System for wide bandwidth damping
First Claim
Patent Images
1. A system for wide bandwidth damping, said system comprising:
- a vibratable mechanical structure to be damped;
an input transducer responsive to an input signal to affect vibration of said mechanical structure;
an output transducer responsive to displacement vibration of said mechanical structure for producing an output signal in accordance therewith;
an active electronic feedback circuit connected from said output transducer for producing a positive feedback signal to each resonant mode to be damped;
a signal souce; and
an input circuit for impressing an input signal on said input transducer directly proportional to the sum of the output signals of said source and said feedback circuit,said feedback circuit supplying said feedback signal to said input circuit with a phase lagging the output signal of said output transducer by more than 0° and
less than 180°
, wherein;
said feedback signal has a phase which lags said output transducer output signal by approximately 90°
, and wherein;
said input and output transducers are vibration sensitive transducers fixed to said structure in spaced relative positions;
said electronic feedback circuit is connected from said output transducer to said input transducer,said circuit having a Laplace transfer function H(ω
) where ω
is radian frequency,said circuit having circuit components with values such that H(ω
) meets conditions (1), (2) and (3) as follows;
space="preserve" listing-type="equation">G(ω
)H(ω
)<
1 for all ω
when Im[G(ω
)H(ω
)]=0 (1)G(ω
) being the Laplace transfer function through said input transducer, through said structure and through said output transducer, Im[G(ω
)H(ω
)] being the imaginary part of the complex product G(ω
)H(ω
),(2) co Re[H(ω
)]<
1, for all ω
>
0 that Im[H(ω
)]=0, co being a constant, Re[H(ω
)] being the real part of the complex variable H(ω
), and Im[H(ω
)] being the imaginary part of H(ω
), and(3) cn Im[H(ω
)]>
0 for all ω
>
0 and one or more of the modes to be damped, where for each said mode n=1, 2, . . . , each cn being a constant, Im[H(ω
)] being the imaginary part of the complex variable H(ω
).
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Abstract
A positive electronic feedback circuit for mechanical vibration damping. The feedback circuit is connected from an output transducer fixed to a vibratable structure to an input transducer fixed to the structure. Preferably the feedback circuit has an output signal with a phase about 90 degrees lagging its input signal. Three conditions set forth herein make this possible.
17 Citations
10 Claims
-
1. A system for wide bandwidth damping, said system comprising:
-
a vibratable mechanical structure to be damped; an input transducer responsive to an input signal to affect vibration of said mechanical structure; an output transducer responsive to displacement vibration of said mechanical structure for producing an output signal in accordance therewith; an active electronic feedback circuit connected from said output transducer for producing a positive feedback signal to each resonant mode to be damped; a signal souce; and an input circuit for impressing an input signal on said input transducer directly proportional to the sum of the output signals of said source and said feedback circuit, said feedback circuit supplying said feedback signal to said input circuit with a phase lagging the output signal of said output transducer by more than 0° and
less than 180°
, wherein;said feedback signal has a phase which lags said output transducer output signal by approximately 90°
, and wherein;said input and output transducers are vibration sensitive transducers fixed to said structure in spaced relative positions; said electronic feedback circuit is connected from said output transducer to said input transducer, said circuit having a Laplace transfer function H(ω
) where ω
is radian frequency,said circuit having circuit components with values such that H(ω
) meets conditions (1), (2) and (3) as follows;
space="preserve" listing-type="equation">G(ω
)H(ω
)<
1 for all ω
when Im[G(ω
)H(ω
)]=0 (1)G(ω
) being the Laplace transfer function through said input transducer, through said structure and through said output transducer, Im[G(ω
)H(ω
)] being the imaginary part of the complex product G(ω
)H(ω
),(2) co Re[H(ω
)]<
1, for all ω
>
0 that Im[H(ω
)]=0, co being a constant, Re[H(ω
)] being the real part of the complex variable H(ω
), and Im[H(ω
)] being the imaginary part of H(ω
), and(3) cn Im[H(ω
)]>
0 for all ω
>
