Ultrasonic Doppler velocity sensing within a hydraulic actuator

US 4,995,635 A
Filed: 03/21/1990
Issued: 02/26/1991
Est. Priority Date: 03/21/1990
Status: Expired due to Fees

First Claim

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1. A hydraulic actuator connecting the sprung and unsprung portions of a vehicle, said hydraulic actuator operable to measure changes in the relative velocity between the telescopically movable components thereof, said hydraulic actuator comprising:

a cylinder forming a working chamber operable to store damping fluid;

a piston disposed within said cylinder defining a first and a second portion of said working chamber, said piston being movable within said cylinder;

first transducer means for emitting sound waves through damping fluid contained within said second portion of said working chamber;

means for driving said first transducer means so as to cause said first transducer means to emit sound waves;

means for reflecting the sound waves emitted by said first transducer means, said reflecting means being disposed within said cylinder;

second transducer means for receiving sound waves reflected by said reflecting means;

measuring means for determining the change in frequency between the sound waves received by said second transducer means and the sound waves emitted by said first transducer means and generating an output in response thereto; and

means for calculating the relative velocity of said piston within said cylinder in response to said output from said measuring means.

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Abstract

A direct acting hydraulic damper comprising an internal, non-contact sensing means for the direct measurement of relative velocity between the piston and the cylinder of the damper. The damper comprising a cylinder forming a working chamber operable to store damping fluid. A piston is disposed within the cylinder defining an upper and lower portion of the working chamber. The damper further comprises a first transducer for emitting ultrasonic waves within the lower portion of the working chamber. The ultrasonic waves emitted by said first transducer are reflected by a base valve or end surface of the cylinder facing the transducers and are received by a second transducer. A frequency detection circuit determines the difference in frequency between the emitted and reflected ultrasonic waves and generates an output in response thereto. A computer then calculates the relative velocity of the piston with respect to the base valve or end surface, based on the Doppler principle. The velocity signal is then used for automatic control of suspension parameters according to predefined algorithm.

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27 Claims

1. A hydraulic actuator connecting the sprung and unsprung portions of a vehicle, said hydraulic actuator operable to measure changes in the relative velocity between the telescopically movable components thereof, said hydraulic actuator comprising:
- a cylinder forming a working chamber operable to store damping fluid;
  
  a piston disposed within said cylinder defining a first and a second portion of said working chamber, said piston being movable within said cylinder;
  
  first transducer means for emitting sound waves through damping fluid contained within said second portion of said working chamber;
  
  means for driving said first transducer means so as to cause said first transducer means to emit sound waves;
  
  means for reflecting the sound waves emitted by said first transducer means, said reflecting means being disposed within said cylinder;
  
  second transducer means for receiving sound waves reflected by said reflecting means;
  
  measuring means for determining the change in frequency between the sound waves received by said second transducer means and the sound waves emitted by said first transducer means and generating an output in response thereto; and
  
