Rotary low-frequency sound reproducing apparatus and method

US 5,191,618 A
Filed: 12/20/1990
Issued: 03/02/1993
Est. Priority Date: 12/20/1990
Status: Expired due to Term

First Claim

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1. A rotary acoustic transducer apparatus for producing sound in response to an applied audio signal, comprising a rotary acoustic radiator assembly, a torque motor, a position sensor, and a microcomputer, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through the walls of said cylindrical chamber to direct air flow into and out of the cylinder in response to movement of the movable vanes, a torque motor coupled to the shaft applying rotational reciprocating movement to the rotor assembly, a position sensor for ascertaining the position of said rotor assembly, and means coupling said microcomputer to said torque motor and to said position sensor to control the operations of said torque motor by applying a drive signal in accordance with the applied audio signal and corrections thereto derived by said microcomputer.

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Abstract

Apparatus for reproducing low frequency sound in response to an applied audio signal having a rotary acoustic radiator comprised of an enclosure having a cylindrical sidewall and end walls adjoining the sidewall and forming a cylindrical chamber. A rotor assembly including a hub and movable vanes secured to the hub is rotatably mounted in the chamber for rotation on a longitudinal axis. Stationary vanes are mounted in the chamber and extend between the cylindrical sidewall and the hub and extend between the end walls. The enclosure has ports therein opening into the chamber and disposed adjacent the stationary vanes on opposite sides of said stationary vanes. The movable vanes are disposed on opposite sides of the stationary vanes and extend between the cylindrical sidewall and the hub and between the end walls. A torque motor is provided for applying rotational reciprocating movement to the rotor assembly whereby upon rotation in one direction air is forced out through the ports on one side of the stationary vanes and upon rotation of the rotor assembly in an opposite direction air is forced through the ports on the other side of the stationary vanes. A position sensor is provided for sensing the rotational position of the rotor assembly. A microcomputer is provided for controlling the reciprocating movement of the torque motor in response to the applied audio signal.

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39 Claims

1. A rotary acoustic transducer apparatus for producing sound in response to an applied audio signal, comprising a rotary acoustic radiator assembly, a torque motor, a position sensor, and a microcomputer, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through the walls of said cylindrical chamber to direct air flow into and out of the cylinder in response to movement of the movable vanes, a torque motor coupled to the shaft applying rotational reciprocating movement to the rotor assembly, a position sensor for ascertaining the position of said rotor assembly, and means coupling said microcomputer to said torque motor and to said position sensor to control the operations of said torque motor by applying a drive signal in accordance with the applied audio signal and corrections thereto derived by said microcomputer.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
- - 2. Apparatus as in claim 1 for use in a user environment together with a cabinet in the user environment and means of mounting said rotary acoustic radiator assembly so that it is carried by said cabinet and that certain of said ports open into the cabinet and certain of said ports open externally of the cabinet and produce an air flow into and out of the user environment.
  - 3. Apparatus as in claim 1 for use in a user environment together with a diffuser attenuator means disposed in the vicinity of said rotary acoustic radiator for redirecting and slowing air flow to and from ports opening into the user environment.
  - 4. Apparatus as in claim 3 wherein the diffuser attenuator means includes acoustic absorbent material to reduce noise in the air flow passing through the diffuser attenuator.
  - 5. Apparatus as in claim 1 wherein the microcomputer includes means for generating a centering signal in the drive signal to the torque motor for maintaining the average position of the rotor assembly in the center of its rotational travel arc limits.
  - 6. Apparatus as in claim 5 wherein the microcomputer includes means for generating an infrasonic signal to modulate the centering signals in the drive signal to the torque motor so that the operating center of said torque motor and rotor assembly wanders slowly about an index position to distribute bearing wear.
  - 7. Apparatus as in claim 1 wherein the microcomputer includes means for preventing contact of the moving vanes of the rotor assembly and the stationary vanes by operating on the applied audio signal.
  - 8. Apparatus as in claim 1 wherein the microcomputer includes means for calibrating motor torque linearity as a function of rotational position and for operating on the applied audio signal to compensate for any torque motor nonlinearity.
  - 9. Apparatus as in claim 1 wherein the microcomputer includes means for measuring air compliance as a function of the position of the rotor assembly and operating on the applied audio signal to compensate for any air compliance nonlinearity.
  - 10. Apparatus as in claim 1 wherein the microcomputer includes means for measuring air leakage as a function of rotor assembly position and operating on the applied audio signal to compensate for the leakage.
  - 11. Apparatus as in claim 1 wherein the microcomputer includes means for measuring bearing breakaway friction as a function of extent and velocity of bearing rotation prior to stop and duration of the bearing stop at local peaks of the applied audio signal waveform, and operating on the applied audio signal to provide a drive signal to the torque motor which produces torque when bearing rotation resumes to overcome the bearing breakaway friction.
  - 12. Apparatus as in claim 1 wherein the microcomputer includes means for providing an infrasonic signal in the drive signal to the torque motor to continue bearing rotation at local audio waveform peaks to forestall extended bearing non-rotation.
  - 13. Apparatus as in claim 1 wherein the microcomputer means provides an audio signal delay of a few milliseconds to facilitate bearing breakaway friction management by sampling and assessing the applied audio signal prior to their being supplied to the torque motor by the microcomputer.
  - 14. Apparatus as in claim 1 wherein the microcomputer includes means for sensing torque motor armature temperature and cooling the torque motor by providing an infrasonic signal in the drive signal to the torque motor to produce infrasonic oscillation of the rotor assembly.

