JP6481480B2 - Electroacoustic transducer - Google Patents

Description

  The present invention relates to an electroacoustic apparatus suitable for a speaker that reproduces sound by vibrating a convex surface or a microphone that collects sound.

A general dynamic speaker is a speaker that emits sound by piston motion in which a diaphragm is driven back and forth by a voice coil motor. It functions as a point sound source at a low frequency and has a wide directional characteristic. In this case, the directivity becomes sharp in a band that is equal to or higher than the frequency at which the aperture of the diaphragm and the half wavelength of the reproduced sound are substantially equal. For this reason, a small speaker using a small-diameter diaphragm is used for reproduction in the high sound range.
The same can be said for a dynamic microphone having an operation principle opposite to that of a dynamic speaker. That is, in order to collect a high sound range with wide directivity, a small microphone using a diaphragm having a small diameter is used.

  In contrast, the Riffel type speaker has a diaphragm composed of a pair of rectangular curved plates, has a wide directivity in the mid-high range, and the sound spreads in the lateral direction along the bending direction of the diaphragm. Therefore, it is considered that an ideal sound space can be provided by continuing in the vertical direction as a line array speaker.

Conventionally, such Riffel type speakers are disclosed in, for example, Patent Document 1 or Patent Document 2.
In Patent Document 1, a conductor pattern as a voice coil is printed on the center portion of the polymer resin film, and the center portion is folded and bonded to form a plate-like portion having a conductor pattern; A vibration plate is formed integrally with the curved first and second vibration parts, and a flat plate-like portion of the vibration plate is disposed in a magnetic gap in the magnetic circuit, and the tips of both vibration parts Discloses a speaker having a structure fixed to a support member.
In Patent Document 2, the center portion of the diaphragm is folded back with a concave portion, and a flat voice coil wound in an oval shape is disposed in the concave portion, and the voice coil is separated vertically. A speaker having a structure arranged in two magnetic gaps is disclosed. Also in this speaker, the outer peripheral part of the diaphragm is fixed on an annular frame.

JP 2002-78079 A JP 2007-174233 A

  However, since this type of riffel type speaker is not suitable for reproduction in the low frequency range, a multi-speaker system using a low frequency range speaker (woofer) is separately used to reproduce the entire audible range. There is a need.

  The present invention has been made in view of such circumstances, and provides an inexpensive electroacoustic transducer having a wide directivity over a wide frequency band from a low frequency range to a high frequency range with a single unit. With the goal.

  An electroacoustic transducer according to the present invention includes a vibrating body, a conversion unit that converts vibrations of the vibrating body and an electric signal corresponding to the vibration, and supports the vibrating body so as to vibrate along the direction of the vibration. And the vibrating body includes a pair of convex surfaces each including a convex surface of each of the pair of vertically split cylindrical portions, and a trough portion between one side portions of each of the pair of convex surfaces. The formed wing-like vibrating part, the valley closing part that connects between the outer peripheral edges of the pair of convex surfaces at both ends of the valley part and closes both ends of the valley part, the outer peripheral part of the valley closing part, and the pair And a cone-shaped vibrating portion formed in a cone shape that is joined to the other side portion of the convex surface and extends around the valley closing portion and the wing-shaped vibrating portion.

  This electroacoustic transducer has two types of vibration parts: a wing-like vibration part having a convex surface of each of a pair of vertically split cylindrical parts, and a cone-like vibration part provided on the outside thereof. When applied to a speaker, the wing-like vibration part has a wide directivity in the mid-high range, similar to the Riffel-type speaker, and the cone-like vibration part arranged outside the wing-like vibration part has a wide directivity characteristic in the low sound range. have. In addition, since the entire vibrating body that is vibrated by the conversion unit performs a piston motion, it has a high sound pressure even in a low sound range, like a dynamic speaker. Therefore, it is possible to realize a full-range speaker unit that can be reproduced with a wide directivity over the entire audible band from the low sound range to the mid-high sound range with a single speaker unit.

  In this case, when the vibrating body is formed only by the wing-like vibrating part, the vibration behavior becomes unstable, such as the rigidity of the convex surface is reduced and local divided vibration is likely to occur when the vibrating body is enlarged in diameter. This makes it difficult to obtain a uniform frequency characteristic of reproduced sound pressure within the audible band. The present invention arranges a wing-like vibration part at the center of the vibrating body, suppresses the wing-like vibration part to an appropriate outer diameter, and arranges a cone-like vibration part on the outside thereof, thereby reproducing wing-like vibration in the mid-high range. The cone-shaped vibrating portion plays a low-frequency range while the unit plays a role, and a wide directivity is secured in the entire audible band even in speaker units having various apertures.

In addition, when the vibrating body is formed only by the wing-like vibrating portion, the outer peripheral edge has a complicated shape, so the structure of the support portion is also complicated, but the outer peripheral portion of the vibrating body is formed by the cone-like vibrating portion. Therefore, similarly to a normal conical vibrator, a support having a simple shape such as a circular ring shape or an elliptical ring shape can be used, and can be manufactured at low cost.
Even when the present invention is applied to a microphone, each convex surface of the pair of vertically split cylindrical portions is a vibrating surface, and the entire vibrating body vibrates uniformly, so that directivity is good while maintaining sensitivity. Thus, sound can be collected with a wide directivity over a wide frequency band from a low sound range to a high sound range.

