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titanium powder
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Image
Published: 30 April 2020
Fig. 2.16 Sponge titanium powder formed by using a reaction between titanium tetrachloride and molten sodium, with subsequent removal of the NaCl via water immersion
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Image
in Cold Spray Applications in the Defense Industry
> High Pressure Cold Spray: Principles and Applications
Published: 01 June 2016
Fig. 9.27 Hydraulic tubing with commercially pure titanium powder deposited to prevent chafing. (a) Tube in the as-sprayed condition. (b) Same area after a surface finish. Courtesy of South Dakota School of Mines and Technology
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Image
Published: 30 April 2020
Fig. 2.2 Large, spherical titanium powder fabricated by plasma atomization, giving a spherical particle shape
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Image
Published: 30 April 2020
Fig. 2.3 Sponge nanoscale titanium powder fabricated by hydrogen reduction of titanium tetrachloride in a plasma reactor
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Image
Published: 30 April 2020
Fig. 8.3 Sintered density versus hold time for 42 μm titanium powder vacuum sintered at three temperatures. Faster rates of densification (steeper slopes) are associated with shorter times and higher temperatures.
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Image
in History and Extractive Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 1.1 Reaction vessel for making titanium powder using the Kroll process. The equipment was capable of producing 7 kg (15 lb) batches.
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Image
in History and Extractive Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 1.16 The Armstrong/International Titanium Powder process. The TiCl 4 is directly injected in a vapor form, resulting in the reduction of TiCl 4 to commercially pure titanium. Courtesy of K. Akhtar, Armstrong/Crystal, Sept 2013
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Image
in History and Extractive Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 1.17 Schematic of how the Armstrong/International Titanium Powder process can simplify the fabrication of titanium shapes. The Armstrong process results in commercially pure (CP) titanium, which can be combined or directly used in powder metallurgy processes to produce a final product
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Image
in Melting, Casting, and Powder Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Image
in Powder Production Techniques for High-Pressure Cold Spray
> High Pressure Cold Spray: Principles and Applications
Published: 01 June 2016
Fig. 6.7 (a) Example of mechanically alloyed powder. (b) Microstructure of titanium nanocomposite coating. Courtesy of MBN Nanomaterialia S.p.A.
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Image
Published: 01 December 2000
Fig. 7.6 Typical tensile properties of blended elemental titanium alloy powder compacts. Shaded areas represent observed ranges.
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Image
in History and Extractive Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 1.20 Titanium metal powder suitable for use in near-net shape manufacturing, which produces components that are close to the finished size and shape. Courtesy of J. Barnes, CSIRO, Oct 2013
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 January 2015
DOI: 10.31399/asm.tb.tpmpa.t54480161
EISBN: 978-1-62708-318-8
... toughness investment casting melting microstructure powder metallurgy titanium alloys titanium powder tensile properties vacuum arc remelting THIS CHAPTER DISCUSSES techniques for melting and casting of titanium and its alloys and describes applications of powder metallurgy (PM...
Abstract
Casting is the most economical processing route for producing titanium parts, and unlike most metals, the properties of cast titanium are on par with those of wrought. This chapter covers titanium melting and casting practices -- including vacuum arc remelting, consumable electrode arc melting, electron beam hearth melting, rammed graphite mold casting, sand casting, investment casting, hot isostatic pressing, weld repair, and heat treatment -- along with related equipment, process challenges, and achievable properties and microstructures. It also explains how titanium parts are produced from powders and how the different methods compare with each other and with conventional production techniques. The methods covered include powder injection molding, spray forming, additive manufacturing, blended elemental processing, and rapid solidification.
Image
in Melting, Casting, and Powder Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 8.39 Schematic of plasma rotating electrode process for producing prealloyed titanium powder
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 2000
DOI: 10.31399/asm.tb.ttg2.t61120047
EISBN: 978-1-62708-269-3
... Abstract This chapter discusses the advantages and disadvantages of producing titanium parts using powder metallurgy (PM) techniques. It compares the typical properties of wrought, cast, and PM titanium alloy products, addresses various manufacturing challenges, and describes several...
Abstract
This chapter discusses the advantages and disadvantages of producing titanium parts using powder metallurgy (PM) techniques. It compares the typical properties of wrought, cast, and PM titanium alloy products, addresses various manufacturing challenges, and describes several consolidation and shaping processes along with associated property data.
Image
in Melting, Casting, and Powder Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 8.35 Pilot-scale unit at ADMA Products for manufacturing hydrogenated titanium powder. Annual capacity is 113,400 kg (250,000 lb). Courtesy of ADMA Products Inc.
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Image
in Melting, Casting, and Powder Metallurgy[1]
> Titanium<subtitle>Physical Metallurgy, Processing, and Applications</subtitle>
Published: 01 January 2015
Fig. 8.59 Effect of oxygen content on the strength and ductility of sintered commercially pure titanium powder. UTS, ultimate tensile strength; E, elongation. Courtesy of Daido Steel Co.
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Image
Published: 30 April 2020
Fig. 5.22 The role of particle shape on mixture rheology is evident by using three titanium powders (spherical, rounded, and irregular) in a paraffin wax binder. Torque rheometry identifies significant differences in solids loading for the target 1 N ∙ m mixing torque.
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Image
Published: 01 June 2016
Fig. 3.25 Window of deposition illustrated on the plane of particle velocity and particle temperature for titanium powder sprayed with nitrogen and nozzle type D24 at 4 MPa (580 psi). The data points show impact conditions corresponding to particles of different sizes: (A) 10, (B) 25, and (C
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 2000
DOI: 10.31399/asm.tb.ttg2.t61120131
EISBN: 978-1-62708-269-3
.... Realistically speaking, however, materials such as titanium aluminides and titanium matrix composites or technologies such as powder metallurgy have been, and will continue to be, spurred by military requirements. The preceding discussion pertains to advanced alloy and process development. It should...
Abstract
This chapter discusses some of the promising developments in the use of titanium, including titanium aluminides, titanium matrix composites, superplastic forming, spray forming, nanotechnology, and rapid solidification rate processing. It also reports on efforts to increase the operating temperature range of conventional titanium alloys and reduce costs.
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