JP5818666B2 - Portable gas alarm - Google Patents

Description

  The present invention relates to a portable gas alarm.

In general, for example, in underground construction sites, tunnels, places where people enter, work areas, etc., there is a risk that dangerous gases such as carbon monoxide gas or hydrogen sulfide gas may be contained in the air of the environment. In many cases, there is a possibility that the air in the environmental atmosphere is in a dangerous state or in a dangerous state, such as when the oxygen gas concentration in the air may be lowered.
And when it becomes dangerous to humans due to the high concentration of dangerous gas contained in the air or low oxygen gas concentration, it is necessary to immediately know that In view of such a demand, portable gas alarm devices including an alarm notification mechanism using a buzzer sound from an alarm buzzer that operates when a gas to be detected is detected by a gas sensor are widely used.

Thus, such portable gas alarms are used in an environment where ignition or explosion may occur due to the presence of an explosive atmosphere containing flammable gas or steam. It is necessary that the structure itself does not become an ignition source, that is, a structure that satisfies the so-called explosion-proof specification.
In addition, since it may be used to measure the state of air in a gas measurement target space such as a manhole where water is collected, water containing water droplets or the like in the atmosphere is inside the housing. It is desirable that a waterproof structure be adopted in order to prevent entry into the water.

  Normally, in such a portable gas alarm device, a buzzer sound emission opening is formed in the housing, and a buzzer arrangement portion is provided so as to communicate with the buzzer sound emission opening, and for example, a piezoelectric buzzer is arranged thereon. In addition, a dustproof mesh with countless minute through holes is provided to close the buzzer sound emission opening, and water such as water droplets in the atmosphere is prevented from entering the inside of the housing through the hole of the dustproof mesh. Therefore, a waterproof sheet is provided (see Patent Document 1).

JP 2007-200286 A

Thus, in a portable gas alarm device equipped with an alarm buzzer, it is desired that a loud buzzer sound be emitted. However, the structure for blocking the buzzer sound emission opening with a dustproof mesh and a waterproof sheet is required. However, there is a problem that the buzzer sound cannot be emitted with a sufficiently high sound pressure level (large volume) because the transmission of the buzzer sound is greatly hindered.
Also, as described above, a high-output alarm buzzer cannot be used for structural reasons that require a configuration that satisfies explosion-proof specifications.

  The present invention has been made based on the above situation, and provides a portable gas alarm device having a predetermined explosion-proof structure and capable of emitting a buzzer sound having a sufficiently large sound pressure level. The purpose is to do.

The portable gas alarm device according to the present invention includes a casing in which a resonance space that is partitioned to communicate with an internal space in which a main board is disposed via a communication port is formed in a front side region, and the communication in the main board. An alarm buzzer provided at a position facing the mouth, and a waterproof filter having sound permeability provided to cover the communication port,
A slit-like buzzer sound emission opening that communicates the resonance space with the outside is formed in a front surface of the casing at a position displaced so as not to face the communication port.

In the portable gas alarm device according to the present invention, the resonance space is formed so as to surround the periphery of the opening edge of the first-stage recess extending in one direction so as to open in the front of the casing. A cap member is provided in the protruding edge portion, and a second step recess is formed in one end side region in the one direction on the bottom wall portion that defines the first step recess. And the communication port is formed in the bottom wall that defines the second-stage recess.
A cutout portion extending in the one direction is formed in a part of the outer peripheral edge portion of the cap member, and an opening formed between the outer peripheral surface of the cap member and the inner peripheral surface of the protruding edge portion. Preferably, the buzzer sound emission opening is formed.

  In the portable gas alarm device of the present invention, a buzzer sound adjusting hole is formed in the cap member at a position displaced to the other end side in the one direction so as not to face the communication port. It is preferable.

  According to the portable gas alarm device of the present invention, the slit-shaped buzzer sound emission opening that communicates the resonance space formed in the front side region inside the casing to the outside has the resonance space at the front of the casing. The buzzer sound generated by the alarm buzzer is regulated in a direction within a specific angle range by being configured to be displaced so as not to face the communication port communicating with the internal space where the main board is arranged. As a result, the sound pressure level of the buzzer sound can be improved.