  means for calculating the relative velocity of said piston within said cylinder in response to said output from said measuring means.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)
- - 2. The hydraulic actutator according to claim 1 further comprising a control circuit and logic operable to selectively change at least one suspension parameter in response to the relative movement of said piston within said cylinder.
  - 3. The hydraulic actuator according to claim 1, wherein said actuator is a hydraulic direct acting, telescopic damper.
  - 4. The hydraulic actuator according to claim 1, wherein the frequency of the sound waves emitted by said first transducer means reside within the ultrasonic spectrum.
  - 5. The hydraulic actuator according to claim 4, wherein said driving means comprises a wave generating circuit operable to cause said first transducer means to generate ultrasonic waves.
  - 6. The hydrualic actuator according to claim 5, wherein said wave generation circuit enables said first transducer means to generate ultrasonic waves having a fixed controlled frequency and duration.
  - 7. The hydraulic actuator according to claim 6, wherein said first transducer means comprises a transmitter mounted to a surface of said piston opposite a piston rod and being operable to propagate ultrasonic waves through said damping fluid contained in said second portion of said working chamber.
  - 8. The hydraulic actuator according to claim 7, wherein said second transducer means comprises a receiver mounted to said piston adjacent to said transmitter.
  - 9. The hydraulic actuator according to claim 8, wherein said transmitter and said receiver comprise piezoelectric transducers.
  - 10. The hydraulic actuator according to claim 8, wherein said transmitter and said receiver comprise magnetorestrictive transducers.
  - 11. The hydraulic actuator according to claim 7, wherein said reflecting means comprises a base valve secured to an end surface of said cylinder facing said transmitter and receiver.
  - 12. The hydraulic actuator according to claim 11, wherein said base valve further comprises means for compensating for changes in the speed of propagation of said sound waves.
  - 13. The hydraulic actuator according to claim 7, wherein said reflecting means comprises a end surface of said cylinder facing said transmitter and receiver.
  - 14. The hydraulic actuator according to claim 1, wherein said measuring means comprises a frequency detection circuit operable to continuously generate an output in response to changes in frequency between the sound waves received by said second transducer means and the sound waves emitted by said first transducer means.
  - 15. The hydraulic actuator according to claim 1, wherein said means for calculating the relative movement of said piston comprises an electronic processor such as a computer.

16. A method of determining the relative movement of a piston within a pressure cylinder of a damper, said method comprising the steps of:
- delivering an electrical signal generated by a wave generation circuit to an ultrasonic transmitter, said ultrasonic transmitter operable to emit ultrasonic waves of fixed and controlled frequency in response to said electrical signal generated by said wave generation signal;
  
  reflecting said ultrasonic waves emitted by said ultrasonic transmitter against a fixed inner surface of said pressure cylinder;
  
  receiving said ultrasonic waves reflected by said fixed inner surface by an ultrasonic receiver positioned adjacent to said ultrasonic transmitter;
  
  providing measuring means for comparing the frequency of said ultrasonic waves received by said ultrasonic receiver and the frequency of said ultrasonic waves emitted by said ultrasonic transmitter and generating an output signal in response thereto;
  
  calculating the relative movement between said piston and said fixed inner surface in response to said output signal from said measuring means; and
  
  selectively changing a suspension parameter in response to said relative movement between said piston and said fixed inner surface.
- View Dependent Claims (17, 18, 19, 20)
- - 17. The method of claim 16, wherein said piston has a first surface facing said fixed inner surface of said pressure cylinder, said ultrasonic transmitter being mounted to said first surface of said piston.
  - 18. The method of claim 16, wherein said step of comparing the frequency of said ultrasonic waves received by said ultrasonic receiver and the frequency of said ultrasonic waves emitted by said ultrasonic transmitter comprises delivering said outputs from said ultrasonic receiver and said wave generation circuit to a frequency detection circuit, said frequency detection circuit operable to continuously determine changes in frequency of said ultrasonic waves received by said ultrasonic receiver with respect to said ultrasonic waves emitted by said ultrasonic transmitter and generate said output signal in response thereto.
  - 19. The method of claim 16, wherein said step of calculating said relative movement between said piston and said fixed inner surface comprises delivering said output signal from said frequency detection circuit to a computer, said computer calculating said relative movement from said output.
  - 20. The method of claim 19, wherein said computer determines the relative movement between said piston and said fixed inner surface of said pressure cylinder according to either of the following equations:
    - ##EQU2## where f₁ = frequency of said ultrasonic waves emitted by said ultrasonic transmitter;
      
      f₂ = frequency of said ultrasonic waves received by said ultrasonic receiver;
      
      f_b = "beating frequency" defines as f₂ -f₁ ;
      
      v = relative velocity between said piston and said fixed member;
      
      c = speed of propagation of said ultrasonic waves through said damping fluid.

