JP2016063444A - Waterproof structure and electronic apparatus with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waterproof structure capable of satisfactorily suppressing deterioration in the sound quality of reproduced sounds or recorded sounds and variations in the sound quality caused by an electroacoustic transducer.SOLUTION: The waterproof structure includes: a housing (1) including a sound transmission hole (1a); an electroacoustic transducer (M) including a case (M1) with which a vent hole (M3) is formed, and disposed at a position corresponding to the sound transmission hole (1a); a packing (3) that is interposed between the housing (1) and the electroacoustic transducer (M); a thin film part (3a2) which is provided in a portion corresponding to the vent hole (M3) in the packing (3); an annular protrusive engaging part (3g) which is provided so as to surround the thin film part (3a2) and protrude closer to the housing (1); and an annular recess (1d) which is provided on a surface (1b) of the housing (1) opposite to the electroacoustic transducer (M) and into which the protrusive engaging part (3g) is firmly fitted. The protrusive engaging part (3g) is bent radially outwardly by being firmly fitted into the recess (1d) and a tensile force is applied to the thin film part (3a2).SELECTED DRAWING: Figure 4

Description

  The present invention relates to a waterproof structure and an electronic apparatus including the waterproof structure.

As an example of a waterproof structure when an electroacoustic transducer (for example, a microphone or a speaker) is attached to a case panel, there is a structure described in Patent Document 1.
The waterproof structure described in Patent Document 1 is a structure in which a microphone is press-fitted and fitted into a sleeve of a case panel while being held by a substantially cylindrical rubber shield member. And, it is said that waterproofing and good acoustic characteristics can be obtained by forming a space between the thin film part and the microphone as a thin film in the part of the shield member facing the microphone mouthpiece formation region. Yes.

JP 2006-333076 A

In the waterproof structure described in Patent Document 1, the characteristics of the sound recorded by the microphone depend on the tension of the thin film. That is, if the thin film has slackness, the sound deteriorates, and if the tension of the thin film is different, the sound quality varies depending on the difference.
Therefore, it is desired that the tension of the thin film is uniform and stable so that there is no looseness and there is little variation between individual structures (products).

However, in the waterproof structure described in Patent Document 1, there is a possibility that the presence or absence of the thin film after assembling and the degree of tension are greatly different for each product due to variations in assembling work. As a result, there are concerns about the occurrence of problems such as deterioration and variation in the sound quality obtained, and improvement has been desired.
When this electroacoustic transducer is used as a speaker, this problem also occurs in the reproduced sound that is output through the thin film.

  Therefore, the problem to be solved by the present invention is a waterproofing that can satisfactorily suppress deterioration in sound quality and variation in sound quality of reproduced sound or recorded sound by the electroacoustic transducer when applied to the electroacoustic transducer. The object is to provide a structure and an electronic apparatus including the structure.

In order to solve the above problems, the present invention has any one of the following configurations 1) and 2).

1) a housing having a sound passage hole;
An electroacoustic transducer having a case in which a sound hole is formed and disposed at a position corresponding to the sound hole;
A packing interposed between the housing and the electroacoustic transducer;
In the packing, a thin film portion provided in a portion corresponding to the sound hole and an annular projecting engagement portion provided to surround the thin film portion and project toward the housing side,
An annular recess that is provided on a surface of the housing facing the electroacoustic transducer and into which the protruding engagement portion is strongly fitted;
With
The projecting engagement portion is a waterproof structure configured to bend radially outward by strong insertion into the recess and to apply tension to the thin film portion.
2) a housing having a through hole;
An electroacoustic transducer having a case in which a sound hole is formed and being disposed to enter the through hole from one side of the housing;
A packing attached to the other surface side of the housing so as to cover the through hole;
In the packing, a thin film portion provided in a portion corresponding to the sound hole and an annular projecting engagement portion provided to surround the thin film portion and project toward the housing side,
An annular recess provided on the other surface of the housing and into which the protruding engagement portion is strongly fitted; and
With
The projecting engagement portion is a waterproof structure configured to bend radially outward by strong insertion into the recess and to apply tension to the thin film portion.

  According to the present invention, it is possible to obtain an effect that it is possible to satisfactorily suppress deterioration in sound quality and variation in sound quality of reproduced sound or recorded sound.

