Assessment of Micro-Geometric and Macro-Geometric Parameters after Machining Composite Material with Natural Fibres

Zuzana Hutyrová; Imrich Orlovský

doi:10.4028/www.scientific.net/AMM.616.276

Paper Titles

Dynamics of Core Taking out at Die Casting
p.244

Diagnostics of Strain Hardening Exponent and Material Constant of Steel Sheets
p.252

Using Recycled Rubber Particles as Filler of Polymers
p.260

Up Milling Technology and its Outputs
p.268

Assessment of Micro-Geometric and Macro-Geometric Parameters after Machining Composite Material with Natural Fibres
p.276

Comparison Measurement of the Distance between Axes of Holes with the Roundtest RA-120 and Thome Präzision-Rapid
p.284

Impact of Cutting Speed on the Resultant Cutting Tools Durability in Turning Process of Steel 100CrMn6
p.292

Comparison of Theory and Practice in Analytical Expression of Cutting Tools Durability for Potential Use at Manufacturing of Bearings
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Analysis of Selected Properties of Cutting Ceramics at Machining Process of Bearing Steel 100Cr6
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 616Assessment of Micro-Geometric and Macro-Geometric...

Assessment of Micro-Geometric and Macro-Geometric Parameters after Machining Composite Material with Natural Fibres

Abstract:

This paper present problem of the examination of the parameters of cutting process on the micro-geometric and macro-geometric parameters after the turning of composite material with natural reinforcement (material is combination of two different phases the plastic matrix and wood flour). The article deals with effect of feed rate and cutting speed to roundness deviation and maximum roughness depth. The results were analyzed using device of surface roughness, roundness/cylindricity and digital microscopic camera. From the result, the surface roughness are mostly influenced by feed rate.

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Periodical:

Applied Mechanics and Materials (Volume 616)

Pages:

276-283

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.616.276

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Online since:

August 2014

Authors:

Zuzana Hutyrová*, Imrich Orlovský

Keywords:

Composite Material, Inhomogeneity, Machining, Roughness, Roundness

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