Effects of TiCN Composite Die with Low Thermal Conductivity on Hot Forging Performances

Matsumoto, Ryo; Itamochi, Tomio; Mori, Shoji

doi:10.17265/2159-5275/2016.02.001

Cited by 2 publications

(2 citation statements)

References 9 publications

(9 reference statements)

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“…The shear friction factor along the hollow part of the upper die was varied in the range 0.1 ≤ m b1 ≤ 1.0, while the shear friction factors at the other parts of the upper and lower dies were assumed to be m b2 = m f = 0.4. The heat transfer coefficients for the die-workpiece interface and the free surface of the workpiece were determined from heating and cooling tests to be 6000 W•m -2 •K -1 and 100 W•m -2 •K -1 , respectively [13].…”

Section: Finite Element Simulationmentioning

confidence: 99%

Lubrication in Hot Forging with Pulsed Ram Motion

Matsumoto

Utsunomiya

Ishigai³

2018

KEM

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The effect of pulsed (oscillating) ram motion control on lubrication was investigated in hot forging of stainless steel workpiece with oxide glass lubricant. During the retreat in the pulsed ram motion, the workpiece was re-lubricated by flow of lubricant through the gap between the workpiece and the die. A hot spike-type forging test on a servo press with pulsed ram motions was carried out to investigate the lubrication performance of the oxide glass. In the test, the workpiece with a temperature of 1223 K was extruded into the hollow part of the upper die together with oxide glass in a manner that combined pulsed and stepwise ram operations. The re-lubrication of the workpiece with oxide glass was confirmed by the test results showing 5–10% reduction in the forging load and 5% longer length of the backward extruded part of the workpiece under an appropriate pulsed ram motion.

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Section: Finite Element Simulationmentioning

confidence: 99%

Lubrication in Hot Forging with Pulsed Ram Motion

Matsumoto

Utsunomiya

Ishigai³

2018

KEM

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“…Accordingly, conventional die steels, for example, H13, Finkl, 4340, and Uddeholm Dievar; specialty steels, including maraging steels; and superalloys like A286, 718, 720, Waspaloy, Hastelloy, and Stellite are common, depending on the application and the stringent requirements of the forging parts [3][4][5][6][7]. The performance requirements of hot-forging dies typically include good (a) hardenability, (b) toughness and ductility, (c) temper resistance, (d) hardness and strength at room and elevated temperatures, (e) wear resistance, (f) oxidation and corrosion resistance, (g) thermal conductivity, (h) thermal and mechanical fatigue, and some other requirements [3][4][5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Strategic Selection of Refractory High-Entropy Alloy Coatings for Hot-Forging Dies by Applying Decision Science

Jayaraman,

Canumalla

2023

Coatings

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We compiled, assessed, and ranked refractory high-entropy alloys (RHEAs) from the existing literature to identify promising coating materials for hot-forging dies. The selection methodology was rigorously guided by decision science principles, seamlessly integrating multiple attribute decision making (MADM), principal component analysis (PCA), and hierarchical clustering (HC). By employing a combination of twelve diverse MADM methods, we successfully ranked a total of 22 RHEAs. This analytical technique unveiled the top five RHEAs: Ti20-Zr20-Hf20-Nb20-Cr20, Al20.4-Mo10.5-Nb22.4-Ta10.1-Ti17.8-Zr18.8, Ti20-Zr20-Hf20-Nb20-V20, Al11.3-Nb22.3-Ta13.1-Ti27.9-V4.5-Zr20.9, and Al7.9-Hf12.8-Nb23-Ta16.8-Ti18.9-Zr20.6 pertinent for generating data on other significant properties, including wear resistance, fatigue (both thermal and mechanical), bonding compatibility with the substrate die material, oxidation resistance, potential reactions with the workpiece, cost-effectiveness, fabricability, and more. The three highest-ranked RHEAs share key characteristics, including a body-centered cubic (BCC) crystal structure, thermal conductivity below ~70 W/mK, and impressive yield strength at ambient and elevated temperatures, surpassing 1100 MPa. Moreover, they exhibit a remarkable ~73% similarity among themselves. The decision science-driven analyses yield sound metallurgical insights and provide valuable guidelines for developing RHEA coatings tailored for hot-forging dies. The strategy for designing RHEA-based coating materials for hot-forging dies should focus on compositions featuring a substantial presence of refractory metals while maintaining a BCC crystal structure. This combination is likely to deliver the desired blend of thermal and mechanical properties, rendering these coatings exceptionally well-suited for the demanding requirements of hot-forging operations.

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Effects of TiCN Composite Die with Low Thermal Conductivity on Hot Forging Performances

Cited by 2 publications

References 9 publications

Lubrication in Hot Forging with Pulsed Ram Motion

Lubrication in Hot Forging with Pulsed Ram Motion

Strategic Selection of Refractory High-Entropy Alloy Coatings for Hot-Forging Dies by Applying Decision Science

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