FIG. 1 is a partial exploded view for explaining a waterproof structure BK of Example 1 of the waterproof structure according to the embodiment of the present invention. FIG. 2 is a longitudinal sectional view showing the packing 3 used in the waterproof structure BK. FIG. 3 is a perspective vertical sectional view showing a state in which the packing 3 is put on the microphone M waterproofed by the waterproof structure BK. FIG. 4 is a cross-sectional view after assembling at the S1-S1 position in FIG. 1 for explaining the waterproof structure BK. It is an expanded sectional view of the A section in FIG. FIG. 6 is a partial exploded view for explaining a waterproof structure BK2 of Example 2 of the waterproof structure according to the embodiment of the present invention. FIG. 7 is a cross-sectional view after assembly at the S2-S2 position in FIG. 6 for explaining the waterproof structure BK2.

The preferred embodiments of the present invention will be described with reference to FIGS.
The waterproof structure described as an embodiment is a waterproof structure applied to an electric signal converter that converts an electric signal into sound or converts sound into an electric signal, and is an example that employs a microphone M as an electroacoustic converter. First, the waterproof structure BK of Example 1 will be described with reference to FIGS.

<Example 1>
FIG. 1 is a partial exploded view for explaining a waterproof structure BK in the vicinity of the microphone M in an electronic device (for example, a wireless device) DK in which the microphone M is mounted.
FIG. 2 is a longitudinal sectional view for explaining the packing 3 used in the waterproof structure BK.
FIG. 3 is a perspective longitudinal sectional view showing a state in which the packing 3 is put on the microphone M to a predetermined position.
FIG. 4 is a cross-sectional view after assembling at the S1-S1 position in FIG. 1 for explaining the waterproof structure BK.
FIG. 5 is an enlarged cross-sectional view of part A in FIG.

The electronic device DK includes a housing 1, a circuit board 2 housed in the housing 1, a microphone M that is an electroacoustic transducer mounted on the circuit board 2, and the housing 1 and the microphone M that are covered with the microphone M. And a packing 3 interposed therebetween.
The circuit board 2 is provided with a signal transmission unit ST that processes an electric signal output from the microphone M and transmits the electric signal to the outside wirelessly or by wire.
The microphone M has a case M1 formed in a cylindrical shape with a thin metal material, and a diaphragm SD (see FIG. 4) provided inside the case M1.
A plurality of ventilation holes M3 are formed in the front end surface M2 of the case M1 as sound holes for transmitting air vibration from the outside to the diaphragm SD.
A region where the plurality of vent holes M3 are formed on the distal end surface M2 is referred to as an opening region AR1.

The housing 1 has a circuit board 2 assembled and a sound-passing hole 1a that is formed in a position corresponding to the opening area AR1 of the microphone M to allow sound to pass therethrough and a range in the vicinity of the sound-passing hole 1a on the inner surface 1b. And an engaging portion 1c that is raised and thickened inward (circuit board 2 side). The casing 1 is formed by injection molding of resin.
The engaging portion 1c is formed with an annular recess 1d that is concentric with the sound passage hole 1a in the assembled state. The recess 1d is provided on the surface facing the microphone M on the inner surface 1b.
The recess 1d includes an outer peripheral wall 1d1, an inner peripheral wall 1d2, and a bottom wall 1d3, and has a rectangular cross-sectional shape.
The packing 3 is engaged with the recess 1d. Details of this engagement will be described later.

The packing 3 is provided at an intermediate position in the direction of the axis CL1 of the cylindrical base portion 3k, a claw portion 3b that is provided at one end of the base portion 3k (upper end in FIG. 2) and protrudes inwardly, and the base portion 3k. And a wall 3a that separates the space in the base 3k.
The nail | claw part 3b is projectingly formed in the cyclic | annular form.
The wall 3a extends perpendicular to the axis CL1. The wall portion 3a is a thin film portion 3a2 having a predetermined diameter D33 centered on the axis line CL1 and formed in a film shape thinner than the peripheral edge portion 3a1 which is an outer annular portion.
The thin film portion 3a2 of the wall portion 3a is formed closer to the claw portion 3b than the center of the base portion 3k in the direction of the axis CL1. The surface on the claw portion 3b side of the wall portion 3a is a flat surface without a step.
Thus, the one end side with respect to the wall part 3a is made into the protrusion engaging part 3g which protruded cyclically | annularly. The protruding engagement portion 3g has an annular claw portion 3b that protrudes inward.

