JP2006060418A - Speaker device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a speaker device with stable operation by restricting a pressure variation caused by a change in ambient temperature or inner pressure and generated at a space, which includes absorbent for absorbing gas physically. <P>SOLUTION: The speaker device includes a cabinet 10, a speaker unit 11, an absorbent 12 arranged at a hollow room R, a rear face plate 13, an inlet valve 14, and an exhaust valve 15. In this way, a variation in sound pressure at the rear face plate of the speaker unit 11 is restricted through physical absorption function of the absorbent 12 and low-pitched sound reproduction is realized in a small cabinet. The pressure variation inside the cabinet caused by a change in ambient temperature and atmospheric pressure is restricted through air intake and exhaust of the inlet valve 14 and the exhaust valve 15. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a speaker device, and more particularly to a speaker device that realizes low-frequency sound reproduction with a small speaker cabinet.

  In general, it is difficult for a small speaker device to realize a speaker system capable of low-frequency reproduction due to the influence of acoustic stiffness exhibited by a vacant space of a speaker cabinet. Conventionally, in order to realize bass reproduction with this small speaker device, as one means for solving the problem of the bass reproduction limit determined by the cabinet volume, there is a sealed speaker device in which a lump of activated carbon is arranged inside the cabinet. (For example, refer to Patent Document 1).

  FIG. 10 is a structural cross-sectional view of the main part of the speaker device disclosed in Patent Document 1. In FIG. 10, the speaker device includes a cabinet 101, a bass speaker 102, activated carbon 103, a support member 104, a diaphragm 105, and a vent pipe 106. The low-frequency speaker 102 is attached to the front surface of the cabinet 101. The activated carbon 103 is arranged in a lump shape inside the cabinet 101 and is supported by the back surface, bottom surface, top surface, left and right side surfaces of the cabinet 101, and the support member 104. The support member 104 has pores that allow air to pass through the entire surface thereof. The vent pipe 106 is provided in the diaphragm 105 and vents between the activated carbon 103 and the bass speaker 102.

  Next, the operation of the speaker device will be described. When an electrical signal is applied to the bass speaker 102, the pressure in the cabinet 101 changes, and the diaphragm 105 vibrates due to this pressure. And the pressure of the empty room in which the activated carbon 103 is arrange | positioned with the vibration of the diaphragm 105 changes. The activated carbon 103 is supported in a lump by the support member 104 and the cabinet 101, but since pores are provided on the entire surface of the support member 104, air molecules accompanying pressure changes due to vibration of the diaphragm 105 are generated in the activated carbon 103. By adsorbing, the pressure fluctuation in the cabinet 101 is suppressed.

As described above, the conventional speaker device operates as a cabinet having an equivalently large volume, so that bass reproduction is possible as if the speaker unit was mounted in a large cabinet while being a small cabinet. The vent pipe 106 prevents pressure fluctuations in the space surrounded by the diaphragm 105 including the activated carbon 103 and the cabinet 101 due to changes in the ambient temperature of the speaker device and the internal pressure.
JP-T-60-500635

  However, the speaker device disclosed in Patent Document 1 releases the pressure when the space surrounded by the diaphragm 105 including the activated carbon 103 and the cabinet 101 is fluctuated due to a change in ambient temperature or internal pressure of the speaker device. The space is inside the cabinet 101 which is the back surface of the bass speaker 102 through the vent pipe 106. Therefore, in the sealed speaker device, since the degree of sealing of the back space of the bass speaker 102 is high, the pressure change directly affects the diaphragm of the bass speaker 102.

  For example, when the pressure in the space surrounded by the diaphragm 105 including the activated carbon 103 and the cabinet 101 rises due to the temperature rise of the speaker device, the high-pressure air released from the vent pipe 106 causes the diaphragm of the low-frequency speaker 102 to be exposed to the outside. Push to the space side. Then, the position of the diaphragm of the low-frequency speaker 102 deviates from the normal equilibrium position, the driving force generated in the voice coil and the suspension supporting force become non-linear, and the reproduction sound pressure of the speaker device is distorted.

  Therefore, the object of the present invention is to suppress the pressure fluctuation generated in the space including the adsorbent (activated carbon) that physically adsorbs the gas without affecting the operation of the speaker unit due to the ambient temperature of the speaker device or the internal pressure change. Thus, it is to provide a speaker device that maintains a stable operation.

In order to achieve the above object, the present invention has the following features.
1st invention is a speaker apparatus provided with a cabinet, a speaker unit, an adsorbent, an exhaust valve, and an intake valve. The speaker unit is attached to the cabinet. The adsorbent is disposed in an empty space inside the cabinet and physically adsorbs the gas. In the exhaust valve, the pressure in the empty space inside the cabinet is larger than the pressure outside the cabinet, and the difference between the pressures opens when the pressure is equal to or higher than the first pressure, and the gas inside the cabinet is discharged to the outside. The intake valve has a pressure outside the cabinet that is greater than the pressure in the vacant space inside the cabinet, and the difference between these pressures opens when the pressure is greater than or equal to the second pressure, allowing gas to be taken into the cabinet from the outside.

  According to a second aspect, in the first aspect, the first pressure at which the exhaust valve opens is based on a difference between a maximum value of a change in pressure generated inside the cabinet by driving the speaker unit and a pressure outside the cabinet. large. The second pressure at which the intake valve opens is greater than the difference between the pressure outside the cabinet and the minimum value of the change in pressure generated inside the cabinet when the speaker unit is driven.

