RU2361371C2 - Acoustic device and method of making said device - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: acoustic device, contains a diaphragm (10) with a radiating surface, and with an operating frequency range, and diaphragm (10) has resonance modes in the operating band, an electromechanical transducer, comprising an excitation component, connected to the diaphragm (10) and capable of exchanging energy with the diaphragm, and at least one device (20, 22, 24) for mechanical resistance, joined with the diaphragm or integral with it. Positioning and mass of the excitation component (26) of the transducer and at least one device (20, 22, 24) for mechanical resistance are such that, the resultant speed of transverse modes on the surface of the diaphragm (10) approaches zero.

EFFECT: another method of making an acoustic device is presented.

87 cl, 60 dwg

Description

The text of the description is given in facsimile form.

Claims (87)

1. An acoustic device containing a diaphragm having an area and having an operating frequency range, and the diaphragm is such that it has resonance modes in the working frequency range, an electromechanical converter with an excitation component associated with the diaphragm and configured to exchange energy with the diaphragm, and at least one means of mechanical resistance connected to the diaphragm or integral with it, moreover, the positioning and mass of the excitation component in the transducer and in m nshey least one mechanical impedance means being such that the resulting velocity of transverse modes of the diaphragm area tends to zero. 2. The acoustic device according to claim 1, in which the diaphragm parameters are such that there are two types of diaphragm vibrations in the operating frequency range. 3. The acoustic device according to claim 1, in which the operating frequency range includes a transition from the piston to the wave mode and the transducer is adapted to move the diaphragm during the conversion. 4. The acoustic device according to claim 1, in which the excitation component of the Converter is associated with the diaphragm in the middle position of the mode nodes in the operating frequency range. 5. The acoustic device according to claim 1, in which at least one means of mechanical resistance is connected to the diaphragm or is integral with it in the middle position of the mode nodes in the operating frequency range. 6. The acoustic device according to claim 1, in which the transducer is a device with a moving coil, comprising a voice coil, which makes up the excitation component, and a magnetic system, and contains means connecting the voice coil with a diaphragm in the middle position of the mode nodes in the operating range frequencies. 7. The acoustic device according to claim 1, containing a chassis (frame) and an elastic suspension connecting the diaphragm to the chassis, the suspension is connected to the diaphragm in the middle position of the nodes for the modes in the operating frequency range. 8. The acoustic device according to claim 7, in which the transducer is a moving coil device comprising a voice coil, which makes up the excitation component, and a magnetic system, and comprises means connecting the voice coil to the diaphragm in the middle position of the mode nodes in the operating range frequencies, and the magnetic system is grounded on the chassis. 9. The acoustic device according to claim 7, in which the position in which the excitation component of the transducer is connected to the diaphragm is a position different from that in which said suspension is connected to the diaphragm. 10. An acoustic device according to any preceding claim, wherein the diaphragm has a generally circular perimeter and a center of mass. 11. The acoustic device of claim 10, wherein the aperture parameters are such that the first aperture mode is below ka = 2, where k is the wave number and a is the radius of the diaphragm. 12. The acoustic device of claim 10, depending on any of claims 4 to 9, in which one of the middle positions of the nodes or each is in a flat ring and the ratio of the diameter of the flat ring to the diameter of the diaphragm depends on the number of modes in the operating frequency range. 13. The acoustic device according to item 12, in which the axial modes are considered additionally. 14. The acoustic device of claim 10, in which the excitation component of the Converter is connected concentrically relative to the center of mass of the diaphragm. 15. The acoustic device of claim 10, depending on claim 7, in which the suspension is connected concentrically relative to the center of mass of the diaphragm and in the direction from its outer edge. 16. The acoustic device of claim 10, in which at least one means of mechanical resistance has the form of an annular mass. 17. The acoustic device according to clause 16, containing several annular masses associated with the diaphragm or integral with it, in the middle positions of the mode nodes in the operating frequency range. 18. An acoustic device according to any one of claims 1 to 9, in which the diaphragm is generally rectangular and has a center of mass. 19. The acoustic device according to claim 18, wherein the aperture parameters are such that the first aperture mode is below kl = 4, where k is the wave number and 1 is the length of the aperture. 20. The acoustic device according to claim 18, depending on any of claims 4 to 9, in which one of the middle positions of the nodes or each is in a pair of opposite positions and the ratio of the distance of each opposite position from the center of mass to half the length of the diaphragm depends on the number of modes in the operating frequency range. 21. The acoustic device according to claim 20, containing a pair of transducers, each of the pair being installed in one of the opposite positions. 22. The acoustic device according to claim 20, in which the transducer is mounted centrally on the diaphragm so that its excitation component actuates the two opposite positions. 23. The acoustic device according to claim 20, depending on claim 7, wherein the suspension is located in said opposed positions. 24. The acoustic device according to claim 20, in which the means of mechanical resistance has the form of a pair of masses, each of which is located in one of the mentioned opposite positions. 