Sub-Solidus HIP Process for P/M Superalloy Conventional Billet Conversion

Pierron, X.; Banik, A.; Maurer, G. E.; Lemsky, J.; Furrer, David; Jain, Sudheer

doi:10.7449/2000/superalloys_2000_425_433

Cited by 12 publications

(7 citation statements)

References 7 publications

(7 reference statements)

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“…-HIP B material is not subjected to a sub-solidus heat treatment like in [5] and therefore the grain growth is possible while maintaining a fine gamma prime microstructure, and the risk of incipient melting is eliminated.…”

Section: Methodsmentioning

confidence: 99%

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Process Development and Mechanical Properties of Alloy U720LI for High Temperature Turbine Disks

Couturier¹,

Burlet²,

Terzi³

et al. 2004

Superalloys 2004 (Tenth International Symposium)

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Recent interest in nuclear high temperature reactor combined with a closed-cycle helium gas turbine provides the need for developing creep-resistant superalloys for the turbine disks and blades. Superalloy Udimet 720LI TM has been selected as a candidate material to produce the large diameter turbine disks because of its high creep strength and industrial maturity. Studies were performed on both Powder Metallurgy (P/M) and Cast & Wrought (C&W) billet samples. The effort was focussed on tailoring the microstructure to ensure a high creep strength and a good thermal stability. A new P/M process route has been developed to increase the grain size of the alloy and to ensure a good workability of P/M U720 with conventional forging route. The creep deformation and damage of P/M Udimet 720 was analysed to develop a creep predictive model based on physical damage parameters.

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Section: Methodsmentioning

confidence: 99%

“…The PPBs have also a detrimental effect on the workability of as-HIPed material, and initial attempts to use conventional forging routes were unsuccessful [5]. Therefore, high-cost extrusion processes were developed to ensure the minimum forging ratios imposed for critical applications [6].…”

Section: Tms (The Minerals Metals and Materials Society) 2004mentioning

confidence: 99%

Process Development and Mechanical Properties of Alloy U720LI for High Temperature Turbine Disks

Couturier¹,

Burlet²,

Terzi³

et al. 2004

Superalloys 2004 (Tenth International Symposium)

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“…In order to select the targeted isothermal holding temperatures ( s -1 to 300 K s -1 using a holding time of only 0.5 s, but changed little with higher heating rates. In the present study, precipitates (including ') actually started to form in the powders during the HIP process, moving the alloy phase fractions closer to equilibrium [18,19]. Therefore, while some difference in  from DSC measurements and during Joule heating and holding for 10 s of HIPed powders can be expected, it was likely less than the 12 K measured for the atomised powders over much shorter timescales.…”

Section: Accepted Manuscriptmentioning

confidence: 54%

Numerical and physical simulation of rapid microstructural evolution of gas atomised Ni superalloy powders

et al. 2017

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The rapid microstructural evolution of gas atomised Ni superalloy powder compacts over timescales of a few seconds was studied using a Gleeble 3500 thermomechanical simulator, finite element based numerical model and electron microscopies. The study found that the microstructural changes are governed by the characteristic temperatures of the alloy. At a temperature below the ' solvus, the powders maintained the dendritic structures. Above the ' solvus temperature but in the solid-state, rapid grain spheroidisation and coarsening occurred, although the fine-scale microstructures were largely retained. Once the incipient melting temperature of the alloy was exceeded, microstructural change was rapid, and when the temperature was increased into the solid+liquid state, the powder compact partially melted and then re-solidified with no trace of the original structure, despite the fast timescales. The study reveals the relationship between short, severe thermal excursions and microstructural evolution in powder processed components, and gives guidance on the upper limit of temperature

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“…However, presence of PPBs in the as-HIPed condition has been a perennial problem, and has necessitated post-HIP thermomechanical processing of these alloys, which not only increases the manufacturing cost, but also restricts the efficient use of HIPing as a process for manufacturing near net shape components. Specifically, processing involves canning of gas-atomised powders and HIPing, followed by hot extrusion and/or isothermal forging [20,21]. Post-HIP thermomechanical processing is performed in order to "break" the PPB network present in the as-HIPed products (i.e., via recrystallization).…”

Section: Implications Of the Present Study For Powder-hiped Components With Low-medium Sfementioning

confidence: 99%

Effect of Powder Characteristics and Oxygen Content on Modifications to the Microstructural Topology During Hot Isostatic Pressing of an Austenitic Steel

et al. 2018

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Sub-Solidus HIP Process for P/M Superalloy Conventional Billet Conversion

Cited by 12 publications

References 7 publications

Process Development and Mechanical Properties of Alloy U720LI for High Temperature Turbine Disks

Process Development and Mechanical Properties of Alloy U720LI for High Temperature Turbine Disks

Numerical and physical simulation of rapid microstructural evolution of gas atomised Ni superalloy powders

Effect of Powder Characteristics and Oxygen Content on Modifications to the Microstructural Topology During Hot Isostatic Pressing of an Austenitic Steel

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