  In a third aspect based on the first aspect, the adsorbent is activated carbon.

  In a fourth aspect based on the first aspect, the adsorbent is a carbon nanotube.

  In a fifth aspect based on the first aspect, the adsorbent is fullerene.

  In a sixth aspect based on the first aspect, the empty space inside the cabinet is a single space sealed from the outside, and the exhaust valve and the intake valve are provided in the cabinet.

  In a seventh aspect based on the first aspect, a drone cone and a port are further provided. The drone cone is provided inside the cabinet, and divides the vacant space inside the cabinet into a first vacant space formed on the speaker unit side and a second vacant space formed on the back side of the speaker device. The port is provided in the cabinet and opens the first vacancy to the outside. The adsorbent is disposed in the second empty chamber. The exhaust valve opens when the pressure in the second vacant chamber is greater than the pressure outside the cabinet, and the difference between the pressures exceeds the first pressure, and discharges the gas in the second vacant chamber to the outside. The intake valve has a pressure outside the cabinet larger than the pressure in the second vacant chamber, and the difference between these pressures opens when the pressure is greater than or equal to the second pressure, and takes in gas from the outside into the second vacant chamber.

  In an eighth aspect based on the seventh aspect, the exhaust valve and the intake valve are provided in a cabinet forming the second empty chamber.

  In a ninth aspect based on the seventh aspect, the drone cone is supported via a partition plate fixed inside the cabinet. The exhaust valve is provided on the partition plate, and discharges the gas in the second vacancy to the outside through the first vacancy when the valve is opened. The intake valve is provided on the partition plate, and takes the gas from the outside into the second empty chamber through the first empty chamber when the valve is opened.

  In a tenth aspect based on the first aspect, a drone cone, a port, and a low-pass filter are further provided. The drone cone is provided inside the cabinet and divides the vacant space inside the cabinet to form a first vacant space on the speaker unit side. The port is provided in the cabinet and opens the first vacancy to the outside. The low-pass filter is provided on the back side of the drone cone inside the cabinet, and the third empty room formed on the back side of the speaker device and the second empty room formed on the drone cone side of the empty room inside the cabinet. And further divided. The adsorbent is disposed in the second empty chamber. The exhaust valve is provided in the cabinet, and the pressure in the third vacant chamber is larger than the pressure outside the cabinet, and the difference between these pressures opens when the pressure is greater than or equal to the first pressure. Discharge. The intake valve is provided in the cabinet, and the pressure outside the cabinet is larger than the pressure in the third vacant space, and the difference between these pressures opens when the pressure is equal to or higher than the second pressure. Incorporate.

  According to the first invention, the adsorbent that physically adsorbs the gas is disposed inside the cabinet to which the speaker unit is attached, and the exhaust valve and the intake valve are provided. As a result, the acoustic stiffness exhibited by the cabinet vacancy on the back of the speaker unit is reduced, the cabinet volume is increased equivalently, and bass reproduction is realized in a small cabinet. Furthermore, even if the pressure inside the cabinet changes due to changes in temperature or atmospheric pressure, for example, in the surrounding environment where the speaker device is placed, the exhaust valve and intake valve suppress fluctuations in pressure inside the cabinet. A speaker device in which the acoustic performance is less likely to change can be realized.

  According to the second invention, the exhaust valve and the intake valve do not open due to a change in internal pressure that occurs when a music signal is applied to the speaker unit, so that the valve opening operation does not affect the reproduction characteristics of the speaker device. .

  According to the third to fifth inventions, by configuring the adsorbent with any one of activated carbon, carbon nanotube, and fullerene, the cabinet volume can be increased equivalently, and bass reproduction can be realized in a small cabinet. it can.

  According to the sixth invention, when the cabinet is a hermetically sealed system, the exhaust valve and the intake valve are provided in the cabinet, and the pressure change in the cabinet is adjusted by the exhaust and intake air from the outside of the cabinet, depending on the surrounding environmental conditions Changes in acoustic performance can be avoided.

  According to the seventh invention, a bass-reflex speaker device is provided, and the bass reproduction band is further expanded by acoustic resonance of the port.

  According to the eighth invention, in the bass reflex type speaker device, the exhaust valve and the intake valve are provided in the cabinet. As a result, the pressure change in the cabinet is adjusted by the exhaust and intake air from the outside of the cabinet, and the change in acoustic performance due to the surrounding environmental conditions is avoided.

  According to the ninth invention, in the bass reflex type speaker device, the exhaust valve and the intake valve are provided on the partition plate between the first and second vacant chambers. As a result, since the intake and exhaust from the second vacancy are performed through the first vacancy, the adsorbent is caused by the exhaust and intake even under environmental conditions where the surroundings of the speaker device are deteriorated, such as in a dusty place. It is possible to prevent a decrease in the adsorption effect.

  According to the tenth aspect of the invention, the change in pressure in the second vacant chamber due to the change in ambient temperature of the speaker device and the change in atmospheric pressure becomes a change close to a direct current component in accordance with the cutoff frequency of the low-pass filter. That is, during normal music reproduction, sound does not pass through the low-pass filter and is not transmitted to the third vacant space where the intake valve and the exhaust valve are provided, and the intake valve is caused by pressure change during music reproduction (for example, low frequency component). And the exhaust valve will not malfunction. For this reason, it is possible to separate whether the internal pressure change of the third vacant chamber is due to music reproduction or environmental change by frequency components, so that the valve opening operation is performed only by the pressure change due to the change in the use environment of the speaker device. Can be reliably suppressed.

