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Comparison of Different Techniques for Characterizing the Diesel Injector Internal Dimensions

  • F. J. Salvador
  • J. Gimeno
  • J. De la Morena
  • M. Carreres
Article

Abstract

The geometry of certain parts of diesel injectors is key to the injection, atomization and fuel-air mixing phenomena. Small variations on the geometrical parameters may have a strong influence on the aforementioned processes. Thus, OEMs need to assess their manufacturing tolerances, whereas researchers in the field (both experimentalists and modelers) rely on the accuracy of a certain metrology technique for their studies. In the current paper, an investigation of the capability of different experimental techniques to determine the geometry of a modern diesel fuel injector has been performed. For this purpose, three main elements of the injector have been evaluated: the control volume inlet and outlet orifices, together with the nozzle orifices. While the direct observation of the samples through an optical microscope is only possible for the simplest pieces, both Computed Tomography Scanning and the visualization of silicone molds technique have proven their ability to characterize the most complex internal shapes corresponding to the internal injector elements. Indeed, results indicate that the differences observed among these methodologies for the determination of the control volume inlet orifice diameter and the nozzle orifice dimensions are smaller than the uncertainties related to the experimental techniques, showing that they are both equally accurate. This implies that the choice of a given technique for the particular application of determining the geometry of diesel injectors can be done on the basis of availability, intrusion and costs, rather than on its accuracy.

Keywords

Injector Metrology Orifices 

Notes

Acknowledgements

This work was partly sponsored by "Ministerio de Econom ía y Competitividad", of the Spanish Government, in the frame of the Project "Estudio de la interacción chorro-pared en condiciones realistas de motor", Reference TRA2015-67679-c2-1-R.

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Copyright information

© The Society for Experimental Mechanics, Inc 2018

Authors and Affiliations

  • F. J. Salvador
    • 1
  • J. Gimeno
    • 1
  • J. De la Morena
    • 1
  • M. Carreres
    • 1
  1. 1.CMT-Motores TérmicosUniversitat Politècnica de ValènciaValenciaSpain

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