Blast (explosives): Difference between revisions
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'''Blast''' is the process by which | '''Blast''' is the process by which explosives, in a millisecond or less, are converted to hot explosive gases. Depending on the construction of the container holding the explosive, as much as half the force may go into disrupting it rather than producing effects; the strongest cases are military [[warhead]]s and gravity bombs. | ||
Blast effects are most complex in air, although they are not trivial in air or in solids. Indeed, there is a complex discipline of forming solid structures with explosive waves, perhaps most complex in the compression systems of | Blast effects are most complex in air, although they are not trivial in air or in solids. Indeed, there is a complex discipline of forming solid structures with explosive waves, perhaps most complex in the compression systems of nuclear weapons. | ||
==Air== | ==Air== | ||
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[[Image:Pressure-vs-time in blast.png|left|450px|thumb|Pressure vs. time in air explosion]] | [[Image:Pressure-vs-time in blast.png|left|450px|thumb|Pressure vs. time in air explosion]] | ||
The inertia of these gases are prevented, by their inertia, from slowing abruptly at the shock front, but rarefaction still take place, and a low-pressure region may follow behind the leading edge of the gases. Indeed, there may even be a lower-than-atmospheric area further behind, and a vacuum area produces. "When the pressure becomes less than atmospheric, the wind reverses in direction and blows backward toward the point of detonation. Any light object, such as a leaf, when struck by the shock front, is rapidly carried away from the point of detonation and then is blown back almost to the original position when the wind reverses." In especially hot explosions, the heating of the air and its consequence reduction and density becomes important, especially in [[nuclear weapons|nuclear explosions]]. There may even be circumstances, however, where strong structures such as walls are pulled backward by a negative force. | The inertia of these gases are prevented, by their inertia, from slowing abruptly at the shock front, but rarefaction still take place, and a low-pressure region may follow behind the leading edge of the gases. Indeed, there may even be a lower-than-atmospheric area further behind, and a vacuum area produces. "When the pressure becomes less than atmospheric, the wind reverses in direction and blows backward toward the point of detonation. Any light object, such as a leaf, when struck by the shock front, is rapidly carried away from the point of detonation and then is blown back almost to the original position when the wind reverses." In especially hot explosions, the heating of the air and its consequence reduction and density becomes important, especially in [[nuclear weapons|nuclear explosions]]. There may even be circumstances, however, where strong structures such as walls are pulled backward by a negative force. | ||
==Effects== | ==Effects== | ||
Blast effect is measured by two criteria, peak pressure and impulse. | Blast effect is measured by two criteria, peak pressure and impulse. | ||
*Peak pressure is the pressure | *Peak pressure is the pressure differential between the shock wave and the atmosphere on which it impacts, or the differnce of the highest shock wave pressure after atmospheric pressure has been subtracted. It measures the maximum force exerted against a surface by a blast wave, since force is equal to the product of pressure and area. ''This is a simplified model that does not consider reflection and reinforcement of shock waves by the [[Mach effect]].'' | ||
the maximum force exerted against a surface by a blast | *Impulse is mathematically equal to the area under the time pressure curve for the duration of the positive phase, or, stated more formally, the integral of pressure over time. This is approximately half the peak pressure multiplied by the duration of the positive phase. | ||
wave, since force is equal to the product of pressure and | |||
area. | |||
*Impulse is mathematically equal to the area under the time pressure curve for the duration of the positive phase. This is approximately half the peak pressure multiplied by the duration of the positive phase. | |||
==Water== | ==Water== | ||
==Solid== | ==Solid== | ||
Blast may take place in a porous natural cavity, such as an underground chamber, or in extremely complex manufactured shapes. No shape is more complex than the implosion system of a [[fission device]], in which explosives of different detonation velocities, shaped into complex forms, interact with controlled precise voids, temporary shields, and blast reflectors. | |||
In a nuclear weapon, there may be multiple high explosive detonations to create a shape and then cause actions upon it. The basic shape that will eventually be compressed for fission is a sphere, but that may not be the stored shape. In a linear implosion system, for example, the first explosive system compresses a roughly cylindrical system into a sphere, and the second system then compresses neutron reflectors around it and maximally compresses the sphere.<ref name=NW4>{{citation | |||
| url = http://nuclearweaponarchive.org/Nwfaq/Nfaq4-1.html | |||
| contribution = 4.1.6.3.2 Linear Implosion | |||
| title = 4.1 Elements of Fission Weapon Design | |||
| publisher = Nuclear Weapons Archive}}</ref> | |||
==References== | ==References== | ||
{{reflist|2}} | {{reflist|2}}[[Category:Suggestion Bot Tag]] |
Latest revision as of 12:05, 23 July 2024
This article may be deleted soon. | ||
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Blast is the process by which explosives, in a millisecond or less, are converted to hot explosive gases. Depending on the construction of the container holding the explosive, as much as half the force may go into disrupting it rather than producing effects; the strongest cases are military warheads and gravity bombs. Blast effects are most complex in air, although they are not trivial in air or in solids. Indeed, there is a complex discipline of forming solid structures with explosive waves, perhaps most complex in the compression systems of nuclear weapons. Air
At the leading edge of the detonation is a sharply delineated reagion called the shock front, in which the pressure rises dramatically. Its initial velocity is much greater than sound but drops dramatically. The gases of detonation follow it.[1] While the emphasis here is on the gases and the shock wave, explosive blast also produces thermal effects, light and sound, with additional and stronger effects from nuclear weapons.[2] The preliminary discussion also assumes the blast takes place near the ground, since, even with high explosives, the Mach effect can cause complex interactions of reinforcement of transmitted and reflected shock waves from bursts above the ground. The inertia of these gases are prevented, by their inertia, from slowing abruptly at the shock front, but rarefaction still take place, and a low-pressure region may follow behind the leading edge of the gases. Indeed, there may even be a lower-than-atmospheric area further behind, and a vacuum area produces. "When the pressure becomes less than atmospheric, the wind reverses in direction and blows backward toward the point of detonation. Any light object, such as a leaf, when struck by the shock front, is rapidly carried away from the point of detonation and then is blown back almost to the original position when the wind reverses." In especially hot explosions, the heating of the air and its consequence reduction and density becomes important, especially in nuclear explosions. There may even be circumstances, however, where strong structures such as walls are pulled backward by a negative force.
EffectsBlast effect is measured by two criteria, peak pressure and impulse.
WaterSolidBlast may take place in a porous natural cavity, such as an underground chamber, or in extremely complex manufactured shapes. No shape is more complex than the implosion system of a fission device, in which explosives of different detonation velocities, shaped into complex forms, interact with controlled precise voids, temporary shields, and blast reflectors. In a nuclear weapon, there may be multiple high explosive detonations to create a shape and then cause actions upon it. The basic shape that will eventually be compressed for fission is a sphere, but that may not be the stored shape. In a linear implosion system, for example, the first explosive system compresses a roughly cylindrical system into a sphere, and the second system then compresses neutron reflectors around it and maximally compresses the sphere.[3] References
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