It is a front view which shows the structure in an example of the portable gas alarm device of this invention. It is the sectional view on the AA line in FIG. It is the BB sectional view taken on the line in FIG. It is an expanded sectional view which expands and shows a part in FIG. It is a disassembled perspective view which abbreviate | omits and shows a part of portable gas alarm device shown in FIG. It is a longitudinal cross-sectional view along the axial direction which shows the structure of the casing main body in the portable gas alarm device shown in FIG. (A) Plan view, (b) Front view, (c) (B) cross-sectional view taken along line AA, (d) (b) showing the configuration of the rechargeable battery power supply unit in the portable gas alarm device shown in FIG. It is a BB sectional view taken on the line in FIG. (A) Top view which shows the structure of the dry battery power supply unit used in the portable gas detector shown in FIG. 1, (b) Rear view, (c) The sectional view on the AA line in (b), (d) (b It is a BB line sectional view in). The front view which shows a part of structure of the portable gas alarm device for demonstrating the positional relationship of the communicating port formed in the top cover in the portable gas alarm device shown in FIG. 1, and the opening part for buzzer sound emission. It is. It is a side view which shows a part of structure of the portable gas alarm device for demonstrating the directivity of the buzzer sound emitted from the portable gas alarm device shown in FIG. It is a front view which shows a part of structure of the portable gas alarm device for demonstrating the positional relationship of the communication port formed in the top cover in the portable gas alarm device for a comparison, and the opening part for buzzer sound emission. is there.

Hereinafter, embodiments of the present invention will be described in detail.
1 is a front view showing a configuration of an example of a portable gas alarm device of the present invention, FIG. 2 is a cross-sectional view taken along line AA in FIG. 1, and FIG. 3 is a cross-sectional view taken along line BB in FIG. 4 is an enlarged cross-sectional view showing a part of FIG. 3 in an enlarged manner, and FIG. 5 is an exploded perspective view showing a part of the portable gas alarm shown in FIG.
The portable gas alarm device includes a gas alarm body 10 and a rechargeable battery power supply unit 85 including a rechargeable battery 90 that is detachably attached to the gas alarm body 10. Yes.
On the front side of the gas alarm device main body 10, a display unit 11 is formed in the central region and an operation unit 12 is formed in a lower region of the display unit 11. In addition, an alarm light emitting unit 13 is formed in the upper region of the display unit 11 on the front surface of the gas alarm device body 10, the front region on the upper surface following this, and the front region on both sides of the gas alarm device body 10. Has been.

  The gas alarm device body 10 includes a substrate assembly 20 in which functional members related to gas detection operations are collectively arranged on one end portion in the length direction of a flat main substrate 21 that is long in one direction. Inside, the main board | substrate 21 is arrange | positioned and comprised so that it may extend in parallel with the front surface and back surface of a casing. Here, as functional members, there are a gas sensor 41, a pump unit 35 for supplying a gas to be detected to the gas sensor 41, an alarm notification mechanism such as an alarm light emitting element 23 and an alarm buzzer 30, and a display mechanism for displaying a gas detection result. Including.

On the front surface of the main board 21 constituting the board assembly 20, a panel-like display mechanism 22 is provided at the center position of one end side portion, and a plurality of warning light emitting elements are provided. For example, three warning light emitting elements 23 are provided at positions spaced apart from each other in the width direction at one end edge portion on the front surface of the main substrate 21, and the panel-like display mechanism 22 on both side edge portions on the front surface of the main substrate 21. Two alarm light emitting elements (only one alarm light emitting element is shown in FIG. 5) are provided at two positions between the main board 21 and the main board 21, respectively.
In addition, a plurality of switch elements 24 are disposed on the other end portion of the front surface of the main board 21.

An alarm buzzer 30 and a pump unit 35 are arranged at a position in the width direction of one end edge portion on the back surface of the main board 21.
The alarm buzzer 30 is a short columnar shape in which a piezoelectric vibrator 32 is disposed in a case 31 having a sound emission port 31A that is open on one side, and the sound emission port 31A is formed on the main board 21. It arrange | positions so as to oppose the formed opening 21A.
The pump unit 35 includes a diaphragm pump driven by a motor, for example, and has a performance capable of supplying air in an environmental atmosphere with a flow rate of 0.75 liter / min or more, for example.

  A flat sensor substrate 40 is provided on the back side of the alarm buzzer 30 so as to extend in the axial direction in parallel with the main substrate 21. On the back side of the sensor substrate 40, the types of detection target gases or the detection gases are mutually detected. A plurality of (5 in this example) button type gas sensors 41 having different levels are provided. Each gas sensor 41 is provided with a sensor cap 44 that is screwed and fixed to the casing main body 51 via the planar packing 43 in a state where a part of the gas sensor 41 is accommodated in the sensor holding portion of the sensor holder 42. Has been. A gas flow passage extending along the arrangement pattern of the gas sensor 41 is formed in the sensor cap 44.

