Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets
Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence...
Ausführliche Beschreibung
Gespeichert in:
| Autor*in: |
PENG, Kewen [verfasserIn] |
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| Format: |
E-Artikel |
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| Sprache: |
Englisch |
| Erschienen: |
2018transfer abstract |
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| Schlagwörter: |
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| Umfang: |
8 |
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| Übergeordnetes Werk: |
Enthalten in: 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery - 2012, Amsterdam [u.a.] |
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| Übergeordnetes Werk: |
volume:45 ; year:2018 ; number:2 ; pages:343-350 ; extent:8 |
| Links: |
|---|
| DOI / URN: |
10.1016/S1876-3804(18)30038-7 |
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ELV042660521 |
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| 245 | 1 | 0 | |a Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets |
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| 520 | |a Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. | ||
| 520 | |a Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. | ||
| 650 | 7 | |a cavitating bubble |2 Elsevier | |
| 650 | 7 | |a collapse intensity |2 Elsevier | |
| 650 | 7 | |a hydraulic parameters |2 Elsevier | |
| 650 | 7 | |a self-resonating cavitating jet |2 Elsevier | |
| 650 | 7 | |a fluid properties |2 Elsevier | |
| 700 | 1 | |a TIAN, Shouceng |4 oth | |
| 700 | 1 | |a LI, Gensheng |4 oth | |
| 700 | 1 | |a HUANG, Zhongwei |4 oth | |
| 700 | 1 | |a YANG, Ruiyue |4 oth | |
| 700 | 1 | |a GUO, Zhaoquan |4 oth | |
| 773 | 0 | 8 | |i Enthalten in |n Elsevier |t 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery |d 2012 |g Amsterdam [u.a.] |w (DE-627)ELV016100263 |
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10.1016/S1876-3804(18)30038-7 doi GBV00000000000197A.pica (DE-627)ELV042660521 (ELSEVIER)S1876-3804(18)30038-7 DE-627 ger DE-627 rakwb eng 620 660 620 DE-600 660 DE-600 610 VZ 670 VZ 35.80 bkl PENG, Kewen verfasserin aut Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets 2018transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. cavitating bubble Elsevier collapse intensity Elsevier hydraulic parameters Elsevier self-resonating cavitating jet Elsevier fluid properties Elsevier TIAN, Shouceng oth LI, Gensheng oth HUANG, Zhongwei oth YANG, Ruiyue oth GUO, Zhaoquan oth Enthalten in Elsevier 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery 2012 Amsterdam [u.a.] (DE-627)ELV016100263 volume:45 year:2018 number:2 pages:343-350 extent:8 https://doi.org/10.1016/S1876-3804(18)30038-7 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U GBV_ILN_20 35.80 Makromolekulare Chemie VZ AR 45 2018 2 343-350 8 045F 620 |
| spelling |
10.1016/S1876-3804(18)30038-7 doi GBV00000000000197A.pica (DE-627)ELV042660521 (ELSEVIER)S1876-3804(18)30038-7 DE-627 ger DE-627 rakwb eng 620 660 620 DE-600 660 DE-600 610 VZ 670 VZ 35.80 bkl PENG, Kewen verfasserin aut Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets 2018transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. cavitating bubble Elsevier collapse intensity Elsevier hydraulic parameters Elsevier self-resonating cavitating jet Elsevier fluid properties Elsevier TIAN, Shouceng oth LI, Gensheng oth HUANG, Zhongwei oth YANG, Ruiyue oth GUO, Zhaoquan oth Enthalten in Elsevier 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery 2012 Amsterdam [u.a.] (DE-627)ELV016100263 volume:45 year:2018 number:2 pages:343-350 extent:8 https://doi.org/10.1016/S1876-3804(18)30038-7 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U GBV_ILN_20 35.80 Makromolekulare Chemie VZ AR 45 2018 2 343-350 8 045F 620 |
| allfields_unstemmed |
10.1016/S1876-3804(18)30038-7 doi GBV00000000000197A.pica (DE-627)ELV042660521 (ELSEVIER)S1876-3804(18)30038-7 DE-627 ger DE-627 rakwb eng 620 660 620 DE-600 660 DE-600 610 VZ 670 VZ 35.80 bkl PENG, Kewen verfasserin aut Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets 2018transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. cavitating bubble Elsevier collapse intensity Elsevier hydraulic parameters Elsevier self-resonating cavitating jet Elsevier fluid properties Elsevier TIAN, Shouceng oth LI, Gensheng oth HUANG, Zhongwei oth YANG, Ruiyue oth GUO, Zhaoquan oth Enthalten in Elsevier 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery 2012 Amsterdam [u.a.] (DE-627)ELV016100263 volume:45 year:2018 number:2 pages:343-350 extent:8 https://doi.org/10.1016/S1876-3804(18)30038-7 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U GBV_ILN_20 35.80 Makromolekulare Chemie VZ AR 45 2018 2 343-350 8 045F 620 |