25. The acoustic device according to paragraph 24, containing several pairs of masses associated with the diaphragm or integral with it. 26. The acoustic device according to claim 18, wherein the diaphragm is lucid and the modes are along the longitudinal axis of the beam. 27. The acoustic device according to claim 26, wherein the excitation component of the transducer means and at least one mechanical resistance means are associated with the diaphragm along the longitudinal axis of the beam. 28. The acoustic device according to p, in which the ratio of the diameter of the excitation component of the Converter to the width of the diaphragm is such as to suppress the lower transverse mode. 29. The acoustic device according to p, in which the ratio of the diameter of the excitation component of the Converter to the width of the diaphragm is approximately 0.8. 30. The acoustic device according to clause 16 or 25, in which the masses decrease in value towards the center of the diaphragm. 31. The acoustic device according to PP.16, 25 or 30, in which the masses are scaled with respect to the mass of the excitation component of the Converter. 32. An acoustic device according to any one of claims 1 to 9, in which the diaphragm is isotropic with respect to bending stiffness. 33. An acoustic device according to any one of claims 1 to 9, containing damping means that is mounted with the diaphragm or is integral with it at the location of the high speed of the diaphragm in order to damp the mode. 34. The acoustic device according to claim 33, wherein the diaphragm has a generally circular perimeter and center of mass, and in which the damping means is an annular plate connected concentrically relative to the center of mass of the diaphragm. 35. An acoustic device according to any one of claims 1 to 9, containing a size adapter in the form of a lightweight rigid connecting element that connects the transducer to the diaphragm. 36. The acoustic device according to clause 35, in which the connecting element is connected to the transducer in the first diameter and connected to the diaphragm in the second diameter. 37. The acoustic device according to clause 35, in which the connecting element has the shape of a truncated cone. 38. An acoustic device according to any one of claims 1 to 9, in which said diaphragm comprises an opening. 39. The acoustic device according to claim 38, comprising a second diaphragm mounted inside the hole, the second diaphragm has an area and an operating frequency range and the second diaphragm is such that it has resonant modes in the operating frequency range, an electromechanical converter having an excitation component is connected with the diaphragm and is configured to exchange energy with the diaphragm, and at least one means of mechanical resistance is connected to the diaphragm or is integral with it, and positioning and mass transducer excitation component and at least one mechanical impedance means being such that the resulting velocity of transverse modes over the area of the second diaphragm tends to zero. 40. An acoustic device according to claim 38, comprising an element mounted in said hole, whereby the hole is substantially acoustically sealed. 41. An acoustic device according to any one of claims 1 to 9, in which the diaphragm is essentially flat. 42. An acoustic device according to any one of claims 1 to 9, depending on claim 7, in which the mass of the suspension is scalable by the mass of the excitation component of the transducer. 43. An acoustic device according to any one of claims 1 to 9, in which the acoustic device is a loudspeaker and the transducer is configured to apply bending wave energy to the diaphragm in response to an electrical signal applied by the transducer, and wherein the diaphragm is configured to emit an acoustic signal ( sound) over the radiating area. 44. The acoustic device according to item 43, containing a partition surrounding the radiating area of the diaphragm. 45. A method of creating an acoustic device with a diaphragm having an area and having an operating frequency range, which comprises the step of selecting the diaphragm parameters so that it has resonant modes in the working frequency range, the step of linking the excitation component of the electromechanical transducer with the diaphragm in order to exchange energy with the diaphragm , the step of adding at least one mechanical resistance to the diaphragm and the step of selecting the position and mass of the transducer excitation component and position parameters of at least one means of mechanical resistance so that the resulting speed of the transverse modes of said area tends to zero. 46. The method according to item 45, containing the step of displaying the velocity profiles of the freely oscillating diaphragm on those for the said diaphragm. 47. The method according to item 45, comprising the step of providing such aperture parameters to have two types of diaphragm vibrations in the operating frequency range. 48. The method according to item 45, containing the step of providing an operating frequency range, including the transition from the piston to the wave mode, and providing the Converter with the ability to move the diaphragm during the conversion. 49. The method according to item 45, containing the step of connecting the excitation component of the Converter with the diaphragm in the middle position of the mode nodes in the operating frequency range. 50. The method according to item 45, containing the stage of location of at least one means of mechanical conversion in the middle position of the nodes for the diaphragm modes in the operating frequency range. 51. The method according to item 45, in which the Converter is a device with a moving coil, comprising a voice coil, which is a component of the excitation, and a magnetic system, and includes the step of connecting the voice coil with a diaphragm in the middle position of the mode nodes in the operating frequency range. 52. The method according to item 45, comprising the step of connecting the elastic suspension with the diaphragm in the middle position of the mode nodes in the operating frequency range and connecting the suspension to the chassis (frame). 53. The method according to paragraph 52, in which the Converter is a moving coil device, comprising a voice coil, which makes up the excitation component, and a magnetic system, and includes the step of connecting the voice coil with the diaphragm in the middle position of the mode nodes in the operating frequency range and the step of connecting the magnetic system to the chassis. 54. The method according to paragraph 52, comprising the step of connecting the excitation component of the transducer to the diaphragm at a position other than that in which the suspension is connected to the diaphragm. 