  In the electroacoustic transducer according to the present invention, two pairs of the convex surfaces are provided on the wing-like vibrating portion, and the two pairs of convex surfaces form a valley portion between valleys between the convex surfaces of each pair. The side portions opposite to the side portions forming the ridge portions may form ridge portions, and at least one of the valley portions or the ridge portions may be arranged orthogonally.

The wing-like vibration part responsible for reproduction and sound collection in the mid-high range has a characteristic that sound directivity in the lateral direction along the circumferential direction of the pair of convex surfaces is wide and narrow in the vertical direction. In this electroacoustic transducer, the wing-like vibration part having such characteristics is obtained by arranging either a valley part or a peak part of two pairs of convex surfaces orthogonally.
By arranging the intersecting portion where the valleys or the mountain portions are orthogonal to each other on the axial center of the cone-shaped vibrating portion, the normal direction (front direction) passing through the intersecting portion particularly with respect to the sound in the middle and high range. At the listening position, the sound due to the vibration of each pair of convex surfaces propagates evenly. On the other hand, at the listening position deviated from the normal direction, the sound from the pair of convex surfaces closest to the deviated direction and the circumferential direction of the convex surface is relatively loud and the sound from the other pair of convex surfaces is relatively Become smaller. And since this pair of convex surfaces is provided in two pairs with different directions, the sound from each pair of convex surfaces complements each other and is synthesized, resulting in wide directivity in any direction; Become. Therefore, this electroacoustic transducer can exhibit excellent directivity regardless of the installation direction such as the vertical direction or the horizontal direction.
It is also possible to dispose the intersecting portion by shifting it from the axial center of the cone-shaped vibrating portion, in which case it has a directivity characteristic that is biased with respect to the axial direction of the cone-shaped vibrating portion, and the listening position and each convex surface By appropriately setting the area ratio, it is possible to control to a desired directivity.

In the electroacoustic transducer according to the aspect of the invention, it is preferable that the wing-like vibrating portion and the valley closing portion are integrally formed continuously with an inner peripheral edge of a small-diameter side end portion of the cone-like vibrating portion.
For example, the wing-like vibration part, valley closing part, and cone-like vibration part can be integrally formed by vacuum molding, injection molding, press molding, etc. of a resin film, and a stable quality speaker or microphone can be easily manufactured. be able to.

  When the electroacoustic transducer according to the present invention is applied to a speaker, the speaker plays a low-frequency range with the cone-shaped vibrating part, and in the middle-high frequency range, the sound is emitted from the convex surface of the vertically split cylindrical part. Has a wide directivity. Moreover, the entire low-frequency range has a high sound pressure due to piston motion, and a single speaker unit realizes a full-range speaker unit with wide directivity in a wide range from low to mid-high range. Can do. Moreover, it is possible to apply a normal dynamic speaker component, and it can be manufactured at low cost. Further, when the electroacoustic transducer of the present invention is applied to a microphone, the microphone can pick up sound with a wide directivity over a wide frequency band from a low sound range to a high sound range.

It is a disassembled perspective view which shows the speaker of 1st Embodiment of this invention. It is a perspective view which shows the assembly state of the speaker of FIG. It is a front view of the speaker of FIG. FIG. 4 is a cross-sectional view taken along line AA in FIG. 3. It is the perspective view which made the half of FIG. 2 the cross section. It is a perspective view of the vibrating body used for the speaker of FIG. It is a front view of the vibrating body of FIG. FIG. 8 is a side view of FIG. 7. It is an arrow expanded sectional view which follows the BB line of FIG. It is the graph which compared the frequency characteristic of the speaker of 1st Embodiment, and this, and a speaker from which a shape and an aperture differ. It is a longitudinal cross-sectional view in the speaker of 2nd Embodiment of this invention, and is corresponded in sectional drawing of FIG. 4 of 1st Embodiment. It is the perspective view which made the cross section the half of the speaker of 2nd Embodiment. It is a perspective view of a vibrating body in a 3rd embodiment of the present invention. It is a front view of the vibrating body of FIG. It is an arrow expanded sectional view which follows the CC line of FIG. It is a disassembled perspective view which shows typically the combination structure of two pairs of vertically divided cylindrical parts.

Hereinafter, an embodiment in which an electroacoustic apparatus of the present invention is applied to a speaker will be described with reference to the drawings.
<First Embodiment>
FIGS. 1-10 shows the speaker (an example of an electroacoustic apparatus) of 1st Embodiment of this invention.
1. Overall Configuration A speaker 100 according to this embodiment includes a vibrating body 1, an actuator (an example of a conversion unit) 2 that reciprocates the vibrating body 1, and a support frame 3 that supports the vibrating body 1 and the actuator 2. And an edge portion 4 for supporting the vibrating body 1 on the support frame 3 so as to be reciprocally movable.
In FIG. 2, the vertical direction is set so that the side on which the edge portion 4 is provided is on the top and the side on which the actuator 2 is provided on the bottom, and a trough in the wing-like vibration portion of the vibrating body 1 to be described later The extending direction is defined as the vertical direction, and the direction perpendicular thereto is defined as the horizontal direction. Further, the surface facing upward is referred to as the front surface, and the surface facing downward is referred to as the back surface. Further, as illustrated, the vertical direction may be referred to as the x direction, the horizontal direction as the y direction, and the vertical direction as the z direction.

