JP2012005061A - Speaker device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a speaker device of which speakers can be stored without being exposed when not in use.SOLUTION: A rotation axis 73 whose axial direction is the longitudinal direction of a housing case 71 is rotatably provided in the housing case 71. The left end of a sound emitting unit 6 is fixed to the rotation axis 73. A winding mechanism 74 is provided for storing the sound emitting unit 6 pulled out from a housing unit 7 by winding the sound emitting unit around the rotation axis 73. In the state where the sound emitting unit 6 is wound up on the rotation axis 73, that is, in the state where the sound emitting unit 6 is stored in the housing case 71 of the housing unit 7, the sound emitting unit 6 is stored without being exposed to the outside. The housing case 71 prevents the force applied from the outside of the housing case 71 from being directly transmitted to electrostatic speakers of the sound emitting unit 6, thereby reducing the possibility of breaking electrostatic speakers (vibrators) of the sound emitting unit 6 by the force applied from the outside.

Description

  The present invention relates to a speaker device.

In the field of speakers, there are speakers called electrostatic speakers. This electrostatic speaker is composed of two electrodes facing each other at an interval and a conductive sheet-like vibrating body inserted between the two electrodes. When a bias voltage is applied and the voltage applied to the electrode is changed, the electrostatic force acting on the vibrating body is changed, and thereby the vibrating body is displaced. If the applied voltage is changed according to the input acoustic signal, the vibrating body repeats displacement accordingly, and an acoustic wave corresponding to the acoustic signal is generated from the vibrating body. And, as described in Non-Patent Document 1, such an electrostatic speaker can be deformed into various shapes by using two electrodes and a vibrating body made of a soft material. A flexible electrostatic speaker has been devised.
Patent Document 1 discloses a projection screen having a screen portion in which a piezoelectric plastic film-like speaker is bonded and fixed to a screen base material, and a winding frame attached to the lower end portion of the screen portion. . When the projection screen is stored, the screen portion is wound around a winding frame.

Japanese Utility Model Publication No. 5-45689

Adult Takeoka, 5 others, “1-bit wavefront recording and playback system using condenser microphone / speaker”, IEICE technical report. EA, Applied Acoustics, The Institute of Electronics, Information and Communication Engineers, June 2005, pp. 25-30

  Speakers such as those described above can be folded and wrapped around other objects, so they can be made smaller and cleared when not in use. However, the speaker remains exposed only by being folded or wrapped around another object.

  The present invention has been made under the background described above, and it is an object of the present invention to provide a technique that can be cleared without exposing the speaker when not in use.

  The present invention relates to a sheet-like sound emitting portion having an electrostatic speaker having a bendable electrode and a vibrating body that is bendable and spaced apart from the electrode, and a bias to the vibrating body A drive unit that applies a voltage and supplies an input acoustic signal to the electrode, and a space that houses the sound emitting unit, and an opening that opens from the space to the outside and through which the sound emitting unit passes. Provided is a speaker device having a housing.

  In the present invention, the housing has an end portion of the sound emitting portion fixed, a shaft for winding the sound emitting portion, and a winding means for rotating the shaft in a direction to wind the sound emitting portion, The sound emitting part may have a fixing means for fixing a free end opposite to the end fixed to the shaft to the other speaker device.

  In the present invention, the sound emitting unit includes a plurality of the electrostatic speakers, and includes a detecting unit that detects the electrostatic speakers outside the housing among the plurality of electrostatic speakers, The drive unit may be configured to supply the acoustic signal to the electrode of the electrostatic speaker detected by the detection unit.

  According to the present invention, when not in use, the speaker can be cleared without being exposed.

It is the figure which showed the apparatus which comprises an acoustic system. It is a front view of a speaker system. It is the figure which showed typically the structure and electrical structure of an electrostatic speaker. It is the sectional view on the AA 'line of the speaker apparatus of FIG. 2, and the BB' sectional view. It is a block diagram which shows the hardware constitutions of a control unit. It is a front view of the speaker system which concerns on a modification. It is sectional drawing of the speaker apparatus which concerns on a modification. It is a front view of the speaker system which concerns on a modification. It is sectional drawing of the speaker apparatus which concerns on a modification.

Hereinafter, an acoustic system according to the present invention will be described with reference to the drawings.
(1) Configuration (sound system configuration)
FIG. 1 is a diagram showing devices constituting the acoustic system 1.
The acoustic system 1 includes a playback device 2, a speaker system 4, and a cable 3. The playback device 2 is a so-called music player, and reads out acoustic data recorded on an optical disk or HDD (Hard Disk Drive). The playback device 2 decodes the read sound data, generates an analog signal (sound signal) of the sound represented by the sound data, and outputs the analog signal to the speaker system 4. The speaker system 4 includes a connection unit (not shown) to which the cable 3 is connected, and is connected to the playback device 2 via the cable 3. The speaker system 4 generates an acoustic wave corresponding to the acoustic signal input from the playback device 2.

