On the sharpness of straight edge blades in cutting soft solids: Part II - Analysis of blade geometry

C. T. McCarthy, A. Ní Annaidh, M. D. Gilchrist

Research output: Contribution to journalArticlepeer-review

Abstract

In Part I of this paper a new metric, titled the "blade sharpness index" or "BSI", for quantifying the sharpness of a straight edge blade when cutting soft solids was derived from first principles and verified experimentally by carrying out indentation type cutting tests with different blade types cutting different target or substrate materials. In this Part II companion paper, a finite element model is constructed to examine the effect of different blade variables including tip radius, wedge angle and blade profile on the BSI developed in Part I. The finite element model is constructed using ABAQUS implicit and experiments are performed to characterise the non-linear material behaviour observed in the elastomeric substrate. The model is validated against the experiments performed in Part I and a suitable failure criterion is determined by carrying out experiments on blades with different tip radii. The paper finds that a simple maximum stress criterion is a good indicator for predicting the onset of cutting. The validated model is then used to examine blade geometry. It is shown that finite element analysis is an important tool in helping to understand the mechanics of indentation. Furthermore, the study finds that all the blade geometric variables have an influence on the sharpness of a blade, with the BSI being most sensitive to tip radius. Increasing the tip radius and wedge angle decreases the sharpness of the blade.

Original languageEnglish
Pages (from-to)437-451
Number of pages15
JournalEngineering Fracture Mechanics
Volume77
Issue number3
DOIs
Publication statusPublished - Mar 2010

Keywords

  • Cutting
  • Elastomers
  • Finite element analysis
  • Indentation
  • Sharpness

Fingerprint

Dive into the research topics of 'On the sharpness of straight edge blades in cutting soft solids: Part II - Analysis of blade geometry'. Together they form a unique fingerprint.

Cite this