FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4309339997> ?p ?o ?g. }

• W4309339997 endingPage "334" @default.
• W4309339997 startingPage "323" @default.
• W4309339997 abstract "The microball end mills are widely used in the processing of micro parts in the fields of aerospace. These micro parts are often made of hard to machine materials with high hardness and strength, such as martensitic stainless steel. As the main processing tool of these parts, the micro cutting tools wear fast and have a short service life. At the same time, because of the small diameter and complex structure of the micro ball end milling tool, its preparation process is complex, and its quality is difficult to guarantee. In order to solve the above problems, a micro ball end milling tool with a flat edge and conical flank (FC-MBMT) made of cemented carbide is proposed, which reduces the difficulty of tool preparation through the design of the flat edge, and reduces the friction between the flank and the machined surface through the design of the conical flank. Firstly, based on the theory of the spherical helix, the mathematical model of FC-MBMT was established. Then, the motion expression of each axis of the machine tool in the grinding process of FC-MBMT is obtained by deriving the transformation matrix between the machine tool coordinate system and the tool coordinate system. The precision grinding of the FC-MBMT is realized, and its geometric parameter error is less than 8%. Finally, based on the above methods, two kinds of FC-MBMT with a flank width of 16 μm and a flank width of 24 μm were prepared, and their cutting performance was verified by micro groove milling experiments of martensitic steel. Ordinary equal guide cutting edge ball end milling tool participated in the machining as a comparison item. The milling experiment results show that the surface roughness of the FC-MBMT is less than 0.52 μm and the total cutting force is less than 7 N. The machining quality of the FC-MBMT with a conical flank width of 16 μm is better than the FC-MBMT with a flank width of 24 μm, and its cutting force is smaller than the FC-MBMT with a flank width of 24 μm, which indicates that it has better cutting performance with a conical flank width of 16 μm. The wear morphology shows that the wear forms of the FC-MBMT are chip adhesion on the conical flank and slight cutting edge wear. The anti-wear ability of the FC-MBMT with a conical flank width of 16 μm is obviously better than the FC-MBMT with a flank width of 24 μm. Compared with the ordinary micro ball end milling tool, the cutting performance and wear resistance of the FC-MBMT with a flank width of 16 μm are not significantly different. The experimental results verify the feasibility of the proposed tool structure." @default.
• W4309339997 created "2022-11-26" @default.
• W4309339997 creator A5024134085 @default.
• W4309339997 creator A5028175777 @default.
• W4309339997 creator A5029653138 @default.
• W4309339997 creator A5039503551 @default.
• W4309339997 creator A5040813805 @default.
• W4309339997 creator A5051901213 @default.
• W4309339997 creator A5053453125 @default.
• W4309339997 creator A5072693668 @default.
• W4309339997 creator A5076624668 @default.
• W4309339997 creator A5078035917 @default.
• W4309339997 date "2023-01-01" @default.
• W4309339997 modified "2023-10-17" @default.
• W4309339997 title "Research on design and fabrication of micro ball end milling tool with flat edge and conical flank" @default.
• W4309339997 cites W166946825 @default.
• W4309339997 cites W1964609467 @default.
• W4309339997 cites W1966907886 @default.
• W4309339997 cites W1982994463 @default.
• W4309339997 cites W1990127912 @default.
• W4309339997 cites W2005505979 @default.
• W4309339997 cites W2008990844 @default.
• W4309339997 cites W2047345795 @default.
• W4309339997 cites W2054964627 @default.
• W4309339997 cites W2058108328 @default.
• W4309339997 cites W2058327874 @default.
• W4309339997 cites W2114912773 @default.
• W4309339997 cites W2159819579 @default.
• W4309339997 cites W2913202600 @default.
• W4309339997 cites W3021287752 @default.
• W4309339997 cites W3025588678 @default.
• W4309339997 cites W3026577634 @default.
• W4309339997 cites W3041251407 @default.
• W4309339997 cites W3082746725 @default.
• W4309339997 cites W3128047546 @default.