  An example of the combination of the gas sensor 41 is a measurement of% LEL (explosive lower limit concentration) of a combustible gas such as a hydrocarbon gas comprising a hydrogen sulfide gas detection gas sensor comprising a constant potential electrolytic gas sensor and a contact combustion gas sensor. The first combustible gas sensor for detecting in the range, the carbon monoxide gas detecting gas sensor consisting of a constant potential electrolytic gas sensor, and the combustible gas such as hydrocarbon gas consisting of a heat conduction type gas sensor in the volume% measurement range Examples of the gas sensor for oxygen gas detection include a second combustible gas sensor for detection and a galvanic cell type gas sensor.

  In the casing, the casing main body 51 and the top cover 70 are detachably connected and fixed via a seal member made of a ring-shaped packing 80 disposed over the entire circumference of the contact surface between the casing main body 51 and the top cover 70. It is configured. The top cover 70 is fixed to the casing body 51 by a plurality of, for example, four fixing screws 81.

  The casing body 51 is made of, for example, a transparent resin material, and is configured as an integral body having no joint portion. Specifically, as shown in FIG. 6, the casing main body 51 has a bottomed structure in which one end side portion of the substrate assembly 20 in which the functional member is disposed is accommodated inside, and one side (upward in FIG. 6) opens. The first cylindrical part 60 and a flat bottomed second cylindrical part 61 whose dimension in the direction perpendicular to the flat surface constituting the front is smaller than the dimension of the first cylindrical part 60. The second cylindrical portion 61 defines the first cylindrical portion 60 in a state where the three circumferential surfaces, that is, the front surface and both side surfaces form a continuous surface with the front surface and both side surfaces of the first cylindrical portion 60, respectively. It is continuous with the outer surface of the bottom wall portion 54 so as to extend outward in the axial direction.

  The internal space of the first tubular portion 60 and the internal space of the second tubular portion 61 are in communication with each other, and the inner surface of the bottom wall portion 55 that defines the second tubular portion 61 is connected to the main space in the substrate assembly 20. A main board holding part 56 is formed to hold the other end edge of the board 21 and hold it. In addition, on the inner surface of the side wall portion defining the second cylindrical portion 61 in the both side walls 53 of the casing main body 51, a receiving guide portion 57 in which both side edges of the main substrate 21 in the substrate assembly 20 are guided as guided portions. It is formed to extend toward the other end side in the axial direction. Here, the guide surface 57A on the front side of the main board 21 of the receiving guide part 57 is continuous with the main board holding part 56 via a taper part 57B that is inclined inward from the one end side in the axial direction toward the other end side. doing.

  The opening end surface 51A of the casing main body 51 (first tubular portion 60) is inclined to the front side from the one end side in the axial direction toward the other end side in a side view, and has such a configuration. Accordingly, a part of the substrate assembly 20 (for example, a region from one edge of the main substrate 21 to a position where the opening 21A is formed) is exposed to the outside of the casing body 51. The attachment and detachment with respect to 51 can be performed easily, and maintainability can be improved.

In the other end side portion (front wall portion defining the second cylindrical portion 61) of the front wall 52 of the casing body 51, positions facing the switch elements 24 in the substrate assembly 20 (immediately above the switch elements 24). In the position), a hole 52A is formed in which the switch element driving button 25 elastically displaced in a direction perpendicular to the surface thereof is mounted.
A protective film material 68 having a transparent deformability is attached to the entire area of the front surface of the casing main body 51, and each switch element driving button 25 is covered on the protective film material 68. There is a display indicating the type of switch in the part, and the operation unit 12 is configured thereby.
Further, the upper end side portion of the front wall 52 of the casing body 51 (the front wall portion that defines the first cylindrical portion 60 and the second cylindrical portion 61 that is continuous therewith) that is covered with the protective film material 68 is defined. A part of the front wall portion) functions as a protective window for protecting the panel-like display mechanism 22 in the substrate assembly 20, and thus the display unit 11 is configured. That is, the portable gas alarm device itself is more robust than the configuration in which the display unit 11 is formed by forming an opening in the casing body 51 itself and providing a separate protective window member in the opening. It can be configured as having a structure.