  The claw portion 3b includes, in a longitudinal sectional shape, an inclined portion 3b1 that is inclined so as to gradually decrease in diameter from the tip surface 3k1 of the base portion 3k toward the wall portion 3a, an inner end portion 3b2 of the inclined portion 3b1, and an inner periphery of the base portion 3k. And a rising portion 3b3 formed so as to connect the surface 3k2 and to be orthogonal to the axis CL1.

The packing 3 is formed of an elastic material having flexibility and resilience. An example of the material is a rubber material, preferably silicone rubber.
The thin film portion 3a2 is formed with such a thin thickness that air vibrations from one surface side can be transmitted (passed) to the air on the other surface side without causing any trouble as an application of the electroacoustic transducer.
For example, when the material of the thin film portion 3a2 is silicone rubber, the thickness is desirably 0.2 mm or less. In particular, in the case of a microphone, since it is desired to increase the sensitivity at a small volume (small amplitude), it is more desirable that the thickness be 0.15 mm or less. The thickness of the peripheral part 3a1 and the base part 3k is, for example, 1.0 mm, and is set sufficiently thicker than the thin film part 3a2.
The thin film portion 3a2 is formed so as to extend orthogonally to the axis CL1 in the assembled state.

Here, each dimension is defined as follows.
For the recess 1d, as shown in FIG. 4, the inner diameter of the outer peripheral wall 1d1 is D11, the outer diameter of the inner peripheral wall 1d2 is D12, and the distance in the height direction from the surface of the circuit board 2 after assembly to the bottom wall 1d3. Let it be H11.
As for packing 3, as shown in FIG. 2, the outer diameter of the base 3k is D31, the inner diameter of the inner end 3b2 of the claw 3b is D32, and the diameter of the thin film 3a2 is D33 as described above. The inner diameter of the base 3k is D34. Regarding the distance, the distance between the tip surface 3k1 that is the length of the base portion 3k in the axis CL1 direction and the lower end surface 3k3 that is the other end is H31, and the distance between the rising portion 3b3 and the lower end surface 3k3 is H32. The distance between the surface of the wall 3a opposite to the claw 3b and the lower end surface 3k3 is H33.
For the microphone M, as shown in FIG. 4, the distance (height) of the tip end surface M2 from the surface of the circuit board 2 is HM1, and the outer diameter is DM1.

Next, an example of an assembling method for assembling the above-described members and a state after assembling will be described in detail.
The worker puts the packing 3 on the microphone M mounted on the circuit board 2 (see FIG. 3). That is, the microphone M is fitted inside the base 3 k of the packing 3.
2 and 4, the inner diameter D34 of the base 3k of the packing 3 is formed to be the same as or slightly smaller than the outer diameter DM1 of the case M1 of the microphone M. Thereby, fitting of the microphone M to the base 3k is substantially press-fitted.
Further, the packing 3 is formed such that the distance H33, which is the height of the portion into which the microphone M is inserted, is the same as or slightly smaller than the height direction distance HM1 of the microphone M.
In the assembled state of the packing 3 shown in FIG. 3, the front end surface M2 of the microphone M and the peripheral edge 3a1 of the wall 3a are brought into close contact with each other.

An operator attaches the circuit board 2 to the housing 1. This attachment is performed by screwing or the like in a state where the circuit board 2 is applied to a boss or a rib (not shown) formed on the housing 1 side.
In this attachment, the projecting engagement portion 3 g which is the tip portion of the packing 3 is engaged with the engagement portion 1 c of the housing 1. Specifically, the claw portion 3b of the packing 3 is fitted into the recess 1d of the engaging portion 1c by a strong fit.

As described above, the outer diameter D12 of the inner peripheral wall 1d2 of the recess 1d is formed larger than the inner diameter D32 of the inner end 3b2 of the claw 3b.
Thereby, when the claw portion 3b enters the recess 1d, the opening edge 1d4 of the inner peripheral wall 1d2 comes into contact with the inclined portion 3b1 in the course of the entry, and as shown in FIG. The entire claw portion 3b enters the recess 1d. In this state, the inner peripheral wall 1d2 tries to bend the claw portion 3b and the distal end portion of the base portion 3k provided with the claw portion 3b radially outward with the force F1.
Here, the inner diameter D11 of the outer peripheral wall 1d1 of the recess 1d is formed larger than the outer diameter D31 of the base 3k.
Therefore, the outward bending of the claw portion 3b by the force F1 is allowed.
That is, the engagement state shown in FIGS. 4 and 5 is a strong fitting insertion (strong fitting), and the claw portion 3b is bent outward in the radial direction while its shape is deformed.