21. A direct acting hydraulic damper operable to selectively vary a suspension characteristic thereof in response to the relative velocity between a piston and a cylinder end surface, said damper comprising:
- a pressure cylinder forming a working chamber operable to store damping fluid;
  
  a piston disposed within said pressure cylinder defining a first and second portion of said working chamber, said piston being movable with respect to said pressure cylinder and comprising valve means for metering the flow of damping fluid between said first and second portions of said working chamber during movement of said piston within said pressure cylinder;
  
  first transducer means for emitting and axially transmitting sound waves through said damping fluid contained within said second portion of said working chamber, said first transducer means being mounted to a surface of said piston facing said second portion;
  
  means for driving said first transducer means;
  
  an end surface of said second portion of said working chamber, said end surface operable to reflect sound waves emitted by said first transducer means, said end surface having means for compensating for variations in the speed of propagation of said sound waves through said damping fluid;
  
  second transducer means for receiving the sound waves reflected by said end surface, said second transducer means being mounted on a piston surface adjacent to said first transducer means;
  
  a frequency detection circuit for measuring the difference in frequency of said sound waves emitted by said first transducer means and said sound waves received by said second transducer means and generating an output in response thereto;
  
  a processor for calculating the relative velocity of said piston relative to said end surface from said output of said frequency detection circuit; and
  
  a control circuit for selectively controlling said desired suspension characteristic in response to the velocity of said piston relative to said end surface.
- View Dependent Claims (22, 23, 24, 25, 26, 27)
- - 22. The direct acting hydraulic damper according to claim 21, wherein said sound waves emitted by said first transducer means and said sound waves received by said second transducer means reside within the ultrasonic spectrum.
  - 23. The direct acting hydraulic damper according to claim 22, wherein said means for driving said first transducer means comprises a wave generation circuit, said wave generation circuit operable to cause said first transducer means to generate constant frequency ultrasonic waves.
  - 24. The direct acting hydraulic damper according to claim 22, wherein said first and second transducer means comprise piezoelectric devices.
  - 25. The direct acting hydraulic damper according to claim 22, wherein said first and second transducer means comprise magnetorestrictive devices.
  - 26. The direct acting hydraulic damper according to claim 22, wherein said frequency detection circuit continuously generates an output in response to changes in the frequency of said second transducer means.
  - 27. The direct acting hydraulic damper according to claim 21, wherein said compensation means associated with said end surface comprises a step-like end surface configuration having first and second reflecting surface, said first and second axially displaced reflecting surfaces separated by a predetermined axial distance such that said transducer means receives sound waves reflected by said first and second reflecting surfaces so as to define a reference signal.

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Current Assignee
Tenneco Automotive Operating Company Incorporated (Apollo Global Management, Inc.)
Original Assignee
Monroe Auto Equipment Company (Apollo Global Management, Inc.)
Inventors
Guy, Yoram
Primary Examiner(s)
Rice, Kenneth R.

Application Number

US07/496,673
Time in Patent Office

342 Days
Field of Search

280/707
US Class Current

188/280
CPC Class Codes

B60G 17/01933   Velocity, e.g. relative vel...

B60G 2202/24   Fluid damper

B60G 2400/202   Piston speed; Relative velo...

B60G 2400/60   Load

B60G 2400/91   Frequency

B60G 2401/176   Radio or audio sensitive me...

B60G 2500/10   Damping action or damper

B60G 2600/26   Electromagnets; Solenoids

B60G 2600/90   other signal treatment means

B60G 2800/012   Rolling condition

B60G 2800/014   Pitch; Nose dive

B60G 2800/18   Starting, accelerating

B60G 2800/22   Braking, stopping

B60G 2800/24   Steering, cornering

F16F 9/3292   Sensor arrangements

G01S 15/88   Sonar systems specially ada...

Ultrasonic Doppler velocity sensing within a hydraulic actuator

First Claim

4 Assignments

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Abstract

Citations

27 Claims

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Ultrasonic Doppler velocity sensing within a hydraulic actuator

First Claim

4 Assignments

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0 Petitions

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Accused Products

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Abstract

Citations

27 Claims

Specification

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Solutions

Use Cases

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