2. Configuration of Each Part (1) Configuration of Vibrating Body As the vibrating body 1 is enlarged and shown in FIGS. 6 to 9, the convex surfaces 5 of a pair of vertically split cylindrical portions (convex portions) are formed in parallel. In addition, a wing-like vibrating portion 7 having a surface shape in which a valley portion 6 is formed between one side portions of adjacent convex surfaces 5 (or between the convex surfaces 5 of a pair of vertically split cylindrical portions), and the wing-like vibration. A trough closing portion 8 for connecting the outer peripheral edges of the pair of convex surfaces 5 at both ends of the trough portion 6 of the portion 7 to close both ends of the trough portion 6, and an outer peripheral edge portion of the trough closing portion 8 and the other of the convex surfaces 5. A cone-shaped vibration part 9 is formed which is joined to the side part and is formed in a conical shape extending around the valley closing part 8 and the wing-like vibration part 7. In addition, a pair of vertically divided cylindrical part is comprised by two members among the several members obtained by dividing | segmenting a cylindrical member in the vertical direction (axial direction of a cylinder part).
The wing-like vibrating portion 7 in the illustrated example is constituted by a pair of curved plates 11 as a pair of vertically split cylindrical portions each having a convex surface 5, and the side portions forming the valley portions 6 of both curved plates 11. It is assumed that the two are joined.
In addition, the pair of convex surfaces 5 formed by the pair of curved plates 11 are arranged in parallel and facing each other in the direction of the convex toward the same surface side. In other words, the pair of curved plates 11 are not arranged such that the convex surface 5 of one curved plate of the pair of curved plates 11 and the concave surface of the other curved plate face each other. The concave surfaces are not arranged so as to face each other. The one side portions of each of the pair of convex surfaces 5 are disposed closer to each other than the other side portions of the pair of convex surfaces 5, or the other side portions of each of the pair of convex surfaces 5 are By arranging the two side portions so as to be in contact with each other, a valley portion 6 having a bottom near one side portion is formed between the pair of convex surfaces 5.

Further, the convex surface 5 of the curved plate 11 does not necessarily have to be a single circular arc surface, and a cross-section along the circumferential direction (lateral direction) of the convex surface 5 is a curvature such as a parabolic shape or a spline curve. It is possible to employ one having a constant or continuous change, one having a square cylindrical surface, one having a plurality of steps in a step shape, and the like. In addition, the convex surface 5 of the present embodiment is curved in one direction (circumferential direction of the convex surface 5: lateral direction), and is orthogonal to the one direction (the vertical direction of the convex surface 5, and the cylindrical portion of the vertically divided cylindrical portion). The convex surface 5 is a curved surface in which the curvature of the cross section along the vertical direction is smaller than the curvature of the cross section along the horizontal direction (a constant curvature or a plurality of curvatures that change continuously). (Convex surface) may be used. As shown in FIG. 9, in the joint portion 13, the two curved plates 11 are joined at a slight interval, and the longitudinal direction of the convex surface 5 is between the two curved plates 11 along the joint portion 13. A trough 6 is formed in a straight line along the line.
Further, as shown in FIGS. 6 and 7, the valley 6 (or joint 13) of the wing-like vibrating portion 7 is arranged in a straight line along the diameter direction of the cone-like vibrating portion 9, and the axis of the cone-like vibrating portion 9. It is integrated in a coaxial manner in which the center position in the length direction of the valley portion 6 is arranged on the center. The center of the valley portion 6 in the length direction is defined as a center M of the wing-like vibrating portion 7.
Further, in order to obtain a uniform reproduced sound, as shown in FIG. 9, the cross section of the curved plates 11 along the circumferential direction (y direction) of the convex surface 5 is axisymmetric with respect to the center M of the wing-like vibrating portion 7. It is preferable to form so that it becomes. However, in the present invention, the cross sections of the two curved plates 11 do not necessarily have line symmetry.

  The valley closing portion 8 closes both ends in the length direction of the valley portion 6 of the wing-like vibrating portion 7. As shown in FIG. 7, the outer peripheral edge of the curved plate 11 of the wing-like vibrating part 7 is formed in an arc shape on the side opposite to the side part forming the valley part 6 in front view. In this case, the curved plate 11 has a slightly longer diameter in the direction orthogonal to the valley 6 than the diameter in the extending direction of the valley 6, but is formed in a substantially semicircular shape in front view. A trough closing portion 8 is formed so as to connect the arc-shaped outer peripheral edges of the curved plate 11. Further, a connecting portion 8 a for the cone-shaped vibrating portion 9 is formed at the outer peripheral edge portion of the valley closing portion 8, and this connecting portion 8 a is the extending direction of the valley portion 6 at the outer peripheral edge of the valley closing portion 8. Since the curved plate 11 extends in the direction orthogonal to the vicinity of the apex of the curved plate 11, it is provided so as to substantially surround the entire circumference of the wing-like vibrating portion 7, and its outer peripheral edge is formed in a circle in front view.

