 2022
Fig. 8 Transmission electron micrograph of carbon black showing agglomerates held together by van der Waals forces. Source: Ref 5
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Image
Published: 01 December 2008
Fig. 21 Flow pattern of inductive and inert gas injection stirring in ladles. Left: regular flow (no particle agglomeration). Right: irregular flow (increased particle agglomeration)
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Image
Published: 30 September 2015
Fig. 2 Process of trapping an incremental volume of powder between two balls in a randomly agitated charge of balls and powder. (a) through (c) trapping and compaction of particles. (d) Agglomeration. (e) Release of agglomerate by elastic energy
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in Metallography and Microstructures of Powder Metallurgy Alloys
> Metallography and Microstructures
Published: 01 December 2004
Fig. 16 Scanning electron microscope images of water-atomized iron powders (a) Arrows indicate a fair degree of irregularity or roughness on the surface. (b) Water-atomized and annealed iron powder. Arrows indicate small fines that were agglomerated onto the larger particles. (c) Water
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Image
Published: 31 December 2017
of smooth wear track. (d) Micrograph of smooth wear track on agglomeration of wear particles. (e) Schematic image of smooth wear track composed of Al 2 O 3 grains and agglomerates of wear particles. Source: Ref 30
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Book: Powder Metallurgy
Series: ASM Handbook
Volume: 7
Publisher: ASM International
Published: 30 September 2015
DOI: 10.31399/asm.hb.v07.a0006089
EISBN: 978-1-62708-175-7
.... It discusses the changes in powder particle morphology that occur during milling of metal powders produced by various processes such as microforging, fracturing, agglomeration, and deagglomeration. The article also provides useful information on milling equipment such as tumbler ball mills, vibratory ball...
Abstract
Milling of materials, whether hard and brittle or soft and ductile, is of prime interest and of economic importance to the powder metallurgy (PM) industry. This article discusses the principles of milling, milling parameters, and the powder characteristics required for the process. It discusses the changes in powder particle morphology that occur during milling of metal powders produced by various processes such as microforging, fracturing, agglomeration, and deagglomeration. The article also provides useful information on milling equipment such as tumbler ball mills, vibratory ball mills, attrition mills, and hammer and rod mills.
Book: Thermal Spray Technology
Series: ASM Handbook
Volume: 5A
Publisher: ASM International
Published: 01 August 2013
DOI: 10.31399/asm.hb.v05a.a0005727
EISBN: 978-1-62708-171-9
..., namely, crushing, milling, attriting, and machining. The article describes two prime methods of agglomeration. One method uses a binder by way of agglutination, while the other relies on a sintering operation. The article discusses the technology and principles of the processes that relate to thermal...
Abstract
This article discusses three types of powder-feeder systems that are commonly used throughout the thermal spray (TS) industry: gravity-based devices, rotating wheel devices, and fluidized-bed systems. It provides information on the various mechanical methods for producing powders, namely, crushing, milling, attriting, and machining. The article describes two prime methods of agglomeration. One method uses a binder by way of agglutination, while the other relies on a sintering operation. The article discusses the technology and principles of the processes that relate to thermal spraying, and offers an understanding for choosing particular feedstock materials that are classified based on the thermal spray process, material morphology, chemical nature of the material, and applications. Sieving, the most common method of separating powders into their size fractions, is also reviewed. The article also provides information on the topical areas and precautions to be undertaken to protect the operator from safety hazards.
Series: ASM Handbook
Volume: 17
Publisher: ASM International
Published: 01 August 2018
DOI: 10.31399/asm.hb.v17.a0006445
EISBN: 978-1-62708-190-0
... and sintered PM parts: density variations, compaction and ejection cracks, microlaminations, poor degree of sintering, and voids from prior lubricant agglomerates. It describes the various methods applicable to green compacts: direct-current resistivity testing, radiographic techniques, computed tomography...
Abstract
The potential for introducing defects during processing becomes greater as the relative density of pressed and sintered powder metallurgy (PM) parts increases and more multilevel parts with complex geometric shapes are produced. This article discusses the potential defects in pressed and sintered PM parts: density variations, compaction and ejection cracks, microlaminations, poor degree of sintering, and voids from prior lubricant agglomerates. It describes the various methods applicable to green compacts: direct-current resistivity testing, radiographic techniques, computed tomography, and gamma-ray density determination. The article also discusses the methods for automated nondestructive testing of pressed and sintered PM parts: acoustic methods-resonance testing, eddy current testing, magnetic bridge comparator testing, ultrasonic techniques, radiographic techniques, gamma-ray density determination, and visual inspection.
Image
Published: 01 January 2003
or with each other. As chromium was leached from the surface of the metal, a concentration (activity) gradient resulted and caused chromium atoms from the underlying region to diffuse toward the surface, leaving behind a zone enriched with vacancies. These vacancies would then agglomerate at suitable sites
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Image
Published: 30 September 2015
Fig. 13 Closed-loop process of fracture ( F ), microforging ( M ), and agglomeration by welding ( A w )
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Image
Published: 30 September 2015
Fig. 9 Comparison of simulated and experimental results for sintering shrinkage and surface area loss for agglomerated tantalum flakes. Source: Ref 18
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