This thesis work primarily focusses on the study of the structure and development of the free jet generated though the round air jet nozzle. It also involves the study of the velocity fields generated by round jet at the nozzle exit velocity 5.67 m/s and with corresponding Reynolds number of 3070.The investigation was carried out in 2D (stereo PIV) and 3D (Tomo PIV). The scope of the study was further extended to understand the characteristics of all three velocity components in the developing shear layer and deriving the pressure fields over the space using the available velocity field data. Pulsed laser sheets were aligned such that it illuminates the centreline plane of the jet. The set-up was calibrated to translate the resulting pixel displacements into X, Y, and Z velocity components. The measurement was done with varying the laser power and varying the laser pulse time i.e. delay time. For measurement of the Tomo PIV the volume optics were used also volume self-calibration were carried out. The tracer particles used in the experiment were generated from the vegetable oil and compressed air was used for providing the necessary acceleratory movement to the particles.
The result helped to study the different structures and development of the free jet along its centreline axis direction. The velocity range over entire field and pressure variations along the streamline axis are discussed. The maximum particle velocity was found to be 25 m/s in the jet core.
Annotation in English
This thesis work primarily focusses on the study of the structure and development of the free jet generated though the round air jet nozzle. It also involves the study of the velocity fields generated by round jet at the nozzle exit velocity 5.67 m/s and with corresponding Reynolds number of 3070.The investigation was carried out in 2D (stereo PIV) and 3D (Tomo PIV). The scope of the study was further extended to understand the characteristics of all three velocity components in the developing shear layer and deriving the pressure fields over the space using the available velocity field data. Pulsed laser sheets were aligned such that it illuminates the centreline plane of the jet. The set-up was calibrated to translate the resulting pixel displacements into X, Y, and Z velocity components. The measurement was done with varying the laser power and varying the laser pulse time i.e. delay time. For measurement of the Tomo PIV the volume optics were used also volume self-calibration were carried out. The tracer particles used in the experiment were generated from the vegetable oil and compressed air was used for providing the necessary acceleratory movement to the particles.
The result helped to study the different structures and development of the free jet along its centreline axis direction. The velocity range over entire field and pressure variations along the streamline axis are discussed. The maximum particle velocity was found to be 25 m/s in the jet core.
Keywords
Development of free jet,nozzle geometry,Tomo-PIV,stereo PIV,continual jet,vorticity,pressure distribution,tracer particle,PIV errror,PIV uncertainity quantification
Keywords in English
Development of free jet,nozzle geometry,Tomo-PIV,stereo PIV,continual jet,vorticity,pressure distribution,tracer particle,PIV errror,PIV uncertainity quantification
Length of the covering note
73p. (14 622 characters)
Language
AN
Annotation
This thesis work primarily focusses on the study of the structure and development of the free jet generated though the round air jet nozzle. It also involves the study of the velocity fields generated by round jet at the nozzle exit velocity 5.67 m/s and with corresponding Reynolds number of 3070.The investigation was carried out in 2D (stereo PIV) and 3D (Tomo PIV). The scope of the study was further extended to understand the characteristics of all three velocity components in the developing shear layer and deriving the pressure fields over the space using the available velocity field data. Pulsed laser sheets were aligned such that it illuminates the centreline plane of the jet. The set-up was calibrated to translate the resulting pixel displacements into X, Y, and Z velocity components. The measurement was done with varying the laser power and varying the laser pulse time i.e. delay time. For measurement of the Tomo PIV the volume optics were used also volume self-calibration were carried out. The tracer particles used in the experiment were generated from the vegetable oil and compressed air was used for providing the necessary acceleratory movement to the particles.
The result helped to study the different structures and development of the free jet along its centreline axis direction. The velocity range over entire field and pressure variations along the streamline axis are discussed. The maximum particle velocity was found to be 25 m/s in the jet core.
Annotation in English
This thesis work primarily focusses on the study of the structure and development of the free jet generated though the round air jet nozzle. It also involves the study of the velocity fields generated by round jet at the nozzle exit velocity 5.67 m/s and with corresponding Reynolds number of 3070.The investigation was carried out in 2D (stereo PIV) and 3D (Tomo PIV). The scope of the study was further extended to understand the characteristics of all three velocity components in the developing shear layer and deriving the pressure fields over the space using the available velocity field data. Pulsed laser sheets were aligned such that it illuminates the centreline plane of the jet. The set-up was calibrated to translate the resulting pixel displacements into X, Y, and Z velocity components. The measurement was done with varying the laser power and varying the laser pulse time i.e. delay time. For measurement of the Tomo PIV the volume optics were used also volume self-calibration were carried out. The tracer particles used in the experiment were generated from the vegetable oil and compressed air was used for providing the necessary acceleratory movement to the particles.
The result helped to study the different structures and development of the free jet along its centreline axis direction. The velocity range over entire field and pressure variations along the streamline axis are discussed. The maximum particle velocity was found to be 25 m/s in the jet core.
Keywords
Development of free jet,nozzle geometry,Tomo-PIV,stereo PIV,continual jet,vorticity,pressure distribution,tracer particle,PIV errror,PIV uncertainity quantification
Keywords in English
Development of free jet,nozzle geometry,Tomo-PIV,stereo PIV,continual jet,vorticity,pressure distribution,tracer particle,PIV errror,PIV uncertainity quantification
Research Plan
Make the "state of art" of the problem.
Perform the velocity fields experiments with the 3D PIV and evaluate the pressure fields.
Analyze the data and do the comparison with the literature.
Research Plan
Make the "state of art" of the problem.
Perform the velocity fields experiments with the 3D PIV and evaluate the pressure fields.
Analyze the data and do the comparison with the literature.
Recommended resources
\matsymb{lbrack}1\matsymb{rbrack} {WIENEKE, Bernhard. PIV Uncertainty Quantification and Beyond.} Unpublished {[online]. 2017 [vid. 2019-04-25]. Dostupné z: doi:10.13140/rg.2.2.26244.42886}
\matsymb{lbrack}2\matsymb{rbrack} {NEETESON, N. J., S. BHATTACHARYA, D. E. RIVAL, D. MICHAELIS, D. SCHANZ a A. SCHRÖDER. Pressure-field extraction from Lagrangian flow measurements: first experiences with 4D-PTV data.} Experiments in Fluids {[online]. 2016, 57(6) [vid. 2019-04-25]. ISSN 0723-4864, 1432-1114. Dostupné z: doi:10.1007/s00348-016-2170-4}
Recommended resources
\matsymb{lbrack}1\matsymb{rbrack} {WIENEKE, Bernhard. PIV Uncertainty Quantification and Beyond.} Unpublished {[online]. 2017 [vid. 2019-04-25]. Dostupné z: doi:10.13140/rg.2.2.26244.42886}
\matsymb{lbrack}2\matsymb{rbrack} {NEETESON, N. J., S. BHATTACHARYA, D. E. RIVAL, D. MICHAELIS, D. SCHANZ a A. SCHRÖDER. Pressure-field extraction from Lagrangian flow measurements: first experiences with 4D-PTV data.} Experiments in Fluids {[online]. 2016, 57(6) [vid. 2019-04-25]. ISSN 0723-4864, 1432-1114. Dostupné z: doi:10.1007/s00348-016-2170-4}
Enclosed appendices
No
Appendices bound in thesis
graphs, tables
Taken from the library
Yes
Full text of the thesis
Appendices
Reviewer's report
Supervisor's report
Defence procedure record
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