On the other hand, the cone-shaped vibrating portion 9 is formed in a conical surface shape that gradually expands from the small diameter side end portion 9 b to the large diameter side end portion 9 a, and the small diameter side end portion 9 b is formed on the connecting portion 8 a of the valley closing portion 8. An annular connecting portion 9 c joined to the outer peripheral edge and continuously formed outside the large-diameter side end portion 9 a is connected to the inner peripheral edge of the edge portion 4. In this case, the wing-like vibrating portion 7 and the cone-like vibrating portion 9 are, as viewed from the front shown in FIG. 7, the diameter of the wing-like vibrating portion 7 (the direction orthogonal to the extending direction of the valley 6 at the outer peripheral edge of the curved plate 11. The distance between the vertices) D1 is set to be approximately half the diameter D2 of the large-diameter end 9a of the cone-shaped vibrating portion 9. Therefore, in this embodiment, the area of the cone-shaped vibrating portion 9 is set larger than the area of the wing-shaped vibrating portion 7.
In the cross section passing through the axial center of the cone-shaped vibrating portion 9, the vibrating body 1 has a height from the joining portion 13 when the joining portion 13 of the curved plate 11 is arranged on the lower side as shown in FIGS. 4 and 8. About half of the direction is the wing-like vibrating portion 7, and the cone-like vibrating portion 9 is arranged at the upper end of the wing-like vibrating portion 7.
The diameter D1 of the wing-like vibration part 7 does not necessarily have to be approximately half the diameter D2 of the large-diameter side end 9a of the cone-like vibration part 9, and the convex surface 5 and the cone-like vibration of the wing-like vibration part 7 are not necessarily required. Each of the sections 9 functions as a vibration surface, and can be set as appropriate within a range in which a predetermined frequency band can be emitted.

The material of the vibrating body 1 is not limited, and a material such as a synthetic resin, paper, or metal generally used as a diaphragm for a speaker can be used. Vacuum molding, injection molding, press molding, and the like can be employed. For example, a film made of a synthetic resin such as polypropylene or polyester can be molded relatively easily by vacuum molding.
The vibrating body 1 of this embodiment is formed by integrally molding a single film made of synthetic resin, and the joint portion 13 is formed by molding the central portion of the film into a U-shaped cross-section.

(2) Configuration of Each Part Other than Vibrating Body The actuator 2 uses, for example, a voice coil motor, and includes a voice coil 20 provided at the joint 13 of the curved plate 11 and a magnet mechanism 21 fixed to the support frame 3. Composed.
The voice coil 20 is formed by winding a coil 20b around a cylindrical bobbin 20a, and the upper end and the joint of the voice coil 20 are arranged so that the joint 13 of the curved plate 11 is disposed in the diameter direction thereof. 13 is fixed to the lower edge via an adhesive or the like. The outer periphery of the voice coil 20 is supported by the support frame 3 via the damper 22, and the voice coil 20 can reciprocate along the axial direction of the voice coil 20 with respect to the support frame 3. The damper 22 may be made of a material used for a general dynamic speaker.
The magnet mechanism 21 includes an annular magnet 23, a ring-shaped outer yoke 24 fixed to one pole of the magnet 23, and an inner yoke 25 fixed to the other pole. By disposing the tip of the central pole portion 25 a in the outer yoke 24, an annular magnetic gap 26 is formed between the outer yoke 24 and the inner yoke 25, and a voice coil is formed in the magnetic gap 26. 20 ends are arranged in the inserted state.

The support frame 3 is formed of, for example, a metal material, and in the illustrated example, a flange portion 30 formed in a rectangular frame shape, a plurality of arm portions 31 extending below the flange portion 30, and lower ends of these arm portions 31. And an annular frame portion 32 formed. And the inner peripheral surface of the flange part 30 is formed in the circumferential surface, the vibration body 1 is arrange | positioned inside that the junction part 13 is faced below, and the cyclic | annular form of the cone-shaped vibration part 9 of the vibration body 1 is carried out. The connecting portion 9 c is supported on the upper surface of the flange portion 30 via the edge portion 4. Accordingly, the edge portion 4 is formed in a circular ring shape corresponding to the cone-shaped vibrating portion 9 of the vibrating body 1. The edge portion 4 can also be made of a material used for a general dynamic speaker.
In addition, the degree of deformation (rigidity) of the vibrating body 1 in the depth direction of the valley 6 is greater than the degree of rigidity (rigidity) of the edge 4 in the depth direction of the valley 6. Thus, the vibrating body 1 and the edge part 4 are formed. In other words, when the vibrating body 1 vibrates in the depth direction of the valley portion 6, the vibrating body 1 and the edge portion 4 have a deformation amount of the vibrating body 1 caused by the vibration of the vibrating body 1. It is comprised so that it may become smaller than the deformation amount of the edge part 4 caused by.
In this invention, the support part 35 which supports the vibrating body 1 so that a vibration is possible is comprised by the support frame 3 and the edge part 4 in this embodiment.
In the edge portion 4, one end of the edge portion 4 is fixed to the annular connection portion 9 c of the cone-shaped vibrating portion 9, and the other end of the edge portion 4 is fixed to the support frame 3. Accordingly, the large-diameter side end portion 9a of the cone-shaped vibrating portion 9 can vibrate relative to the support frame 3 in the vertical direction when the edge portion 4 is deformed. The vibrator 1 is supported while allowing the whole 1 to vibrate in the vertical direction.