(First embodiment)
A speaker device according to a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a cross-sectional view showing a schematic internal structure of the speaker device.

  In FIG. 1, the speaker device includes a cabinet 10, a speaker unit 11, an adsorbent 12, a back plate 13, an intake valve 14, and an exhaust valve 15. As shown in FIG. 1, the first embodiment is a sealed speaker device.

  The cabinet 10 constitutes a front surface, a back surface, an upper surface, a lower surface, and left and right side surfaces of the speaker device housing. The speaker unit 11 is an electrodynamic speaker and is attached to the front surface of the cabinet 10. Then, by attaching the back plate 13 to the cabinet 10, a vacant space R of the speaker device is formed therein.

  The adsorbent 12 is disposed inside the empty room R. The adsorbent 12 is a porous material that physically adsorbs gas, for example, activated carbon. The porous material can physically adsorb air with micro-sized pores. Other examples of the adsorbent 12 may be a carbon nanotube or fullerene. Note that a gap for venting in the front-rear direction of the speaker device is formed in the upper portion of the adsorbent body 12 and the like.

The back plate 13 is provided with an intake valve 14 and an exhaust valve 15. When the internal pressure (P _r ) of the vacant chamber R increases and becomes higher than the external pressure (P _G ) of the cabinet 10, the difference between these pressures becomes equal to or higher than the first pressure (P ₁ ) (that is, P _r −P _G ≧ P ₁ ), the exhaust valve 15 is opened, and the air inside the empty room R is discharged to the outside of the speaker device. Further, when the internal pressure (P _r ) of the empty room R decreases and becomes lower than the external pressure (P _G ) of the cabinet 10, and the difference between these pressures becomes equal to or higher than the second pressure (P ₂ ) ( That is, P _G −P _r ≧ P ₂ ), the intake valve 14 is opened, and the air outside the speaker device is taken into the vacant chamber R. The detailed structure and operation of the intake valve 14 and the exhaust valve 15 will be described later. In the present application, if there is no change in the external pressure (P _G) is (i.e. P _G is a constant) will be described assuming. In this case, when the internal pressure (P _r ) of the empty room R becomes P _G + P ₁ or higher, the exhaust valve 15 opens, and the internal pressure (P _r ) of the empty room R becomes P _G −P ₂ or lower. When this happens, the intake valve 14 opens. In the following description, P _G + P ₁ is described as the first valve opening pressure, and P _G −P ₂ is described as the second valve opening pressure. In this case, the first valve opening pressure> the second valve opening pressure is established. Further, if it is the need to take into account the external pressure of the cabinet 10 (P _G) is varied, it may be considered a pressure P _G as a variable rather than a constant.

  Next, the operation of the speaker device according to the first embodiment will be described with reference to FIGS. FIG. 2 is a cross-sectional view showing a state in which the speaker device discharges the air inside the empty room R to the outside. FIG. 3 is an enlarged cross-sectional view of the vicinity of the exhaust valve 15 showing the operation of the exhaust valve 15 when the speaker device discharges the air inside the empty room R to the outside. FIG. 4 is a cross-sectional view showing a state in which the speaker device takes air from the outside into the vacant chamber R. FIG. 5 is an enlarged cross-sectional view of the vicinity of the intake valve 14 showing the operation of the intake valve 14 when the speaker device takes air from the outside into the interior of the empty room R.

  In FIG. 2, the operation of the speaker unit 11, which is an electrodynamic speaker, is well known, so detailed description thereof will be omitted here. However, when a music signal is applied to the speaker unit 11, a force is generated in the voice coil, resulting in a cone type Sound is generated by vibrating the diaphragm. The sound pressure generated by the cone-type diaphragm increases the internal pressure of the empty space R formed by the cabinet 10 and the back plate 13. However, since the adsorbent 12 is disposed in the vacant chamber R, the pressure fluctuation in the vacant chamber R is suppressed by the gas adsorbing action of the adsorbent 12, and the vacant chamber R has an equivalently large volume. That is, the speaker device operates as if the speaker unit 11 is attached to the cabinet 10 having a large volume. The above operation is almost the same as that of the conventional speaker device described in the background art.

  On the other hand, when the internal temperature of the empty room R rises due to the usage environment such as an increase in the ambient temperature in the speaker device or the heat generation of the loudspeaker unit 11, the air inside the empty room R expands and the internal pressure rises. This increased pressure is transmitted to the intake valve 14 and the exhaust valve 15. When the difference between the internal pressure of the empty space R and the pressure outside the cabinet 10 reaches the first pressure (that is, the internal pressure of the empty space R rises to the first valve opening pressure), the exhaust valve 15 opens. The air inside the vacant chamber R is discharged to the outside and the internal pressure of the vacant chamber R is adjusted (arrow a in the figure).

  In FIG. 3, the exhaust valve 15 includes a valve 16 and a spring spring 17. The exhaust valve 15 is inserted through an exhaust hole 13 ha formed in the back plate 13. The valve 16 is urged and supported by a spring spring 17 in the direction from the outside toward the empty space R, and closes the exhaust hole 13ha by closely contacting the outer surface of the back plate 13 when the valve is closed. The internal pressure of the vacant chamber R is applied to the valve 16 through the exhaust hole 13ha.