(Speaker system configuration)
FIG. 2 is a front view of the speaker system 4.
In the following description of the drawings, directions are indicated by orthogonal X, Y, and Z axes. When the speaker system 4 is viewed from the front, the horizontal direction is the X axis direction, and the depth direction is the Y axis direction. The height direction is the Z-axis direction. Also, in the figure, “•” in “○” means an arrow heading from the back of the drawing to the front, and “×” in “○” is the front of the drawing. It means an arrow pointing from the back to the back. In addition, the dimensions of each component in the drawing are different from the actual dimensions so that the shape of the component can be easily understood. The speaker system 4 includes a speaker device 5a that generates an acoustic wave and a speaker device 5b that is connected to the speaker device 5a. In the present embodiment, the speaker system 4 is configured by arranging the speaker device 5a on the left side and the speaker device 5b on the right side. In the present embodiment, since the speaker devices 5a and 5b have the same configuration, the subscripts “a” and “b” are omitted when it is not particularly necessary to distinguish between the two. The same applies to the other constituent elements for the omission of the characters appended to the end of the reference numerals. The speaker device 5 constituting the speaker system 4 includes a sound emitting unit 6, a housing unit 7, and a support unit 8.

  The sound emitting unit 6 has a rectangular shape when viewed from the front, and includes protective cloths 611 and 612, electrostatic speakers 621, 622, and 623, and male connectors 631a and 632a. The left end of the sound emitting unit 6 is fixed inside the housing unit 7 as a fixed end. The right end of the sound emitting unit 6 is a free end and includes male connectors 631a and 632a. The upper end and the lower end of the sound emitting unit 6 are free ends. The male connectors 631a and 632a can be connected to or disconnected from the female connectors 721b and 722b provided in the speaker device 5b. That is, the male connector functions as an example of a fixing unit that fixes the free end opposite to the end fixed to the shaft to another speaker device.

  The protective cloths 611 and 612 are so-called cloths and have a rectangular shape when viewed from the front. Between the protective cloth 611 and the protective cloth 612, electrostatic speakers 621, 622, and 623 with the Z-axis direction as the longitudinal direction are arranged at a predetermined interval in the X-axis direction. The protective cloth 611 and the protective cloth 612 prevent the force applied from the outside of the protective cloth 611 and 612 from being directly transmitted to the electrostatic speakers 621, 622 and 623. In FIG. 2, a part of the protective cloth 611 is omitted for convenience of explanation, and a part of the electrostatic speakers 621, 622, and 623 is exposed without being covered with the protective cloth 611. Actually, all of the electrostatic speakers 621, 622, and 623 are covered with a protective cloth 611.

  The electrostatic speakers 621, 622, and 623 generate acoustic waves corresponding to the acoustic signals input thereto. The electrostatic speakers 621, 622, and 623 are long in the Z-axis direction and have a rectangular shape when viewed from the front. The lengths of the electrostatic speakers 621, 622, and 623 in the Z-axis direction are shorter than the lengths of the protective cloths 611 and 612 in the Z-axis direction. The total length of the electrostatic speakers 621, 622, and 623 in the X-axis direction is shorter than the length of the protective cloth 611 in the X-axis direction. The length of the electrostatic speakers 621, 622, 623 in the Y-axis direction is several mm, and the length of the electrostatic speakers 621, 622, 623 in the X-axis direction is equal to that of the electrostatic speakers 621, 622. It is shorter than the length of 623 in the Z-axis direction. Since the electrostatic speakers 621, 622, and 623 are bonded to the protective cloths 611 and 612 with an adhesive tape (not shown), the positional relationship between the members does not change. In this adhesive tape, an adhesive is applied to both the front and back surfaces, and air and sound are allowed to pass through without electricity. In the present embodiment, the configurations of the electrostatic speakers 621, 622, and 623 are the same. Therefore, when there is no need to distinguish each of them, the description of the electrostatic speaker 621 is given as a representative, and A description of the electric speakers 622 and 623 is omitted. Note that the length of the electrostatic speaker 621 in the Y-axis direction is not limited to several mm, and may be several tens of mm.

FIG. 3 is a diagram schematically showing the structure and electrical configuration of the electrostatic speaker 621.
The electrostatic speaker 621 includes a vibrating body 6211, elastic members 6212U and 6212L, and electrodes 6213U and 6213L. In the present embodiment, the configuration of the elastic members 6212U and 6212L and the configuration of the electrodes 6213U and 6213L are the same. Therefore, if there is no particular need to distinguish between the two, the suffixes “U” and “L” Description is omitted.

First, each member constituting the electrostatic speaker 621 will be described. The vibrating body 6211 is obtained by depositing a metal film or applying a conductive paint on a film such as PET (polyethylene terephthalate) or PP (polypropylene), and has a thickness of about several μm to several tens of μm. It has become. The electrode 6213 is a cloth obtained by plain weaving conductive warp and weft having the same conductivity. Since the electrode 6213 is plain woven so that air can pass therethrough, sound transmission is ensured. Note that the electrode 6213 may be wrapped with an insulating cloth woven with insulating yarn so that the electrodes 6213 do not short-circuit even if the electrodes 6213 come into contact with each other. The electrode 6213 is made of a synthetic resin film having insulation properties such as PET or PP, and a conductive metal is deposited on one surface of the film to form a conductive film. The electrode 6213 penetrates from the front surface to the back surface. The structure which provided two or more holes to perform may be sufficient.
The elastic member 6212 is obtained by compressing batting by applying heat, and has elasticity, air permeability, and insulation. The elastic member 6212 deforms when a force is applied from the outside, and returns to its original shape when the force applied from the outside is removed. Note that the elastic member 6212 may be a material other than the batting, and may be, for example, a synthetic resin made into a sponge or non-woven fabric.