In a state in which the vibrating body 1 is attached to the support frame 3, the convex surface 5 has a line (in the illustrated example, the curved plate 11 of the curved plate 11) that connects the outermost ends along the curved direction of the convex surface 5. When the boundary line H is a tangent line at the connection point between the tip of the side opposite to the joint 13 and the cone-shaped vibrating part 9), the distance gradually increases from the boundary line H toward the valley 6. Bend in the direction you want.
As described above, the convex surface 5 is not limited to a single circular arc surface, but has a plurality of continuous curvatures, a section whose parabolic shape or spline curve has a constant or continuously changing curvature, a rectangular cylindrical surface, However, it is preferable that the convex surface has a shape that does not exceed the boundary line H connecting the tips.
1 and 2, reference numeral 33 denotes a terminal for connecting the voice coil 20 to the outside.

3. Operation When the driving current corresponding to the audio signal flows through the voice coil 20 of the actuator 2 fixed to the vibrating body 1, the speaker configured as described above changes the magnetic flux generated by the driving current and the magnetic field in the magnetic gap 26. As a result, a driving force corresponding to the driving current acts on the voice coil 20 to vibrate the voice coil 20 in a direction orthogonal to the magnetic field (the axial direction of the voice coil 20, the vertical direction indicated by the arrow in FIG. 4). Thereby, the vibrating body 1 connected to the voice coil 20 vibrates along the depth direction of the valley portion 6 of the wing-like vibrating portion 7 (the axial direction of the cone-like vibrating portion 9), and reproduced sound from the surface. Is emitted.

In this case, the vibrating body 1 is composed of a wing-like vibrating portion 7 arranged so as to constitute approximately half of the height direction, and a cone-like vibrating portion 9 arranged so as to spread outward on the upper side thereof. It is constituted by two differently shaped vibrating parts.
For this reason, the wing-like vibrating portion 7 has a characteristic that sound directivity in the lateral direction along the circumferential direction of the convex surface 5 is wide and narrow in the vertical direction. Further, like the diaphragm used in the Riffel type speaker, it has a wide directivity in the mid-high range. In this case, if both ends of the valley portion 6 are in an open state, a part of the sound wave radiated by the vibrating body 1 passes through the open space to the back surface side of the curved plate 11, but the valley portion Since both ends of the valley portion 6 are blocked by the blocking portion 8, the sound wave is prevented from coming off to the back side of the curved plate 11, and the sound is efficiently emitted from the entire front surface of the vibrating body 1. be able to.
In addition, the vibrating body 1 is supported by the edge portion 4 so that the outer peripheral edge of the cone-shaped vibrating portion 9 can be reciprocally oscillated on the support frame 3, so that the entire portion from the joint 13 to the outer peripheral edge is an actuator. 2 vibrate uniformly, and so-called piston motion vibration occurs. For this reason, like a dynamic speaker, it has a high sound pressure even in a low sound range.
That is, in this speaker, in a low frequency range, sound is radiated by a piston motion in which the cone-shaped vibrating portion 9 and the wing-shaped vibrating portion 7 are integrated, and the reproduction frequency is increased and the amplitude of the vibrating body is decreased. Accordingly, the radiated sound from the wing-like vibrating portion 7 becomes dominant, and a wide directivity sound is reproduced even in a high frequency range.
As described above, it is possible to realize a full-range speaker unit that can be reproduced with a wide directivity over the entire audible band from the low sound range to the mid-high sound range with a single speaker unit.

FIG. 10 is a comparison of the frequency characteristics of the vibrating body 1 of the first embodiment and a vibrating body having a different shape and diameter. The wing-like vibration is obtained by removing the cone-shaped vibrating portion from the vibrating body of the first embodiment. A vibrating body (A) constituted only by a part and a valley closing part, and a vibrating body (B) whose wing-like vibrating part and valley closing part are enlarged to the outer diameter of the cone-like vibrating part of the first embodiment; The frequency characteristics of the vibrating body (C) having the cone-shaped vibrating portion, the wing-shaped vibrating portion, and the valley closing portion in this embodiment are compared.
The vibrating body (A) indicated by the alternate long and short dash line has a wide directivity in the middle and high range due to the wing-like vibrating part, but the caliber is small because it does not have a cone-like vibrating part. Yes. Since the vibrating body (B) indicated by the broken line has a larger diameter than the vibrating body (A), the sound pressure in the low range increases, but the rigidity of the entire vibrating body is ensured so that the entire vibrating body vibrates uniformly. This makes it difficult to generate peaks and dips in the frequency characteristics. For this reason, even if the vibrating body (B) has a wide frequency characteristic, it is difficult to obtain a flat frequency characteristic.
In contrast to these vibrating bodies (A) and (B), the vibrating body (C) of the present embodiment indicated by the solid line has a larger aperture in the cone-shaped vibrating portion, and thus the sound pressure in the low range is also secured. Since it has a cone shape, the rigidity of the entire diaphragm can be secured, and a flat frequency characteristic can be obtained even in a low frequency range. Further, in the mid-high range, as described above, sound is emitted mainly by the wing-like vibrating portion, and the wing-like vibrating portion can ensure rigidity with an appropriate outer diameter, and thus flat frequency characteristics are also ensured.

