A theoretical estimation of the pre-breakdown-heating time in the underwater discharge acoustic source

Wang, Yibo; Shang-wu, Wang; Zeng, Xinwu

doi:10.1088/1674-1056/21/5/055203

Cited by 6 publications

(7 citation statements)

References 15 publications

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“…The second phase, which shows an intense oscillation, is the post-breakdowndischarge phase. According to our previous study [6], when the gap interval is fixed, the intensity of the shockwave in electro-thermal breakdown mainly lies on the temperature of the discharge arc, which mainly lies on the remaining voltage after the pre-breakdown-heating phase (U B in Fig.2). Fig.1 The main setup of the underwater puse discharge device Fig.2 The evolution of the voltage on the underwater gap [7] A good electrode for the electro-thermal breakdown with a fixed gap interval, should reduces the energy leakage in its affiliate area and raise the remaining voltage.…”

Section: Physics Modelingmentioning

confidence: 87%

“…In the pre-breakdownheating phase, an amount of energy must be deposited to the underwater gap from the external circuit, and the temperature of the gap water must be raised to a threshold value, which can be regarded as one of the necessary conditions for the succeeding breakdown. In our previous study [6], that threshold temperature is estimated to be 800K. However, that estimation is not accurate, because the figure of the electrode is out of consideration and the electric field in the underwater gap is assumed to be a homogeneous field.…”

Section: Introductionmentioning

confidence: 99%

“…According to our previous study [5], most of the underwater discharge devices are operated in a "electro-thermal breakdown" mode, which usually happens in conductive water under a weak electric field of 10 kV/cm order. The characteristic of the electro-thermal breakdown is that there exists a pre-breakdown-heating phase before breakdown, which may last 100μs~1ms.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A COMSOL modeling of the pre-breakdown heating phase in the electro-thermal breakdown of conductive water

Wang¹,

Liao²,

Zhang³

et al. 2016

Proceedings of the 2016 3rd International Conference on Materials Engineering, Manufacturing Technology and Control

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Section: Physics Modelingmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A COMSOL modeling of the pre-breakdown heating phase in the electro-thermal breakdown of conductive water

Wang¹,

Liao²,

Zhang³

et al. 2016

Proceedings of the 2016 3rd International Conference on Materials Engineering, Manufacturing Technology and Control

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show abstract

“…However, for the prebreakdown process, the main factors affecting the prebreakdown time include the synchronization of trigger switches, the distance between discharge electrodes, discharge voltage, discharge current, conductivity, and so on. Secondly, discharge electrode material, discharge electrode structure (tip-tip or tip-plate structure), water temperature, and other factors will also affect the prebreakdown time [20][21][22][23][24]. In the experimental study, it is assumed that the trigger switch has good synchronization performance, and the discharge electrode adopts a tip-to-tip structure, which can reduce the discreteness of plasma channel formation.…”

Section: Analysis Of Prebreakdown Processmentioning

confidence: 99%

Effect of Prebreakdown Time on Shock Wave Generation Characteristics of Underwater Plasma Sound Source

Liu

Lin

Lei

2022

Mathematical Problems in Engineering

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Acoustic array bunching is an effective method to realize the directional radiation of underwater plasma sound source (UPSS). The prebreakdown time is one of the decisive factors for the performance of acoustic array bunching. The working characteristics of the underwater plasma sound source and the prebreakdown process of underwater plasma arc discharge are deeply analyzed. The precondition of plasma sound source array bunching is given by analyzing the waveforms of electrical signals and acoustic signals. Through the experiments of arc discharge based on different aqueous solutions, a feasible scheme of underwater plasma sound source array bunching in salt water is proposed. Through the arc discharge experiments based on different system discharge parameters, the variation of prebreakdown time under the influence of different charging voltage, conductivity, and other parameters was studied. The experimental results show that the prebreakdown time decreases with the increase of charging voltage and conductivity. At the same time, the discharge current increases, the oscillation time decreases, and the energy injection rate on the electrode accelerates. The research results are helpful to understand the prebreakdown mechanism of plasma sound source and optimize the underwater plasma sound source array bunching scheme and the acoustic shock wave waveform.

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“…When a voltage pulse is applied to the electrodes underwater, the water medium between two electrodes cannot be broken down immediately. At the first phase, the electrodes are surrounded with the border water, which is heated by the initial arc and the Joule heating form the ionic current [29]. When the temperature of the border water reaches a threshold value (773 K) [29], the thermal kinetic energy of the water molecules will be enough to overcome the hydrogen bonds.…”

Section: Applied Voltage Waveformmentioning

confidence: 99%

Electric characteristic and cavitation bubble dynamics using underwater pulsed discharge

Shan

Chen²,

Yao

et al. 2019

Plasma Sci. Technol.

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Underwater pulsed discharge is widely applied in medicine, machining, and material modification. The induced cavitation bubble and subsequent cavitation collapse are considered the major motivations behind these applications. This paper presents an underwater pulsed discharge system. The experimental setup is established to induce and investigate the cavitation bubble assisted with a high-speed camera. Three aspects, including the characteristic of the discharge with different applied voltages and conductivities, the evolution of the cavitation bubble profile, and the energy efficiency of cavitation bubble inducing, are investigated, respectively. Especially, the mechanism of pre-discharge time delay in the low field intensity case is explained using the Joule heat effect. The results show the validity of the underwater pulsed discharger and experimental setup. The present underwater pulsed discharger is proved to be a simple, portable, and easy-to-implement device for the investigation of cavitation bubble dynamics.

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A theoretical estimation of the pre-breakdown-heating time in the underwater discharge acoustic source

Cited by 6 publications

References 15 publications

A COMSOL modeling of the pre-breakdown heating phase in the electro-thermal breakdown of conductive water

A COMSOL modeling of the pre-breakdown heating phase in the electro-thermal breakdown of conductive water

Effect of Prebreakdown Time on Shock Wave Generation Characteristics of Underwater Plasma Sound Source

Electric characteristic and cavitation bubble dynamics using underwater pulsed discharge

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