Specifications
which was prepared by infiltrating molten cast iron into SiC particles preforms, were studied on
self-made slurry inject erosion wear machine. The results show that the erosion wear rate of the
SiCp/cast iron surface composite would be the lowest at impact angle of 30°, and the largest at
impact angle of 60°. The erosion wear rate increases gradually when impact angle is changed
from 30° to 60°, and then decreased with increasing the impact angle. The erosion wear
mechanism of the SiCp/cast iron surface composite is dominated by cutting and grooving at low
impact angle, and by fatigue spalling and cutting at high impact angle. For the gray cast iron, the
erosion wear rate of would be increased gradually with the increase of impact angle, reaching the
peak value at 90°, which indicates the typical characteristics of brittle material in slurry erosion
wear process. © (2012) Trans Tech Publications, Switzerland.
Number of references: 8
Main heading: Wear of materials
Controlled terms: Cast iron - Silicon carbide - Tribology
Uncontrolled terms: Erosion wear - Gray cast iron - Grey cast iron - High
impact - Impact angles - Iron surface - Peak values - SiC particles - Slurry
erosion - Surface composites
Classification code: 421 Strength of Building Materials; Mechanical Properties - 545.2
Iron Alloys - 804.2 Inorganic Compounds - 931 Classical Physics; Quantum Theory;
Relativity - 951 Materials Science
DOI: 10.4028/www.scientific.net/MSF.724.339
Database: Compendex
Compilation and indexing terms, © 2013 Elsevier Inc.
23.
Accession number: 20130515975977
Title: The theory of the density-based gravure spot-color matching
Authors: Luo, Rubai1, 2 ; Jiang, Nan1, 2 ; Zhou, Shisheng1, 2 ; Zhang, Yan1, 2/罗如柏; ;蒋楠;
周世生;
Author affiliation:
1 School of Printing and Packing Engineering, Xi'an University of Technology, Xi'an, China
2 Shaanxi Key Laboratory of Printing and Packing Engineering, Xi'an University of Technology,
Xi'an, China
Corresponding author: Luo, R. (luorubai@xaut.edu.cn)
Source title: Applied Mechanics and Materials
Abbreviated source title: Appl. Mech. Mater.
Volume: 262
Monograph title: Advances in Printing and Packaging Technologies
Issue date: 2013
Publication year: 2013
Pages: 69-73
Language: English
ISSN: 16609336
E-ISSN: 16627482
ISBN-13: 9783037855720
Document type: Conference article (CA)