0 and one or more of the modes to be damped, where for each said mode n=1, 2, . . . , each cn being a constant, Im[H(ω
)] being the imaginary part of the complex variable H(ω
). - View Dependent Claims (2)
-
-
3. A system for wide bandwidth damping, said system comprising:
-
a vibratable mechanical structure to be damped; an input transducer responsive to an input signal to affect vibration of said mechanical structure; an output transducer responsive to displacement vibration of said mechanical structure for producing an output signal in accordance therewith; an active electronic feedback circuit connected from said output transducer for producing a positive feedback signal to each resonant mode to be damped; a signal source; and an input circuit for impressing an input signal on said input transducer directly proportional to the sum of the output signals of said source and said feedback circuit, said feedback circuit supplying said feedback signal to said input circuit with a phase lagging the output signal of said output transducer by more than 0° and
less than 180°
, wherein;said input and output transducers are vibration sensitive transducers fixed to said structure in spaced relative positions; - View Dependent Claims (5, 7, 9)
-
-
4. said electronic feedback circuit is connected from said output transducer to said input transducer,
said circuit having a Laplace transfer function H(ω - ) where ω
is radian frequency,said circuit having circuit components with values such that H(ω
) meets conditions (1), (2) and (3) as follows;
space="preserve" listing-type="equation">G(ω
)H(ω
)<
1 for all ω
when Im[G(ω
)H(ω
)]=0 (1)G(ω
) being the Laplace transfer function through said input transducer, through said structure, and through said output transducer, Im[G(ω
)H(ω
)] being the imaginary part of the complex product G(ω
)H(ω
),(2) co Re[H(ω
)]<
1, for all ω
>
0 that Im[H(ω
)]=0, co being a constant, Re[H(ω
)] being the real part of the complex variable H(ω
), and(3) cn Im[H(ω
)]<
0 for all ω
>
0 and one or more of the modes to be damped, where for each said mode n=1, 2, . . . , each cn being a constant, Im[H(ω
)] being the imaginary part of the complex variable H(ω
).
- ) where ω
-
6. In a system for damping mechanicl vibrations, the combination comprising:
-
a vibratable mechanical structure; input and output vibration sensitive transducers fixed to said structure in spaced relative positions; an electronic feedback circuit connected from said output transducer to said input transducer, said circuit having a Laplace transfer function H(ω
) where ω
is radian frequency,said circuit having circuit components with values such that H(ω
) meets conditions (1), (2) and (3) as follows;
space="preserve" listing-type="equation">G(ω
)H(ω
)<
1 for all ω
when Im[G(ω
)H(ω
)]=0 (1)G(ω
) being the Laplace transfer function through said input transducer, through said structure and through said output transducer, Im[G(ω
)H(ω
)], being the imaginary part of the complex product G(ω
)H(ω
),(2) co Re[H(ω
)]<
1, for all ω
>
0 that Im[H(ω
)]=0, co being a constant, Re[H(ω
)] being the real part of the complex variable H(ω
), and(3) cn Im[H(ω
)]<
0 for all ω
>
0, and one or more of the modes to be damped, where for each said mode n=1, 2, . . . , each cn being a constant, Im[H(ω
)] being the imaginary part of the complex variable H(ω
).
-
-
8. The method of damping mechanical vibrations, said method comprising the steps of:
-
providing a vibratable structure; mounting input and output vibration transducers on said structure; empirically determining the constants co and c1 of the transfer function G(ω
) through said input transducer, through said structure and through said output transducer, where;
##EQU22## where K is the number of resonant modes controlled, and θ
is the relative damping; andconnecting an electronic feedback circuit from said output transducer to said input transducer, said circuit having a Laplace transfer function H(ω
) where ω
is radian frequency,said circuit having circuit components with values such that H(ω
) meets conditions (1), (2) and (3), as follows;
space="preserve" listing-type="equation">G(ω
)H(ω
)<
1 for all ω
when Im[G(ω
)H(ω
)]=0 (1)Im[G(ω
)H(ω
)] being the imaginary part of the complex product G(ω
)H(ω
),(2) co Re[H(ω
)]<
1, for all ω
>
0 that Im[H(ω
)]=0, Re[H(ω
)] being the real part of the complex variable H(ω
), and(3) cn Im[H(ω
)]<
0 for all ω
>
0, and one or more of the modes to be damped, where for each said mode n=1, 2, . . . , Im[H(ω
)] being the imaginary part of the complex variable H(ω
). - View Dependent Claims (10)
-
Specification