| allfieldsGer |
10.1016/S1876-3804(18)30038-7 doi GBV00000000000197A.pica (DE-627)ELV042660521 (ELSEVIER)S1876-3804(18)30038-7 DE-627 ger DE-627 rakwb eng 620 660 620 DE-600 660 DE-600 610 VZ 670 VZ 35.80 bkl PENG, Kewen verfasserin aut Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets 2018transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. cavitating bubble Elsevier collapse intensity Elsevier hydraulic parameters Elsevier self-resonating cavitating jet Elsevier fluid properties Elsevier TIAN, Shouceng oth LI, Gensheng oth HUANG, Zhongwei oth YANG, Ruiyue oth GUO, Zhaoquan oth Enthalten in Elsevier 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery 2012 Amsterdam [u.a.] (DE-627)ELV016100263 volume:45 year:2018 number:2 pages:343-350 extent:8 https://doi.org/10.1016/S1876-3804(18)30038-7 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U GBV_ILN_20 35.80 Makromolekulare Chemie VZ AR 45 2018 2 343-350 8 045F 620 |
| allfieldsSound |
10.1016/S1876-3804(18)30038-7 doi GBV00000000000197A.pica (DE-627)ELV042660521 (ELSEVIER)S1876-3804(18)30038-7 DE-627 ger DE-627 rakwb eng 620 660 620 DE-600 660 DE-600 610 VZ 670 VZ 35.80 bkl PENG, Kewen verfasserin aut Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets 2018transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. cavitating bubble Elsevier collapse intensity Elsevier hydraulic parameters Elsevier self-resonating cavitating jet Elsevier fluid properties Elsevier TIAN, Shouceng oth LI, Gensheng oth HUANG, Zhongwei oth YANG, Ruiyue oth GUO, Zhaoquan oth Enthalten in Elsevier 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery 2012 Amsterdam [u.a.] (DE-627)ELV016100263 volume:45 year:2018 number:2 pages:343-350 extent:8 https://doi.org/10.1016/S1876-3804(18)30038-7 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U GBV_ILN_20 35.80 Makromolekulare Chemie VZ AR 45 2018 2 343-350 8 045F 620 |
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Enthalten in 178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery Amsterdam [u.a.] volume:45 year:2018 number:2 pages:343-350 extent:8 |
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178 Final office evaluation findings in E-SISTER participants at one center: A glimpse into the long-term results of stress incontinence surgery |
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PENG, Kewen @@aut@@ TIAN, Shouceng @@oth@@ LI, Gensheng @@oth@@ HUANG, Zhongwei @@oth@@ YANG, Ruiyue @@oth@@ GUO, Zhaoquan @@oth@@ |
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bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets |
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Bubble dynamics characteristics and influencing factors on the cavitation collapse intensity for self-resonating cavitating jets |
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Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. |
| abstractGer |
Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. |
| abstract_unstemmed |
Based on bubble dynamics theory, a mathematic model describing the cavitation bubble size variation in the flow field of self-resonating cavitating jet was developed considering the pressure field and mass and heat exchange between cavitation bubble and ambient fluid. With this model, the influence factors on the cavitation intensity are investigated. The results show that the destructiveness of cavitating jet in breaking rocks depends on the bubble's first collapse, with decreasing intensity in the subsequent collapses. The self-resonating effect significantly enhances the cavitation intensity by promoting the collapse pressure and elongating its duration. Hydraulic parameters are proven to be the dominating factors influencing cavitation intensity: while collapse intensity monotonously increases with jet velocity, there exists an optimum ambient pressure where highest collapse intensity can be achieved. Conversely, the fluid properties show minor influences: cavitation intensity only slightly decreases with the increasing of fluid's density and barely changes with the variation of viscosity and surface tension. The results from this investigation help to uncover the mechanism of the enhanced erosion potential of self-resonating cavitating jet. The conclusions can be used to further improve the performance of self-resonating cavitating jet in field applications. |
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