The present invention relates to a hybrid speaker combining a speaker function that produces sounds from a diaphragm with an actuator function that transmits vibrations to a speaker panel, to which the speaker is attached, so as to simultaneously produce sounds from the speaker panel. The present invention particularly relates to a hybrid speaker that, although compact, provides powerful high-pitched, medium pitched and low pitched sounds.
A composite speaker (see the specification of WO2011/077770) emits sounds from both a diaphragm and a speaker panel. The composite speaker is provided with: a plural number of magnets arranged at a predetermined interval; a yoke that forms magnetic circuits with the magnets, with magnetic gaps; voice coils that are disposed so as to cross magnetic circuits between the magnets and between the magnets and the yoke; a diaphragm, at one face of which the voice coils are secured; a frame that supports the diaphragm at periphery portions of the diaphragm and that accommodates the magnets and the yoke; the speaker panel, to which the frame is secured at a side of the frame that is opposite to the side thereof that supports the diaphragm; and a resilient member provided between the speaker panel and the yoke.
In the composite speaker recited in WO 2011/077770, the diaphragm emits high pitched sounds and the speaker panel emits medium and low pitched sounds. Thus, auditory localization is possible and the composite speaker has rich medium and low pitched sound components.
In recent years, there have been calls for hybrid speakers whose efficiency is more excellent than composite speakers and whose fabrication costs are low.
An object of the present invention is to provide a hybrid speaker that provides more powerful high sounds and medium and low sounds than the composite speaker recited in Patent Reference 1, and that is competitive in price.
A first aspect of the present invention relates to a hybrid speaker including: first magnets that are arranged at predetermined intervals such that one of south poles or north poles thereof are oriented to the same side; second magnets that have smaller volumes than the first magnets and that are arranged singly or in pluralities between the first magnets such that the magnetic poles thereof are oriented the opposite way to the first magnets; a yoke that accommodates the first and second magnets and that forms magnetic circuits with the first magnets; a voice coil that is disposed so as to cross magnetic circuits between the first magnets and the second magnets and between the first magnets and the yoke; a diaphragm, at one face of which the voice coil is fixed; a frame, to which the diaphragm is fixed at periphery portions of the face at the side of the diaphragm at which the voice coil is fixed; and a yoke support member that resiliently supports the yoke at the frame, at a face of the frame that is at the opposite side thereof from the side at which the diaphragm is fixed.
This hybrid speaker has a structure in which the first magnets and the second magnets with smaller volumes than the first magnets are arranged in a row such that the magnetic poles thereof are opposite. Therefore, magnetic fields produced between the first magnets and the second magnets are more intense than in a structure in which first magnets and second magnets have the same volume and are arranged at intervals.
Therefore, a larger diaphragm driving force can be generated by sound signals with the same strength flow in the voice coil.
Further, because the yoke is resiliently supported at the face that is at the opposite side of the frame from the side thereof at which the diaphragm is fixed, when a sound signal flows in the voice coil, as well as the diaphragm vibrating, the magnets and the yoke vibrate; the diaphragm and the yoke vibrate in anti-phase. The diaphragm is disposed such that the voice coil is placed at an aperture portion of the frame, the diaphragm being fixed to the frame at the outer side relative to the aperture portion of the frame. Therefore, when the frame is fixed to a speaker panel that includes an aperture portion that corresponds with the frame aperture portion, a region of the diaphragm at the inner side of the frame aperture portion functions as a diaphragm with a size corresponding to the frame aperture portion, and a region of the diaphragm at the outer side relative to the frame aperture portion functions as an actuator that causes the speaker panel to vibrate. Thus, high sounds are directly emitted from the diaphragm. For medium and low sounds, in addition to vibrations of the diaphragm, vibrations of the yoke are reversed in phase by the yoke support member and transmitted to the panel via the frame and the diaphragm. Therefore, powerful high sounds and medium and low sounds are produced.
A second aspect of the present invention relates to the hybrid speaker of the first aspect wherein the yoke support member is a plate spring of which one end is fixed to the yoke and the other end is fixed to the frame.
In this hybrid speaker, because the yoke support member is a plate spring, it is simple to specify a spring coefficient of the yoke support member, and functioning is reliable.
A third aspect of the present invention relates to the hybrid speaker of the second aspect wherein the plate spring is fixed to the yoke by the one end of the plate spring being nipped by a plate spring holding member and an end portion of the yoke, and the plate spring holding member is formed so as to protrude from the end portion of the yoke toward the other end portion of the plate spring.
In this hybrid speaker, the plate spring holding member is formed so as to protrude from the end portion of the yoke toward the other end portion of the plate spring. Therefore, the effective length of the plate spring differs between when the yoke moves in the direction approaching the diaphragm and when the yoke moves in the direction away from the diaphragm. When the yoke moves in the direction approaching the diaphragm, the effective length of the plate spring is shorter and deformation of the plate spring is suppressed.