The thin film portion 3a2 is pulled outward in the radial direction by the radially outward force F2 generated along with the bending of the claw portion 3b.
As described above, the claw portion 3b is formed in an annular shape that is continuous around the axis CL1.
Therefore, the thin film portion 3a2 is pulled so as to be spread in the radial direction over the entire circumference.
Thereby, there is no slackness in the thin film portion 3a2.
The housing 1 and the packing 3 are formed by molding using a mold.
Accordingly, the dimensions of the outer diameter D12 of the inner peripheral wall 1d2 and the inner diameter D32 of the inner end 3b2 are maintained with high accuracy, and the influence of variations in assembly work can be ignored.
Therefore, the degree of tension of the thin film portion 3a2 is constant and uniform and highly stable.
In addition, the waterproof function and the suppression of deterioration and variation in sound quality are realized with only three member configurations of the electroacoustic transducer (microphone M), the packing 3, and the housing 1.
Thereby, even if the dispersion | variation in a component single-piece | unit accumulates, the dispersion | variation in the whole structure is suppressed few and cost is also suppressed.
As described above, according to the first embodiment, the thin film portion 3a2 has a uniform and uniform degree of tension without sagging, and is highly stable. Therefore, deterioration and variation in sound quality obtained can be satisfactorily suppressed. Also, the cost can be kept low.

According to the waterproof structure BK obtained by the above assembly, the wall of the packing 3 is placed between the sound hole 1a and the case M1 of the microphone M even if water drops due to rain or shower enter the inside through the sound hole 1a. Since the part 3a is interposed, water does not enter the inside of the microphone M.
Moreover, even if the water that has entered the inside through the sound hole 1a tries to pass over the recess 1d, the annular claw portion 3b and at least the inner peripheral wall 1d2 of the annular recess 1d are in close contact with each other continuously. Therefore, it does not enter the circuit board 2 side beyond the recess 1d.

In addition, the sound that has entered from the outside through the sound hole 1a passes through the space V1 formed by being surrounded by the thin film portion 3a2, the inner peripheral surface of the peripheral portion 3a1, and the front end surface M2 of the case M1 in the microphone M. The diaphragm SD reaches the diaphragm SD in the case M1 from the ventilation hole M3, and the diaphragm SD is vibrated to collect sound.
At that time, since the thin film portion 3a2 is uniformly stretched with a constant tension without slack, the deterioration and variation in the recorded sound quality of the microphone M can be satisfactorily suppressed by applying the waterproof structure of the first embodiment.

<Example 2>
In the first embodiment, the packing 3 is a member that covers the microphone M inside the housing 1. On the other hand, a packing 13 that is disposed outside the housing 1 and is formed so as to block the sound hole 1a provided in the housing 1 from the outside, and a waterproof structure BK2 using the packing 13 are described as Example 2. This will be described with reference to FIGS.
FIG. 6 is a partial exploded view for explaining a waterproof structure BK2 in the vicinity of the microphone M in an electronic device (for example, a radio device) DK2 on which the microphone M is mounted.
FIG. 7 is a cross-sectional view after assembly at the S2-S2 position in FIG. 6 for explaining the waterproof structure BK2.

The electronic device DK2 is attached so as to cover the casing 11, the circuit board 2 housed inside the casing 11, the microphone M that is an electroacoustic transducer mounted on the circuit board, and the outer surface of the casing 11. Packing 13 is provided.
The circuit board 2 is provided with a signal transmission unit ST that processes an electric signal output from the microphone M and transmits the electric signal to the outside wirelessly or by wire.
The microphone M is the same as that used in the first embodiment, and includes a case M1 formed in a cylindrical shape with a thin metal material, and a diaphragm SD (see FIG. 4) provided inside the case M1. doing.
A plurality of ventilation holes M3 are formed in the front end surface M2 of the case M1 as sound holes for transmitting air vibration from the outside to the diaphragm SD.
A region where the plurality of vent holes M3 are formed in the front end surface M2 is an opening region AR1.

