Issue 30

C. Barile et alii, Frattura ed Integrità Strutturale, 30 (2014) 211-219; DOI: 10.3221/IGF-ESIS.30.27 211 Focussed on: Fracture and Structural Integrity related Issues Considerations on the choice of experimental parameters in residual stress measurements by hole-drilling and ESPI C. Barile, C. Casavola, G. Pappalettera, C. Pappalettere Dipartimento di Meccanica, Matematica e Management, Politecnico di Bari, viale Japigia 182, Bari, Italy claudia.barile@poliba.it A BSTRACT . Residual stresses occur in many manufactured structures and components. Great number of investigations have been carried out to study this phenomenon. Over the years, different techniques have been developed to measure residual stresses; nowadays the combination of Hole Drilling method (HD) with Electronic Speckle Pattern Interferometry (ESPI) has encountered great interest. The use of a high sensitivity optical technique instead of the strain gage rosette has the advantage to provide full field information without any contact with the sample by consequently reducing the cost and the time required for the measurement. The accuracy of the measurement, however, is influenced by the proper choice of several parameters: geometrical, analysis and experimental. In this paper, in particular, the effects of some of those parameters are investigated: misknowledgment in illumination and detection angles, the influence of the relative angle between the sensitivity vector of the system and the principal stress directions, the extension of the area of analysis and the adopted drilling rotation speed. In conclusion indications are provided to the scope of optimizing the measurement process together with the identification of the major sources of errors that can arise during the measuring and the analysis stages. K EYWORDS . Residual stress; Electronic Speckle Pattern Interferometry (ESPI); Hole Drilling Method (HD); Process parameters; Titanium grade 5. I NTRODUCTION he stress field existing in some materials without application of an external source of stress, such as loads or thermal gradients, is known as residual stress. These residual stresses are generated in almost all manufacturing processes such as machining, grinding, forming, rolling, casting, forging, welding, heat treatment, etc. or may occur during the life of structures. The hole drilling method is one of the most widely used techniques for measuring residual stresses [1, 2]. This technique consists in the localized removal of stressed material and in measuring the strain field consequent to the relieved stresses. The hole drilling method using strain gauge rosettes [3, 4] is a consolidated approach for stress determination and it follows the ASTM test standard [5]. Even though strain gauges are usually used to measure these displacements, they have some disadvantages: the specimen surface has to be flat and smooth so that the rosettes can be attached, the surface of the material has to be accurately prepared, the hole has to be drilled exactly in the center of the rosette in order to avoid eccentricity errors, and time and costs associated with installing rosettes are consistent. Furthermore the amount of available data is limited: for each measurement, only three discrete readings are available (six in the case of some special rosettes), just sufficient to fully characterize the in-plane residual stresses. T

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