  On the back side of the second cylindrical portion 61 in the casing body 51, a space extending in the axial direction formed by a dimensional difference between the first cylindrical portion 60 and the second cylindrical portion 61 in a direction perpendicular to the front surface. A power supply unit mounting portion 65 is formed by the unit, and one of the rechargeable battery power supply unit 85 and the dry battery power supply unit 95 including the dry battery is the other of the power supply unit mounting portion 65. It can be exchanged for things. In this example, the state where the rechargeable battery power supply unit 85 is mounted is shown as described above.

In the power supply unit mounting portion 65, the axially lower end side of the outer surface of the bottom wall portion 54 defining the first cylindrical portion 60 is provided on each of both sides in the width direction on the back surface of the second cylindrical portion 61 of the casing body 51. A thin plate-shaped power supply unit guide portion 66 extending toward the surface is formed, and a groove portion 86 </ b> F formed on each side surface of the rechargeable battery power supply unit 85 and the dry battery power supply unit 95 on the inner surface of the power supply unit guide portion 66. , 96E (see FIGS. 7 and 8) is formed to extend in the axial direction.
Further, in the power supply unit mounting portion 65, a contact terminal in the board assembly 20 is exposed to form a connector portion (not shown) on the outer surface of the bottom wall portion 54 that defines the first cylindrical portion 60. Therefore, the rechargeable battery power supply unit 85 and the dry battery power supply unit 95 are electrically connected to the gas alarm device main body 10 by being slidably engaged with the power supply unit mounting portion 65.

  The portable gas alarm device described above is configured by assembling a casing main body 51, a substrate assembly 20, a top cover 70, and, for example, a rechargeable battery power supply unit 85 that are configured as a single unit. That is, the board assembly 20 is inserted from the opening of the first cylindrical portion 60 of the casing body 51 (the white arrow in FIG. 5 indicates the insertion direction), and the other end portion of the main board 21 is the second cylinder. In the state in which the one end side portion of the main substrate 21 is guided by the receiving guide portion 57 of the shape portion 61 and is accommodated in the first tubular portion 60, the other end portion of the sensor substrate 40 causes the first tubular portion 60. The inner surface of the bottom wall portion 55 that is sandwiched and held by the sensor substrate holding portion 54 </ b> A provided on the inner surface of the bottom wall portion 54 that is defined and the other end portion of the main substrate 21 defines the second cylindrical portion 61. Are held and held by a main board holding part 56 formed on the board. When the top cover 70 is attached to the opening of the casing body 51, one end of the main substrate 21 and one end of the sensor substrate 40 are respectively provided on the inner surface of the upper wall 74 of the top cover 70. In this state, the top cover 70 is fixed in a state of being hermetically sealed to the casing body 51 by the fixing screw 81. Further, a sensor cap 44 is mounted on a sensor cap mounting opening 59 formed on the back surface of the casing body 51 and exposing a gas sensor arrangement region in the substrate assembly 20 to the outside, whereby the gas alarm body 10 is configured. The

  As shown in FIG. 7, the rechargeable battery power supply unit 85 has a bottom that defines a second cylindrical portion 61 of the casing main body 51 that constitutes the gas alarm device main body 10 at the lower edge of the flat surface that constitutes the front surface. The housing member 86 has a rectangular tubular housing member 86 that has an engaged portion 86E that is slidably engaged with an engaging portion 58 that is formed on the outer surface of the wall portion 55. One side wall 86A is formed by a lid member 89 that is attached to the opening of the housing member 86 to form a sealed space inside the housing member 86, and a battery support portion 87 that is formed in the side wall 86A side region inside the housing member 86. A rechargeable battery 90 having a cylindrical shape that is supported and disposed so as to extend along the front side, and a front side at a position on the other side wall 86B side of the rear side region inside the housing member 86. For example, an epoxy resin in which the rechargeable battery 90 and the power supply circuit board 91 are filled in the housing member 86. And embedded in a resin block 92 made of a thermosetting resin. Here, as the rechargeable battery 90, for example, a high-capacity secondary battery such as a lithium ion battery is used.

  A tapered portion 88 that is inclined inwardly from the opening end surface side of the housing member 86 toward the bottom surface side is formed at a position aligned with the battery support portion 87 on the inner surface of the front flat wall 86D of the housing member 86. With such a configuration, it becomes easy to fill the thermosetting resin, so that the state where the rechargeable battery 90 and the power supply circuit board 91 are embedded in the thermosetting resin can be reliably obtained. The explosion-proof property of the period can be reliably obtained, and the amount of the relatively expensive thermosetting resin can be suppressed to be small, so that it can be produced advantageously in terms of cost.

