Add to ORKGNano/micro grinding of tungsten carbide (WC) mould inserts was performed. A form accuracy of 〜200nm (in PV) and a surface roughness of 〜7nm were achieved. Nanoindentation revealed that small chipping or cracking occurred even at a penetration depth of 38nm, which could hinder the further improvement of surface quality during grinding. It was found that when grinding was conducted at nanometric scale, the microstructure of the work material and the morphology of the WC grains should be taken into account to enable a fully ductile removal. Copyright 2005 by the Japan Society of Mechanical Engineer
Grinding is a key step on the manufacturing process of WC–Co cemented carbides (hardmetals). In this...
This study is aimed at experimentally investigating the effect of microgrinding on the integrity of ...
[EN] In this work ultrafine and nanocrystalline WC-Co mixtures were obtained by low energy milling i...
The influence of microstructure on the ultraprecision grinding response of a series of cemented carb...
The effect of microstructure of cemented tungsten carbide materials on their mechanical properties a...
This paper reports the development of microgrinding technologies for the fabrication of aspherical m...
The surface characteristics and removal mechanism of cemented tungsten carbide materials with differ...
Nanoindenting and nanoscratching were used to investigate removal and fracture characteristics of ce...
Manufacturing moulds for the wafer-scale replication of precision glass optics sets new demands in t...
This paper concentrates on the morphology of the ground surface of cobalt tungsten carbide (WC) comp...
he unique combination of hardness, toughness, and wear resistance exhibited by heterogeneous hard ma...
The present investigation reports for the first time a dramatic decrease in the sintering temperatur...
The metallic binder phase dictates the toughening behavior of WC-Co cemented carbides (hardmetals), ...
This paper summarised our recent results on the development of grinding technologies for the fabrica...
Grinding is a key step on the manufacturing process of WC–Co cemented carbides (hardmetals). In this...
Grinding is a key step on the manufacturing process of WC–Co cemented carbides (hardmetals). In this...
This study is aimed at experimentally investigating the effect of microgrinding on the integrity of ...
[EN] In this work ultrafine and nanocrystalline WC-Co mixtures were obtained by low energy milling i...
The influence of microstructure on the ultraprecision grinding response of a series of cemented carb...
The effect of microstructure of cemented tungsten carbide materials on their mechanical properties a...
This paper reports the development of microgrinding technologies for the fabrication of aspherical m...
The surface characteristics and removal mechanism of cemented tungsten carbide materials with differ...
Nanoindenting and nanoscratching were used to investigate removal and fracture characteristics of ce...
Manufacturing moulds for the wafer-scale replication of precision glass optics sets new demands in t...
This paper concentrates on the morphology of the ground surface of cobalt tungsten carbide (WC) comp...
he unique combination of hardness, toughness, and wear resistance exhibited by heterogeneous hard ma...
The present investigation reports for the first time a dramatic decrease in the sintering temperatur...
The metallic binder phase dictates the toughening behavior of WC-Co cemented carbides (hardmetals), ...
This paper summarised our recent results on the development of grinding technologies for the fabrica...
Grinding is a key step on the manufacturing process of WC–Co cemented carbides (hardmetals). In this...
Grinding is a key step on the manufacturing process of WC–Co cemented carbides (hardmetals). In this...
This study is aimed at experimentally investigating the effect of microgrinding on the integrity of ...
[EN] In this work ultrafine and nanocrystalline WC-Co mixtures were obtained by low energy milling i...