  When the difference between the internal pressure of the empty room R and the pressure outside the cabinet 10 reaches the first pressure, the force applied in the direction separating the valve 16 from the back plate 13 (direction A in the figure) by the internal pressure is a spring. It becomes larger than the urging force of the spring 17 and is pushed by the internal pressure to move the valve 16 in the direction A in the figure. As a result, the exhaust hole 13ha is opened, and the internal air of the empty room R is discharged to the outside air as indicated by the arrow a. And by this discharge | emission, the internal pressure of the empty room R falls, and when it becomes less than the said 1st pressure, the exhaust valve 15 will close. As will become apparent from the description below, the intake valve 14 is normally closed when the internal pressure of the chamber R is greater than the second valve opening pressure, so the internal pressure of the chamber R is the first valve opening pressure. In the vicinity, the intake valve 14 is closed.

  Further, in FIG. 4, when the air inside the empty room R contracts due to a decrease in the ambient temperature in the speaker device, the internal pressure of the empty room R decreases. This reduced pressure is also transmitted to the intake valve 14 and the exhaust valve 15. When the difference between the pressure outside the cabinet 10 and the internal pressure in the empty room R reaches the second pressure (that is, the internal pressure in the empty room R decreases to the second open valve pressure), the intake valve 14 opens. The air is taken into the empty room R from the outside, and the internal pressure of the empty room R is adjusted (arrow b in the figure).

  In FIG. 5, the intake valve 14 includes a valve 18 and a spring spring 19. The intake valve 14 is inserted into an intake hole 13 hb formed in the back plate 13. The valve 18 is urged and supported by the spring spring 19 in the direction from the empty room R to the outside. When the valve is closed, the valve 18 is in close contact with the inner surface of the back plate 13 and closes the intake hole 13hb. The internal pressure of the vacant chamber R is applied to the valve 18.

  When the difference between the pressure outside the cabinet 10 and the internal pressure in the empty room R reaches the second pressure, the valve 18 is sucked in the direction away from the back plate 13 (direction B in the figure) due to the decrease in the internal pressure. When the suction force becomes larger than the urging force of the spring spring 19, the valve 18 is moved in the direction B in the drawing by being sucked by the internal pressure. As a result, the intake hole 13hb is opened, and air is taken into the empty room R from the outside as indicated by the arrow b. When the intake pressure increases the internal pressure of the vacant chamber R and becomes greater than the second pressure, the intake valve 14 is closed. Since the exhaust valve 15 is always closed when the internal pressure of the empty space R is less than the first valve opening pressure, the exhaust valve 15 is closed when the internal pressure of the empty space R is near the second open valve pressure. It becomes a state.

  Here, the first pressure and the second pressure will be described. In general, when a music signal is applied to the speaker unit 11, the internal pressure of the vacancy R changes, but the degree to which the internal pressure of the vacancy R changes due to a change in temperature or a change in atmospheric pressure depends on the music signal. Much greater than changing pressure. In particular, when the adsorbent 12 disposed in the vacant space R is activated carbon, the adsorbed gas is released when the activated carbon is overheated due to a temperature rise. There is no bigger than the traditional sealing method. Therefore, the intake valve 14 and the exhaust valve 15 do not open due to a change in the internal pressure of the vacant space R that occurs when a music signal is applied to the speaker unit 11, but open due to a large pressure change caused by a change in temperature or atmospheric pressure. The first pressure and the second pressure are set so as to control. Specifically, the first pressure and the second pressure can be adjusted by adjusting the strengths of spring springs 17 and 19 provided in the intake valve 14 and the exhaust valve 15, respectively.

  As described above, the speaker device of the present embodiment is adjusted so that the change in the internal pressure does not vary greatly between the intake valve and the exhaust valve. In addition, when the pressure changes due to the operation of the speaker unit, the intake valve and the exhaust valve do not open, so the reproduction characteristics of the speaker device are not affected. As a result, it is possible to realize a speaker device capable of stable operation while reducing the influence of changes in the surrounding environment of the speaker device and heat generation of the speaker unit.

(Second Embodiment)
A speaker device according to a second embodiment of the present invention will be described with reference to FIG. FIG. 6 is a cross-sectional view showing a schematic internal structure of the speaker device.

  In FIG. 6, the speaker device includes a cabinet 30, a speaker unit 31, a partition plate 32, a drone cone 33, an adsorbent 36, a back plate 37, an intake valve 38, an exhaust valve 39, and a port 40. As shown in FIG. 6, the second embodiment is a bass reflex type speaker device.

  The cabinet 30 constitutes a front surface, a back surface, an upper surface, a lower surface, and left and right side surfaces of the speaker device housing. The speaker unit 31 is an electrodynamic speaker and is attached to the front surface of the cabinet 30. A back plate 37 is attached to the cabinet 30. In addition, a partition plate 32 provided with a drone cone 33 is fixed inside the cabinet 30 and divides the internal space of the speaker device into a first vacancy R1 and a second vacancy R2. The drone cone 33 includes a diaphragm 34 and a suspension 35 that supports the outer periphery of the diaphragm 34. A vacant room on the front side of the speaker device on which the back surface of the speaker unit 31 is provided is referred to as a first vacant room R1. In addition, a port 40 is provided on the front surface of the cabinet 30, and the first vacant space R <b> 1 is opened to the outside through the port 40.