  On the outer surface of the lid member 89, a connector that is electrically connected to a connection connector portion formed on the bottom wall portion 54 that defines the first tubular portion 60 of the casing body 51 that constitutes the gas alarm device body 10. The part is formed.

  As described above, in the portable gas alarm device, one of the rechargeable battery power supply unit 85 and the dry battery power supply unit 95 selected with respect to the power supply unit mounting portion 65 in the gas alarm device body 10. Is mounted by being slide-engaged along the back surface of the second tubular portion 61 in the casing body 51 constituting the gas alarm device body 10.

As shown in FIG. 8, the dry battery power supply unit 95 has a common outer shape (flat box shape) with the rechargeable battery power supply unit 85, and a gas detector While having an engaged portion 96A that is slidably engaged with an engaging portion 58 formed on the outer surface of the bottom wall portion 55 that defines the second cylindrical portion 61 of the casing main body 51 that constitutes the main body 10, A connector portion 96B that is electrically connected to a connector portion for connection formed on the bottom wall portion 54 that defines the first cylindrical portion 60 of the casing body 51 that constitutes the gas detector body 10 is formed on the upper surface. Yes.
The dry battery power supply unit 95 in this example includes a housing member 96 having a battery receiving portion 96D having a battery mounting opening 96C that opens rearward on the back surface, and packing P in the opening of the battery insertion port 96C in the housing member 96. A battery receiving portion cover lid 97A that is airtightly mounted via the power supply circuit board 98 disposed on the front side of the battery receiving portion 96D, and a power supply that is airtightly mounted on the front surface of the housing member 96 via the packing P. A plate-shaped protective member 97B that protects the circuit board 98, and the battery receiving portion 96D has, for example, three cylindrical dry batteries (for example, AA type dry batteries (AA size)) 99 adjacent to each other. The negative electrode and the negative electrode are mounted in parallel so as to face in opposite directions, and are connected in series.

  In this portable gas alarm device, each of the gas alarm device main body 10 (the casing main body 51 and the top cover 70), the rechargeable battery power supply unit 85 and the dry battery power supply unit 95 includes, for example, an antistatic resin (antistatic resin). The protective cover 18 is integrally attached, and in the state where the protective cover 18 is attached, the size of the resin surface portion exposed to the outside is restricted to a predetermined size or less. Will have sufficient and reliable explosion-proof properties. In addition, the material constituting the protect cover 18 functions as a buffer material (protective material) of the portable gas alarm device due to the impact resistance of the material itself, so that the portable gas alarm device is broken or damaged due to dropping or the like. It can be avoided.

Thus, in the portable gas alarm device described above, the top cover 70 has the resonance space S partitioned so as to communicate with the internal space in which the substrate assembly 20 is disposed via the communication port 73B. Is formed.
Specifically, the front wall 71 of the top cover 70 is formed with a first step recess 72 that opens in the front direction so as to extend in the width direction, and defines the first step recess 72. A second-stage recess 73 is located at a position displaced in the direction of one side wall from the front center position in the bottom wall portion 72A, that is, at a position facing the sound emission port 31A in the case 31 of the alarm buzzer 30 in the board assembly 20. The communication port 73 </ b> B is formed in the bottom wall portion 73 </ b> A that defines the second-stage recess 73. A buzzer cap 75 is provided in a cylindrical projecting edge portion 71A formed so as to surround the periphery of the first-stage recess 72 on the front surface of the front wall 71, whereby a resonance space (resonance space) S is formed. Is formed.
A dustproof / waterproof filter 83 made of, for example, polypropylene is provided on the inner surface of the bottom wall 73A that defines the second-stage recess 73 so as to cover the communication port 73B.

