JP6064365B2 - Alarm - Google Patents

Description

  The present invention relates to an alarm device that detects an abnormality of at least one detection object such as gas leakage, incomplete combustion, or fire, and issues an alarm.

  In general, as an alarm device, a gas alarm device that generates an alarm by detecting that the concentration of carbon monoxide (CO) gas generated due to incomplete combustion and the leaked gas is equal to or higher than a predetermined alarm concentration, or an indoor temperature In addition to fire alarms that detect the occurrence of a fire from a change and issue an alarm, there are combined alarms that integrate a gas alarm and a fire alarm.

  Such an alarm device has an LED inside. A display portion is provided on the outer surface. A user or the like visually recognizes a lighting state such as lighting, extinguishing, or blinking of an LED inside the alarm device through the display unit. Thereby, the user etc. can recognize the energization (normal operation | movement) state of a warning device, a gas leak detection state, etc.

For example, in a conventional gas alarm device, light emitting elements (LEDs) are arranged in a row as an indicator lamp in the order of energized “green”, CO alarm “yellow”, and gas alarm “red”.
At this time, in Patent Document 1, a substantially rectangular parallelepiped light guide part is formed in each optical path until light from each light emitting element reaches the display part. The plurality of light guide portions are each configured in a column shape from the display portion to the vicinity of the light emitting element. The light from each light emitting element is guided to the display unit through the respective light guide unit, and the alarm state is displayed to the outside.

  Moreover, in patent document 2, it has the structure which guides the light from each light emitting element to a display part with one light guide part, and displays an alarm state outside.

JP 2005-316540 A JP 2005-18174 A

However, such a conventional alarm device has the following problems.
When a plurality of light guides are used for each light emitting element as in Patent Document 1, the cost increases due to an increase in the number of parts and the number of manufacturing steps.

  Moreover, although patent document 2 uses one light guide part, the material with a high diffusivity is used for the light guide part. Therefore, light is scattered in the light guide. As a result, there are problems that light is scattered and transmitted to a display portion of a nearby color, causing the display portions of other colors to shine, and light of close distances to be mixed together.

  For example, as described above, in the display unit of the alarm device in which the light emitting elements are arranged in a line of green, yellow, and red, green (energized state) is always lit. When a gas leak is detected, red (gas alarm) is turned on. At this time, the green and red lights are turned on simultaneously. However, when light scattering occurs and mixed with green and red light, yellow light is synthesized between the two colors. This yellow combined light is generated in the same color as that at the time of alarm at the CO alarm display position.

  That is, there has been a dangerous problem that the user or the like cannot clearly identify the presence or absence of the CO alarm due to color interference. In particular, since gas leaks and fires are dangerous situations related to human lives, the fact that they cannot be accurately identified has been a very serious problem.

  Furthermore, when a transparent or low diffusivity material is used for one light guide portion, the inside of the product can be seen through from the outside through the display portion, which deteriorates the appearance. For this reason, it is necessary to use a blind member in a portion where the inside can be seen through, and there has been a problem of cost increase due to an increase in the number of materials.

  Accordingly, an object of the present invention is to prevent light interference between the light emitting elements when the single light guide unit is used in order to solve the above-described problem, and the internal structure of the alarm device is transparent from the outside. It is to prevent it from being seen.

In order to achieve the above object, according to the present invention, a detection unit that detects one or more detection targets, a plurality of light emitting elements that notify a detection result of the detection unit and an energization state of the device, a light guide portion for optically light guide the outside from the plurality of light emitting elements, wherein the detection unit and the alarm device comprising a housing for housing said plurality of light emitting elements and the light guide portion, the light guide portion , formed integrally of a transparent or translucent material, wherein the plurality on the opposite surfaces and a plurality of cylindrical light guide which projects respectively to the vicinity of the front Symbol plurality of light emitting elements, the plurality of cylindrical light guide is projected A display unit that displays light from the light emitting element, and a shielding member is provided so as to cover each of the cylindrical outer peripheral surfaces of the plurality of cylindrical light guide units. The alarm device is characterized by being composed of gray.