  Moreover, in this embodiment, since the outer peripheral edge part of the vibrating body 1 is formed by the cone-shaped cone-shaped vibrating part 9, the edge part 4 can be made into a simple circular ring shape. Furthermore, since the voice coil 20 of the actuator 2 is also formed in a cylindrical shape and the upper end portion thereof is fixed to the vibrating body 1, the actuator 2 may be applied to a normal dynamic speaker. Therefore, as the edge portion 4, the support frame 3, the actuator 2, and the like, components common to a dynamic speaker having a normal cone-shaped diaphragm can be applied and can be manufactured at low cost.

Second Embodiment
11 and 12 show the speaker of the second embodiment.
In the speaker 100 according to the first embodiment, since the upper end of the voice coil 20 and the lower edge of the joint portion 13 of the wing-like vibrating portion 7 are fixed via an adhesive or the like, the fixing position of the vibrating body 1 and the voice coil 20 is However, the speaker 200 according to the second embodiment is configured such that the entire circumference of the upper end of the bobbin 20a of the voice coil 20 is fixed to the back surface of the wing-like vibrating portion 7 although there are only two places in the circumferential direction of the voice coil 20. That is, the upper end of the bobbin 20a of the voice coil 20 extends to the back surface of the wing-like vibrating portion 7, and has a tip shape that matches the back surface shape of the curved plate 11 and the back surface shape of the joint portion 13 of the wing-like vibrating portion 7. The curved plate 11 is in close contact with the back surface of the curved plate 11 and the back surface of the joint portion 13.
With such a connection structure, the vibrator 1 can be driven more firmly by the bobbin 20a of the voice coil 20, and stable vibration can be performed.

<Third Embodiment>
13 to 16 show a vibrating body used in the third embodiment. In the speaker according to the third embodiment, since the same components as the first embodiment (actuators, supports, and edge portions) other than the vibrating body are used, the illustration is omitted. The same elements as those in the embodiment are denoted by the same reference numerals to simplify the description. The vibrating body has the same configuration as that of the first embodiment with respect to the cone-shaped vibrating portion.
In the vibrating body 51 of the third embodiment, the wing-like vibrating part 52 disposed inside the cone-like vibrating part 9 is such that the convex surface 5 and the valley part 6 of the two pairs of vertically split cylindrical parts are orthogonal to each other on the xy plane. It is the structure different from the vibrating body 1 of 1st Embodiment in the point which is arrange | positioned so that it may be made and it is set as the shape which united both.

FIG. 16 schematically shows a shape in which two pairs of vertically split cylindrical portions are combined, and the shape of the vibrating body 51 will be described in detail with reference to FIG. 16. In FIG. In each pair of convex surfaces 5, the two fan-shaped portions F1 and F2 whose length in the circumferential direction gradually increases from the central portion in the longitudinal direction of the valley portion 6 toward both ends, and these fan-shaped portions are left. The portions G1 and G2 sandwiched between the two are removed. In FIG. 16A, for the sake of convenience, the removed portions of the two pairs of convex surfaces 5 are indicated by two-dot chain lines.
And the convex surface 5 of these two pairs of fan-shaped parts F1 is the center of the convex surface 5 of the other two pairs of fan-shaped parts F2 and the valley part 6 as shown in FIG. The wing-like vibrating part 52 is formed by being merged so as to make up the removed portions G1 and G2 so as to make up for each other.

In the example shown in FIGS. 13 and 14, the cross section in the horizontal direction of each convex surface 5 is formed in a circular arc shape from the valley portion 6 to the middle position in the height direction, and the radius of curvature is increased from the middle position in the height direction. However, it is formed in a substantially planar shape. The former is an arcuate surface portion 5a, and the latter is an inclined surface portion 5b.
Each pair of convex surfaces 5 is arranged in parallel with the convex direction facing the same surface side as in the case of the first embodiment, and adjacent side portions are joined to each other. In the joint portion 13, the both convex surfaces 5 are joined with a slight gap, and along this joint portion 13, the valley portions 6 are linearly formed along the longitudinal direction of the convex surface 5 between the both convex surfaces 5. Is formed.