The housing 11 is formed with a through hole 11a into which the microphone M is inserted in a state where the circuit board 2 is assembled.
Further, the outer surface 11b of the housing 11 is formed with a recess 11d that is concentric with the axis CL2 that is the central axis of the through hole 11a and is annularly wound so as to surround the through hole 11a.
The recess 11d has an outer peripheral wall 11d1, an inner peripheral wall 11d2, and a bottom wall 11d3, and has a rectangular longitudinal cross-sectional shape.
The packing 13 engages with the recess 11d. Details of this engagement will be described later.

  The housing 11 has an engaging portion 11c in which a portion having a larger diameter than the concave portion 11d rises from the inner surface 11e of the housing 11 toward the inside (the circuit board 2 side) and is thick.

The packing 13 has a base portion 13k formed in a sheet shape with a thickness t1. The packing 13 is attached to the outer surface 11b of the housing 11 by a well-known attachment method (not shown) so as to cover at least the through hole 11a and the recess 11d in the housing 11.
The base portion 13k has a thin film portion 13a2 in a range covering at least the opening area AR1 of the microphone M inserted into the through hole 11a in a state assembled to the housing 11. The thin film portion 13a2 is formed in a film shape with a thickness t2 thinner than the base portion 13k.

The position in the thickness direction where the thin film portion 13a2 is formed is biased toward the housing 11 side rather than the outer surface side.
Further, after the assembly shown in FIG. 7, the position of the inner surface 13a3 (the surface on the housing 11 side) of the thin film portion 13a2 is outward from the outer surface 11b of the housing 11 by a distance HA3.
The outer surface 13b of the packing 13 and the outer surface 13a4 of the thin film portion 13a2 are connected by an inclined surface 13c that is inclined so that the thickness becomes thinner toward the axis CL2.
The thin film portion 13a2 is formed so as to extend orthogonally to the axis line CL2 in the assembled state.

A rib 13e is formed on the inner surface 13d of the base 13k of the packing 13 so as to continuously protrude toward the housing 11 so as to surround the thin film portion 13a2.
On the tip side of the rib 13e, there is formed a claw portion 13f that protrudes in an annular shape continuously from the inside.
In the longitudinal cross-sectional shape, the tip of the rib 13e is a tip surface 13e1, which is an annular flat surface.
The claw portion 13f connects the inclined portion 13f1 inclined so as to gradually decrease in diameter from the distal end surface 13e1 toward the base portion 13k, the inner end portion 13f2 of the inclined portion 13f1, and the inner peripheral surface 13e2 of the rib 13e. And rising portions 13f3 formed so as to be orthogonal to each other.

The packing 13 is formed of an elastic material having flexibility and resilience. An example of the material is a rubber material, preferably silicone rubber.
As in the first embodiment, the thin film portion 13a2 is thin enough to transmit (pass) the air vibration from the one surface side to the air on the other surface so as not to interfere with the use of the electroacoustic transducer. Is formed.
For example, when the material of the thin film portion 13a2 is silicone rubber, the thickness is desirably 0.2 mm or less. In particular, in the case of a microphone, since it is desired to increase the sensitivity at a small volume (small vibration), it is more desirable that the thickness be 0.15 mm or less. The thickness of the base portion 13k is, for example, 1.0 mm, and is set sufficiently thicker than the thin film portion 13a2.

Here, each dimension is defined as follows.
For the recess 11d, as shown in FIG. 6, the inner diameter of the outer peripheral wall 11d1 is DA1, the outer diameter of the inner peripheral wall 1d2 is DA2, and the distance from the outer surface 11b to the bottom wall 11d3 is HA1.
For the packing 3, as shown in FIG. 6, the outer diameter of the rib 13e is DA3, the inner diameter of the inner end portion 13f2 of the claw portion 13f is DA4, and the diameter of the thin film portion 13a2 is DA5.

Next, an example of an assembling method for assembling the above-described members and a state after assembling will be described in detail.
An operator attaches the circuit board 2 on which the microphone M is mounted to a predetermined position of the housing 11. In this predetermined position, the axis CL2 of the through hole 11a of the housing 11 coincides with the central axis of the microphone M, and the microphone M is inserted into the through hole 11a.
With the circuit board 2 attached to the housing 11, the height direction position of the front end surface M <b> 2 of the microphone M is substantially at the position of the outer surface 11 b of the housing 11. As a result, a gap having a distance HA3 is formed in the height direction between the distal end surface M2 and the inner surface 13a3.