In addition, according to the present invention, in the above configuration, the display unit is subjected to a texture processing that scatters light.
According to the present invention, in the above configuration, the shielding member is cylindrical, and the tubular light guide is fitted and accommodated in the shielding member. .

  Moreover, according to this invention, it is set as the alarm device characterized by the above-mentioned structure WHEREIN: Only the part near the said display part is comprised in black or gray among the said shielding members.

  According to the present invention, even when a single light guide is used, the interference between the light emitting elements is prevented, and the alarm that prevents the internal structure of the alarm from being seen through from the outside is prevented. Can be realized.

It is a general view of the external appearance of the alarm device of the Example of this invention. It is AA sectional view taken on the line of the alarm device of the Example of this invention. It is BB sectional drawing of the alarm device of the Example of this invention. It is the figure which showed transmission of the light of the alarm device of the Example of this invention. It is the figure which showed transmission of the light at the time of using a material with high diffusivity for the alarm device of the Example of this invention as a comparative example. It is the figure which showed the modification of the Example of this invention.

  An embodiment of the present invention will be described below with reference to the drawings. However, the following description is merely an example of the present invention, and the present invention is not limited to this. That is, it is possible for a person having ordinary knowledge in the field to implement many modifications within the technical idea of the present invention.

[External configuration of alarm device of embodiment of the present invention: FIG. 1 (overall view of appearance)]
First, the configuration of the alarm device according to the embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is an overall view of the appearance of an alarm device according to an embodiment of the present invention. 1 is a housing, 2 is a display unit, 7 is a sensor unit, and 8 is a reporting unit.

  FIG. 1 is a combined gas alarm that detects gas and carbon monoxide (CO). The outer shape is composed of a housing 1, and a display unit 2 for displaying the state of the alarm is provided on the front. Inside the housing 1, there are a sensor unit 7 as a detection unit for detecting CO and gas leakage, and a control unit (not shown) for performing a predetermined alarm operation when the gas sensor detects CO or gas leakage. And an alarm unit 8 that issues an alarm sound as an alarm operation, and a light emitting element (described later) that lights and blinks to display the alarm operation to the outside.

[Internal configuration of alarm device of embodiment of the present invention: FIG. 2 (cross-sectional view taken along line AA) and FIG. 3 (cross-sectional view taken along line BB)]
FIG. 2 is a cross-sectional view taken along line AA of the alarm device according to the embodiment of the present invention. FIG. 3 is a cross-sectional view of the alarm device according to the embodiment of the present invention taken along line BB. 2a is a display unit (green), 2b is a display unit (yellow), 2c is a display unit (red), 3 is a light guide unit, 4a is a light emitting element (green), 4b is a light emitting element (yellow), and 4c is a light emitting element. (Red), 5a-c are shielding members, 6a is a cylindrical light guide (green), 6b is a cylindrical light guide (yellow), and 6c is a cylindrical light guide (red).

  As shown in FIG. 2, light emitting elements (green, yellow, red) 4 a to 4 c are arranged in a row as indicator lights inside the housing 1. The light emitting elements 4a to 4c are LEDs. These light emitting elements 4 a to 4 c emit light from the inside of the housing 1 toward the display unit 2. Specifically, the light emitting element 4a is “energization display (normal operation): green LED”, 4b is “CO alarm: yellow LED”, and 4c is “gas alarm: red LED”, each emitting light.

  And in the display part 2, each light corresponding to light emitting element 4a-c is displayed. Specifically, the display units (green, yellow, red) 2a to c are displayed in a row corresponding to the light emitting elements (green, yellow, red) 4a to c, respectively. By these displays, the energization state and alarm state of the alarm device can be displayed to the outside. The display units 2a to 2c are subjected to a texture processing for scattering light.