Therefore, even when large sound signals are inputted into the voice coil, contact between the magnets and the voice coil and the production of abnormal sounds can be prevented. Moreover, an air gap between the voice coil and the first and second magnets may be made smaller. Therefore, larger acoustic pressures can be provided even when sound signals of the same magnitude are inputted.
A fourth aspect of the present invention relates to the hybrid speaker of any one of the first to third aspects wherein a shape in plan view of the diaphragm is a high-order curve represented by the following expression in an X-Y co-ordinate system whose origin is a central point of the diaphragm:
ri=|x|i+|y|i
(in which r represents a radius and i represents an integer from 5 to 7),
In this hybrid speaker, the diaphragm has a plan view shape that is a semi-stadium shape with an outline that is a fifth- to seventh-order curve. Therefore, when the diaphragm and the magnets vibrate, strongly chaotic irregular vibrations are caused. Thus, degeneration does not occur and the characteristic frequency distribution follows a Wigner distribution.
Thus, a hybrid speaker is provided that may reproduce both medium and low sounds and high sounds more faithfully than in a case in which a diaphragm has a plan view shape other than the plan view shape described above.
According to one aspect of the present invention as described herein, because functioning of the spring is reliable and a face of the hybrid speaker at which the diaphragm is disposed is placed on the panel, more powerful high sounds and medium and low sounds are provided relative to the composite speaker recited in WO 2011/077770; and because the volume of the magnets is reduced, a hybrid speaker whose fabrication costs are inexpensive is provided.
Herebelow, examples of the hybrid speaker of the present invention are described in detail with reference to the drawings.
—Structure—
As shown in
As shown in
As shown in
Regarding the volumes of the first magnets 1 and second magnets 2, if the volume of each first magnet 1 is represented by V and the volume of each second magnet 2 is represented by v, it is preferable if the relationship therebetween is ½≧v/V≧⅕. Therefore, if a length×width×thickness of the first magnet 1 is 10 mm×10 mm×3 mm, a Length×width×thickness of the second magnet 2 of around 5 mm×5 mm×3 mm is preferable. As shown in
As shown in
Suspension blocks 16 are fixed by screws 14 to central portions of the short sides of the upper side face of the frame 5. One end portions of the plate springs 7 are fixed to end portions of the yoke 4 and other end portions of the plate springs 7 are fixed to the suspension blocks 16. In a state in which the other end portion of each plate spring 7 is nipped by a spacer 11 and a plate spring holding member 10, the other end portion of the plate spring 7 is fixed to an upper face of the suspension block 16 by screws 12. In
As shown in
ri=|x|i+|y|i
(in which r represents a radius and i represents an integer from 5 to 7), since a hybrid speaker having the diaphragm 6 and the frame 5 having a shape of high-order curves having an order of 5 to 7 would produce high pitched sounds as well as medium and low pitched sounds more faithfully than a hybrid speaker having the diaphragm 6 and the frame 5 not in a shape of a fifth to seventh order high-order curves.
—Operation—
Herebelow, operation of the hybrid speaker 100 is described.
As described above, the south poles of the first magnets 1 and the north poles of the second magnets 2 are arranged inside the yoke 4 so as to oppose the diaphragm 6. Therefore, lines of magnetic force from the first magnets 1 to the second magnets 2 are generated. Lines of magnetic force are also generated between the first magnets 1 and the yoke 4.
The voice coils 3 are fixed to the face at the upper side of the diaphragm 6 so as to oppose the first magnets 1. Therefore, windings of the voice coils 3 cross the lines of magnetic force between the first magnets 1 and the second magnets 2 and the lines of magnetic force between the first magnets 1 and the yoke 4.
Thus, when sound signals are inputted to the voice coils 3, varying magnetic fields are produced at the voice coils 3. The varying magnetic fields interact with the lines of magnetic force from the first magnets 1 to the second magnets 2 and the lines of magnetic force between the first magnets 1 and the yoke 4, and the diaphragm 6 vibrates.
The first magnets 1 and the second magnets 2 with smaller volumes than the first magnets 1 are arranged in a straight line, and the second magnets 2 are arranged singly or in pairs between the first magnets 1. Therefore, more intense lines of magnetic force are produced between the first magnets 1 and second magnets 2 than if the first magnets 1 and second magnets 2 had the same volume and were spaced therebetween.
From
Therefore, in the hybrid speaker 100, even though the volume of the magnets is greatly reduced, the diaphragm 6 vibrates with greater amplitudes than if sound signals of the same magnitude were inputted to the voice coils 3 in a case in which the first magnets 1 and second magnets 2 have the same volumes.
In
When sound signals are inputted to the voice coils 3, in addition to the diaphragm 6 vibrating, the yoke 4 vibrates, at the opposite phase from the diaphragm 6. However, because the yoke 4 is resiliently supported at the frame 5 via the suspension blocks 16 and the plate springs 7 fixed to the two ends of the yoke 4, the phase of the vibrations of the yoke 4 is reversed and the frame 5 is caused to vibrate in the same phase of the vibrations of the diaphragm 6.