  Next, the configuration of the electrostatic speaker 621 will be described. The vibrating body 6211 is sandwiched between the elastic member 6212U and the elastic member 6212L. The elastic member 6212U has an electrode 6213U disposed on the surface opposite to the surface on which the vibrating body 6211 is disposed, and the elastic member 6212L includes a surface on which the vibrating body 6211 is disposed. An electrode 6213L is arranged on the opposite surface. That is, the electrode 6213U and the electrode 6213L are disposed so as to face each other with the elastic members 6212U and 6212L and the vibrating body 6211 interposed therebetween. In the electrostatic speaker 621, the electrodes 6213U and 6213L, the vibrating body 6211, and the elastic members 6212U and 6212L are sewn together with an insulating thread (not shown). The relationship never changes. In addition, the electrode 6213, the vibrating body 6211, and the elastic member 6212 can be bent and have flexibility, so that the shape can be freely deformed even when they are stitched together with a thread. Has been.

  Next, the electrical configuration of the electrostatic speaker 621 will be described. The electrostatic speaker 621 includes a transformer 6214, an input unit 6215 to which an acoustic signal is input from the outside, and a bias power source 6216 that applies a DC bias to the vibrating body 6211. The bias power source 6216 is connected to the vibrating body 6211 and the output-side midpoint of the transformer 6214, and the two electrodes 6213U and 6213L are connected to one end and the other end on the output side of the transformer 6214, respectively. . In this configuration, when an acoustic signal is input to the input unit 6215, a voltage corresponding to the input acoustic signal is applied to the electrodes 6213U and 6213L, and the electrostatic speaker 621 is a push-pull electrostatic speaker. Operate. That is, the bias power source 6216, the transformer 6214, and the input unit 6215 function as an example of a drive unit that applies a bias voltage to the vibrating body and supplies the input acoustic signal to the electrodes.

  For example, when an acoustic signal is input to the input unit 6215, a voltage corresponding to the input acoustic signal is applied from the transformer 6214 to the electrode 6213U and the electrode 6213L. When a potential difference is generated between the electrode 6213U and the electrode 6213L due to the applied voltage, the vibrating body 6211 between the electrode 6213U and the electrode 6213L is attracted to either the electrode 6213U or the electrode 6213L. Such electrostatic force works.

  When an acoustic signal is input to the input unit 6215, the acoustic signal is supplied to the transformer 6214, a positive voltage is applied to the electrode 6213U, and a negative voltage is applied to the electrode 6213L, a bias power source is supplied to the vibrating body 6211. Since a positive voltage is applied by 6216, the vibrating body 6211 repels the electrode 6213U to which a positive voltage is applied, while being attracted to the electrode 6213L to which a negative voltage is applied and moves toward the electrode 6213L. Displace.

  In addition, when an acoustic signal is input to the input unit 6215, the acoustic signal is supplied to the transformer 6214, a negative voltage is applied to the electrode 6213U, and a positive voltage is applied to the electrode 6213L, the vibrator 6211 is positive. Repels the electrode 6213L to which a negative voltage is applied, while it is attracted to the electrode 6213U to which a negative voltage is applied and is displaced toward the electrode 6213U.

  As described above, the vibrating body 6211 is displaced toward the electrode 6213U or the electrode 6213L according to the acoustic signal, and the displacement direction is sequentially changed to generate vibration, and the sound according to the vibration state (frequency, amplitude, phase). Is generated from the vibrating body 6211. The generated sound passes through the elastic members 6212U and 6212L and the electrodes 6213U and 6213L and is radiated to the outside of the electrostatic speaker 621.

(Structure of the accommodating part 7)
4 is a cross-sectional view of the speaker device 5a of FIG. 4A is a cross-sectional view taken along line AA ′ of the speaker device 5a of FIG. FIG. 4B is a cross-sectional view taken along the line BB ′ of the speaker device 5a of FIG.
As shown in FIGS. 2 and 4, the accommodating portion 7 includes an accommodating housing 71, a rotating shaft 73, a winding mechanism 74, female connectors 721 and 722, a position detector 75, and an opening 76. It has. The housing case 71 of the housing portion 7 is formed in a cylindrical shape from a relatively hard material such as metal or various resin materials. Note that the housing 71 of the housing 7 is made of a material that is harder (the Vickers hardness and Young's modulus are larger) than the material of the sound emitting unit 6. A rectangular opening 76 that communicates with the space inside and outside the housing 71 is provided on the side surface of the housing 71. The length of the opening 76 in the Z-axis direction is longer than the length of the sound emitting unit 6 in the Z-axis direction, and the length of the opening 76 in the Y-axis direction is longer than the length of the sound emitting unit 6 in the Y-axis direction. It is formed long. The female connectors 721 and 722 are disposed on the outer peripheral surface of the housing 71 and are disposed at positions facing the opening 76 when the housing 71 is viewed from the Z-axis direction. The female connector 721 and the female connector 722 are provided in the housing 71 with a predetermined interval in the Z-axis direction. The female connector 721 and the female connector 722 are connected to a male connector provided in a sound emitting portion of another speaker device, thereby supporting the sound emitting portion of the other speaker device in a tensioned state. It is configured as follows. For example, in FIG. 2, the female connector 721b and the male connector 631a are connected, and the female connector 722b and the male connector 632a are connected, so that the female connector 721b and the female connector 722b are connected to the speaker device. The sound emission part 6 of 5a is supported in the state where tension was applied.