As shown in FIG. 9, the buzzer cap 75 has a notch 76 extending in the width direction at the center of the upper edge, whereby a buzzer sound emission opening 77 that opens the resonance space S to the outside is formed. Is formed. Accordingly, the buzzer sound emitting opening 77 is positioned so as to be displaced upward in the axial direction with respect to the communication port 73B formed in the bottom wall portion 73A that defines the second-stage recess 73, and the alarm buzzer. 30 buzzer sound is emitted with high directivity in a predetermined direction.
In this example, as shown in FIG. 10, the angle α formed with respect to the upward direction (0 °) along the surface (front surface) of the buzzer cap 75 in a side view is within an angular range of 45 to 55 °, for example. Directivity that increases the sound pressure of the buzzer sound, especially in the direction where the angle α to the upward direction is 50 ° (for example, the portable gas alarm is inclined by about 50 ° with respect to the horizontal plane so that its front faces diagonally downward. It is preferable that the buzzer sound emission opening 77 is formed so as to obtain directivity that maximizes the sound pressure of the buzzer sound emitted in the horizontal direction).

Further, the buzzer cap 75 has a plurality of buzzer sound adjustment holes at positions displaced toward the other side wall in the width direction so as not to face the communication port 73B formed in the bottom wall portion 73A of the second-stage recess 73. Is formed. Specifically, in the upper edge side region of the buzzer cap 75, for example, four buzzer sound adjustment holes 78A having the same diameter are formed side by side in the width direction, for example, at regular intervals. In the central region in the axial direction, for example, four buzzer sound adjusting holes 78B having the same hole diameter are formed side by side in the width direction. The buzzer sound adjustment hole 78B located in the central region is larger in diameter than the buzzer sound adjustment hole 78A located in the upper edge side region, and is formed at a position between the adjacent buzzer sound adjustment holes 78A in the width direction. ing.
By adopting such a configuration, the sound pressure improving effect of the buzzer sound can be obtained more reliably as shown in the results of Examples described later.

In this portable gas alarm device, when air in the ambient atmosphere is sucked and introduced by the pump unit 35 through the filter unit 84 provided in the top cover 70, the gas flow passage formed in the sensor cap 44 is passed through. The gas to be detected is sequentially supplied to each of the gas sensors 41 to detect the detection target gas, and the type and concentration of the detected gas are displayed on the display unit 11, and the concentration of any detection target gas is the reference. When it is detected that the value is exceeded, an alarm operation signal is issued, whereby the alarm buzzer 30 and the alarm light emitting element 23 are activated.
For example, in the case of oxygen gas (O ₂ gas), the reference value is, for example, 18.0% by volume (vol%), and an alarm operation signal is issued when the reference value is lower than that. The reference value is, for example, 10% LEL (gas concentration with respect to the lower explosion limit concentration) in the case of hydrocarbon gas (HC gas), and is, for example, 25 ppm in the case of carbon monoxide gas (CO gas). In the case of hydrogen sulfide gas (H ₂ S gas), for example, it is 10 ppm, and an alarm operation signal is issued when the reference value is exceeded.

  Thus, according to the portable gas alarm device having the above-described configuration, the front wall 71 of the top cover 70 surrounds the periphery of the opening edge of the first-stage recess 72 extending in the width direction so as to open to the front. A buzzer cap 75 in which a notch 76 extending in the width direction is formed in the upper edge portion is provided in the cylindrical protruding edge portion 71A formed as described above, whereby an internal space in which the substrate assembly 20 is disposed. And a resonance space S partitioned so as to communicate with each other through the communication port 73B, and a slit-like buzzer is formed by an opening formed between the outer peripheral surface of the buzzer cap 75 and the inner peripheral surface of the projecting edge portion 71A. A sound emission opening 77 is formed. Accordingly, the buzzer sound generated by the alarm buzzer 30 is emitted from the buzzer sound emission opening 77 mainly by increasing the sound pressure level due to the action of the resonance space S. Since the buzzer sound is positioned so as not to be opposed to the communication port 73B in the axial direction, the buzzer sound is a peripheral wall that defines the second-stage recess 73 that forms part of the resonance space S. Since the buzzer sound emission opening 77 of the buzzer cap 75 and the buzzer cap 75 is controlled in a direction within a specific angle range with respect to the direction perpendicular to the front surface of the buzzer cap 75, it is emitted to the outside. As is clear from the result of the example, the sound pressure level of the buzzer sound can be improved. As described above, since the buzzer sound has a directivity so that the buzzer sound is emitted upward, the portable gas alarm is mounted on the user's body and used. Even in this case, since the buzzer sound from the portable gas alarm can be recognized with certainty, it is possible to reliably avoid an unexpected situation.

