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[[Image:Saturn v schematic.jpg|thumb|right|Three sets of ullage motors are shown in this schematic of the [[Saturn V]] rocket]] |
[[Image:Saturn v schematic.jpg|thumb|right|Three sets of ullage motors are shown in this schematic of the [[Saturn V]] rocket]] |
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Liquid, [[cryogenic]] rockets keep their propellant in tanks. These tanks are never completely filled, to allow for expansion of the cold liquid propellant. In [[weightlessness|micro-gravity]] conditions the [[ |
Liquid, [[cryogenic]] rockets keep their propellant in insulated tanks. These tanks are never completely filled, to allow for expansion of the cold liquid propellant. In [[weightlessness|micro-gravity]] conditions the cryogenic liquid is without a [[free surface]] existing in a slushy state between solid, liquid, and gas. In this mixed state, [[ullage]] gas may be sucked into the engines, which is very undesirable. Small rocket engines, called ullage motors, are sometimes used to settle the propellant prior to the main engine ignition to allow the formation of a temporary free surface (with a distinct boundary between liquid and gas states). These motors provide acceleration that moves the main engine liquid propellants to the bottom of their tanks ("bottom" in this usage always meaning relative to the alignment of the main motor the ullage motors are serving), so they can be pumped into the engine plumbing. Meanwhile the ullage gas floats to the top, away from the engine inlets. Such motors were first invented by Soviet engineers for the [[Molniya (rocket)|Molniya]] interplanetary [[launch vehicle]] in 1960. |
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The firing of the ullage motors is used during stage separation of rocket and/or stabilization of a rocket when there are brief reductions in acceleration which could allow the liquid propellant to float away from the engine intakes. Ullage motors are also commonly employed on deep-space missions where a [[liquid rocket]] needs to start a burn after traveling in micro-gravity. |
The firing of the ullage motors is used during stage separation of rocket and/or stabilization of a rocket when there are brief reductions in acceleration which could allow the liquid propellant to float away from the engine intakes. Ullage motors are also commonly employed on deep-space missions where a [[liquid rocket]] needs to start a burn after traveling in micro-gravity. |
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Ullage motors are typically very small; research{{Who|date=June 2008}} shows that accelerations of the order <math>10^{-3} g</math> are needed to avoid excessive gas intake. Some vehicles use other techniques to hold liquid at the inlet, as once the main engines are ignited, ullage motors are no longer required. |
Ullage motors are typically very small; research{{Who|date=June 2008}} shows that accelerations of the order <math>10^{-3} g</math> are needed to avoid excessive gas intake. Some vehicles use other techniques to hold liquid at the inlet, as once the main engines are ignited, ullage motors are no longer required. |
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The four ullage motors of the [[Saturn V rocket]] used in the American [[Apollo program]] were located on the second stage. In the third stage (known as [[S-IVB]]), there was a more general Auxiliary Propulsion System that also had ullage functions. |
The four ullage motors of the [[Saturn V rocket]] used in the American [[Apollo program]] were located on the second stage. In the third stage (known as [[S-IVB]]), there was a more general Auxiliary Propulsion System that also had ullage functions. Ullage is often a secondary function of the [[attitude control system]] such as on the Apollo [[Command Service Module]]. |
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==References== |
==References== |
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Find sources: "Ullage motor" – news · newspapers · books · scholar · JSTOR (June 2008) (Learn how and when to remove this message) |
Ullage motors (also known as ullage enginesor ullage rockets) are relatively small, independently-fueled rocket engines that may be fired to accelerate the rocket prior to main engine ignition, when the vehicle is in a zero-g situation.
Liquid, cryogenic rockets keep their propellant in insulated tanks. These tanks are never completely filled, to allow for expansion of the cold liquid propellant. In micro-gravity conditions the cryogenic liquid is without a free surface existing in a slushy state between solid, liquid, and gas. In this mixed state, ullage gas may be sucked into the engines, which is very undesirable. Small rocket engines, called ullage motors, are sometimes used to settle the propellant prior to the main engine ignition to allow the formation of a temporary free surface (with a distinct boundary between liquid and gas states). These motors provide acceleration that moves the main engine liquid propellants to the bottom of their tanks ("bottom" in this usage always meaning relative to the alignment of the main motor the ullage motors are serving), so they can be pumped into the engine plumbing. Meanwhile the ullage gas floats to the top, away from the engine inlets. Such motors were first invented by Soviet engineers for the Molniya interplanetary launch vehicle in 1960.
The firing of the ullage motors is used during stage separation of rocket and/or stabilization of a rocket when there are brief reductions in acceleration which could allow the liquid propellant to float away from the engine intakes. Ullage motors are also commonly employed on deep-space missions where a liquid rocket needs to start a burn after traveling in micro-gravity.
Ullage motors are typically very small; research[who?] shows that accelerations of the order are needed to avoid excessive gas intake. Some vehicles use other techniques to hold liquid at the inlet, as once the main engines are ignited, ullage motors are no longer required.
The four ullage motors of the Saturn V rocket used in the American Apollo program were located on the second stage. In the third stage (known as S-IVB), there was a more general Auxiliary Propulsion System that also had ullage functions. Ullage is often a secondary function of the attitude control system such as on the Apollo Command Service Module.