That song is "Magic" by Mick Smiley. It is on the Ghostbusters soundtrack.
It was only a temporary vessel. The body couldn't contain lucifer for an extended time and when he left to go into Sam, the vessel disintergrated.
A) licence the vessel
Uriel
marine vessel
Containment compartments in the ship's hull had separating walls that did not go all the way up to the ceiling of each compartment. Thus, water flowed from one compartment to the next instead of being contained. This resulted in a faster sinking of the vessel. Had the compartments each been sealed completely, more time would have elapsed before the situation became dire. Perhaps the ship could have remained afloat indefinitely. If the ship could have remained at least partially afloat for several hours until daylight, more than likely there would have been many more survivors due to less panic and the ability of rescue ships to come to the stranded vessel's aid.
environmentally cleaner
No, a vessel could be a number of things, such as a containment pod or space shuttel.
Cold War was the name of the game. Containment was a movement. Example: If a communist tank advanced 100 yards towards the border; an allied tank would counter that move...in an effort to containment any movement. If a communist jet entered neutral airspace, an allied jet might want to accompany it upon it's flight. If a communist vessel cruised the seas, an allied vessel would screen it (follow it/shadow it).
V. L. Porter has written: 'Pretest analyses of the steel containment vessel model' -- subject(s): Mathematical models, Safety measures, Nuclear reactors, Nuclear pressure vessels, Containment
Not due to fission or a nuclear chain reaction. If the core overheats it can melt through its containment vessel and if it hits water that may have been pooled in the vessel due to a coolant leak and generates steam, it can cause a steam explosion.
In a 'meltdown', the nuclear fuel rods will overheat and melt, not explode. It is the build-up of pressure within the containment vessel that can cause an explosion.
Fusion is not used in the production of nuclear power, other than in the Sun and stars, due to technological problems, primarily in containment. The Sun has it easy, so to speak, because its large gravity and mass causes the temperature and pressure necessary to initiate and sustain fusion, while its gravity also eliminates the need for containment. Attempting to do this on the Earth would not work because the size of the reactor would vastly exceed the size of the Earth. The alternative, building a containment vessel, is not working because the many millions of degrees of heat required for the plasma would destroy any vessel we have. Building a magnetic containment vessel, such as the tokamak (ITER) shows promise, but the technical problems of having supercold magnets in close proximity to superhot plasma are very overwhelming. First fusion for this project is set for 2019, and my guess is that commercial power from fusion is at least 50 to 100 years away.
One answer is a bomb. But taking normal nuclear reactors, the result would ultimately be fuel meltdown, what happens after that would depend on the integrity of the pressure vessel and secondary containment
It's fairly literal. The nuclear core of a reactor, where the nuclear fuel is, needs to be shielded so that the radiation and any radioactive components inside do not escape into the general environment.The primary radiation type inside the core is neutron radiation. One of the best shields for neutron radiation is a hydrogen-dense substance, thus pure water is often used. Water, if circulated in a heat sink system, also serves as a heat-removal method (cooling system).The enclosure for the core and the water pool is a containment vessel made out of something that is airtight and which shields against other kinds of direct radiation. Steel is a common material, perhaps supplemented by concrete and other reinforcement to guard against being damaged by an earthquake, explosion, or an airplane impact (for example).There is usually an outer containment building that encloses the reactor containment vessel itself. This is a sort of "second line of defense" in case the reactor is breached. Containment buildings are designed to withstand extremely high internal pressures (such as superheated steam) and forces of almost any direction and realistic magnitude. The specific shape of buildings at a nuclear plant are part of their function. The concave towers that are so symbolic of nuclear power are a common design for cooling towers (and not the reactor core itself). Domes are a common shape for reactor containment buildings for a variety of reasons that have mostly to do with encouraging steam condensation.Another Answer:The first line of defense is the design of the fuel pin, which contains the fuel, preventing its release into the reactor itself. The pin is made of a zirconium alloy that can withstand extremely high temperature and pressure. These fuel pins are about one half inch in diameter and about 12 feet long, depending on the reactor design. They are organized into bundles, then into assemblies, then into the core complex itself.The second line of defense is the reactor pressure vessel. Made of high carbon steel with a stainless steel inner liner, it is often about six inches thick. Along with the core cooling system, it forms the primary pressure boundary for the reactor.The third line of defense is the primary containment. Depending on the reactor design, this is typically a building surrounding the pressure vessel, suppresion pool, and other critical components that is from four to seven feet of hyper structurally reinforced concrete. In the event of a depressurization event of the pressure vessel, the primary containment will hold that release and condense it into the suppression pool.The fourth line of defense is the secondary containment. Again, depending on the reactor design, this is typically a building around the primary containment and its supporting systems such as the emergency core cooling systems and spent fuel pool, that is around two feet thick.All of these containment systems are designed to maximize the length of time you have to restore emergency core cooling before you have an uncontrolled release of radiation and/or radioactivity.There are other lines of defense, but the question only asked about containment.
It is the containment building in which the reactor vessel and the primary cooling plumbing is housed. During normal operation, radiation levels inside are lethal. Additionally, this structure is designed to "contain" the highly radioactive materials in the event of a major accident.
the PWC
its a vessel in your eye. its a vessel in your eye.