As shown in FIG. 14, the wing-like vibrating portion 52 has a cross shape when viewed from the front side (in front view), as the convex surface 5 having the above-described shape is arranged with the valley portions 6 orthogonal to each other. The two troughs 6 that are orthogonal to each other at the center and four raised portions 53 that are divided by these troughs 6 and rise to the surface side. In each raised portion 53, the other side of the different pair of convex surfaces 5 (the other side with respect to one side forming the valley 6 at the position rotated by 45 ° with respect to the valley 6 on the xy plane) Ridges 54 that connect the inclined surfaces 5b and the arcuate surfaces 5a are formed, and the four ridges 53 form four peaks 54. These peak portions 54 are also arranged so as to be orthogonal to each other in the xy plan view.
In addition, the corner | angular part of the four protruding parts 53 is arrange | positioned closely at the crossing part 15 of the trough part 6. Thereby, as shown in FIG. And is formed in a planar shape wider than the width of the straight portion of the valley portion 6. A portion where the convex surfaces 5 and the corners of the raised portion 53 are joined to each other at the bottom of the valley portion 6 is referred to as a joint portion 13. This joint portion 13 has a cross shape in the same front view (or rear view) as the valley portion 6, and forms the lower end of the wing-like vibration portion 52.

The valley closing portion 8 extends from the tip of the ridge-like vibrating portion 52 on the side opposite to the intersecting portion 15 of the ridge-like vibrating portion 52 and closes both ends of the two valley portions 6 between the ridge portions 53. An annular connecting portion 8a is formed so as to connect the valley connecting portions 8, and the small-diameter side end portion 9b of the cone-shaped vibrating portion 9 is connected to the outer peripheral edge of the annular connecting portion 8a.
Therefore, the lower half of the vibrating body 51 is formed by the wing-like vibrating portion 52 and the valley closing portion 8 at the lower half of the height direction, and the lower end is constituted by the lower surface of the joint portion 13 that intersects 90 °. The upper half of the height direction is formed by the cone-shaped vibrating portion 9, and the upper end of the vibrating body 1 is formed in a circular shape by the upper edge of the cone-shaped vibrating portion 9. For this reason, four locations in the circumferential direction of the voice coil 20 are fixed to the joint portion 13 of the vibrating body 51.

  In the vibrating body 1 of the third embodiment, as described above, the convex surface 5 of the vertically divided cylindrical portion has a wide sound directivity in the direction along the circumferential direction, and is narrow in the direction orthogonal thereto. Has characteristics. And this vibrating body 51 is comprised by the two pairs of convex surfaces 5, and since each pair cross | intersects at the angle of 90 degrees, in the listening position of the normal line direction (front direction) which passes the cross | intersection part 15, Sound due to vibration of each pair of convex surfaces 5 propagates evenly. On the other hand, at the listening position deviated from the normal direction of the intersection 15, the sound from the pair of convex surfaces 5 closest to the deviated direction and the circumferential direction of the convex surface 5 becomes relatively loud, and another pair of The sound from the convex surface 5 becomes relatively small.

  For example, when the listening position is shifted in the x direction from the front of the intersection 15 in FIG. 14, a pair of convex surfaces 5 having valleys 6 along the y direction orthogonal to the x direction (in the example shown in FIG. The sound from the convex surface 5 facing the trough 6 extending in the direction becomes relatively loud, and the pair of convex surfaces 5 having the trough 6 along the x direction (in the example shown in FIG. The sound from the convex surface 5) facing through the valley 6 extending in the direction is relatively small. Conversely, when the listening position is shifted in the y direction from the front of the intersection 15, the sound from the pair of convex surfaces 5 having the valleys 6 along the x direction increases, and the pair having the valleys 6 along the y direction. The sound from the convex surface 5 becomes small.

  When the listening position moves in the direction between the x direction and the y direction from the front of the intersection 15, the pair of convex surfaces 5 (in other words, the listening position of the listening position are closest to the circumferential direction of the convex surface 5). The sound from the pair of convex surfaces 5) whose direction orthogonal to the moving direction is closest to the extending direction of the valley 6 is relatively large, and the sound from the other pair of convex surfaces 5 is relatively small.

  As described above, since the vibrating body 51 is provided with two pairs of the convex surfaces 5 whose directions are changed by 90 ° and orthogonal to each other, even if the listening position is moved from the front in either the x direction or the y direction, The sound from the pair of convex surfaces 5 having the valleys 6 along the direction close to the direction orthogonal to the direction that has been made becomes relatively loud, and from the pair of convex surfaces 5 having the valleys 6 along the direction close to the moved direction. The sound from each pair of convex surfaces 5 is less likely to interfere with each other, and the sounds from each pair of convex surfaces 5 are synthesized by complementing each other. It will have directivity. Therefore, this electroacoustic transducer can exhibit wide directivity in the entire range from the low range to the mid-high range regardless of the installation direction such as the vertical direction or the horizontal direction.

In this third embodiment, the troughs of the two pairs of vertically split cylindrical parts are orthogonal to each other, and the intersecting part is arranged on the axis of the cone-shaped vibrating part. It is also possible to displace them from the axis. In that case, it has directivity characteristics deviated with respect to the axial direction of the cone-shaped vibrating portion, and can be controlled to a desired directivity by appropriately setting the listening position and the area ratio of each convex surface.
In the third embodiment, both the valleys and the peaks are orthogonal to each other, but it is sufficient that at least one of them is orthogonal.