  Moreover, the light guide part 3 is provided between the light emitting elements 4a to 4c and the display parts 2a to 2c. Light from the light emitting elements 4 a to 4 c is guided to the display units 2 a to 2 c through the light guide unit 3. The light guide unit 3 has a function of condensing the light on the target display units 2a to 2c without leaking the light from the light emitting elements 4a to 4c to others.

  As shown in FIGS. 2 and 3, the light guide 3 includes cylindrical light guides 6 a to 6 c that protrude from the vicinity of the display unit toward the light emitting elements 4 a to 4 c, respectively. The cylindrical light guides 6a to 6c are formed corresponding to the optical paths of the light emitted from the light emitting elements 4a to 4c, respectively.

  Specifically, the cylindrical light guides (green, yellow, red) 6a to c are formed in a line corresponding to the light emitting elements (green, yellow, red) 4a to 4c, respectively. Entrance portions for introducing light from the light emitting elements 4a to 4c into the cylindrical light guides 6a to 6c are opened in the vicinity of the light emitting elements 4a to 4c of the cylindrical light guides 6a to 6c. Yes. The light guide part 3 is formed by integral molding including the cylindrical light guide parts 6a to 6c. The light guide 3 (cylindrical light guides 6a to 6c) is made of a transparent material.

  Further, shielding members 5a to 5c are formed as internal structures of the housing 1 around the cylindrical light guides 6a to 6c of the light guide 3 so as to cover the cylindrical light guides 6a to 6c, respectively. . The shielding members 5a to 5c are also in a cylindrical shape, and the cylindrical light guides 6a to 6c are fitted and accommodated in the respective interiors.

  That is, as for the internal structure of the display part of the alarm device of the present embodiment, the integrally formed light guide part 3 (cylindrical light guide parts 6a to 6c) is fitted into the shielding members 5a to 5c provided inside the housing 1. It is constituted by being.

  And shielding member 5a-c is comprised with the material of the color with low brightness. In this embodiment, it is black or gray. Black or gray means Munsell brightness V = 0 to 5 in the Munsell display system industry standard (JISZ8721).

  On the other hand, the outer surface of the housing 1 is used in a shade with high brightness such as white or ivory that is generally used as an appearance color of an alarm device. In addition, the housing | casing 1 is comprised by the material (Munsell lightness V = 0-5) of the color (Munsell lightness V = 0-5) with the lightness (Munsell lightness V = 10) whose outer surface is high lightness, and the internal shielding members 5a-c. However, such a two-color arrangement that divides the brightness is realized as one component by a general molding technique such as two-color molding.

The above is description of the structure of the alarm device of the Example of this invention.
[Operation of Alarm Device of Embodiment of the Present Invention: FIGS. 4 and 5 (Transmission of Light)]
Next, the operation (transmission of light) of the alarm device according to the embodiment of the present invention will be described with reference to FIGS.

  FIG. 4 is a diagram illustrating light transmission of the alarm device according to the embodiment of the present invention. FIG. 5 is a diagram showing the transmission of light as a comparative example when a material with high diffusivity is used for the alarm device of the embodiment of the present invention. The arrows in FIGS. 4 and 5 indicate the trajectories of light from the light emitting elements 4a to 4c in this embodiment.

When the sensor unit 7 of the gas alarm detects gas leakage or carbon monoxide (CO) and detects a gas or CO of a certain concentration or more, the control unit performs alarm notification with sound and colored light.
An alarm sound is output from the alarm unit 8 as an audio alarm. Light from the internal light emitting elements 4 a to 4 c is displayed on the display unit 2 on the outer surface of the housing 1 as an alarm by colored light.

The alarm by the colored light will be described in detail.
As shown in FIG. 4, in the alarm using colored light, green light (light from the light emitting element 4a) indicating the energization state of the alarm device is displayed on the display unit 2a, and yellow light (light from the light emitting element 4b) indicating the CO alarm is displayed. Red light (light from the light emitting element 4c) indicating a gas leak alarm is displayed on the position of the display unit 2c on the unit 2b.