  The adsorbent 36 is disposed inside the second empty room R2. The adsorbent 36 is a porous material that physically adsorbs a gas such as activated carbon, as in the first embodiment, and can also be realized with carbon nanotubes or fullerenes. Note that an opening that penetrates in the front-rear direction of the speaker device is formed in a substantially central portion of the adsorbent 36.

  The back plate 37 is provided with an intake valve 38 and an exhaust valve 39. When the difference between the internal pressure of the second chamber R2 and the pressure outside the cabinet 30 reaches the first pressure (that is, the internal pressure of the second chamber R2 rises to the first valve opening pressure), exhaust The valve 39 opens to discharge the air inside the second empty chamber R2 to the outside of the speaker device. Further, when the difference between the pressure outside the cabinet 30 and the internal pressure of the second empty chamber R2 reaches the second pressure (that is, the internal pressure of the second empty chamber R2 decreases to the second valve opening pressure). Then, the intake valve 38 is opened, and the air outside the speaker device is taken into the second empty chamber R2. Here, the first valve opening pressure> the second valve opening pressure.

  Next, the operation of the speaker device according to the second embodiment will be described. The operation of the speaker unit 31 is the same as that of the speaker unit 11 described in the first embodiment. The sound pressure generated in the diaphragm of the speaker unit 31 is transmitted to the diaphragm 34 of the drone cone 33 via the first empty chamber R1 in the cabinet 30. Since the outer periphery of the diaphragm 34 is supported by the suspension 35, the diaphragm 34 vibrates and raises the internal pressure of the second empty chamber R2. However, since the adsorbent 36 is disposed in the second empty chamber R2, the pressure fluctuation in the second empty chamber R2 is suppressed by the gas adsorbing action of the adsorbent 36, and the second empty chamber R2 Equally large volume. In other words, the speaker device operates as if the speaker unit is attached to a large volume cabinet, and operates as a large volume bass reflex system by the action of the port 40.

  On the other hand, the internal pressure of the second empty chamber R2 varies with changes in the ambient temperature and atmospheric pressure in the speaker device. For example, when the internal temperature of the second empty room R2 increases, the air in the second empty room R2 expands and the internal pressure increases. This increased pressure is transmitted to the intake valve 38 and the exhaust valve 39. When the difference between the internal pressure of the second empty chamber R2 and the pressure outside the cabinet 30 reaches the first pressure, the exhaust valve 39 opens and the internal air of the second empty chamber R2 is discharged to the outside. Thus, the internal pressure of the second empty chamber R2 is adjusted. Further, when the internal air of the second vacant chamber R2 contracts due to a decrease in ambient temperature or the like in the speaker device, the internal pressure of the second vacant chamber R2 decreases. This reduced pressure is also transmitted to the intake valve 38 and the exhaust valve 39. When the difference between the pressure outside the cabinet 30 and the internal pressure of the second empty chamber R2 reaches the second pressure, the intake valve 38 is opened and air is taken into the second empty chamber R2 from the outside. The internal pressure of the second vacant chamber R2 is adjusted. The structure, operation, and valve opening pressure (first pressure, second pressure) of the intake valve 38 and the exhaust valve 39 are the same as those of the intake valve 14 and the exhaust valve 15 described in the first embodiment. Detailed description is omitted. Needless to say, the first pressure and the second pressure are adjusted in accordance with the characteristics of the speaker device.

  Here, the adsorbent 36 acts to suppress the internal pressure of the second empty chamber R2, but when the temperature rises, the adsorbent 36 itself has a great effect of releasing the gas and moisture adsorbed. . That is, the internal pressure of the second vacant chamber R2 is higher than when the adsorbent 36 is not installed. However, since the internal pressure change of the second empty chamber R2 is adjusted so as not to fluctuate greatly by the intake valve 38 and the exhaust valve 39, the change in the ambient environment of the speaker device and the speaker unit are the same as in the first embodiment. A speaker device capable of stable operation with less influence of heat generation or the like can be realized.

  The speaker device of the present embodiment is different from the first embodiment in that a port 40 is provided in the cabinet 30 and a bass reflex system is adopted. As a result, the low-frequency sound reproduction band of the speaker device according to the second embodiment is expanded as compared with the sealed speaker device according to the first embodiment. In the bass reflex system, the first vacant chamber R1 inside the speaker device is opened to the outside by the port 40, but the adsorbent 36 is prevented from always contacting the outside air by the partition plate 32 and the drone cone 33. Therefore, it is possible to prevent the adsorbent 36 from adsorbing moisture or unnecessary gas in the outside air and deteriorating the air adsorbing action. As described above, the bass reflex type speaker device that operates stably against the fluctuation of the use environment over a long period of time by separating the adsorbent 36 and the outside air by the drone cone 33 and further by the intake valve 38 and the exhaust valve 39 is provided. realizable.

  In the above-described embodiment, the intake valve 38 and the exhaust valve 39 adjust the internal pressure of the second empty chamber R2 by sucking or exhausting air between the outside air of the speaker device and the second empty chamber R2. However, the intake valve 38 and the exhaust valve 39 may be provided in other parts. For example, as shown in FIG. 7, the intake valve 38 and the exhaust valve 39 may be provided between the first empty chamber R1 and the second empty chamber R2 (for example, the partition plate 32). In this case, since the intake and exhaust from the second vacant chamber R2 are performed through the first vacant chamber R1, the exhaust and intake air can be used even under environmental conditions in which the surroundings of the speaker device are deteriorated, such as in a dusty place. An effect of preventing the adsorption effect of the adsorbent 36 from being lowered can be expected.