15. A rotary acoustic radiator assembly for producing sound in response to a reciprocating rotational movement of a torque motor driven by an audio signal, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through the end walls of said cylindrical chamber adjacent to each therewith a port in an end wall on one side of said stationary vane and a port in the other end wall on the other side of said stationary vane to permit air flow into and out of the cylinder in response to movement of the movable vanes.

16. A rotary acoustic radiator assembly for producing sound in response to a reciprocating rotational movement of a torque motor driven by an audio signal, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through the end walls of said cylindrical chamber adjacent to each stationary vane, each stationary vane having associated therewith a port in an end wall on one side of said stationary vane and a port in the other end wall on the other side of said stationary vane to permit air flow into and out of the cylinder in response to movement of the movable vanes, said cylindrical means including additional ports formed in the cylindrical sidewall adjacent to each stationary vane.

17. A rotary acoustic radiator assembly for producing sound in response to a reciprocating rotational movement of a torque motor driven by an audio signal, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through the cylindrical chamber adjacent to each stationary vane, each stationary vane having associated therewith a sidewall port on one side of said stationary vane and an end wall port on the other side of said stationary vane to permit air flow into and out of the cylinder in response to movement of the movable vanes.

18. A rotary acoustic radiator assembly for producing sound in response to a reciprocating rotational movement of a torque motor driven by an audio signal, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through at least certain of the end walls and the sidewall and into said cylindrical chamber to permit air flow into and out of the cylindrical chamber in response to movement of the movable vanes, certain of said ports in the cylindrical chamber walls being at least partially superposed in the same angular sector about the axis.

19. A rotary acoustic radiator assembly for producing sound in response to a reciprocating rotational movement of a torque motor driven by an audio signal, said rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having certain ports opening through an end wall of said cylindrical chamber to permit air flow into and out of the cylindrical chamber in response to movement of the movable vanes, said certain ports being arranged so that air flow therethrough passes through said torque motor for cooling the torque motor.

20. In a rotary acoustic transducer apparatus for producing sound in response to an applied audio signal, comprising a rotary acoustic radiator assembly and a torque motor, the rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening through at least certain of the walls to permit air flow into and out of the cylinder in response to movement of the movable vanes, said torque motor coupled to the shaft applying rotational reciprocating movement in accordance with an applied audio signal, said torque motor including a torque motor shaft and an armature mounted on the shaft and a capstan formed of an insulating material mounted on said torque motor shaft, first and second conducting metal foil strips secured to said capstan at separate positions thereon having first ends connected to said armature and having second ends supported and tensioned individually by conductive leaf springs so that the capstan may rotate over a limited range while maintaining electrical continuity through said metal foil strips and leaf springs, and means connecting said leaf springs to the applied audio signal.

21. A rotary acoustic transducer for producing sound in response to an audio signal in a user environment, comprising a rotary acoustic radiator assembly and torque motor, the rotary acoustic radiator assembly comprising a generally cylindrical means with a cylindrical sidewall and end walls forming a cylindrical chamber having an axis, a shaft, bearings mounting said shaft in said cylindrical means for rotation about said axis, a cylindrical hub secured to said shaft and extending between said end walls, movable vanes secured to said shaft, said shaft, said hub, and said movable vanes forming a rotor assembly, stationary vanes mounted in said chamber between said moving vanes and extending between said cylindrical sidewall and said hub and between said end walls, said cylindrical means having ports opening into said cylindrical chamber and into the user environment to permit air flow into and out of the cylindrical chamber in response to movement of the movable vanes, said torque motor being coupled to said shaft and applying rotational reciprocating movement in accordance with the applied audio signal and diffuser attenuator means disposed in the vicinity of said acoustic radiator for redirecting and slowing air flow into and from ports opening into the user environment.
- View Dependent Claims (22)
- - 22. Apparatus as in claim 21 wherein the diffuser attenuator means includes acoustic absorbent material to reduce noise in the air flow passing through the diffuser attenuator.