  A rotation shaft 73 having an axial direction in the longitudinal direction of the housing case 71 is rotatably provided inside the housing case 71. Further, the left end of the sound emitting unit 6 is fixed to the rotating shaft 73. The winding mechanism 74 is provided for winding the sound emitting part 6 drawn out from the accommodating part 7 around the rotating shaft 73 and accommodating it. For example, the winding mechanism 74 has a so-called mainspring spring formed by winding a strip-like metal rich in elasticity spirally in the surface direction. The mainspring spring of the winding mechanism 74 is wound by rotating the rotating shaft 73 in the direction in which the sound emitting unit 6 is pulled out, and stores a force for returning the swirled spiral as a power source. Further, the mainspring spring of the winding mechanism 74 rotates the rotating shaft 73 in a direction in which the sound emitting unit 6 is wound using a force for returning the wound spiral as a power source. That is, the rotating shaft functions as an example of a shaft that winds up the sound emitting portion with the end of the sound emitting portion fixed, and the winding mechanism is a winding means that rotates the shaft in the direction of winding up the sound emitting portion. It serves as an example.

  In a state where the sound emitting unit 6 is wound around the rotary shaft 73, that is, in a state where the sound emitting unit 6 is accommodated in the accommodating housing 71 of the accommodating unit 7, the sound emitting unit 6 is not exposed to the outside. It is cleared up. Further, since the housing case 71 prevents the force applied from the outside of the housing case 71 from being directly transmitted to the electrostatic speaker of the sound emitting unit 6, the force of the sound emitting unit 6 is applied by the force applied from the outside. Reduce the possibility of damage to the electrostatic speaker (vibrating body).

  The position detector 75 is, for example, an absolute type rotary encoder, and an angle (hereinafter referred to as rotation) by which the rotation shaft 73 rotates with reference to the angle of the rotation shaft 73 in a state where all of the sound emitting units 6 are accommodated in the accommodation unit 7. Is measured and output. The rotating shaft 73 rotates when the sound emitting unit 6 is pulled out from the housing unit 7. That is, since the rotation angle is uniquely determined according to the length of the sound emitting unit 6 drawn out from the storage unit 7, the rotation angle output from the position detector 75 is the sound output unit 6 drawn out from the storage unit 7. The value according to the length of is shown.

(Configuration of support portion 8)
The support portion 8 is a member for preventing the accommodating portion 7 from falling down, and the shape thereof is a disc shape. In the support housing 81 of the support portion 8, a hole 83 is provided at the center of the upper surface. In the housing case 71 of the housing portion 7, a male screw 77 is provided at the center of the lower surface. By inserting and fitting the male screw 77 into the hole 83, the housing case 71 of the housing portion 7 is fixed to the support housing 81 of the support portion 8. That is, the support housing 81 of the support portion 8 supports the housing housing 71 of the housing portion 7. A control unit 82 that controls each part of the speaker device 5 is provided inside the support housing 81 of the support unit 8. In addition, the support housing 81 and the housing housing 71 may be capable of drawing and drawing out wiring or the like, for example, by providing a hole that can share the space in each housing.

(Hardware configuration of control unit)
Next, the hardware configuration of the control unit 82 will be described with reference to FIGS. 2, 4, and 5. In the present embodiment, each of the speaker device 5a and the speaker device 5b includes a control unit 82. Therefore, it is assumed that the control unit 82 of FIG. 5 is provided in the speaker device 5a shown in FIGS. FIG. 5 is a block diagram showing a hardware configuration of the control unit 82. As shown in the figure, the control unit 82 includes a control unit 821, a connection unit 822, and a signal processing unit 823.

  The connection unit 822 includes a connector to which the cable 3 is connected. In addition, an acoustic signal output from the playback device 2 is input to the connection unit 822 via the cable 3. The signal processing unit 823 includes an amplifier corresponding to each of the electrostatic speakers 621, 622, and 623, amplifies the acoustic signal output from the playback device 2, and outputs to the electrostatic speakers 621, 622, and 623. Output function.

The control unit 821 includes an arithmetic processing device such as a CPU (Central Processing Unit) and various memories such as a ROM (Read Only Memory) and a RAM (Random Access Memory). The CPU of the control unit 821 has a function of controlling each unit of the speaker device 5 by reading a program stored in the ROM, loading it into the RAM, and executing it.
A male connector 631a and a female connector 721a are connected to the control unit 821. In addition, the control unit 821 has a function for detecting that a female connector provided in another speaker device is connected to the male connector 631a. For example, a case where the control unit 821 detects that the female connector 721b is connected to the male connector 631a will be described. First, a signal output from the control unit 821 of the speaker device 5b is input to the female connector 721b. When the female connector 721b and the male connector 631a are connected, this signal is supplied from the female connector 721b to the male connector 631a. The male connector 631a is connected to the control unit 821. Therefore, the signal supplied from the female connector 721b to the male connector 631a is supplied to the control unit 821 via the male connector 631a. By detecting this signal, the control unit 821 determines that the female connector 721b is connected to the male connector 631a. Note that the control unit 821 outputs a signal to the female connector 721a in the same manner as the control unit 821 of the speaker device 5b.

