The use of acoustic inversion to estimate the bubble size distribution in pipelines

Leighton, Timothy G.; Baik, Kyungmin; Jiang, Jian

doi:10.1098/rspa.2012.0053

Cited by 21 publications

(33 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Humans have spent over a century researching this interaction for a range of applications (Ainslie, Leighton, 2009). These include attempts to derive beneficial effects from bubble acoustics, in fields as diverse as: climate science for air/sea transfer (Thorpe, 1992 ; the processing and monitoring of pharmaceuticals and food (Campbell, Mougeot, 1999;Skumiel et al, 2013), and of fuel and coolant (Leighton et al, 2012a); the generation of microfluidic devices (Carugo et al, 2011); ultrasonic cleaning (Leighton et al, 2005;Offin et al, 2014); and, in biomedicine, the provision of acoustic contrast agents and drug delivery vectors (Ferrara et al, 2007), and the use of cavitation as a therapy monitor (McLaughlan et al, 2010;Leighton et al, 2008a). Studies also include attempts to mitigate or exploit the detrimental effects of bubbles, for example in the cavitation erosion of turbines and propellers Szantyr, Koronowicz, 2006), ship noise and its environmental impact (Kozaczka, Grelowska, 2004;Parks et al, 2007;Grelowska et al, 2013), and the sonar clutter that oceanic bubbles can produce.…”

Section: Introductionmentioning

confidence: 99%

Dolphin-Inspired Target Detection for Sonar and Radar

Leighton¹,

White²

2015

Archives of Acoustics

View full text Add to dashboard Cite

Gas bubbles in the ocean are produced by breaking waves, rainfall, methane seeps, exsolution, and a range of biological processes including decomposition, photosynthesis, respiration and digestion. However one biological process that produces particularly dense clouds of large bubbles, is bubble netting. This is practiced by several species of cetacean. Given their propensity to use acoustics, and the powerful acoustical attenuation and scattering that bubbles can cause, the relationship between sound and bubble nets is intriguing. It has been postulated that humpback whales produce 'walls of sound' at audio frequencies in their bubble nets, trapping prey. Dolphins, on the other hand, use high frequency acoustics for echolocation. This begs the question of whether, in producing bubble nets, they are generating echolocation clutter that potentially helps prey avoid detection (as their bubble nets would do with manmade sonar), or whether they have developed sonar techniques to detect prey within such bubble nets and distinguish it from clutter. Possible sonar schemes that could detect targets in bubble clouds are proposed, and shown to work both in the laboratory and at sea. Following this, similar radar schemes are proposed for the detection of buried explosives and catastrophe victims, and successful laboratory tests are undertaken.

show abstract

Section: Introductionmentioning

confidence: 99%

Dolphin-Inspired Target Detection for Sonar and Radar

Leighton¹,

White²

2015

Archives of Acoustics

View full text Add to dashboard Cite

show abstract

“…This is because the liquid and pipe are acoustically coupled 20,21 and because, over most of the frequency range of interest in some pipe systems (such as SNS), modal acoustic propagation occurs with distinct frequencydependent sound speeds and attenuations for each mode. The current authors 10 showed that errors of þ/À 1000% can occur when such an approach is followed in a pipe of similar dimension to that used in the SNS at Oak Ridge National Laboratory (ORNL). Further complications occur with the acoustic inversion techniques that are based on the bubble pulsation resonance since the pipe can alter the inertia, 17,[22][23][24] frequency, 25 and damping 26 of that bubble resonance.…”

Section: Introductionmentioning

confidence: 99%

“…7 Recently, detectors for helium bubbles in steel pipelines filled with liquid mercury have been investigated for a spallation neutron source (SNS). [8][9][10] The ability to control the bubble size distribution, and to generate and detect a broad range of acoustic frequencies with controlled and calibrated amplitude in order to measure the bubble population, is however more characteristic of the laboratory than of industry.…”

Section: Introductionmentioning

confidence: 99%

“…Here, the coupling between liquid and wall generates similar effects to the coupling seen in SNS TTF. 20,21 Having therefore (i) characterized the bubble-free baseline 20,21 and (ii) shown that application of the "free field" inversion method (when bubbles are added) can produce overcounts and undercounts of þ/À 1000% in bubble numbers, 10 a new inversion was produced that is applicable to data taken in pipes. 10 The plan to implement this inversion with a broadband acoustic source was, however, interrupted: mid-way through this study the new funding pressure on the sponsors made the planned 1-1000 kHz frequency range unaffordable.…”

Section: Introductionmentioning

confidence: 99%

“…The initial intention was to invert the measured sound speeds and attenuation across this frequency range to obtain an estimation of the bubble population. 10 The first stage of this was to characterize propagation in bubble-free pipelines at SNS TTF, which further showed that useful data could be taken on 1:1 scale model pipelines built of water-filled polymethylmethacrylate (PMMA) pipes (Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Investigation of a method for real time quantification of gas bubbles in pipelines

Baik

Leighton

Jiang

2014

The Journal of the Acoustical Society of America

View full text Add to dashboard Cite

The need to measure the dynamic void fraction (the proportion of flowing bubbly liquid that is gas) is common across many power, processing and manufacturing industries. Many such pipelines and liquids are optically opaque, and work on margins that require a low cost solution that is not commensurate with the size of the challenge. Such a solution will therefore be a compromise, and in this paper costs are reduced by using a narrowband acoustic solution that cannot, on its own, contain enough information to characterize the void fraction in real time unambiguously. The ambiguity is reduced using likely estimates of the general shape of the bubble size distribution so that, with a single sourcereceiver pair attached to the outside of the pipe, the absolute gas content can be estimated. While the data that are required a priori (the general shape of the bubble size distribution) are not identical to the output of the inversion (the absolute void fraction of gas entrained as bubbles in the flow), the requirement for such a priori information could limit the usefulness of the technique in industry.

show abstract

Determination of bubble size distribution in gas–liquid two‐phase systems via an ultrasound‐based method

Chen

Hussein

Becker

2017

Engineering in Life Sciences

View full text Add to dashboard Cite

Over the past few years, ultrasonic techniques are increasingly used to determine bubble size distribution in gas-liquid two-phase systems. However, the development of a precise and efficient measuring system is very challenging because bubbles are dynamic and unstable relative to time and space in a moving fluid, thus hindering an accurate validation of the measuring system. Therefore, this study examined the possibility of using artificial bubbles to establish an ultrasonic measuring system. The main concept for this study involved developing an ultrasound-based measuring system with the aid of a certain type of artificial bubbles. The developed system was subsequently adapted to the bypass pipeline of a propagator to demonstrate the reliability of this concept. The results indicated that the established system could measure a microbubble size distribution with a root mean squared error of validation that corresponded to 0.1243 % v/v. Additionally, the estimates of real bubble measurement agreed well with the reference method. Thus, this study demonstrated that the developed system could be a potential method to determine bubble size distributions in gas-liquid two-phase systems.

show abstract

The use of acoustic inversion to estimate the bubble size distribution in pipelines

Cited by 21 publications

References 38 publications

Dolphin-Inspired Target Detection for Sonar and Radar

Dolphin-Inspired Target Detection for Sonar and Radar

Investigation of a method for real time quantification of gas bubbles in pipelines

Determination of bubble size distribution in gas–liquid two‐phase systems via an ultrasound‐based method

Contact Info

Product

Resources

About