• W4309339997 cites W3135451682 @default.
• W4309339997 cites W3215689504 @default.
• W4309339997 doi "https://doi.org/10.1016/j.precisioneng.2022.11.003" @default.
• W4309339997 hasPublicationYear "2023" @default.
• W4309339997 type Work @default.
• W4309339997 citedByCount "0" @default.
• W4309339997 crossrefType "journal-article" @default.
• W4309339997 hasAuthorship W4309339997A5024134085 @default.
• W4309339997 hasAuthorship W4309339997A5028175777 @default.
• W4309339997 hasAuthorship W4309339997A5029653138 @default.
• W4309339997 hasAuthorship W4309339997A5039503551 @default.
• W4309339997 hasAuthorship W4309339997A5040813805 @default.
• W4309339997 hasAuthorship W4309339997A5051901213 @default.
• W4309339997 hasAuthorship W4309339997A5053453125 @default.
• W4309339997 hasAuthorship W4309339997A5072693668 @default.
• W4309339997 hasAuthorship W4309339997A5076624668 @default.
• W4309339997 hasAuthorship W4309339997A5078035917 @default.
• W4309339997 hasBestOaLocation W43093399971 @default.
• W4309339997 hasConcept C122041747 @default.
• W4309339997 hasConcept C124961601 @default.
• W4309339997 hasConcept C127413603 @default.
• W4309339997 hasConcept C144024400 @default.
• W4309339997 hasConcept C154945302 @default.
• W4309339997 hasConcept C159985019 @default.
• W4309339997 hasConcept C162307627 @default.
• W4309339997 hasConcept C19165224 @default.
• W4309339997 hasConcept C191897082 @default.
• W4309339997 hasConcept C192562407 @default.
• W4309339997 hasConcept C199639397 @default.
• W4309339997 hasConcept C2524010 @default.
• W4309339997 hasConcept C2776100724 @default.
• W4309339997 hasConcept C2777571299 @default.
• W4309339997 hasConcept C2780383046 @default.
• W4309339997 hasConcept C2780395675 @default.
• W4309339997 hasConcept C2984155413 @default.
• W4309339997 hasConcept C33923547 @default.
• W4309339997 hasConcept C41008148 @default.
• W4309339997 hasConcept C523214423 @default.
• W4309339997 hasConcept C5941749 @default.
• W4309339997 hasConcept C78519656 @default.
• W4309339997 hasConceptScore W4309339997C122041747 @default.
• W4309339997 hasConceptScore W4309339997C124961601 @default.
• W4309339997 hasConceptScore W4309339997C127413603 @default.
• W4309339997 hasConceptScore W4309339997C144024400 @default.
• W4309339997 hasConceptScore W4309339997C154945302 @default.
• W4309339997 hasConceptScore W4309339997C159985019 @default.
• W4309339997 hasConceptScore W4309339997C162307627 @default.
• W4309339997 hasConceptScore W4309339997C19165224 @default.
• W4309339997 hasConceptScore W4309339997C191897082 @default.
• W4309339997 hasConceptScore W4309339997C192562407 @default.
• W4309339997 hasConceptScore W4309339997C199639397 @default.
• W4309339997 hasConceptScore W4309339997C2524010 @default.
• W4309339997 hasConceptScore W4309339997C2776100724 @default.
• W4309339997 hasConceptScore W4309339997C2777571299 @default.
• W4309339997 hasConceptScore W4309339997C2780383046 @default.
• W4309339997 hasConceptScore W4309339997C2780395675 @default.
• W4309339997 hasConceptScore W4309339997C2984155413 @default.
• W4309339997 hasConceptScore W4309339997C33923547 @default.
• W4309339997 hasConceptScore W4309339997C41008148 @default.
• W4309339997 hasConceptScore W4309339997C523214423 @default.
• W4309339997 hasConceptScore W4309339997C5941749 @default.
• W4309339997 hasConceptScore W4309339997C78519656 @default.
• W4309339997 hasFunder F4320321001 @default.

• next