  The light emitted from each light emitting element 4a-c passes through the inside of each cylindrical light guide 6a-c of the light guide 3, and each color is displayed on the display 2a-c. At this time, the display units 2a to 2c are subjected to a graining process for scattering light, so that each color is diffusely displayed at a wide angle.

  A transparent material is used for the light guide 3 (cylindrical light guides 6a to 6c). Therefore, the light emitted from the light emitting elements 4a to 4c can go straight through the light guide 3 (cylindrical light guides 6a to 6c) and hardly reach the display units 2a to 2c. . As indicated by an arrow (light trajectory) in FIG. 4, light does not protrude into the display area range of the adjacent color and diffuse.

  In addition, the optical paths through which the light emitted from the light emitting elements 4a to 4c passes are separated by the shielding members 5a to 5c, respectively. Since the shielding members 5a to 5c block the light, the light is prevented from entering the adjacent optical path.

  Here, referring to FIG. 5, a case where a material having a high diffusivity as in the prior art is used for the light guide 3 (cylindrical light guides 6a to 6c) in the configuration of this embodiment will be described as a comparative example. To do.

  In FIG. 5, since a material having a high diffusion rate is used, diffusion occurs in every place. For example, light diffusion occurs at point F in FIG. At this time, as is clear from the arrows (trajectory of light) in FIG. 5, light emitted from the light emitting element 4a (green) for energization display and the light emitting element 4c (red) for gas leak alarm display is converted into CO by diffusion. It will be transmitted to the display part 2b which displays an alarm. And when green and red light mix, yellow synthetic light will generate | occur | produce in the display part 2b.

  Therefore, it becomes difficult for a user or the like to identify whether or not the CO alarm is also displayed. Note that the diffusion of light occurs in every place of the light guide 3 (cylindrical light guides 6a to 6c) in FIG. The above description is given taking point F as an example.

The above is the description of the comparative example.
Next, the state of the internal structure of the display unit 2 will be further described.
In the light guide portion 3 (cylindrical light guide portions 6a to 6c) of the present embodiment, since a transparent material is used, the internal structure can be seen through from the outside through the display portion 2 as it is.

  Here, the recognition of the color and shape of the object is recognized by reflection of light from the outside (except for an object that emits light by itself). Therefore, it is difficult to recognize the shape of an object with little reflection. On the other hand, a non-reflective object can only be identified by contrast with a reflective object.

  In this embodiment, the cylindrical light guides 6a to 6c are covered with the cylindrical shielding members 5a to 5c, and only the shielding members 5a to 5c are black or gray (Munsell brightness V = 0 to 5). ).

  That is, since the cylindrical light guides 6a to 6c are covered with the black or gray shielding members 5a to 5c (tubular) having a low reflectance, the light contrast inside the cylindrical light guides 6a to 6c is reduced. It is getting smaller. Therefore, even when a transparent material is used for the light guide 3 (cylindrical light guides 6a to 6c), the function of blinding to the outside can be sufficiently achieved only by the effect of light diffusion by the texture processing of the surface 2. Can be fulfilled.

The above is description of operation | movement (transmission of light) of the alarm device of the Example of this invention.
[Effect of this embodiment]
Thus, according to the embodiment of the present invention, since the light paths through which the light of the light emitting elements 4a to 4c passes are separated by the shielding members 5a to 5c that block the light, it is possible to prevent interference between adjacent lights.

  In addition, since a transparent material is used for the light guide unit 3, diffusion of light inside the light guide unit 3 can be reduced. Furthermore, in the inside of the light guide part 3, scattering, transmission, mixing of light, etc. of near light can be prevented.

  In addition, cylindrical light guides 6a to 6c are formed in the light guide 3, and around the cylindrical light guides 6a to 6c by black or gray shielding members 5a to 5c (Munsell brightness V = 0 to 5). Therefore, the light contrast inside the cylindrical light guides 6a to 6c can be reduced. Thereby, it can prevent that the internal structure of the surface part 2 of the housing | casing 1 is seen through from the exterior only by giving the surface part 2 an embossing process and interrupting | transmitting transmission by scattered light.