  In addition, the ROM of the control unit 821 is associated with the rotation angle input from the position detector 75, and information (position) for specifying the electrostatic speakers 621, 622, and 623 located outside the storage unit 7. Information). For example, in the ROM of the control unit 821, as position information, the electrostatic speaker 623 is associated with the rotation angle a, the electrostatic speaker 623 and the electrostatic speaker 622 are associated with the rotation angle b (b> a). In correspondence with the rotation angle c (b> c), it is described that the electrostatic speaker 623, the electrostatic speaker 622, and the electrostatic speaker 621 are located outside the housing portion 7. When the rotation angle is input, the control unit 821 identifies the electrostatic speakers 621, 622, and 623 located outside the housing unit 7. That is, the control unit functions as an example of a detection unit that detects an electrostatic speaker outside the housing among the plurality of electrostatic speakers.

(Operation of speaker system 4)
In the speaker device 5, the sound emitting unit 6 is protected by the housing case 71 in a state where the sound emitting unit 6 is housed in the housing unit 7, so that the vibrating body can be damaged by an externally applied force. To reduce the sex.

  In order to install the speaker device 5a and the speaker device 5b as the speaker system 4, the user pulls out the sound emitting unit 6 from the housing unit 7 of the speaker device 5a. At this time, the position detector 75 outputs a rotation angle corresponding to the length of the sound emitting unit 6 drawn from the housing unit 7. The control unit 821 specifies the electrostatic speaker of the sound emitting unit 6 drawn from the storage unit 7 based on the position information described in the ROM and the rotation angle output from the position detector 75.

  Then, the user connects the male connector 631a provided in the sound emitting unit 6 and the female connector 721b provided in the speaker device 5b, and a male connector 632a provided in the sound emitting unit 6; The female connector 722b provided in the speaker device 5b is connected. By this connection, a signal output from the control unit 821 of the speaker device 5b is supplied from the female connector 721b to the male connector 631a.

  When the control unit 821 detects that the male connector 631a and the female connector 721b are connected, the control unit 821 starts control of the signal processing unit 823. The control unit 821 causes the signal processing unit 823 to output the acoustic signal input from the playback device 2 to the electrostatic speakers 621, 622, 623 that are determined to be located outside the housing unit 7. Control. For example, when the control unit 821 specifies that the electrostatic speaker 623 and the electrostatic speaker 622 are located outside the housing unit 7, the control unit 821 performs the operation for the electrostatic speaker 623 and the electrostatic speaker 622. The signal processing unit 823 is controlled so as to output only the acoustic signal. In other words, the control unit 821 generates an acoustic wave corresponding to the acoustic signal only to the electrostatic speakers located outside the housing unit 7 among the electrostatic speakers 621, 622, and 623 provided in the sound emitting unit 6. The electrostatic loudspeaker located inside the housing portion 7 is controlled so as not to generate an acoustic wave.

  Note that the control unit 821 does not start control of the signal processing unit 823 in a state where the connection of the male connector 631 is not detected. That is, since the signal processing unit 823 does not output an acoustic signal to the sound emitting unit 6, an acoustic wave corresponding to the acoustic signal is not generated from the sound emitting unit 6.

[Modification]
The above-described embodiment is merely an example of the implementation of the present invention. The present invention can also be implemented in a mode in which the following modifications are applied to the above-described embodiments. In addition, the modification shown below may be implemented combining each suitably as needed.

(Modification 1)
In the embodiment described above, the speaker system 4 includes the speaker device 5a for generating an acoustic wave, and the speaker device 5b for supporting the sound emitting unit 6a of the speaker device 5a in a tensioned state. It was. However, the configuration of the speaker system 4 is not limited to this, and it is sufficient that the speaker system 4 includes at least two speaker devices 5.
FIG. 6 is a front view of a speaker system according to a modification.
The speaker system 40 includes a speaker device 5a, a speaker device 5b, and a speaker device 5c. The speaker device 5a and the speaker device 5b are provided to generate an acoustic wave corresponding to the acoustic signal. The speaker device 5b is provided to support the sound emitting unit 6a of the speaker device 5a in a tensioned state, and the speaker device 5c supports the sound emitting unit 6b of the speaker device 5b in a tensioned state. Is provided.

  The speaker device 5a includes a connection unit 822a to which the acoustic signal output from the playback device 2 is input. The speaker device 5 a is configured such that the connection portion 822 a and the male connector 6310 are connected, and an acoustic signal input to the connection portion 822 a is supplied to the male connector 6310. The speaker device 5b includes a connection portion 822b connected to the female connector 7210, and is configured such that an acoustic signal input to the female connector 7210 is supplied to the connection portion 822b. The male connector 6310 and the female connector 7210 are provided with electrodes (hereinafter referred to as speaker electrodes) that can transmit acoustic signals. With such a configuration, the speaker system 40 transmits the acoustic signal input to the connection portion 822a of the speaker device 5a via the speaker electrodes provided on the male connector 6310 and the female connector 7210. 5b can be supplied to the connecting portion 822b. The speaker device 5 can generate an acoustic wave from the sound emitting unit 6 according to the acoustic signal input to the connection unit 822a. Therefore, the speaker system 40 can generate an acoustic wave corresponding to the acoustic signal input to the connection unit 822a of the speaker device 5a from the sound emitting unit 6a and the sound emitting unit 6b.