<Modification>
In addition, this invention is not limited to the said embodiment, A various change can be added in the range which does not deviate from the meaning of this invention.
For example, the cone-like vibration part is formed in a conical surface shape and the edge part is formed in a circular ring shape, but the cone-like vibration part is formed in a long elliptical cone shape along the length direction of the valley part of the wing-like vibration part. The edge portion may be formed in an elliptical ring shape. In addition, the cone-like vibration part may have a shape other than a conical surface or an elliptical conical surface as long as it is a diaphragm used as a general dynamic speaker. The shape may be a combination of molds and may be formed in a conical shape as a whole. The shape of the wing-like vibration part can also be changed as appropriate in accordance with the shape of the cone-like vibration part.

In addition, it is preferable that the vibrating body is integrally formed with a cone-shaped vibrating portion, a wing-shaped vibrating portion, and a valley closing portion, but these can be separately formed and joined. The wing-like vibration part may also be formed by bonding one side part of two curved plates, except when integrally molding as a single plate-like material, and the joint part is also U-shaped. In addition to the form formed by folding back into a shape, a form formed by folding a plate-like material into a V shape may be used, or one side portion of two curved plates may be bonded to each other with a predetermined width to form a band plate shape. It is good also as a form. Moreover, it is good also as a form etc. which adhered reinforcement members, such as a strip-shaped reinforcement board or a reinforcement wire, along the junction part, and reinforced the junction part linearly.
Moreover, in order to reinforce the rigidity of the vibration surface on the back surface of the vibration body, a rib, a block, or the like may be added and fixed to the back surface of the vibration body. It is possible to provide plate-like or rod-like ribs along the lateral direction on the convex surface with respect to the radiation surface of the wing-like vibrating portion. As described above, this wing-like vibrating part has a characteristic that the convex surface is a radiating surface of the reproduced sound, so that the directivity in the lateral direction along the circumferential direction of the convex surface is wide but narrow in the vertical direction. For this reason, even if a plate-like or bar-like rib is provided along the lateral direction on the convex radiation surface, there is little acoustic influence.
Furthermore, although the voice coil motor is applied as the conversion unit that reciprocally drives the vibrating body, a piezoelectric element or the like may be used instead of the voice coil motor.

  In the above embodiments, the present invention is applied to a speaker. However, the present invention can also be applied to a microphone. When the present invention is applied to a speaker, a conversion unit such as a voice coil motor converts an electric signal based on a sound signal into vibration of a vibrating body. However, when the present invention is applied to a microphone, a voice coil is used as the conversion unit. A motor or the like can be used, and the conversion unit in that case converts the vibration of the vibrating body that receives a sound wave to vibrate into an electric signal. In the microphone to which the present invention is applied, the cone-shaped vibrating portion and the convex surface of the wing-shaped vibrating portion are vibrating surfaces, and the entire vibrating body vibrates uniformly, so that directivity is good while maintaining sensitivity. Thus, sound can be collected with a wide directivity over a wide frequency band from a low sound range to a high sound range.

  DESCRIPTION OF SYMBOLS 1 ... Vibration body, 2 ... Actuator (conversion part), 3 ... Support frame, 4 ... Edge part, 5 ... Convex surface, 6 ... Valley part, 7 ... Wing-like vibration part, 8 ... Valley part closing part, 8a ... Connection part, DESCRIPTION OF SYMBOLS 9 ... Cone-shaped vibration part, 9a ... Large diameter side edge part, 9b ... Small diameter side edge part, 9c ... Ring connection part, 11 ... Curved plate, 13 ... Joining part, 15 ... Reinforcement plate, 16 ... Joining part, 20 ... Voice coil, 21 ... magnet mechanism, 22 ... damper, 23 ... magnet, 24 ... outer yoke, 25 ... inner yoke, 25a ... pole part, 26 ... magnetic gap, 30 ... flange part, 31 ... arm part, 32 ... annular frame Part, 33 ... terminal, 51 ... vibrating body, 52 ... wing-like vibrating part, 53 ... raised part, 54 ... mountain part

Claims (3)

A vibrating body,
A converter that converts the vibration of the vibrating body and an electrical signal corresponding to the vibration;
A support portion that supports the vibrating body so as to vibrate along the direction of the vibration, and
The vibrator is
A wing-like vibrating portion comprising a pair of convex surfaces each consisting of a convex surface of each of a pair of vertically-divided cylindrical portions, and forming a valley portion between one side portions of each of the pair of convex surfaces;
A valley clogging portion that connects between the outer peripheral edges of the pair of convex surfaces at both ends of the valley portion and blocks both ends of the valley portion;
An electric device comprising: a cone-shaped vibrating portion joined to an outer peripheral edge portion of the valley closing portion and the other side portion of the pair of convex surfaces, and having a cone shape surrounding the valley closing portion and the wing-like vibrating portion. Acoustic transducer. The wing-like vibrating portion is provided with two pairs of convex surfaces, and these two pairs of convex surfaces intersect with each other between valleys between the convex surfaces of each pair, and are opposite to the side portion forming the valley portion. 2. The electroacoustic transducer according to claim 1, wherein the side portions form peaks, and at least one of the valleys or the peaks is arranged orthogonally.   The electroacoustic transducer according to claim 1 or 2, wherein the wing-like vibrating portion and the valley closing portion are integrally formed continuously with an inner peripheral edge of a small-diameter side end portion of the cone-like vibrating portion.

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