A New Method for the Preparation of Cutting Edges via Grinding

Christian Effgen; Bejamin Kirsch

doi:10.4028/www.scientific.net/AMR.769.85

Paper Titles

Micromachining of CP-Titanium on a Desktop Machine - Study on Bottom Surface Quality in Micro End Milling
p.53

Influence of Solid Contaminants in Metal Working Fluids on the Grinding Process
p.61

A High Resolution Surface Model for the Simulation of Honing Processes
p.69

Waterjet Turning of Titanium Alloys
p.77

A New Method for the Preparation of Cutting Edges via Grinding
p.85

Hot Machining: Utilisation of the Forging Heat for Efficient Turning at Elevated Temperatures
p.93

Numerical Investigations on Cutting of Dual-Phase Sheet Steel with an Emphasis on Material Damage at the Cut Edge
p.101

Quantitative Microstructural Analysis of Nanocrystalline Surface Layer Induced by a Modified Cutting Process
p.109

Cutting of Nickel-Based Superalloys with Rotating Indexable Inserts
p.116

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 769A New Method for the Preparation of Cutting Edges...

A New Method for the Preparation of Cutting Edges via Grinding

Abstract:

In this paper, a new method for the preparation of cutting edges via grinding is presented. This method enables the manufacturing of the tool macro and micro geometry in one setup without reclamping, allowing improved flexibility, repeatability and accuracy at reduced processing times. This new method is path controlled using a special elastic bond for the grinding wheels. By using elastic bond, a rounded cutting edge instead of undesired chamfers can be achieved, as the bond nestles around the cutting edge and elastically deforms. The elastic bond is specified by the grain concentration and its basic hardness. Besides the specifications of the bond, the process kinematics highly influences the properties of the cutting edge. The kinematics is a combination of the tool path (machining strategy) and the grinding wheel geometry. The presented experiments include the examination of three different kinematics using three different grinding wheel geometries, FEPA 1A1, 1V1 and 4A2. For each kinematics, three different grain concentrations and three degrees of basic bond hardness were tested, resulting in a complete amount of 27 parameter combinations. The outer diameter cutting edges of cemented carbide milling tools (end mills) were prepared in a 5-axis tool grinding machine. The shape and quality of the achieved cutting edge rounding was qualitatively evaluated by means of scanning electron microscopy (SEM).

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Periodical:

Advanced Materials Research (Volume 769)

Pages:

85-92

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.769.85

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Online since:

September 2013

Authors:

Christian Effgen, Bejamin Kirsch

Keywords:

Cutting Edge Preparation, Grinding, Milling

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References

[1] D. Biermann, K. Weinert, I. Terwey, B. Denkena, J. Haubrock, Vorteile durch Verrundung. Einsatzverhalten komplexer Werkzeuge mit präparierten Schneidkanten, WB Werkstatt und Betrieb 142/11 (2009) 36–40.

Google Scholar

[2] F. Tikal, Schneidkantenpräparation – Ziele, Verfahren und Messmethoden. Kassel university press GmbH, Kassel, 2009.

Google Scholar

[3] B. Denkena, N. Kramer, F. Siegel, J. Kästner, Methoden zur Präparation von Zerspanwerkzeugen: Leistungsoptimierung an der Schneidkante, VDI-Z Special Werkzeuge 8 (2007) 24–26.

Google Scholar

[4] J.C. Aurich, M. Zimmermann, L. Leitz, The preparation of cutting edges using a marking laser, Production Engineering 5/1 (2011) 17-24.

DOI: 10.1007/s11740-010-0275-9

Google Scholar

[5] DIN 6528, Vollhartmetall-Schaftfräser mit durchgehendem Zylinderschaft – Maße, Beuth Verlag GmbH, Berlin, 2002.

DOI: 10.31030/9222755

Google Scholar