55. The method according to paragraph 52, comprising the step of scaling the suspension mass by the mass of the converter excitation component. 56. The method according to any one of claims 45-55, comprising making a diaphragm having a substantially circular perimeter and center of mass. 57. The method of claim 56, comprising the step of providing such aperture parameters such that the first aperture mode is below ka = 2, wherein k is the wave number and a is the radius of the diaphragm. 58. The method according to p. 56 or 57, comprising the step of balancing the diaphragm modes by changing the diameter of the excitation of the diaphragm between its center and its perimeter, the step of calculating the average conductivity of the point of excitation when the diameter of the excitation changes, and the step of adding mechanical resistances at positions specified by the conductivity minima . 59. The method according to claim 56, depending on any one of claims 49-55, comprising the step of arranging one of the middle positions of the nodes or each in a flat ring and determining a ratio of the diameter of the flat ring to the diameter of the diaphragm based on the number of radial modes in the operating frequency range. 60. The method according to § 59, containing the stage of consideration of axial modes. 61. The method according to p, containing the step of linking the excitation component of the Converter with the diaphragm concentrically relative to the center of mass of the diaphragm. 62. The method according to p, containing the step of connecting the suspension concentrically with respect to the center of mass of the diaphragm and away from its outer edge. 63. The method according to p, containing the stage of location of at least one means of mechanical resistance so that it is an annular mass. 64. The method according to item 63, containing the step of providing multiple annular masses. 65. The method according to any one of claims 45-55, comprising the step of making the diaphragm generally rectangular and having a center of mass. 66. The method of claim 65, comprising the step of selecting aperture parameters so that the first aperture mode is below kl = 4, wherein k is the wave number and 1 is the length of the aperture, 67. The method according to item 65, depending on any one of claims 49-55, comprising the step of placing one of the middle positions of the nodes or each in a pair of opposite positions and determining the ratio of the distance of each opposite position from the center of mass to half the length of the diaphragm based on the number of modes in the operating frequency range. 68. The method according to p, containing the step of installing the Converter in each opposite position. 69. The method according to item 67, comprising the step of installing the transducer in the center of the diaphragm so that its excitation component acts on two opposite positions. 70. The method according to item 67, depending on item 52, comprising the step of positioning the suspension in said opposed positions. 71. The method according to item 67, containing the step of adding a means of mechanical resistance in the form of a pair of masses and the location of each mass in one of the mentioned opposite positions. 72. The method according to p, containing the step of adding to the diaphragm several pairs of masses. 73. The method according to item 65, containing the step of making the diaphragm lucid and having a mode along the longitudinal axis of the diaphragm. 74. The method according to p, comprising the step of linking the excitation component of the converter means and at least one mechanical resistance means along the longitudinal axis of the diaphragm. 75. The method according to item 65, containing the step of selecting the ratio of the diameter of the excitation component of the Converter to the width of the diaphragm in order to suppress the transverse mode of the lower order. 76. The method according to item 75, containing the step of selecting the ratio of the diameter of the excitation component of the Converter to the width of the diaphragm equal to approximately 0.8. 77. The method according to item 64, comprising the step of placing the masses so that they decrease in value towards the center of the diaphragm. 78. The method according to claims 64, 72, or 77, comprising the step of scaling the masses by mass of the converter excitation component. 79. The method according to any one of claims 45-55, comprising the step of making the diaphragm isotropic with respect to bending stiffness. 80. The method according to any one of claims 45-55, comprising the step of selecting a mode to be damped and adding damping means to the diaphragm at a location of the high speed of the diaphragm, whereby the selected mode is damped. 81. The method according to p. 80, containing the implementation of the diaphragm having a substantially circular perimeter and center of mass, and the step of connecting a damping means having the form of an annular damping lining concentrically with respect to the center of mass of the diaphragm. 82. The method according to any one of claims 45-55, comprising the step of connecting the transducer to the diaphragm using a size adapter in the form of a lightweight rigid adapter. 83. The method of claim 82, comprising the step of connecting the connecting element to the transducer in a first diameter and connecting the connecting element with a diaphragm in a second diameter. 84. The method according to any one of claims 45-55, comprising the step of providing an opening in said diaphragm. 85. The method of claim 84, comprising the step of executing a second diaphragm inside the opening in said diaphragm, wherein the second diaphragm has an area and an operating frequency range, and comprising the step of selecting parameters of the second diaphragm so that it has resonant modes in the operating frequency range, step the connection of the excitation component of the Converter with the second diaphragm to exchange with it the energy of bending waves and the stage of application to the diaphragm of at least one means of mechanical resistance. 86. The method of claim 84, comprising the step of installing the sealing member in the hole, whereby the hole is substantially acoustically sealed. 87. The method according to any one of claims 45-55, comprising making the diaphragm substantially flat.

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