Furthermore, the speaker device 5a may generate the same acoustic wave (so-called monaural) in the sound emitting unit 6a and the sound emitting unit 6b by switching the input of the sound signal to the sound emitting unit 6a and the sound emitting unit 6b. However, different acoustic waves may be generated. In the case of generating different acoustic waves, the speaker device 5a may generate acoustic waves corresponding to two-channel acoustic signals, such as stereo, for the sound emitting unit 6a and the sound emitting unit 6b, or different. An acoustic wave corresponding to the acoustic signal may be generated. In addition, what is necessary is just to perform switching of an acoustic signal as follows.
The playback device has a function of outputting an acoustic signal through two channels, an L channel and an R channel. Note that an acoustic signal output from the L channel is referred to as an acoustic signal L, and an acoustic signal output from the R channel is referred to as an acoustic signal R. The speaker device 5a includes a control unit 82L corresponding to the L channel and a control unit 82R corresponding to the R channel. The control unit 82L includes a control unit 821L, a connection unit 822L to which the acoustic signal L is input, and a signal processing unit 823L that amplifies the acoustic signal L and outputs it to the sound emitting unit 6a. The control unit 82R includes a control unit 821R, a connection unit 822R to which the acoustic signal R is input, and a signal processing unit 823R that amplifies the acoustic signal R and outputs the amplified signal to the sound emitting unit 6b. That is, the control unit 82L and the control unit 82R have the same configuration as the control unit 82 in the present embodiment. With such a configuration, the control unit 821L of the control unit 82L generates an acoustic wave corresponding to the acoustic signal L from the sound emitting unit 6a, and the control unit 821R of the control unit 82R responds to the acoustic signal R. An acoustic wave can be generated from the sound emitting unit 6b.
Further, the housing portion of the speaker device 5 may be provided with a user interface (input changeover switch) for switching input of an acoustic signal. And the user of the speaker system 40 may switch the input of the acoustic signal with respect to the sound emission part 6 by operating an input switch at arbitrary timings.
Note that the number of channels to which the playback device 2 and the speaker device 5 correspond is not limited to two and may be any number. Further, the acoustic signal corresponding to the channel may be input not for each sound emitting unit 6 but for each electrostatic speaker 621.

  Note that the speaker system 40 outputs an acoustic signal from the playback device 2 to the speaker devices 5a and 5b by connecting the playback device 2 and the speaker device 5a, and the playback device 2 and the speaker device 5b with the cable 3. You may comprise as follows.

(Modification 2)
The number of male connectors provided in the sound emitting unit 6 is not limited to two. It suffices that at least one male connector is provided in the sound emitting unit 6. Moreover, the control part 821 should just detect the connection of a male connector and the female connector with which the other speaker apparatus was equipped. Further, the number of female connectors provided in the accommodating portion 7 is not limited to two. It is sufficient that at least one female connector is provided in the accommodating portion 7, and it is sufficient if the number is the same as the number of male connectors provided in the sound emitting portions of other speaker devices.

The position and number of female connectors provided on the outer peripheral surface of the housing are not limited to the example shown in FIG. FIG. 7 is a cross-sectional view of the speaker device 5 according to a modification.
The female connector 725 is disposed on the outer peripheral surface of the housing 71 and is disposed at a position facing the opening 76 when the housing 71 is viewed from the Z-axis direction. Further, the female connector 724 and the female connector 726 are disposed on the outer peripheral surface of the housing 71, and are disposed to face each other at an intermediate position between the opening 76 and the female connector 725. As described above, when a plurality of female connectors are provided on the outer peripheral surface of the housing 71, a plurality of speaker devices 5 can be connected to one speaker device 5.
The sound emitting unit 6 may be provided with a female connector, and the housing part 7 may be provided with a male connector.

(Modification 3)
In the above-described embodiment, the sound emitting unit 6 is configured by arranging electrostatic speakers having a longitudinal direction in the Z-axis direction at a predetermined interval in the X-axis direction. However, the electrostatic speaker provided in the sound emitting unit 6 does not necessarily have a longitudinal direction in the Z-axis direction. For example, the sound emitting unit 6 may be configured by arranging electrostatic speakers having a longitudinal direction in the X-axis direction with a predetermined interval in the Z-axis direction.
In the above-described embodiment, the speaker device 5 includes one sound emitting unit 6, but the speaker device 5 may include one or more sound emitting units 6.

FIG. 8 is a front view of a speaker system according to a modification.
The speaker system 400 includes a speaker device 5a that generates an acoustic wave and a speaker device 5b that is connected to the speaker device 5a. In this modification, the configurations of the speaker devices 5a and 5b are the same, and therefore the description of “a” and “b” is omitted unless it is particularly necessary to distinguish between the two. The speaker device 5 includes a sound emitting unit 60c, a sound emitting unit 60d, a housing unit 70, and a support unit 8. In the present modification, the configurations of the sound emitting units 60c and 60d are the same, and therefore the description of “c” and “d” is omitted unless it is particularly necessary to distinguish between the two.

  The sound emitting unit 60 has a rectangular shape when viewed from the front, and includes protective cloths 613 and 614, an electrostatic speaker 624, and a male connector 631. The left end of the sound emitting unit 60 is fixed inside the housing unit 70 as a fixed end. The right end of the sound emitting unit 60 is a free end. A male connector 631 is provided at the right end of the sound emitting unit 60. The upper end and the lower end of the sound emitting unit 60 are free ends like the right end. The male connector 631 is connected to a female connector 721 provided in the speaker device 5b. The protective cloths 613 and 614 are so-called cloths having a rectangular shape when viewed from the front. Between the protective cloth 613 and the protective cloth 614, an electrostatic speaker 624 with the X-axis direction as the longitudinal direction is disposed. In FIG. 8, for convenience of explanation, a part of the protective cloth 613 is omitted, and a part of the electrostatic speaker 624 is exposed without being covered with the protective cloth 613. It is assumed that the electrostatic speaker 624 is entirely covered with a protective cloth 613.

