Effect of Cavitation Phenomenon on Bubble Collapse in Venturi Tube

In this study, the vacuum bubble collapse in liquid pool has been simulated using MPS code. The liquid is described using moving particles and the bubble-liquid interface was set to be vacuum pressure boundary without interfacial heat mass transfer. The motion and location of interfacial particles can be competent in configurating the topological shape of vacuum bubble. The time dependent bubble diameter, interfacial velocity and bubble collapse time were obtained under wide parametric range. The comparison with Rayleigh’s prediction showed a good agreement which validates the applicability and accuracy on MPS method in solving present momentum problems. The potential void-induced water hammer pressure pulse was also evaluated which is instructive for cavitaion erosion study. The bubble collapse with noncondensable gas has also been simulated and the rebound phenomenon was successfully captured which is similar with vapor-filled cavitation phenomenon. The present study exhibits some fundamental characteristics of vacuum bubble hydrodynamics and it is also expected to be instructive for further applications of MPS method to in complicated bubble dynamics.

Download Full-text

Fluctuation of Void Fraction in the Microbubble Generator With a Venturi Tube

ASME-JSME-KSME 2011 Joint Fluids Engineering Conference: Volume 1, Symposia – Parts A, B, C, and D ◽

10.1115/ajk2011-10014 ◽

2011 ◽

Cited By ~ 3

Author(s):

Shin-ichiro Uesawa ◽

Akiko Kaneko ◽

Yasumichi Nomura ◽

Yutaka Abe

Keyword(s):

Real Time ◽

Void Fraction ◽

Measurement Techniques ◽

Current Method ◽

Electrical Current ◽

Time Measurement ◽

Venturi Tube ◽

Bubble Collapse ◽

Liquid Volume ◽

Real Time Measurement

Microbubbles are tiny bubbles with less than 1 mm diameter. These bubbles are utilized in various engineering fields, and it is very important to understand physics of flow with microbubbles. Especially, void fraction is one of the significant parameter for two-phase flow. Thus, developments of real-time measurement systems of void fraction are required. In the nuclear power engineering, electrical void fraction measurement methods have been proposed as one of the real-time measurement techniques. In the present study, we apply this method to a microbubble generator with a venturi tube and examine the performance of the generator. Constant electrical current method is adopted as electrical measurement method of void fraction. Microbubbles are generated with a bubble collapse phenomenon through a venturi tube. We can generate microbubbles in high void fraction. However, mechanism of bubble collapse in a ventrui tube is not made clear and void fraction distribution toward flow direction is less understood. The applicability of constant electrical current method in bubbly flow and the process of the bubble breakup in a venturi tube are discussed. In this experiment, a voltage between two electrodes in the generator is measured with various gas-liquid volume flows as inlet conditions. From results we succeeded to measure the void fraction profile in the venturi tube with constant electrical current method. The void fractions achieve a peak before the bubble collapse and it decreased drastically for 10 mm after collapse.

Download Full-text

Bubble Collapse and Flow Characteristics in Bubble Flow in a Venturi Tube

JAPANESE JOURNAL OF MULTIPHASE FLOW ◽

10.3811/jjmf.2019.002 ◽

2019 ◽

Vol 33 (1) ◽

pp. 46-54 ◽

Cited By ~ 1

Author(s):

Keita FUJII ◽

Akiko KANEKO ◽

Yutaka ABE ◽

Masatoshi IKE

Keyword(s):

Flow Characteristics ◽

Venturi Tube ◽

Bubble Collapse ◽

Bubble Flow

Download Full-text

The Boundary Integral Method Applied to Non-Spherical Cavitation Bubble Growth and Collapse Close to a Rigid Boundary

Volume 8A: Heat Transfer and Thermal Engineering ◽

10.1115/imece2015-51687 ◽

2015 ◽

Author(s):

Ali Alhelfi ◽

Bengt Sunden

Keyword(s):

Cavitation Bubble ◽

Integral Method ◽

Bubble Dynamics ◽

Boundary Integral ◽

Solid Surfaces ◽

Boundary Integral Method ◽

Bubble Collapse ◽

Surface Erosion ◽

Rigid Boundary ◽

Cavitation Phenomenon

Recently much attention has been paid to studies concerning bubble dynamics in the cavitation phenomena and this topic has been the subject of many research works. In fact, the simulation of non-spherical bubble dynamics and its interaction with solid boundaries have received much less attention due to the complexity of the problem. One of the main reasons of the structural damages in the cavitation phenomenon is due to the formation of micro jets generated due to the bubble collapse and impinging on the solid surfaces or boundaries. The boundary integral method (BIM) based on Green’s function is used to model the oscillation and collapse of a cavitation bubble close to a rigid boundary. The liquid is considered to be incompressible, inviscid, and irrational around the bubble. These assumptions satisfy the conditions for the Laplacian equation. The theory permits one to predict correctly the interaction between the bubble and the rigid boundary, which is of great importance in the study of cavitation damage due to a bubble collapsing close to the boundaries. The results reveal that the amplitude of bubble oscillation depends on the bubble location away from a rigid surface. Also, the theory for the cavitation bubble dynamics presented in this study has many advantages in various situations and might be helpful to understand effects of the cavitation phenomenon such as generation of excessive vibration, surface erosion and undesirable acoustic emission.

Download Full-text