23. In a method for producing low frequency sound from an applied audio signal by the use of a rotary acoustic transducer apparatus comprising an enclosure providing a cylindrical chamber having one set of stationary vanes mounted therein and having a rotor assembly mounted therein having one set of movable vanes mounted thereon, the enclosure having ports therein in communication with the cylindrical chamber, torque motor means coupled to said rotor assembly for causing rotary reciprocating movement of said rotor assembly, and a microcomputer for receiving the applied audio signal and for supplying a drive signal to the torque motor means, the microcomputer having a memory with at least one table of information having values stored therein related to a physical characteristic of the rotary acoustic transducer apparatus including rotor assembly position, the method comprising the steps of causing the microcomputer to sense the position of the rotor assembly and to read values from said at least one table, and utilizing the sensed rotor assembly position and the read values from said at least one table to control the operation of the rotor assembly.
- View Dependent Claims (24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35)
- - 24. A method as in claim 23 together with the step of measuring physical characteristics of the rotary acoustic transducer apparatus and creating additional tables in microcomputer memory for reference during rotary acoustic transducer apparatus operation.
  - 25. A method as in claim 24 together with the step of updating said additional tables in microcomputer memory during operation for reference during rotary acoustic transducer apparatus operation.
  - 26. A method as in claim 25 wherein bearing means is provided for rotatably mounting the rotor assembly, said bearing means having breakaway friction, together with means for measuring the bearing breakaway friction as a function of the extent and velocity of rotation of the bearing prior to stop, together with the step of causing the microcomputer to measure the bearing breakaway friction and operating on the applied audio signal to provide torque when the bearing rotation resumes to overcome the breakaway friction.
  - 27. A method as in claim 25 together with the step of causing the microcomputer to cause generation of an infrasonic signal in the drive signal to the torque motor to continue bearing rotation at local audio waveform peaks to forestall extended bearing non-rotation.
  - 28. A method as in claim 25 together with the step of causing the microcomputer to provide a delay in the drive signal supplied to the torque motor to facilitate bearing breakaway friction management by sampling and assessing the applied audio signal prior to its being supplied to the torque motor.
  - 29. A method as in claim 25 together with the step of causing the microcomputer to sense torque motor armature temperature and to generate an infrasonic signal in the drive signal in response to the measured armature temperature to produce infrasonic oscillation of the rotor assembly for cooling the torque motor.
  - 30. A method as in claim 24 together with the step of causing the microcomputer to calibrate the linearity of the torque from the torque motor as a function of rotational position of the torque motor and operate on the applied audio signal to compensate for any nonlinearity in the torque motor.
  - 31. A method as in claim 24 for use in cabinetry together with the step of causing the microcomputer to measure air compliance in the chamber and the cabinetry as a function of the position of the rotor assembly and operate on the applied audio signal to compensate for any nonlinearities in the air compliance.
  - 32. A method as in claim 24 together with the step of causing the microcomputer to measure vane and air leakage as a function of rotor assembly position and operate on the applied audio signal to compensate for any measured leakage.
  - 33. A method as in claim 23 together with the step of causing the microcomputer to generate centering signals in the drive signal to the torque motor to maintain the average position of the rotor assembly in the center of its rotational arc limits.
  - 34. A method as in claim 33 together with the step of causing the microcomputer to generate an infrasonic signal to modulate the centering signals in the drive signal for the torque motor and rotor assembly so that the operating center of the rotor assembly wanders slowly to distribute bearing wear.
  - 35. A method as in claim 23 together with the step of causing the microcomputer to prevent contact of the movable vanes of the rotor assembly and the stationary vanes by operating on the applied audio signal.

36. In a method for producing low frequency sound by the use of an applied audio signal by the use of one set of stationary vanes and one set of movable vanes mounted in a cylindrical housing having at least one end wall having end ports therein, said method comprising moving the movable vanes in the housing in accordance with the applied audio signal to cause the movable vanes to move towards and away from the stationary vanes to cause air flow to pass rapidly into and out of the end ports to create low frequency sound.

37. In a method for producing low frequency sound by the use of an applied audio signal by the use of one set of stationary vanes and one set of movable vanes mounted in a cylindrical housing having at least one end wall having end ports therein, said method comprising moving the movable vanes in the housing in accordance with the applied audio signal to cause the movable vanes to move towards and away from the stationary vanes to cause air flow to pass rapidly into and out of the end ports to create low frequency sound and slowing and redirecting the air flow into and out of certain of said ports.
- View Dependent Claims (38, 39)
- - 38. A method as in claim 37 together with the step of absorbing high frequency noise from the air flow into and out of the ports.
  - 39. A method as in claim 37 together with the step of screening the air flow into the ports.

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Current Assignee
Bradner L. Hisey
Original Assignee
Bradner L. Hisey
Inventors
Hisey, Bradner L.
Primary Examiner(s)
Ng, Jin F.
Assistant Examiner(s)
Le, Huyen D.

Application Number

US07/632,047
Time in Patent Office

803 Days
Field of Search

381/165, 381/158, 340/388, 340/390, 340/391, 340/404
US Class Current

381/165
CPC Class Codes

G10K 7/04   by an electric motor

H02K 26/00   Machines adapted to functio...

H04R 23/00   Transducers other than thos...

Rotary low-frequency sound reproducing apparatus and method

First Claim

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85 Citations

39 Claims

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Rotary low-frequency sound reproducing apparatus and method

First Claim

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Abstract

85 Citations

39 Claims

Specification

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Solutions

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