• Home
  • About us
  • Your Publication
  • Catalogue
  • Newsletter
  • Help
  • Account
  • Contact / Imprint
Thesis - Publication series - Conference proceedings - Reference book - Lecture notes/Textbook - Journal - CD-/DVD-ROM - Online publication
Newsletter for authors and editors - New publications service - Archive
View basket
Catalogue : Details

Ali Zahedi

Development and Applications of Laser Generated Microstructures on CBN Grinding Wheels

FrontBack
 
ISBN:978-3-8440-7662-2
Series:Fertigungstechnik
Keywords:Ultrashort pulsed laser; Laser dressing; Microstructuring; CBN grinding wheel
Type of publication:Thesis
Language:English
Pages:150 pages
Figures:109 figures
Weight:222 g
Format:21 x 14,8 cm
Bindung:Paperback
Price:48,80 € / 61,10 SFr
Published:November 2020
Buy:
  » plus shipping costs
Download:

Available PDF-Files for this title:

You need the Adobe Reader, to open the files. Here you get help and information, for the download.

These files are not printable.

 
 DocumentDocument 
 TypePDF 
 Costs36,60 EUR 
 ActionPurchase in obligation and display of file - 44,1 MB (46214234 Byte) 
 ActionPurchase in obligation and download of file - 44,1 MB (46214234 Byte) 
     
 
 DocumentTable of contents 
 TypePDF 
 Costsfree 
 ActionDisplay of file - 3,5 MB (3624307 Byte) 
 ActionDownload of file - 3,5 MB (3624307 Byte) 
     

User settings for registered users

You can change your address here or download your paid documents again.

User:  Not logged in.
Actions:  Login / Register
 Forgotten your password?
Recommendation:You want to recommend this title?
Review copy:Here you can order a review copy.
Link:You want to link this page? Click here.
Export citations:
Text
BibTex
RIS
Abstract:The work describes a method utilizing ultra-short pulsed technology for covering the range of required conditioning processes on superabrasive grinding tools i.e. sharpening, cleaning, dressing, microstructuring and profiling. Furthermore, an analytical approach was proposed for modelling the grinding energy and workpiece surface characteristics based on the measured actual grain distribution on the grinding tool surface. The action of individual grains was simulated through a Finite Element (FE) approach and was extended to the aggregate action of whole grains present on the grinding tool surface according to the process kinematics and tool/workpiece contact conditions. Cylindrical grinding of ductile materials was specifically investigated. However, the generated model is composed of modularly interconnected calculation and evaluation blocks, which facilitates the extension of the model to further material models and grinding processes.