  Therefore, even though a transparent material is used for the light guide unit 3, the internal structure of the display unit 2 can be seen through from the outside, and the appearance is not poor. In addition, since it is not necessary to use a blindfolding member as a separate part, it is possible to reduce costs and improve design flexibility.

Furthermore, since the light is collected by one light guide 3, it is not necessary to manufacture a plurality of light guides, and cost can be reduced.
[Modification (particularly a portion that can be easily seen through from the outside): FIG. 6]
As a modification of the embodiment of the present invention, a portion that is particularly easily visible from the outside among the internal structure of the surface portion 2 of the housing 1 will be described with reference to FIG.

FIG. 6 is a diagram showing a modification of the embodiment of the present invention.
In FIG. 6, among the cylindrical shielding members 5 a to 5 c, an E part that is the closest to the display part 2 is a part that is particularly easily seen through from the outside.

Therefore, only the E portion of the shielding members 5a to 5c can be black or gray having a low reflectance (Munsell brightness V = 0 to 5).
In that case, it is possible to achieve an effect of concealing, in particular, a portion that is easily seen through from the outside by a simple process in which the limited range of only the E portion is made black or gray having a low reflectance.

[Other Modifications (About Shielding Members 5a to 5c)]
Although shielding member 5a-c of a present Example is cylindrical, it is not limited to this, Other shapes, such as plate shape, may be sufficient. Even if it is other shapes such as a plate shape, it is sufficient if the contrast of light inside the cylindrical light guides 6a to 6c can be reduced by surrounding the cylindrical light guides 6a to 6c with black or gray shielding members. .

  Further, in this embodiment, the shielding members 5a to 5c and the cylindrical light guides 6a to 6c are covered in a state of being fitted so as to exactly match, but the present invention is not limited to this. A space may exist between the shielding members 5a to 5c and the cylindrical light guides 6a to 6c.

In addition, if the shielding members 5a to 5c are made of a translucent material (a material having a low light diffusivity) instead of being transparent, the blinding effect can be further enhanced in addition to the texture processing of the surface portion 2.
In this case, translucent means that light can be prevented from diffusing inside one light guide, and specifically, what enables light transmission as shown in FIG. means.

  In addition, even if it is a case where a translucent material is used for shielding member 5a-c, without giving the surface part 2 a texturing process, a blinding effect can be show | played.

1 Housing 2a-c Display section (green, yellow, red)
3 Light guide part 4a-c Light emitting element (green, yellow, red)
5a-c shielding member 6a-c cylindrical light guide (green, yellow, red)
7 Sensor part 8 Reporting part

Claims (4)

A detector for detecting one or more detected respectively, and a plurality of light emitting elements for notifying the current state of the detection results and equipment of the detection unit, the plurality of light that the light guide light to the outside from the light emitting element In an alarm device comprising a portion, and a housing that houses the detection unit and the plurality of light emitting elements and the light guide unit,
The light guide portion is integrally formed of a transparent or translucent material, and a plurality of cylindrical light guide which projects respectively to the vicinity of the front Symbol plurality of light emitting elements, the plurality of cylindrical light guide is projected A display unit for displaying light from the plurality of light emitting elements on the opposite surface ;
A shielding member is provided so as to cover the cylindrical outer peripheral surfaces of the plurality of cylindrical light guides,
The alarm is characterized in that the shielding member is made of black or gray. The alarm device according to claim 1,
The alarm device characterized in that the display portion is subjected to a texture processing for scattering light. The alarm device according to claim 1 or 2,
The shielding member is cylindrical;
The said cylindrical light guide part is fitted and accommodated in the said shielding member, The alarm device characterized by the above-mentioned. The alarm device according to any one of claims 1 to 3,
Of the shielding member, only the vicinity of the display unit is configured in black or gray.

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