  The operator attaches the packing 13 to a predetermined position on the outer surface 11 b of the housing 11. At this predetermined position, the axis CL2 of the through hole 11a coincides with the central axis of the microphone M, and at least the opening area AR1 of the microphone M is covered with the thin film portion 13a2. FIG. 7 shows an example in which the through hole 11a having a larger diameter than the opening area AR1 is covered.

In attaching the packing 13 to the housing 11, the rib 13 e of the packing 13 is engaged with the recess 11 d of the housing 11.
As described above, the outer diameter DA2 of the inner peripheral wall 11d2 of the recess 11d is formed larger than the inner diameter DA4 of the inner end 13f2 of the claw portion 13f of the packing 3.
As a result, when the claw portion 13f enters the recess 11d, the opening edge portion 11d4 of the inner peripheral wall 11d2 abuts on the inclined portion 13f1 during the entry, and the inner peripheral wall 11d2 is moved by the force F11. It tries to bend the rib 13e radially outward.
Here, the inner diameter DA1 of the outer peripheral wall 11d1 of the recess 11d is formed larger than the outer diameter DA3 of the rib 13e.
Therefore, the outward bending of the rib 13e in the radial direction by the force F11 is allowed.
That is, the engagement state between the claw portion 13f and the concave portion 11d of the rib 13e shown in FIG. 7 is a strong fitting insertion (strong fitting), and the rib 13e is bent outward in the radial direction while its shape is deformed. It will be in the state.

The thin film portion 13a2 is pulled outward in the radial direction by the radially outward force F12 generated along with the bending of the rib 13e.
As described above, the rib 13e is formed in an annular shape that is continuous around the axis CL2.
Therefore, the thin film portion 13a2 is pulled so as to be spread in the radial direction over the entire circumference.
Thereby, there is no slackness in the thin film portion 13a2.
The casing 11 and the packing 13 are formed by molding using a mold.
Thereby, the dimensions of the outer diameter DA2 of the inner peripheral wall 11d2 and the inner diameter DA4 of the inner end portion 13f2 are maintained with high accuracy, and the influence of variations in assembly work can be ignored.
Therefore, the degree of tension of the thin film portion 13a2 is constant and uniform and highly stable.
Further, the waterproof function and the suppression of deterioration and variation in sound quality are realized with only three member configurations of the electroacoustic transducer (microphone M), the packing 13, and the housing 11.
Thereby, even if the dispersion | variation in a component single-piece | unit accumulates, the dispersion | variation in the whole structure is suppressed few and cost is also suppressed.
As described above, according to the second embodiment, the thin film portion 13a2 has a uniform and uniform degree of tension without sagging, and is highly stable. Therefore, deterioration and variation in sound quality to be obtained are well suppressed. Also, the cost can be kept low.

  According to the waterproof structure BK2 obtained by the assembly described above, since the through holes 11a are covered with the packing 13, water drops due to rain or shower do not enter the inside through the through holes 11a.

In addition, sound from the outside reaches the diaphragm SD in the case M1 from the air hole M3 through the thin film portion 13a2 and the gap (space V2) between the thin film portion 13a2 and the front end surface M2 of the case M1. The sound is collected by vibrating the diaphragm SD.
At that time, as described above, since the thin film portion 13a2 is uniformly stretched with a constant tension without slack, if the waterproof structure of the second embodiment is applied, the deterioration and variation of the recorded sound quality of the microphone M are suppressed satisfactorily. Is done.

  Each embodiment of the present invention and its modification are not limited to the above-described configuration, and may be modified without departing from the gist of the present invention.

Although the above-described waterproof structures BK and BK2 have been described as examples applied to the microphone M, they can be applied to other acoustic parts having a diaphragm, for example, a speaker.
Also in this case, the thin film portions 3a2 and 13a2 that affect the sound quality of the sound emitted from the speaker are not loosened, and the tension is maintained uniformly at a constant tension, so that the output sound is not deteriorated, Variations in sound quality are also suppressed satisfactorily.
When the electroacoustic transducer is not a microphone but a speaker, the sound hole M3 functions as a sound hole for transmitting air vibration from the speaker diaphragm SD to the outside of the case M1.
Further, the circuit board 2 is provided with a signal receiving unit, and an audio signal received from outside or wirelessly is received by the signal receiving unit and is subjected to signal processing to be output as sound from a speaker.

