Bradley et al., 1972 - Google Patents
Explosive interaction of molten metals injected into waterBradley et al., 1972
- Document ID
- 13113734247291168803
- Author
- Bradley R
- Witte L
- Publication year
- Publication venue
- Nuclear Science and Engineering
External Links
Snippet
A high-speed photographic investigation established the general nature of the explosive interaction between hot molten metal jets and subcooled (75° F) distilled water. The photographic sequences yielded basic information concerning the relationship between …
- 239000002360 explosive 0 title abstract description 52
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Bradley et al. | Explosive interaction of molten metals injected into water | |
| Cole | Boiling nucleation | |
| Baker Jr et al. | Studies of metal-water reactions at high temperatures. III. Experimental and theoretical studies of the zirconium-water reaction | |
| Abe et al. | Study on thermal-hydraulic behavior during molten material and coolant interaction | |
| Manickam et al. | On the fragmentation characteristics of melt jets quenched in water | |
| Cheng et al. | Experimental investigation on the characteristics of melt jet breakup in water: The importance of surface tension and Rayleigh-Plateau instability | |
| Manickam et al. | On the influence of water subcooling and melt jet parameters on debris formation | |
| Zvirin et al. | Boiling on free-falling spheres: drag and heat transfer coefficients | |
| Spencer et al. | Effect of boiling regime on melt stream breakup in water | |
| Song et al. | A use of prototypic material for the investigation of severe accident progression | |
| Henry et al. | Nucleation processes in large scale vapor explosions | |
| Zhang et al. | Energy transfer and interaction between liquid metal with water | |
| Simons et al. | The effect of vapour formation and metal droplet temperature and mass on vapour explosion behaviour | |
| Nettleton | Shock-wave chemistry in dusty gases and fogs: a review | |
| Song et al. | Insights from the recent steam explosion experiments in TROI | |
| Zyszkowski | Thermal interaction of molten copper with water | |
| Furuya et al. | Effect of surface property of molten metal pools on triggering of vapor explosions in water droplet impingement | |
| Nelson | Steam explosions of single drops of pure and alloyed molten aluminum | |
| Witte et al. | Thermal explosion hazards | |
| Żyszkowski | Experimental investigation of fuel-coolant interaction | |
| Briggs | Experimental studies of thermal interactions at AEE Winfrith | |
| Nishimura et al. | Thermal fragmentation of a molten metal jet dropped into a sodium pool at interface temperatures below its freezing point | |
| SHOJI et al. | An experimental study of small-scale vapor explosions for molten tin dropped into water | |
| Rao et al. | Characteristics of debris resulting from simulated molten fuel coolant interactions in SFRS | |
| Epstein et al. | A crystallization theory of underwater aluminum ignition |