Moreover, according to the portable gas alarm device of the said structure, the effect as shown below is acquired.
(1) The casing main body 51 of the gas alarm device main body 10 that forms an internal space in which substantially the entire substrate assembly 20 is accommodated has one end side portion on which functional members related to the gas detection operation of the substrate assembly 20 are arranged. A substrate assembly 20 that extends outward in the axial direction of the first tubular portion 60 continuously to the outer surface of the first tubular portion 60 accommodated therein and the bottom wall portion 54 that defines the first tubular portion 60. The portable gas alarm device itself has a robust structure by being configured as an integral body having no second joint portion having the second cylindrical portion 61 in which the other end portion of the main substrate 21 is accommodated. Therefore, it can be configured as having the desired explosion-proof property and the desired waterproof property.

(2) Since the casing main body 51 is made of a transparent resin material, there is no need to form an opening for forming the display unit 11 in the casing main body 51. Since this portion can function as a protective window for the panel-like display mechanism 22 in the substrate assembly 20, the portable gas alarm device itself can be reliably configured as having a robust structure. . Furthermore, since a power supply unit including one of the rechargeable battery 90 and the dry battery 99 is configured independently of the gas alarm device body 10, for example, both a rechargeable battery such as a lithium ion battery and a dry battery are used. However, the robustness can be improved also in that the casing body 51 does not need to be provided with a battery loading chamber or a battery insertion port for a dry battery.

(3) Furthermore, the substrate assembly 20 is held and fixed by simply inserting the substrate assembly 20 into the casing main body 51, and the top cover 70 is attached to the casing main body 51 and fixed by the fixing screw 18. In the state, the sound emission port 31A in the alarm buzzer 30 is properly positioned with respect to the communication port 73B that connects the resonance space S formed in the top cover 70 and the internal space in which the substrate assembly 20 is accommodated. Since the state can be obtained, the portable gas alarm can be manufactured (assembled) very easily without complicated work, and in the event of a failure or the like, the board assembly 20 can be pulled out of the casing main body 51 and the necessary functional members can be replaced. It is possible to obtain the Nsu property. The gas sensor 41 can be replaced by removing the sensor cap 44 from the casing body 51 without removing the top cover 70.

(4) Furthermore, since the seal portion formed on the joint surface between the casing body 51 and the top cover 70 is a relatively small region, the original performance of the ring-shaped packing 80 is reliably expressed and highly reliable. A seal structure can be formed.

Hereinafter, experimental examples performed for confirming the effects of the present invention will be described.
<Experimental example 1>
A portable gas alarm device according to the present invention was produced according to the above configuration example.
The buzzer sound emitting opening (77) in the top cover (70) has a dimension in the axial direction (vertical direction in FIG. 1) of 1 mm and a dimension in the width direction (horizontal direction in FIG. 1) of 36 mm.
The resonance space (S) in the top cover (70) has a volume of about 2900 mm ³ .
The communication port (73B) in the top cover (70) has a dimension in the axial direction (vertical direction in FIG. 8) of 6 mm and a dimension in the width direction (horizontal direction in FIG. 8) of 7 mm, and the upper end of the communication port (73B). The separation distance in the axial direction between the edge position and the lower edge position of the buzzer sound emission opening (77) is 0.25 mm.
The buzzer sound adjustment hole (78A) formed in the upper edge side region of the buzzer cap (75) has a hole diameter of 1 mm, the buzzer sound adjustment hole (78B) formed in the center region has a diameter of 2 mm, and the adjacent buzzer sound adjustment hole ( 78A) and the distance between adjacent buzzer sound adjustment holes (78B) is 7.5 mm.
The piezoelectric buzzer (30) has an oscillation frequency of 3.53 to 3.95 kHz and an opening diameter of the sound emission port (31A) of φ4 mm.
The dustproof / waterproof filter (83) is a sheet-like material made of polypropylene and having a thickness of 0.03 mm.

  About this portable gas alarm device, when the sound pressure level of the buzzer sound emitted to the outside is α = 0 ° in the upward direction along the front in a side view (see FIG. 9), an angle of 30 ° to 90 ° When measured within the range, the sound pressure level of the buzzer sound is 95 dB or more in the direction within the angle range of 45 ° to 55 °, and particularly the sound pressure of the buzzer sound in the direction of 50 ° (α) with respect to the front. It was confirmed that the level showed a maximum value of 98 dB.