(Third embodiment)
A speaker apparatus according to a third embodiment of the present invention will be described with reference to FIG. FIG. 8 is a cross-sectional view showing a schematic internal structure of the speaker device.

  8, the speaker device includes a cabinet 50, a speaker unit 51, a first partition plate 52, a drone cone 53, an adsorbent 56, a back plate 57, an intake valve 58, an exhaust valve 59, a second partition plate 60, And a port 61. As shown in FIG. 8, the third embodiment is a bass reflex type speaker device.

  The cabinet 50 constitutes a front surface, a back surface, an upper surface, a lower surface, and left and right side surfaces of the speaker device housing. The speaker unit 51 is an electrodynamic speaker and is attached to the front surface of the cabinet 50. A back plate 57 is attached to the cabinet 50. A first partition plate 52 provided with a drone cone 53 is fixed inside the cabinet 50. Further, a second partition plate 60 having a sound hole 60 h formed at a substantially central portion thereof is fixed to the back side of the first partition plate 52 inside the cabinet 50. The first partition plate 52, the drone cone 53, and the second partition plate 60 divide the internal space of the speaker device into the first vacancy R1, the second vacancy R2, and the third vacancy R3. It is divided into. The drone cone 53 includes a diaphragm 54 and a suspension 55 that supports the outer periphery of the diaphragm 54. The first vacant space R1, the second vacant space R2, and the third vacant space R3 are formed in order from the front side of the speaker device on which the back surface of the speaker unit 51 is provided, and the first partition plate 52 and the drone cone 53 are provided. Is arranged between the first vacancy R1 and the second vacancy R2, and the second partition plate 60 is arranged between the second vacancy R2 and the third vacancy R3. In addition, a port 61 is provided on the front surface of the cabinet 50, and the first vacant room R <b> 1 is opened to the outside through the port 61.

  The adsorbent 56 is disposed inside the second empty room R2. The adsorbent 56 is a porous material that physically adsorbs a gas such as activated carbon as in the first and second embodiments, and can also be realized by carbon nanotubes, fullerenes, and the like. Note that an opening that penetrates the speaker device in the front-rear direction is formed in a substantially central portion of the adsorbent 56.

  The back plate 57 is provided with an intake valve 58 and an exhaust valve 59. When the difference between the internal pressure of the third chamber R3 and the pressure outside the cabinet 50 reaches the first pressure (that is, the internal pressure of the third chamber R3 rises to the first valve opening pressure), the exhaust gas is exhausted. The valve 59 opens to discharge the air inside the third vacancy R3 to the outside of the speaker device. Further, when the difference between the pressure outside the cabinet 50 and the internal pressure of the third empty chamber R3 reaches the second pressure (that is, the internal pressure of the third empty chamber R3 is reduced to the second valve opening pressure). Then, the intake valve 58 is opened, and the air outside the speaker device is taken into the third chamber R3. Here, the first valve opening pressure> the second valve opening pressure.

  Next, the operation of the speaker device according to the third embodiment will be described. The operation of the speaker unit 51 is the same as that of the speaker unit 11 described in the first embodiment. The sound pressure generated in the diaphragm of the speaker unit 51 is transmitted to the diaphragm 54 of the drone cone 53 via the first empty chamber R1 in the cabinet 50. Since the outer periphery of the diaphragm 54 is supported by the suspension 55, the diaphragm 54 vibrates to increase the internal pressure of the second empty chamber R2. However, since the adsorbent 56 is arranged in the second vacant chamber R2, the pressure fluctuation in the second vacant chamber R2 is suppressed by the gas adsorbing action of the adsorbent 56, and the second vacant chamber R2 is Equally large volume. In other words, the speaker device operates as if the speaker unit is attached to a cabinet with a large volume, and operates as a large volume bass reflex system by the action of the port 61. This is the same as that of the second embodiment described above. It is the same.

  The speaker device of the present embodiment is different from the second embodiment in that the second partition plate 60 is disposed on the back surface of the second empty room R2, and the second partition plate 60 has a sound hole 60h. The third vacant space R3 is formed on the back surface of the second partition plate 60.

  With these configurations, when the internal pressure of the second vacant chamber R2 changes depending on the temperature or pressure of the usage environment, this pressure change is caused by the third vacant chamber R3 from the sound hole 60h provided in the second partition plate 60. To be told. Then, the internal pressure of the third empty chamber R3 changes, and the pressure change is transmitted to the intake valve 58 and the exhaust valve 59 provided on the back plate 57. When the difference between the internal pressure of the third empty chamber R3 and the pressure outside the cabinet 50 reaches the first pressure, the exhaust valve 59 is opened and the internal air of the third empty chamber R3 is discharged to the outside. Thus, the internal pressure of the third empty chamber R3 is adjusted. Further, when the difference between the pressure outside the cabinet 50 and the internal pressure of the third vacant chamber R3 reaches the second pressure, the intake valve 58 is opened and air is taken into the third vacant chamber R3 from the outside. The internal pressure of the third empty chamber R3 is adjusted. The structure, operation, and valve opening pressure (first pressure, second pressure) of the intake valve 58 and the exhaust valve 59 are the same as those of the intake valve 14 and the exhaust valve 15 described in the first embodiment. Detailed description is omitted. Needless to say, the first pressure and the second pressure are adjusted in accordance with the characteristics of the speaker device.