  The accommodating portion 70 is configured to be able to draw out the sound emitting portion 60c and the sound emitting portion 60d provided at predetermined intervals in the Z-axis direction. The control unit of the speaker device 5a has a function for detecting the connection between the male connector 631c and a female connector provided in another speaker device. Further, the control unit of the speaker device 5a has a function for detecting the connection between the male connector 631d and a female connector provided in another speaker device. And the control part of the speaker apparatus 5a is comprised so that an acoustic wave according to an acoustic signal can be generated from either one or both of the sound emission part 60c and the sound emission part 60d. With such a configuration, the speaker system 400 can generate an acoustic wave from a sound emitting unit that is drawn according to the height of the listener's ear, for example. In addition, when the control unit of the speaker device 5a detects that the plurality of sound emitting units 60 are drawn, the control unit generates a sound wave corresponding to the same sound signal to each sound emitting unit 60. Alternatively, an acoustic wave corresponding to a different acoustic signal may be generated.

(Modification 4)
In the above-described embodiment, the sound emitting unit 6 includes the electrostatic speakers 621, 622, and 623. However, the number of electrostatic speakers included in the sound emitting unit 6 is not limited to three, and it is only necessary to include one or more electrostatic speakers. In the case where the sound emitting unit 6 includes two or more electrostatic speakers, the control unit 821 generates the same acoustic wave by switching the input of the acoustic signal to each electrostatic speaker (so-called monaural). Or different acoustic waves may be generated. When generating different acoustic waves, the control unit 821 may generate acoustic waves corresponding to two-channel acoustic signals, such as stereo, for each electrostatic speaker, or according to different acoustic signals. An acoustic wave may be generated.

(Modification 5)
In the embodiment described above, the speaker device 5a and the speaker device 5b constituting the speaker system 4 have the same configuration. However, when the speaker device 5b is used only to support the sound emitting unit 6a of the speaker device 5a, the speaker device 5b does not need to have the same configuration as the speaker device 5a, and at least the sound emitting unit 6 and A configuration without the control unit 82 may be employed.

(Modification 6)
In the embodiment described above, the control unit 821 selects the electrostatic speaker of the sound emitting unit 6 drawn from the storage unit 7 based on the position information described in the ROM and the rotation angle output from the position detector 75. Identified. Then, the control unit 821 generates an acoustic wave corresponding to the acoustic signal only in the electrostatic speaker located outside the housing unit 7 and generates an acoustic wave in the electrostatic speaker located inside the housing unit 7. It was controlled not to let it.
However, the control unit 821 may control the electrostatic speaker located inside the housing unit 7 to generate an acoustic wave. Further, the control unit 821 may control the volume level, directivity, and frequency characteristics of the acoustic wave generated by the electrostatic speaker according to the length of the sound emitting unit 6 drawn from the housing unit 7. For example, the control unit 821 increases the volume level when the length of the sound emitting unit 6 pulled out from the storage unit 7 is short, or the length of the sound emitting unit 6 pulled out from the storage unit 7 is long. In this case, the volume level may be lowered. Further, for example, the control unit 821 adjusts the delay amount of the acoustic signal supplied to each electrostatic speaker according to the number of electrostatic speakers pulled out from the housing unit 7, thereby allowing the speaker system 4 to The directivity of the emitted sound may be controlled. In addition, since directivity has frequency characteristics, directivity is stronger in the high frequency band than in the low frequency band. Therefore, the control unit 821 may control the directivity of the sound radiated from the speaker system 4 so that the directivity does not change according to the frequency band.

(Modification 7)
The controller 821 may control the directivity of the sound radiated from the speaker system 4 by adjusting the delay amount of the acoustic signal supplied to each electrostatic speaker.
(Modification 8)
In the embodiment described above, the sound emitting unit 6 is housed in the housing unit 7 by being wound around the rotation shaft 73. However, the method of accommodating the sound emitting unit 6 in the accommodating unit 7 is not limited to this.
FIG. 9 is a cross-sectional view of the accommodating portion 700 and the sound emitting portion 600 according to a modification.
As shown in FIG. 9, the housing 710 of the housing 700 is formed in a square cylinder and has an opening 760 on the side surface. The female connector 721 is disposed on the outer peripheral surface of the housing 710 and is disposed at a position facing the opening 760 when the housing 710 is viewed from the Z-axis direction. The left end of the sound emitting unit 600 is fixed as a fixed end to the fixing unit 712 inside the housing 710, and the right end of the sound emitting unit 600 is a free end. A male connector 631 is provided at the right end of the sound emitting unit 600. The upper end and the lower end of the sound emitting unit 600 are free ends like the right end. The sound emitting unit 600 is housed in the housing 710 by being folded in a so-called bellows fold, in which valley folds and mountain folds are alternately repeated.

  The housing 710 is provided with a lid 780 for closing the opening 760. The lid 780 is provided so as to be openable and closable by a hinge 711 provided inside the housing 710 near the opening 760. In a state where the opening 760 is closed, the housing 710 prevents a force applied from the outside of the housing 710 from being directly transmitted to the electrostatic speaker of the sound emitting unit 600. Since the housing 710 is formed of a harder member than the sound emitting unit 600, there is a possibility that the electrostatic speaker (vibrating body) of the sound emitting unit 600 may be damaged by a force applied from the outside. Make it smaller. The shape of the housing 710 is not limited to a cylinder or a square tube, but may be other shapes such as a polygon or an ellipse. Note that the housing 710 may not be provided with the lid 780.

