Auto-adjust apparatus for a vibration isolation system
First Claim
1. An automatic adjustment apparatus for adjusting the optimum equilibrium position of an axial-motion isolator for supporting an object in an equilibrium position relative to a base which includes a support spring for providing stiffness and force supporting capability in an axial direction operatively connected to a negative-stiffness-producing apparatus for producing negative stiffness in the axial direction to allow the support spring and negative-producing-apparatus combine to produce low axial stiffness to suppress the transmission of vibratory motion between the object and base, the automatic adjusting apparatus comprising:
- a control spring having first and second ends operatively connected in parallel with the support spring, wherein translation of said second end of said control spring relative to said first end changes the force carried by said support spring and the equilibrium position of the object relative to the base;
sensor means for sensing a deviation in the equilibrium position of the object relative to the base from the optimum equilibrium position of the object relative to the base and providing an electrical signal indicating such deviation; and
control means for translating the second end of said control spring relative to said first end to correct the deviation of the equilibrium position of the object from the optimum equilibrium position.
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Accused Products
Abstract
An auto-adjust apparatus adjusts a vibration isolator to help accommodate varying weight loads and other effects which can cause the isolator to go out of adjustment, such as variations caused by changes in ambient temperature and creep of the isolator'"'"'s main support spring. A small secondary spring is positioned in parallel with the main support spring of the isolator and is precompressed such that its compression increases the load on the main support spring by a small amount. An increase in the compression of this secondary spring will cause an increase in the load on the main support spring. Similarly, a decrease in the compression on this secondary spring will cause a decrease in the load on the main support spring. Sensors for sensing a deviation in the equilibrium position of the object relative to the base from its optimum equilibrium position are provided and generate an electrical signal indicating such deviations. A control system for correcting the deviation of the equilibrium position of the object from the optimum equilibrium position adjusts the compression on the secondary spring as may be required.
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Citations
21 Claims
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1. An automatic adjustment apparatus for adjusting the optimum equilibrium position of an axial-motion isolator for supporting an object in an equilibrium position relative to a base which includes a support spring for providing stiffness and force supporting capability in an axial direction operatively connected to a negative-stiffness-producing apparatus for producing negative stiffness in the axial direction to allow the support spring and negative-producing-apparatus combine to produce low axial stiffness to suppress the transmission of vibratory motion between the object and base, the automatic adjusting apparatus comprising:
a control spring having first and second ends operatively connected in parallel with the support spring, wherein translation of said second end of said control spring relative to said first end changes the force carried by said support spring and the equilibrium position of the object relative to the base; sensor means for sensing a deviation in the equilibrium position of the object relative to the base from the optimum equilibrium position of the object relative to the base and providing an electrical signal indicating such deviation; and control means for translating the second end of said control spring relative to said first end to correct the deviation of the equilibrium position of the object from the optimum equilibrium position. - View Dependent Claims (2, 3, 4, 5, 6)
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7. An automatic adjustment apparatus for adjusting the optimum equilibrium position of an axial-motion isolator for supporting an object in an equilibrium position relative to a base which includes a support spring for providing stiffness and force supporting capability in an axial direction operatively connected to a negative-stiffness-producing apparatus for producing negative stiffness in the axial direction to allow the support spring and negativeproducing-apparatus combine to produce low axial stiffness to suppress the transmission of vibratory motion between the object and base, the automatic adjusting apparatus comprising:
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sensor means for sensing a deviation in the equilibrium position of the object relative to the base from the optimum equilibrium position of the object relative to the base and providing an electrical signal indicating such deviation; and control means for translating one end of the support spring to correct the deviation of the equilibrium position of the object from the optimum equilibrium position, wherein said sensor means senses at least two different magnitudes of the deviation in the equilibrium position. and said control means translates the end of said support spring at different speeds depending on the magnitude of the deviation of the equilibrium position. - View Dependent Claims (8, 9, 10)
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11. An axial-motion isolator having force-supporting capability in an axial direction for supporting an object in an equilibrium position relative to a base, for suppressing transmission of vibratory motion between the object and base, said isolator having axial stiffness and an optimum equilibrium position of the object relative to the base, comprising:
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a support spring for providing positive stiffness and force supporting capability in the axial direction for supporting the object; negative-stiffness-producing means for producing negative stiffness in the axial direction operatively connected to said support spring, said support spring and negative-stiffness-producing means combining to produce low axial stiffness; and an automatic adjusting apparatus including; a control spring having first and second ends operatively connected in parallel with the support spring, wherein translation of said second end of said control spring relative to said first end changes the force carried by said support spring and the equilibrium position of the object relative to the base; sensor means for sensing a deviation in the equilibrium position of the object relative to the base from the optimum equilibrium position of the object relative to the base and providing an electrical signal indicating such deviation; and control means for translating the second end of said control spring relative to said first end to correct the deviation of the equilibrium position of the object from the optimum equilibrium position. - View Dependent Claims (12, 13, 14, 15, 16)
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17. An axial-motion isolator having force-supporting capability in an axial direction for supporting an object in an equilibrium position relative to a base, for suppressing transmission of vibratory motion between the object and base, said isolator having axial stiffness and an optimum equilibrium position of the object relative to the base, comprising:
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a support spring for providing positive stiffness and force supporting capability in the axial direction for supporting the object; negative-stiffness-producing means for producing negative stiffness in the axial direction operatively connected to said support spring, said support spring and negative stiffness-producing means combining to produce low axial stiffness; and an automatic adjusting apparatus including; sensor means for sensing a deviation in the equilibrium position of the object relative to the base from the optimum equilibrium position of the object relative to the base and providing an electrical signal indicating such deviation; and control means for translating one end of said support spring to correct the deviation of the equilibrium position of the object from the optimum equilibrium position. - View Dependent Claims (18, 19, 20, 21)
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Specification