Therefore, when the face at the side of the frame 5 at which the diaphragm 6 is fixed is placed on a panel with an aperture portion that corresponds with the aperture portion 5A of the frame 5, high pitched sounds are transmitted directly from the diaphragm 6 to the panel, and medium and low pitched sounds are transmitted to the panel by the vibrations of the diaphragm 6 synergistically with vibrations that are transmitted to the panel via the frame 5. Thus, more powerful high pitched sounds and medium and low pitched sounds can be provided.
The panel may be a fiber-molded board in which a fiber material is molded into a board shape, a wooden board, a metal board, a plastic board, a foam plastic board, a composite material of the above, or the like.
Herebelow, alternative examples of the hybrid speaker of the present invention are described.
—Structure—
As shown in
As shown in
As shown in
Regarding the volumes of the first magnets 1 and the second magnets 2, if the volume of each first magnet 1 is represented by V and the volume of each second magnet 2 is represented by v, it is preferable if the relationship therebetween is ½≧v/V≧⅕. Therefore, in the case of an arrangement as illustrated in
In the case of an arrangement as illustrated in
As shown in
The diaphragm 6 is fixed to the face at the side of the frame 5 that is opposite to the side thereof at which the inflected portions 5B, the spring member attachment portion 5C and the spring member attachment portion 5D are formed, which is to say the face at the lower side of the frame 5. The diaphragm 6 is fixed such that the voice coils 3 are disposed at the inner side of the aperture portion 5A of the frame 5. The diaphragm 6 may be fixed to the lower face of the frame 5 by adhesion, and may be fixed by double-sided adhesive tape.
As shown in
The diaphragm 6 is the same as described in the first exemplary embodiment.
—Operation—
The magnetic force intensifying effect caused by the first magnets 1 and second magnets 2 inside the yoke is the same as described in the section on “Operation” of the first exemplary embodiment.
In the hybrid speaker 102, when sound signals are inputted to the voice coils 3, in addition to the diaphragm 6 vibrating, the yoke 4 vibrates, at the opposite phase from the diaphragm 6. However, because the yoke 4 is resiliently supported at the spring member attachment portion 5C and spring member attachment portion 5D of the frame 5 via the plate springs 7 fixed at the two ends of the yoke 4, the phase of the vibrations of the yoke 4 is reversed and the frame 5 is caused to vibrate in the same phase of the vibrations of the diaphragm 6.
Therefore, when the face at the side of the frame 5 at which the diaphragm 6 is fixed is placed on the panel with the aperture portion that corresponds with the aperture portion 5A of the frame 5, high pitched sounds are transmitted directly from the diaphragm 6 to the panel, and medium and low pitched sounds are transmitted to the panel by vibrations of the diaphragm 6 synergistically with vibrations that are transmitted to the panel via the frame 5. Thus, more powerful high pitched sounds and medium and low pitched sounds can be provided.
As in the hybrid speaker 100 according to the first exemplary embodiment, a fiber-molded board in which a fiber material is molded into a board shape, a wooden board, a metal board, a plastic board, a foam plastic board, a composite material of the above, or the like may be employed as the panel.
In addition, in the hybrid speaker 102 according to the second exemplary embodiment, the one end portions of the plate springs 7 are fixed to the yoke 4 not by screws 13 but by the rivets 17. Further, the other end portions of the plate springs 7 are fixed to the spring member attachment portions 5C and 5D formed at the frame 5 by the rivets 17 instead of the screws 12. Thus, slackness between the plate springs 7 and the yoke 4 and frame 5 after use over a long period may be prevented.
Herebelow, a further alternative example of the hybrid speaker of the present invention is described with reference to
As shown in
Instead of the structure as shown in
As shown in
Therefore, even when large sound signals are inputted to the voice coils 3, contact between the magnets and the voice coils 3 and the production of abnormal noises can be prevented. Moreover, an air gap between the voice coils 3 and the first magnets 1 and second magnets 2 may be made smaller. Therefore, larger acoustic pressures can be provided even when sound signals of the same magnitude are inputted.
The foregoing description of the exemplary embodiments of the present invention has been provided for the Purpose of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The exemplary embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2012-115884 | May 2012 | JP | national |
2013-103497 | May 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/063799 | 5/17/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/176053 | 11/28/2013 | WO | A |
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20150010195 | Croft, III | Jan 2015 | A1 |
20150110339 | Colich | Apr 2015 | A1 |
Number | Date | Country |
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2000023439 | Jan 2000 | JP |
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WO0078095 | Dec 2000 | WO |
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Entry |
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International Search Report and Written Opinion in International Application No. PCT/JP2013/063799 mailed Jun. 18, 2013, 7 pages. |
Number | Date | Country | |
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20150222995 A1 | Aug 2015 | US |