  As described above, one of the intake valve 58 and the exhaust valve 59 attached to the back plate 57 is opened to operate so as to suppress the pressure change in the third vacant chamber R3. The sound hole 60h acts as a low-pass filter for the air passing through the sound hole 60h. If the cut-off frequency of the low-pass filter is set to a low sound range (for example, 20 Hz or less), the pressure change in the second empty room R2 due to the ambient temperature change or the atmospheric pressure change of the speaker device becomes a change close to a DC component. That is, at the time of normal music reproduction, sound does not pass through the sound hole 60h and is transmitted to the third vacant space R3, and the intake valve 58 and the exhaust valve 59 are not opened due to pressure changes during music reproduction. . For this reason, in the speaker device of this embodiment, compared with the speaker devices according to the first and second embodiments, whether the internal pressure change in the vacant room in which the intake valve 58 and the exhaust valve 59 are provided is due to music reproduction. Since it can be separated by frequency components whether it is due to the change in the environment, it is possible to reliably suppress the valve opening operation only by the pressure change due to the change in the use environment of the speaker device.

  In the above-described embodiment, the intake valve and the exhaust valve each have a valve and a spiral spring spring, and the valve is lifted when the valve is opened. However, if the same effect can be obtained, other structures are possible. It doesn't matter. For example, as shown in FIG. 9, a structure in which the valve rotates about the rotation axis when the valve is opened may be used. FIG. 9 is an enlarged cross-sectional view of the exhaust valve 71 for illustrating another example of the structure of the intake valve and the exhaust valve.

  In FIG. 9, the exhaust valve 71 includes a valve 72, a spring 73, and a rotating shaft 74. The exhaust valve 71 is provided so as to open and close an exhaust hole 70 h formed in the back plate 70. The valve 72 is rotatable around a rotation shaft 74 provided on the outer side of the back plate 70, and closes the exhaust hole 70h from the outside when located on the most back plate 70 side. The valve 72 is biased by the spring 73 so as to rotate in a direction to close the exhaust hole 70h. When the exhaust valve 71 is closed, the internal pressure of the speaker device is applied to the valve 72 through the exhaust hole 70h.

  When the difference between the internal pressure of the speaker device and the pressure outside the cabinet 70 reaches the first pressure, and the internal pressure becomes equal to or higher than the valve opening pressure (first valve opening pressure) of the exhaust valve 71, The force that causes the valve 72 to rotate away from the back plate 70 by the internal pressure (C direction in the figure) is greater than the urging force of the spring 73, and the valve 72 moves in the C direction in the figure when pressed by the internal pressure. As a result, the exhaust hole 70h is opened, and the internal air of the speaker device is exhausted to the outside air as indicated by an arrow c. Then, the internal pressure of the speaker device decreases due to this discharge, and the exhaust valve 71 is closed when the pressure becomes less than the valve opening pressure.

  Needless to say, the intake valve with the same structure can be configured with the same structure by configuring the exhaust valve 71 in the opposite direction with respect to the back plate 70. The spring 73 may be other types of springs such as a cantilever spring in addition to the spiral spring spring shown in the figure. Further, when a cantilever spring is constituted by a leaf spring or the like, the exhaust hole 70h may be closed by one warp of the leaf spring, and the exhaust hole 70h may be opened and closed by warpage of the leaf spring itself.

  One electromagnetic valve (not shown) may be provided on the back plate. In this case, a sensor (not shown) for detecting the internal pressure of the speaker device and a controller (not shown) for opening and closing the electromagnetic valve according to the pressure detected by the sensor are provided in the speaker device. When the sensor detects the first valve opening pressure, the control unit opens the electromagnetic valve to discharge air from the speaker device, and when the sensor detects the second valve opening pressure, the control is performed. The part opens the electromagnetic valve and takes outside air into the speaker device. That is, the electromagnetic valve also serves as an intake valve and an exhaust valve.

  As described above, according to the speaker devices according to the first to third embodiments, the adsorbent that physically adsorbs the gas is disposed inside the cabinet to which the speaker unit is attached, and the exhaust valve and the intake valve are partially provided in the cabinet. It is set as the structure which provided. As a result, the acoustic stiffness exhibited by the cabinet vacancy on the back of the speaker unit is reduced, the cabinet volume is increased equivalently, and bass reproduction is realized in a small cabinet. Furthermore, even if the pressure inside the cabinet changes due to changes in the ambient environment where the speaker device is placed, for example, temperature or atmospheric pressure, the exhaust valve and the intake valve provided in the cabinet suppress the pressure fluctuation inside the cabinet. It is possible to realize a speaker device in which the acoustic performance hardly changes under the environmental conditions. In particular, since the outside air is temporarily taken into the speaker device when the surrounding environment changes, the adsorbent adsorbs moisture or unnecessary gas in the outside air and deteriorates the physical adsorption action of the gas. Can be prevented. Since the speaker device enables low-frequency reproduction with a small cabinet volume, liquid crystal televisions, PDPs (plasma displays), stereo devices, 5.1-channel reproduction home theater speakers, in-vehicle speakers, and the like that are becoming thinner An audio device that can be used for a high-quality and low-pitched sound reproduction is realized.