In the waterproof structure BK of the first embodiment, the engaging portion 1c does not have to protrude inward (circuit board 2 side) of the housing 1 with respect to the inner surface 1b as described above, and protrudes outward. You may do.
In the waterproof structure BK2 of the second embodiment, the engaging portion 11c does not have to protrude inward (circuit board 2 side) of the housing 11 with respect to the inner surface 11e as described above, and protrudes outward. You may do.
The engaging portions 1c and 11c may have the same thickness as the surrounding portions, but when the casings 1 and 11 are formed by injection molding, the engaging portions 1c and 11c are generally used for injection molded products. It is necessary to make it thicker than a certain thickness (for example, 1 to 2 mm). Therefore, it is desirable to increase the thickness by partially projecting inward or outward from the viewpoint of formability and cost reduction.

DESCRIPTION OF SYMBOLS 1 Housing | casing 1a Sound passage hole, 1b Inner surface, 1c Engagement part, 1d Recessed part 1d4 Opening edge part 2 Circuit board 3 Packing 3a Wall part, 3a1 Peripheral part, 3a2 Thin film part, 3b Claw part 3b1 Inclined part, 3b2 Inner end part 3b3 Rising part 3g Protruding engaging part, 3k base part, 3k1 tip end face 3k2 inner peripheral face, 3k3 lower end face 11 housing 11a through hole, 11b outer face, 11c engaging part, 11d concave part 11d1 outer peripheral wall, 11d2 inner peripheral wall, 11d3 Bottom wall 11d4 Open edge, 11e Inner surface 13 Packing 13a2 Thin film portion, 13a3 Inner surface, 13a4 Outer surface 13b Outer surface, 13c Inclined surface, 13d Inner surface, 13e Rib 13e1 Tip surface, 13e2 Inner peripheral surface, 13f Inclined portion 13f1 Inclined portion 13f1 End, 13f3 Rising part 13k Base AR1 Opening area BK, BK2 Waterproof CL1, CL2 Axis D11, D32, D34, DA1, DA4 Inner Diameter D12, D31, DM1, DA2, DA3, DA5 Outer Diameter, D33 Diameter F1, F2, F11, F12 Force H11, H31, H32, H33, HM1, HA3 Distance DK, DK2 Electronic equipment M Microphone M1 Case, M2 tip surface, M3 Vent hole SD Diaphragm, ST signal sending part t1, t2 thickness, V1, V2 space

Claims (6)

A housing having sound passage holes;
An electroacoustic transducer having a case in which a vent hole is formed and disposed at a position corresponding to the sound hole;
A packing interposed between the housing and the electroacoustic transducer;
In the packing, a thin film portion provided in a portion corresponding to the vent hole, and an annular projecting engagement portion provided so as to surround the thin film portion and project toward the housing side,
An annular recess that is provided on a surface of the housing facing the electroacoustic transducer and into which the protruding engagement portion is strongly fitted;
With
The waterproof structure in which the projecting engagement portion is configured to bend outward in the radial direction by a strong fit into the recess and to apply tension to the thin film portion. A housing having a through hole;
An electroacoustic transducer having a case in which a ventilation hole is formed, and being arranged to enter the through hole from one side of the housing;
A packing attached to the other surface side of the housing so as to cover the through hole;
In the packing, a thin film portion provided in a portion corresponding to the vent hole, and an annular projecting engagement portion provided so as to surround the thin film portion and project toward the housing side,
An annular recess provided on the other surface of the housing and into which the protruding engagement portion is strongly fitted; and
With
The waterproof structure in which the projecting engagement portion is configured to bend outward in the radial direction by a strong fit into the recess and to apply tension to the thin film portion.   The projecting engagement portion has a claw portion that projects annularly inward in the radial direction, and the annular recess is formed such that the outer diameter of the inner wall is larger than the inner diameter of the inner end portion of the claw portion. The waterproof structure according to claim 1 or 2, wherein the claw portion and the inner wall are firmly inserted.   The waterproof structure according to claim 1, wherein the electroacoustic transducer is a microphone.   An electronic apparatus comprising: the waterproof structure according to claim 4; and a signal transmission unit that transmits an audio signal output from the microphone to the outside.   An electronic apparatus comprising the waterproof structure according to claim 1.

Images