(Modification 9)
The winding mechanism 74 is configured to rotate the rotating shaft 73 using a mainspring spring as a power source. However, the winding mechanism 74 may rotate the rotating shaft 73 according to the power of a motor, for example, or may include a handle (not shown) for rotating the rotating shaft 73 and release it by human power. The sound part 6 may be wound up. That is, the winding mechanism 74 only needs to have a configuration for winding the sound emitting unit 6 fixed to the rotating shaft 73 by rotating the rotating shaft 73 in a predetermined direction.

(Modification 10)
In the embodiment described above, the shapes of the sound emitting unit 6 and the electrostatic speakers 621, 622, and 623 are not limited to rectangles, and may be other shapes such as polygons, circles, and ellipses. . In addition, the shape of the housing 71 of the housing 7 is not limited to a cylinder, and may be a polygonal column.

(Modification 11)
The members of the electrodes 6213U and 6213L, the vibrating body 6211, and the elastic members 6212U and 6212L constituting the electrostatic speaker 621 are restrained by an insulating thread, but are restrained by, for example, an insulating adhesive tape. It may be. That is, it is only necessary that the positional relationship among the electrodes 6213U and 6213L, the vibrating body 6211, and the elastic members 6212U and 6212L constituting the electrostatic speaker 621 is not changed.

(Modification 12)
When an external device different from the speaker device 5 has the function of the control unit 82, the speaker device 5 may not include the control unit 82.

(Modification 13)
In the embodiment described above, the control unit 821 identifies the electrostatic speaker located outside the housing unit 7 based on the rotation angle output from the position detector 75. However, the method for specifying the electrostatic speaker located outside the housing portion 7 is not limited to this.
For example, the position detector 75 is an incremental rotary encoder, so that the position detector 75 outputs the number of rotations of the rotary shaft 73. And the control part 821 may specify the electrostatic speaker located in the outer side of the accommodating part 7 based on the information regarding the rotation frequency described in ROM, and the position of an electrostatic speaker.
In addition, for example, a non-contact type IC chip storing information for identifying an electrostatic speaker is provided in association with each electrostatic speaker, and a reader device that reads information on the IC chip is provided in the opening of the housing case. Provided near the section. With such a configuration, the control unit 821 causes the reader device to read information on the IC chip that passes through the opening of the housing case, so that the electrostatic speaker 621 positioned outside the housing unit 7 can be You may specify.

(Modification 14)
In the case where the sound emitting unit includes one electrostatic speaker, the sound emitting unit may not include the protective cloth. In this case, the electrostatic speaker is fixed to the rotating shaft of the housing portion with the left end as a fixed end, and a male connector is provided at the right end which is a free end.

(Modification 15)
In the above-described embodiment, a so-called push-pull type electrostatic speaker having two electrodes and one vibrating body is used, but a so-called single type having one electrode and one vibrating body is used. Alternatively, an electrostatic speaker may be used. In short, an electric field that changes in response to an acoustic signal is formed, and a charged vibrating body is displaced by receiving an electrostatic force from this electric field, and vibration is generated by sequentially changing the direction of displacement, and the vibration state (frequency, Any structure may be used as long as sound according to amplitude and phase is generated from the vibrating body.

DESCRIPTION OF SYMBOLS 1 ... Acoustic system, 2 ... Playback apparatus, 3 ... Cable, 4,40,400 ... Speaker system, 5 ... Speaker apparatus, 6,600,601,602 ... Sound emission part, 611,612,613,614 ... Protective cloth 621, 622, 623, 624 ... electrostatic speaker, 6211 ... vibrating body, 6212 ... elastic member, 6213 ... electrode, 6214 ... transformer, 6215 ... input section, 6216 ... bias power supply source, 631, 632, 6310 ... Male connector, 7,70,700 ... accommodating part, 71,710 ... accommodating housing, 711 ... hinge, 712 ... fixing part, 721,7210,722,724,725,726 ... female connector, 73 ... rotation Axis, 74 ... winding mechanism, 75 ... position detector, 76, 760 ... opening, 780 ... lid, 8 ... support part, 81 ... support housing, 82 ... control unit, 821 Control unit, 822 ... connection section, 823 ... signal processing unit, 83 ... hole, 9 ... power supply

Claims (3)

A sheet-like sound emitting section including an electrostatic speaker having a bendable electrode and a vibrating body that is bendable and spaced apart from the electrode;
A drive unit for applying a bias voltage to the vibrating body and supplying an input acoustic signal to the electrode;
A speaker device comprising: a housing having a space for housing the sound emitting portion therein and having an opening that opens from the space to the outside and through which the sound emitting portion passes. The housing is
An end portion of the sound emitting portion is fixed, and a shaft that winds up the sound emitting portion;
Winding means for rotating the shaft in a direction for winding the sound emitting part;
In the space,
The sound emitting part is
The speaker device according to claim 1, further comprising a fixing unit that fixes a free end opposite to the end fixed to the shaft to the other speaker device. The sound emitting unit has a plurality of the electrostatic speakers,
Among the plurality of electrostatic speakers, the detector has a detecting means for detecting the electrostatic speakers outside the housing,
The speaker device according to claim 1, wherein the driving unit supplies the acoustic signal to the electrode of the electrostatic speaker detected by the detection unit.

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