Pressure oscillation and steam cavity during the condensation of a submerged steam jet

Zhao, Quanbin; Chen, Weixiong; Yuan, Fang; Wang, Wei; Chong, Daotong; Yan, Junjie

doi:10.1016/j.anucene.2015.05.032

Cited by 34 publications

(7 citation statements)

References 29 publications

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“…The oscillation power comparisons of the first and the second frequency bands revealed that, under the test condition, when air mass fraction increases from A=0% to A=5%, the maximum oscillation power of the second frequency band is always higher than that of the first frequency band, as shown in figure 17. This finding is similar to the results reported by Zhao et al(2015). However, after A>1%, the oscillation power gap between the two frequency bands decreases with the rise of air mass fraction.…”

Section: Oscillation Powersupporting

confidence: 91%

“…The axial position of the oscillation peak also moves downstream gradually with rise of air mass fraction. As reported by Zhao et al (2015), the oscillation intensity peak is located at the end of the steam cavity. When air mass fraction increases, heat transfer coefficient of the steam-water interface decreases considerably (Choi et al, 2002;Liang and Griffith, 1994).…”

Section: Condensation Oscillation Intensitysupporting

confidence: 61%

“…When water temperature is about 40-45 °C, it decreases suddenly. When water temperature is above 45 °C, oscillation intensity increases again (Zhao et al, 2015). In addition, the effect of air mass fraction on pressure oscillation intensity is investigated.…”

Section: Condensation Oscillation Intensitymentioning

confidence: 99%

“…Chong et al (2015) proved that the second dominant frequency has always existed in the SC region, and the oscillation power of the second dominant frequency band was larger than that of the first dominant frequency band. Zhao et al (2015) investigated the distribution characteristic of condensation oscillation intensity at sonic jet condensation. They found that along jet direction, an oscillation intensity peak exists.…”

Section: Introductionmentioning

confidence: 99%

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Effect of non-condensation gas on pressure oscillation of submerged steam jet condensation

Zhao

Wang

et al. 2016

Nuclear Engineering and Design

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The effect of air with low mass fraction on the oscillation intensity and oscillation frequency of a submerged steam jet condensation is investigated under stable condensation region. With air mixing in steam, an obvious dynamic pressure peak appears along the jet direction. The intensity peak increases monotonously with the rise of steam mass flux and water temperature. Peak position moves downstream with the rise of air mass fraction. Moreover, when compared with that of pure steam jet, the oscillation intensity clearly decreases as air is mixed. However, when water temperature is lower than approximately 45 °C, oscillation intensity increases slightly with the rise of air mass fraction, and when water temperature is higher than 55 °C, the oscillation intensity decreases greatly with the rise of air mass fraction. Both the first and second dominant frequencies decrease with rise of air mass fraction. Finally, effect of air mass fractions on the oscillation power of the first and second dominant frequency bands shows similar trends. Under low water temperature, the mixed air has little effect on the oscillation power of both first and second frequency bands. However, when water temperature is high, the oscillation power of both first and second frequency bands appears an obvious peak when air mass fraction is about 1%. With further rise of air mass fraction, the oscillation power decreases gradually.

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Section: Oscillation Powersupporting

confidence: 91%

Section: Condensation Oscillation Intensitysupporting

confidence: 61%

Section: Condensation Oscillation Intensitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effect of non-condensation gas on pressure oscillation of submerged steam jet condensation

Zhao

Wang

et al. 2016

Nuclear Engineering and Design

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“…Besides the first domain frequency, the second dominant frequency was found under certain test conditions [19]. Zhao et al [20] investigated the distribution of pressure oscillation intensity and found that its peak at the steam plume tail. Chong et al [21] released that the second dominant frequency was caused by separated steam bubbles.…”

Section: Introductionmentioning

confidence: 99%

Characteristic of pressure oscillation caused by turbulent vortexes and affected region of pressure oscillation

Chen

Zhao

Wang

et al. 2016

Experimental Thermal and Fluid Science

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Submerged steam jet condensation is widely applied in various fields because of its high heat transfer efficiency. Condensation oscillation is a major character of submerged steam turbulent jet, and it significantly affects the design and safe operation of industrial equipment. This study is designed to reveal the mechanism of the low-frequency pressure oscillation of steam turbulent jet condensation and determine its affected region. First, pressure oscillation signals with low frequency are discovered in the downstream flow field through oscillation frequency spectrogram and power analysis. The oscillation frequency is even lower than the first dominant frequency. Moreover, the critical positions, where the low-frequency pressure oscillation signals appear, move downstream gradually with radial distance and water temperature. However, these signals are little affected by the steam mass flux. Then, the regions with low-frequency pressure oscillation occurring are identified experimentally. The affected width of the low-frequency pressure oscillation is similar to the turbulent jet width. Turbulent jet theory and the experiment results collectively indicate that the low-frequency pressure oscillation is generated by turbulent jet vortexes in the jet wake region. Finally, the angular coefficients of the low-frequency affected width are obtained under different water temperatures. Angular coefficients, ranging from 0.2268 to 0.2887, decrease with water temperature under test conditions.

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Entropy and exergy analysis of the steam jet condensation in crossflow of subcooled water

Liu

Zhu

et al. 2023

Annals of Nuclear Energy

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Pressure oscillation and steam cavity during the condensation of a submerged steam jet

Cited by 34 publications

References 29 publications

Effect of non-condensation gas on pressure oscillation of submerged steam jet condensation

Effect of non-condensation gas on pressure oscillation of submerged steam jet condensation

Characteristic of pressure oscillation caused by turbulent vortexes and affected region of pressure oscillation

Entropy and exergy analysis of the steam jet condensation in crossflow of subcooled water

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