Sensitivity of wear rates in the micro-scale abrasion test to test conditions and material hardness

Micro-scale abrasion (ball cratering) tests were performed with different combinations of ball and bulk specimen materials, under different test conditions, such as load and abrasive slurry concentration. Wear modes were classified into two types: with rolling particle motion and with grooving particle motion. Wear rates observed with rolling particle motion were relatively insensitive to test conditions, whereas with grooving motion they varied much more. It is suggested that rolling abrasion is therefore a more appropriate mode if reproducible test results are desired. The motion of the abrasive particles can be reliably predicted from the knowledge of hardnesses and elastic properties of the ball and the specimen, and from the normal load and the abrasive slurry concentration. General trends in wear resistance measured in the micro-scale abrasion test with rolling particle motion are similar to those reported in tests with fixed abrasives with sliding particle motion, although the variation in wear resistance with hardness is significantly smaller. © 2004 Published by Elsevier B.V.

Sources of variability in the free-ball micro-scale abrasion test

In the 'free-ball' version of the micro-scale abrasion or ball-cratering test the rotating ball rests against a tilted sample and a grooved drive shaft. Tests under nominally identical conditions with different apparatus commonly show small but significant differences in measured wear rate. An indirect method has been developed and demonstrated for continuous on-line measurement of the coefficient of friction in the free-ball test. Experimental investigation of the effects of sample tilt angle and drive shaft groove width shows that both these factors influence the stability of the rotation of the ball, and the shape of the abrasive slurry pool, which in turn affect the coefficient of friction in the wear scar area and the measured wear rate. It is suggested that in order to improve the reproducibility of this method the geometry of the apparatus should be specified. For the apparatus used in this work with a steel ball of 25 mm diameter, a sample tilt angle of 60-75° and a shaft groove width of about 10mm provided the most stable ball motion and a wear rate which showed least variability. © 2004 Elsevier B.V. All rights reserved.

Ciberativismo e a dimensão comunicativa dos movimentos sociais: repertório, organização e difusão.

O que é o ciberativismo? Como compreender o fenômeno? Há uma grande variedade de disciplinas e abordagens teóricas que tem se debruçado sobre o tema, gerando uma diversidade de ferramentas analíticas e estudos empíricos sobre aspectos específicos da prática; mas, ao mesmo tempo, uma dificuldade de diálogo entre as interpretações e perspectivas teóricas. Faz-se necessário, assim, uma reflexão que permita pensar esse campo de discussão de forma mais abrangente. Tomando como pressuposto que a dimensão comunicativa não é nova para os movimentos sociais, mas que o ciberativismo, como tal, pressupõe uma nova inflexão, este trabalho propõe um duplo esforço para compreender como as NTICs impactam a ação coletiva. Por um lado, busca-se realizar uma análise de caráter histórico que permita identificar a centralidade da dimensão comunicativa nas práticas dos movimentos sociais; por outro lado, propõe-se tecer uma interpretação de viés teórico que possibilite resgatar alguns eixos de análise das Teorias dos Movimentos Sociais (repertórios de ação, organização e dinâmicas de difusão), de tal forma que ferramentas analíticas possam ser atualizadas para o entendimento da ação coletiva contemporânea.

The effect of nozzle design on laser micro-machining of M2 tool steels

This paper shows how computational techniques have been used to develop axi-symmetric, straight, sonic-line, minimum length micro nozzles that are suitable for laser micro-machining applications. Gas jets are used during laser micro-machining processing applications to shield the interaction zone between laser and workpiece material, and they determine the machining efficiency of such applications. The paper discusses the nature of laser-material interactions and the importance of using computational fluid dynamics to model pressure distributions in short nozzles that are used to deliver gas to the laser-material interaction zone. Experimental results are presented that highlight unique problems associated with laser micro machining using gas jets.