Fracture Properties of SPS Tungsten Copper Powder Composites
Metallurgical and Materials Transactions A • 2013
معلومات البحث
المؤلفون
Medhat Awad El-Hadek & Saleh HamadaKaytbay
الكلمات المفتاحية
Not Available
المجلة العلمية
Metallurgical and Materials Transactions A
الناشر
springer
المجلد
Volume 44 Number 1
العدد
ISSN 1073-5623
الصفحات
Not Available
publication.type
International
رابط البحث
Not Available
المواد المرفقة
Not Available
الملخص
Tungsten-copper composites with various copper nano-particles volume fractions were manufactured
and examined. Tungsten-copper composites with 20 pct, 25 pct, and 30 pct volume
fractions were mechanically mixed and sintered. spark plasma sintering (SPS) method was used
for samples preparation at two different sintered temperatures 1273 K and 1373 K (1000 C and
1100 C). The effect of copper nano-particles on the bulk density, hardness, the coefficient of
thermal expansion (CTE), electrical conductivity, and stress-strain behavior of the produced
composites were studied. The hardness was found to decrease with the increase of the copper
volume fraction in the composites. Conversely, the CTE and electrical conductivity increases
with the increase of the copper volume fraction in the composites. Furthermore, the elastic
modulus were extracted from tensile stress-strain behavior were found to increase with the
increase of the copper volume fraction in the composites. Finally, the fracture surface roughness
was studied using high resolution optical investigations and was noticeably higher with the
increase of the copper volume fraction in the composites.
and examined. Tungsten-copper composites with 20 pct, 25 pct, and 30 pct volume
fractions were mechanically mixed and sintered. spark plasma sintering (SPS) method was used
for samples preparation at two different sintered temperatures 1273 K and 1373 K (1000 C and
1100 C). The effect of copper nano-particles on the bulk density, hardness, the coefficient of
thermal expansion (CTE), electrical conductivity, and stress-strain behavior of the produced
composites were studied. The hardness was found to decrease with the increase of the copper
volume fraction in the composites. Conversely, the CTE and electrical conductivity increases
with the increase of the copper volume fraction in the composites. Furthermore, the elastic
modulus were extracted from tensile stress-strain behavior were found to increase with the
increase of the copper volume fraction in the composites. Finally, the fracture surface roughness
was studied using high resolution optical investigations and was noticeably higher with the
increase of the copper volume fraction in the composites.
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