  The speaker device according to the present invention can reproduce a low sound range with a small cabinet volume, has an effect of suppressing a change in acoustic performance under ambient environmental conditions, and is useful as a small speaker device or the like.

Sectional drawing which shows the internal schematic structure of the speaker apparatus which concerns on the 1st Embodiment of this invention. FIG. 1 is a cross-sectional view showing a state in which the speaker device of FIG. 1 is an enlarged cross-sectional view of the vicinity of the exhaust valve 15 showing the operation of the exhaust valve 15 when the speaker device of FIG. FIG. 1 is a cross-sectional view showing a state in which the speaker device of FIG. 1 is an enlarged cross-sectional view of the vicinity of the intake valve 14 showing the operation of the intake valve 14 when the speaker device of FIG. Sectional drawing which shows the internal schematic structure of the speaker apparatus which concerns on the 2nd Embodiment of this invention. Sectional drawing which shows the other example which provided the intake valve 38 and the exhaust valve 39 in the other site | part with the speaker apparatus of FIG. Sectional drawing which shows the internal schematic structure of the speaker apparatus which concerns on the 3rd Embodiment of this invention. Cross-sectional enlarged view of the exhaust valve 71 for showing another example of the structure of the intake valve and the exhaust valve Cross-sectional view of the main part of a conventional speaker device

Explanation of symbols

10, 30, 50 ... Cabinet 11, 31, 51 ... Speaker unit 12, 36, 56 ... Adsorber 13, 37, 57, 70 ... Back plate 14, 38, 58 ... Intake valve 15, 39, 59, 71 ... Exhaust Valves 16, 18, 72 ... Valves 17, 19 ... Spring spring 32 ... Partition plate 33, 53 ... Drone cone 34, 54 ... Diaphragm 35, 55 ... Suspension 40, 61 ... Port 52 ... First partition plate 60 ... First 2 partition plates 73 ... springs 74 ... rotating shaft

Claims (10)

Cabinet,
A speaker unit attached to the cabinet;
An adsorbent disposed in an empty space inside the cabinet and physically adsorbing a gas;
An exhaust valve for opening the pressure inside the cabinet larger than the pressure outside the cabinet and opening the difference between the pressures at a first pressure or more to discharge the gas inside the cabinet to the outside;
A speaker device comprising: an intake valve that opens when the pressure outside the cabinet is greater than the pressure of an empty space inside the cabinet, and the difference between the pressures is equal to or greater than a second pressure, and takes gas from the outside into the cabinet. The first pressure at which the exhaust valve opens is greater than the difference between the maximum value of the change in pressure generated inside the cabinet and the pressure outside the cabinet when the speaker unit is driven,
The second pressure at which the intake valve opens is larger than a difference between a pressure outside the cabinet and a minimum value of a change in pressure generated inside the cabinet by driving the speaker unit. 2. The speaker device according to 1.   The speaker device according to claim 1, wherein the adsorbent is activated carbon.   The speaker device according to claim 1, wherein the adsorbent is a carbon nanotube.   The speaker device according to claim 1, wherein the adsorbent is fullerene. The vacant space inside the cabinet is a single space sealed from the outside,
The speaker device according to claim 1, wherein the exhaust valve and the intake valve are provided in the cabinet. A drone cone provided inside the cabinet and dividing a vacant space inside the cabinet into a first vacant space formed on the speaker unit side and a second vacant space formed on the back side of the speaker device; ,
A port provided in the cabinet and opening the first vacancy to the outside,
The adsorbent is disposed in the second empty chamber;
The exhaust valve opens when the pressure in the second vacant chamber is greater than the pressure outside the second vacant chamber, and the difference in pressure is greater than or equal to the first pressure. Exhaust the gas to the outside,
The intake valve has a pressure outside the second vacant chamber larger than the pressure in the second vacant chamber, and the difference in the pressure is opened when the pressure exceeds the second pressure. The speaker device according to claim 1, wherein the speaker device is incorporated into a vacant room.   The speaker device according to claim 7, wherein the exhaust valve and the intake valve are provided in a cabinet that forms the second empty chamber. The drone cone is supported via a partition plate fixed inside the cabinet,
The exhaust valve is provided in the partition plate, and exhausts the gas in the second vacancy to the outside through the first vacancy when the valve is opened,
The said intake valve is provided in the said partition plate, and takes in gas from the exterior to the said 2nd empty room through the said 1st empty room at the time of valve opening, The said 2nd empty room is characterized by the above-mentioned. Speaker device. A drone cone that is provided inside the cabinet and divides a vacant space inside the cabinet to form a first vacant space on the speaker unit side;
A port provided in the cabinet and opening the first vacancy to the outside;
A second vacancy formed on the back side of the speaker device, and a second vacancy formed on the back side of the speaker device, provided inside the cabinet on the back side of the drone cone. A low-pass filter that further divides into
The adsorbent is disposed in the second empty chamber;
The exhaust valve is provided in the cabinet, and the pressure of the third vacant chamber is larger than the pressure outside the cabinet, and the difference between the pressures opens when the pressure exceeds the first pressure. Gas is discharged to the outside,
The intake valve is provided in the cabinet, and the pressure outside the cabinet is larger than the pressure in the third vacancy, and the difference between the pressures opens when the pressure exceeds the second pressure. The speaker device according to claim 1, wherein the speaker device is incorporated into three vacant rooms.