Engineering

Volume 2, Issue 3 (March 2010)

ISSN Print: 1947-3931   ISSN Online: 1947-394X

Google-based Impact Factor: 0.66  Citations  

Applications of High-Efficiency Abrasive Process with CBN Grinding Wheel

HTML  Download Download as PDF (Size: 199KB)  PP. 184-189  
DOI: 10.4236/eng.2010.23026    9,619 Downloads   15,876 Views  Citations

Affiliation(s)

.

ABSTRACT

High-efficiency abrasive process with CBN grinding wheel is one of the important techniques of advanced manufacture. Combined with raw and finishing machining, it can attain high material removal rate like turning, milling and planning. The difficult-to-grinding materials can also be ground by means of this method with high performance. In the present paper, development status and latest progresses on high-efficiency abrasive machining technologies with CBN grinding wheel relate to high speed and super-high speed grinding, quick point-grinding, high efficiency deep-cut grinding, creep feed deep grinding, heavy-duty snagging and abrasive belt grinding were summarized. The efficiency and parameters range of these abrasive machining processes were compared. The key technologies of high efficiency abrasive machining, including grinding wheel, spindle and bearing, grinder, coolant supplying, installation and orientation of wheel and workpiece and safety defended, as well as intelligent monitor and NC grinding were investigated. It is concluded that high efficiency abrasive machining is a promising technology in the future.

Share and Cite:

Y. Hou, C. Li and Y. Zhou, "Applications of High-Efficiency Abrasive Process with CBN Grinding Wheel," Engineering, Vol. 2 No. 3, 2010, pp. 184-189. doi: 10.4236/eng.2010.23026.

Cited by

[1] Mechanical strength increasing of abrasive reinforced wheel
Strength of Materials …, 2022
[2] ДОСЛІДЖЕННЯ ТЕПЛОНАПРУЖЕНОСТІ ПРОЦЕСУ ШЛІФУВАННЯ ЦИЛІНДРИЧНИХ ПОВЕРХОНЬ ПЕРИФЕРІЄЮ ОРІЄНТОВАНОГО КРУГА В РЕЖИМІ …
2021
[3] ДОСЛІДЖЕННЯ ДИНАМІЧНИХ ХАРАКТЕРИСТИК ПРОЦЕСУ ШЛІФУВАННЯ ЦИЛІНДРИЧНИХ ПОВЕРХОНЬ ПЕРИФЕРІЄЮ ОРІЄНТОВАНОГО КРУГА В …
2020
[4] Development of a model of tool surface dressing when grinding with crossed wheel and cylindrical part axes
2020
[5] СИНТЕЗ СИСТЕМЫ АВТОМАТИЧЕСКОГО УПРАВЛЕНИЯ ГЛУБИНОЙ РЕЗАНИЯ КРУГЛОШЛИФОВАЛЬНОГО СТАНКА
2020
[6] ДОСЛІДЖЕННЯ ПРОЦЕСУ ШЛІФУВАННЯ ЦИЛІНДРИЧНИХ ПОВЕРХОНЬ У РЕЖИМІ ЗАТУПЛЕННЯ ОРІЄНТОВАНОГО КРУГА, ЗАПРАВЛЕНОГО З РІЗНИМИ …
2020
[7] ДОСЛІДЖЕННЯ ПРОЦЕСУ ШЛІФУВАННЯ ЦИЛІНДРИЧНИХ ПОВЕРХОНЬ У РЕЖИМІ ЗАТУПЛЕННЯ ОРІЄНТОВАНОГО КРУГА, ЗАПРАВЛЕНОГО З …
Технічні науки та технології, 2020
[8] Experimental Studies on MoS2-Treated Grinding Wheel Active Surface Condition after High-Efficiency Internal Cylindrical Grinding Process of INCONEL® Alloy 718
2019
[9] Zastosowanie hybrydowego systemu pomiarowego wykorzystującego obrazowanie i analizę światła rozproszonego do oceny stanu powierzchni szlifowanych
In?ynieria Maszyn, 2015
[10] Maraging steel phase transformation in high strain rate grinding.
2015
[11] Hochleistungs-/Hochgeschwindigkeitsschleifen mit laserstrukturierten CBN-Schleifscheiben
Dissertation, 2015
[12] Maraging steel phase transformation in high strain rate grinding
The International Journal of Advanced Manufacturing Technology, 2015
[13] Investigation into engineering ceramics grinding mechanism and the influential factors of the grinding force
2014
[14] Investigation on the grinding temperature field of nano-ZrO2 dental ceramics with a nanoparticle jet of MQL
International Journal of Computational Materials Science and Surface Engineering, 2014
[15] Modeling and Experimental Investigation of the Flow Velocity Field in the Grinding Zone.
International Journal of Control & Automation, 2014
[16] Investigation into Engineering Ceramics Grinding Mechanism and the Influential Factors of the Grinding Force.
?International Journal of Control & Automation, 2014
[17] Grinding Model and Material Removal Mechanism of Medical Nanometer Zirconia Ceramics
Recent patents on nanotechnology, 2014
[18] Investigation on the grinding temperature field of nano-ZrO 2 dental ceramics with a nanoparticle jet of MQL
?International Journal of Computational Materials Science and Surface Engineering?, 2014
[19] Modeling and experimental investigation of the flow velocity field in the grinding zone
2013
[20] Modeling and numerical simulation of the grinding temperature field with nanoparticle jet of MQL
Advances in Mechanical Engineering, hindawi, 2013
[21] Development of abrasive machining and recent related patents
Recent Pat Mech Eng, 2013
[22] Evaluation of minimum quantity lubrication grinding with nano-particles and recent related patents
Recent patents on nanotechnology, 2013
[23] Theoretical Modeling and Simulation of Airflow Field near Grinding Wheel
International Journal of Control and Automation, 2013
[24] Modeling and Experimental Investigation of Pressure Field in the Grinding Zone with Nanoparticle Jet of MQL
Advances in Mechanical Engineering, hindawi, 2013
[25] Influence of unbalanced response of ultra–high speed grinder spindle on dynamic performance
?International Journal of Materials and Product Technology?, 2012
[26] Application and Development of High-efficiency abrasive process
International Journal of Advanced Science and Technology, 2012
[27] Review of the advanced microscopy techniques used for diagnostics of grinding wheels with ceramic bond
Journal of Machine Engineering, 2012
[28] Influence of unbalanced response of ultra-high speed grinder spindle on dynamic performance
International Journal of Materials and Product Technology, 2012
[29] Knowledge Management for Grinding Technology
2011
[30] ПІДВИЩЕННЯ ТОЧНОСТІ ТА ПРОДУКТИВНОСТІ ШЛІФУВАННЯ ЦИЛІНДРИЧНИХ ПОВЕРХОНЬ ОРІЄНТОВАНИМ КРУГОМ, ЗАПРАВЛЕНИМ ІЗ РІЗНИМИ …

Journals Menu
Follow SCIRP
Contact us
customer@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1655362766
Paper Publishing WeChat

Copyright © 2023 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.