Magnetofluidic accelerometer with partial filling of cavity with magnetic fluid
First Claim
1. A method for detecting acceleration comprising:
- suspending a non-magnetic inertial body using a plurality of separate droplets of magnetic fluid;
measuring a position of the inertial body in response to a force applied to the inertial body, wherein the change in the position of the inertial body is calculated based on changes of magnetic flux line distribution within the magnetic fluid due to a change in the shape of the droplets; and
calculating acceleration based on the change in the position of the inertial body.
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Accused Products
Abstract
A sensor includes a housing and a magnetic fluid within the housing that incompletely fills the housing. An inertial body is in contact with the magnetic fluid. Displacement of the inertial body relative to the magnetic fluid is indicative of acceleration on the housing. The acceleration includes linear and/or angular acceleration. The inertial body can be an air bubble, or a dissimilar liquid. A plurality of magnets are mounted on the housing, wherein the magnetic fluid is positioned in droplets between the magnets and the inertial body. The magnetic fluid can be a single droplet between each magnet and the inertial body, or multiple droplets between each magnet and the inertial body. The remaining volume in the housing can be filled with a non-magnetic fluid.
29 Citations
17 Claims
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1. A method for detecting acceleration comprising:
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suspending a non-magnetic inertial body using a plurality of separate droplets of magnetic fluid; measuring a position of the inertial body in response to a force applied to the inertial body, wherein the change in the position of the inertial body is calculated based on changes of magnetic flux line distribution within the magnetic fluid due to a change in the shape of the droplets; and calculating acceleration based on the change in the position of the inertial body.
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2. A sensing element of an accelerometer comprising:
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a magnetic fluid arranged in separate droplets in contact with a non-magnetic inertial body; at least four magnets surrounding the inertial body, wherein the magnets generate magnetic flux lines within the droplets and maintain the droplets in place; a second fluid different from the magnetic fluid arranged in contact with the magnetic fluid and the inertial body, wherein displacement of the inertial body relative to the droplets changes magnetic flux line distribution within the magnetic fluid due to a change in the shape of the droplets, and wherein the change of the magnetic flux line distribution is indicative of acceleration on the sensing element; and a sensor that detects the changes in the magnetic flux distribution. - View Dependent Claims (3, 4, 5)
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6. A sensing element of an accelerometer comprising:
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a housing; a magnetic fluid within the housing and having a shape of a plurality of separate droplets, the magnetic fluid incompletely filling the housing such that only an air fills the remaining volume within the housing; at least four magnets mounted in the housing, wherein the magnets generate magnetic flux lines within the droplets and maintain the droplets in place, wherein a change in the shape of the droplets due to acceleration changes magnetic flux line distribution within the droplets, and wherein the change of the magnetic flux line distribution is indicative of acceleration on the housing; and a sensor that detects the change in the magnetic flux distribution.
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7. A sensing element of an accelerometer comprising:
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a housing; a magnetic fluid within the housing and having a shape of a plurality of separate droplets, the magnetic fluid incompletely filling the housing; a non-magnetic fluid within the housing filling the entire remaining volume within the housing; at least four magnets mounted in the housing, wherein the magnets generate magnetic flux lines within the droplets and maintain the droplets in place, wherein a change in the shape of the droplets due to acceleration changes magnetic flux line distribution within the droplets, and wherein the change of the magnetic flux line distribution is indicative of acceleration on the housing; and a sensor that detects the changes in the magnetic flux distribution.
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8. A sensing element of an accelerometer comprising:
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a non-magnetic inertial body; a plurality of separate droplets of magnetic fluid holding the inertial body in suspension; at least four magnetic poles surrounding the inertial body and maintaining the droplets of the magnetic fluid in place, wherein displacement of the inertial body relative to the droplets changes magnetic flux line distribution within the magnetic fluid due to a change in the shape of the droplets, and wherein the change of the magnetic flux line distribution is indicative of acceleration on the sensing element; and a sensor that detects the changes in the magnetic flux distribution.
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9. A sensing element of an accelerometer comprising:
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a housing; a magnetic fluid within the housing and having a shape of a plurality of separate droplets; a non-magnetic inertial body in contact with the droplets, wherein the magnetic fluid incompletely fills the housing, in addition to a volume occupied by the inertial body; at least four magnets surrounding the inertial body, wherein the magnets generate magnetic flux lines within the droplets and maintain the droplets in place, and wherein displacement of the inertial body relative to the droplets changes magnetic flux line distribution within the magnetic fluid due to a change in the shape of the droplets, and wherein the change of the magnetic flux line distribution is indicative of acceleration on the housing; and a sensor that detects the changes in the magnetic flux distribution. - View Dependent Claims (10, 11, 12, 13, 14, 15, 16, 17)
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Specification