Detail publikace

Rychlé zahřátí zirkon-oxidového nanočásticového prášku pomocí přenosu tepla infrazářením

KALOUSEK, R. SPOUSTA, J. ZLÁMAL, J. DUB, P. ŠIKOLA, T. SHEN, Z. SALAMON, D. MACA, K.

Český název

Rychlé zahřátí zirkon-oxidového nanočásticového prášku pomocí přenosu tepla infrazářením

Anglický název

Rapid heating of zirconia nanoparticle-powder compacts by infrared radiation heat transfer

Typ

článek v časopise ve Web of Science, Jimp

Jazyk

en

Originální abstrakt

Homogeneous rapid sintering of nanoparticle powder compacts of yttria-stabilized zirconia was achieved by the radiation heat transfer. Green bodies were prepared by cold isostatic pressing (CIP) at various pressures providing different porosity of samples before sintering. Pressure-less sintering was performed in air at a heating rate of 100 C/min up to the 1500 C/1 min. Scanning electron microscopy, mercury intrusion porosimetry, and Archimedes technique were used to characterize the microstructure and to determine the density of the green and sintered bodies. Contrary to expectations, our results reveal opposite dependence of the green- and sintered densities on the CIP pressure. Since the whole sintering process does not exceed 10 min, to propose what processes are responsible for observed results, our attention is focused on the radiation heat transfer from furnace heating elements into the ceramics. Our arguments are supported bynumerical calculations ofthe electromagneticfield enhancementin/between particles.

Český abstrakt

Homogenní rychlé slinování nanočástic práškového yttriem stabilizovaného ozidu zirkonu bylo dosaženo pčenosem tepla infrazářením.

Anglický abstrakt

Homogeneous rapid sintering of nanoparticle powder compacts of yttria-stabilized zirconia was achieved by the radiation heat transfer. Green bodies were prepared by cold isostatic pressing (CIP) at various pressures providing different porosity of samples before sintering. Pressure-less sintering was performed in air at a heating rate of 100 C/min up to the 1500 C/1 min. Scanning electron microscopy, mercury intrusion porosimetry, and Archimedes technique were used to characterize the microstructure and to determine the density of the green and sintered bodies. Contrary to expectations, our results reveal opposite dependence of the green- and sintered densities on the CIP pressure. Since the whole sintering process does not exceed 10 min, to propose what processes are responsible for observed results, our attention is focused on the radiation heat transfer from furnace heating elements into the ceramics. Our arguments are supported bynumerical calculations ofthe electromagneticfield enhancementin/between particles.

Klíčová slova česky

Yttriem stabilizovaný zirkon-oxid; Dielektrické nanočástice; Rychlé slinování; Přenos tepla zářením; Zesílení lokálního elektromagnetického pole

Klíčová slova anglicky

Yttria-stabilized zirconia; Dielectric nanoparticle; Rapid sintering; Radiation heat transfer; Local electromagnetic field enhancement

Vydáno

01.03.2017

ISSN

0955-2219

Ročník

37

Číslo

3

Strany od–do

1067–1072

Počet stran

6

BIBTEX


@article{BUT134132,
  author="Radek {Kalousek} and Jan {Čechal} and Jiří {Spousta} and Jakub {Zlámal} and Petr {Dub} and Tomáš {Šikola} and Zhijian {Shen} and David {Salamon} and Karel {Maca},
  title="Rapid heating of zirconia nanoparticle-powder compacts by infrared radiation heat transfer",
  year="2017",
  volume="37",
  number="3",
  month="March",
  pages="1067--1072",
  issn="0955-2219"
}