Cavitation Bubble Dynamics in Ammoniacal Fluids Transferred by Centrifugal Pumps

Authors

  • Jorge Reyes-Cruz
  • Gerardo Ruiz-Chavarría Universidad Nacional Autónoma de México
  • Roilber Lambert-Sánchez ISMM
  • Alberto Turro-Breff Centro Universitario de Guantánamo
  • Enrique Torres-Tamayo ISMM
  • Sergio Hernández-Zapata Universidad Nacional Autónoma de México

Keywords:

centrifugal pumps, cavitation, bubble formation, flow patterns, ammoniacal liquor.

Abstract

An experiment with water and ammoniacal liquor at 27% and 34% concentrations of ammonia was carried out in order to determine the pressure dynamics during the formation of bubbles and their movement when causing cavitations in centrifugal pumps. The dynamics of bubbles was calculated numerically by applying the Rayleigh-Plesset equation using the bubble radius and the bubble build-up time. It is concluded that the pressure to form the bubbles at 22 ºC is 10,135.103 Pa for water and 45,468.103 Pa for the ammoniacal liquor at a concentration of 34 %. The radius of the bubbles found in ammoniacal liquor is in the range of 30 to 120 times the original bubble radius while the bubbles formed in water are only in the range of 15 times the original radius value.

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Author Biography

Jorge Reyes-Cruz

Departamento de Mecánica

References

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Published

2016-10-12

How to Cite

Reyes-Cruz, J., Ruiz-Chavarría, G., Lambert-Sánchez, R., Turro-Breff, A., Torres-Tamayo, E., & Hernández-Zapata, S. (2016). Cavitation Bubble Dynamics in Ammoniacal Fluids Transferred by Centrifugal Pumps. Minería & Geología, 32(3), 128–146. Retrieved from https://revista.ismm.edu.cu/index.php/revistamg/article/view/art9_No3_2016

Issue

Vol. 32 No. 3 (2016): Julio-Septiembre

Section

Metalurgia extractiva
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