<Comparative Experimental Example 1>
In the portable gas alarm produced in Experimental Example 1, as shown in FIG. 11, the buzzer cap (75A) does not have a notch at the upper edge, and emits a plurality of buzzer sounds over the entire front surface. A comparative portable gas alarm having the same configuration as that of Experimental Example 1 was prepared except that an opening (77A) was used. Each of the buzzer sound emitting openings (77A) has a uniform hole diameter of φ1.6 mm and is formed at intervals of 7.5 mm at the staggered lattice positions in front of the buzzer cap (75A).
About this portable gas alarm device for comparison, when the sound pressure level of the buzzer sound emitted to the outside was measured in the same manner as in Experimental Example 1, the sound pressure level of the buzzer sound emitted in the front direction showed the maximum value. 87 to 90.5 dB.

<Experimental example 2>
In the portable gas alarm produced in Experimental Example 1, the reference portable type having the same configuration as that of Experimental Example 1 except that a buzzer cap without a buzzer sound adjustment hole was used. A gas alarm was produced and the sound pressure level of the buzzer sound emitted to the outside was measured in the same manner as in Experimental Example 1. The sound pressure level of the buzzer sound was 95 dB in the direction within the angle range of 45 ° to 55 °. Although it became the above, it was confirmed that the maximum value of the sound pressure level is 95.5 dB (in the direction of 50 °).

DESCRIPTION OF SYMBOLS 10 Gas alarm device main body 11 Display part 12 Operation part 13 Alarm light emission part 18 Protect cover 20 Board assembly 21 Main board 21A Opening 22 Panel-like display mechanism 23 Alarm light emitting element 24 Switch element 25 Switch element drive button 30 Alarm buzzer 31 Case 31A Sound outlet 32 Piezoelectric vibrator 35 Pump unit 40 Sensor substrate 41 Gas sensor 42 Sensor holder 43 Planar packing 44 Sensor cap 51 Casing body 51A Open end surface 52 Front wall 52A Hole 53 Side wall 54 Bottom wall portion 54A Sensor substrate holding portion 55 Bottom wall portion 56 Main board holding portion 57 Receiving guide portion 57A Guide surface 57B Taper portion 58 Engaging portion 59 Sensor cap mounting opening 60 First cylindrical portion 61 Second cylindrical portion 65 Power supply unit mounting portion 66 Power supply unit Guide section 66A Projection 68 Protective film material 70 Top cover 71 Front wall 71A Projection edge 72 First step recess 72A Bottom wall portion 73 Second step recess 73A Bottom wall portion 73B Communication port 74 Upper wall 74A, 74B Substrate support part 75, 75A Buzzer cap 76 Notch part 77, 77A Buzzer sound emission opening 78A, 78B Buzzer sound adjustment hole S Resonance space 80 Ring-shaped packing 81 Fixing screw 83 Dustproof / waterproof filter 84 Filter Unit 85 Rechargeable battery power supply unit 86 Housing member 86A One side wall 86B The other side wall 86D Front side flat wall 86E Engaged part 86F Groove part 87 Battery support part 88 Taper part 89 Lid member 89A Connector part 90 Rechargeable battery 91 Power supply circuit Substrate 92 Resin block 95 Dry cell power supply unit 96 Howjin Member 96A engaged portion 96B connector portion 96C battery mounting port 96D battery receiving portion 96E groove 97A battery receptacle cover lid 97B protective member 98 the power supply circuit board 99 batteries P Packing

Claims (3)

A casing in which a resonance space partitioned to communicate with an internal space in which the main board is disposed via a communication port is formed in a front side region, and an alarm provided at a position facing the communication port in the main substrate Buzzer and a waterproof filter having sound permeability provided to cover the communication port,
A portable gas alarm characterized in that a slit-like buzzer sound emission opening for communicating the resonance space to the outside is formed at a position displaced so as not to face the communication opening on the front surface of the casing. vessel. The resonance space is provided with a cap member in a cylindrical protruding edge formed so as to surround the periphery of the opening edge of the first step recess formed in one direction so as to open to the front of the casing. The bottom wall portion defining the first step recess is formed with a second step recess in the one end side region in the one direction, and the second step recess The communication port is formed in the partitioning bottom wall,
A cutout portion extending in the one direction is formed in a part of the outer peripheral edge portion of the cap member, and an opening formed between the outer peripheral surface of the cap member and the inner peripheral surface of the protruding edge portion. The portable gas alarm device according to claim 1, wherein the buzzer sound emitting opening is formed.   The portable gas alarm according to claim 2, wherein a buzzer sound adjusting hole is formed in the cap member at a position displaced to the other end side in the one direction so as not to face the communication port. vessel.

Images