Roger K. Nibert scite author profile

Powder flakes prepared from 50 fim thick melt-spun ribbons of Markomet 1064 (Ni 52 . 5 Mo 3g Cr 8 Bj 5 wt %) were shock consolidated in the unannealed and annealed condition. The unannealed powder flakes (microhardness 933 kg/mm 2 ) are amorphous while flakes annealed at 900 °C for 2 h have a fee crystal structure, with a microcrystalline grain size of 0.3 [im and microhardness of 800 kg/mm 2 . The shock-consolidated amorphous powder compact (~250 kJ/kg shock energy) shows no crystal peaks in an x-ray diffractometer scan. Compacts of annealed powder (400-600 kJ/kg shock energies) contain amorphous material (18%-21%), which was rapidly quenched from the melt formed at interparticle regions during the consolidation process. The microhardness of the amorphous interparticle material is 1100 kg/mm 2 . Wear properties of the compacts measured in the low velocity friction apparatus (LVFA) pin-on-disk tests show low average friction values (~0.03). The 60 h cumulative wear appears to correlate with the energy of shock compaction rather than the metallic glass content. The Falex ring-on-block test also showed that both the Markomet amorphous compact and the compact containing a mixture of amorphous and microcrystalline phases performed almost equally and wore half as much as the base-line SAE-01 steel-polished sample.

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Wear Properties of A Shock Consolidated Metallic Glass and Glass-Crystalline Mixtures

Vreeland

Thadhani

Mutz

et al. 1985

MRS Proc.

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Powder flakes prepared from 50 ~m thick melt spun ribbons of Markomet 1064 (Ni Mo Cr B 1 wt%) were shock consolidated in the unannealed and anne~f~~ co~ §iti §n. "lhe unannealed flakes (microhardness g33 kg/mm2) are amorphous while flakes annealed at 900°C for 2 hours have an fcc structure with a grain size of 0.3 ~m and microhardness of 800 kg/mm2. The shock consolidated amorphous powder compact (250 kJ/kg shock energy) shows no crystal peaks in an X-ray diffractometer scan. Compacts of annealed powder (400 to 600 kJ/kg shock energies) contain amorphous material (18-21 %) which was rapidly quenched from the melt formed at interparticle regions during the consolidation process. The microhardness of the amorphous interparticle material is 1100 kg/mm2. Wear properties of the compacts measured in low velocity pin on disk tests show low average dynamic friction values (~.03).The 60 hour cumulative wear appears to correlate with the energy of shock compaction and surface porosity of the compacts rather than the metallic glass content.

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Wet Clutch Lining-Lubricant Additive Interactions

Nibert

Albertson

1974

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Roger K. Nibert

Anti‐shudder durability of automatic transmission fluids: Mechanism of the loss of shudder control

Wear properties of shock-consolidated amorphous and microcrystalline Ni-38 wt % Mo−8 wt % Cr-1. 5 wt % B alloy powders

Wear Properties of A Shock Consolidated Metallic Glass and Glass-Crystalline Mixtures

Wet Clutch Lining-Lubricant Additive Interactions

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