JP7208714B2 - fire detection device - Google Patents

Description

The present invention relates to fire detection devices.

Conventionally, techniques for protecting a temperature detection element have been proposed for a heat sensor that detects fire in a monitored area. In this technology, a temperature detecting element, a sensor body for housing the temperature detecting element, and an insertion hole provided in the lower surface of the sensor body, only a part of the temperature detecting element is inserted into the sensor body. A protector having an insertion hole exposed to the outside and a plurality of ribs formed in the lower surface of the sensor body and having the same shape, the protector for covering the temperature detecting element exposed to the outside. and a heat sensor is constructed. In addition, a display hole is provided in a portion of the lower surface of the sensor body other than the portion corresponding to the protector so that the indicator lamp housed inside the sensor body can be visually recognized from the outside (see, for example, Patent Document 1).

JP 2012-198757 A

However, in the above-described prior art, the protector and the display hole are provided on the lower surface of the sensor body so as to be exposed to the outside. There was a risk of degrading the design of the vessel. In addition, since the plurality of ribs of the protector have the same shape, for example, depending on the installation situation of the heat sensor, it becomes difficult to make the inflow amount of air flowing into the protector uniform from each direction. There was a possibility that it would be difficult to improve the influx of airflow. Therefore, there is room for improvement from the viewpoint of designability or air flow inflow.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fire detection device capable of improving the design and the influx of airflow.

In order to solve the above-described problems and achieve the object, the fire detection device according to claim 1 is a fire detection device that is attached to the installation surface of an installation target, and is a fire detection device for detecting a fire in a monitoring area. A detection device, comprising: a housing; and heat sensing means arranged so that at least a part thereof protrudes from a surface of the housing on the monitoring area side and is exposed to the monitoring area side, wherein the heat associated with the fire and a guard having a plurality of ribs erected on the surface of the housing on the monitoring area side so as to cover a portion of the heat sensing means exposed to the monitoring area side. guard means for protecting the heat sensing means by the plurality of ribs; and display means provided inside the housing for displaying predetermined information toward the monitoring area by emitting light. display means, wherein some ribs of the plurality of ribs of the guard means are formed of a translucent material and the other part of the ribs are formed of a non-translucent material, The predetermined information can be visually recognized from the monitoring area side by guiding the light emitted from the display means through the part of the ribs, and the heat sensing means and the guard means are arranged in the monitoring area. The part of the ribs formed of the translucent material is provided on the outer peripheral side of the central portion of the side surface, and the one portion of the ribs formed of the translucent material is placed on the other portion of the surface on the monitoring area side formed of the non-translucent material. The thickness of the ribs formed of the translucent material is the same as the thickness of the ribs of the other ribs formed of the non-translucent material. thicker than the thickness of

According to the fire detection device of claim 1, for example , by forming only part of the ribs with a translucent material, the It becomes possible to guide the light illuminated from the display means to the outside of the fire detection device. Therefore, since there is no need to provide a display hole in the housing for guiding the light illuminated from the display means to the outside, the conventional technology (technology in which the protector and the display hole are provided so as to be exposed to the outside) can be eliminated. Therefore, it is possible to maintain the design of the fire detection device .

It is a side view which shows the attachment condition of the fire detection apparatus which concerns on embodiment. 2 is an enlarged view of the area of the fire detection device of FIG. 1; FIG. It is a bottom view which shows the fire detection apparatus of the state which removed the mounting base. 4 is a cross-sectional view taken along line AA of FIG. 3; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a fire detection device according to the present invention will be described in detail below with reference to the drawings. First, [I] the basic concept of the embodiment will be described, then [II] the specific contents of the embodiment will be described, and finally [III] modifications of the embodiment will be described. However, the present invention is not limited by the embodiment.

[I] Basic concept of the embodiment First, the basic concept of the embodiment will be described. The embodiment is generally a fire detection device attached to an installation surface of an installation object, and relates to a fire detection device for detecting fire in a monitoring area.

Here, the "fire detection device" is, in the embodiment, a device that thermally detects and notifies a fire in the monitored area. This concept includes mechanical and optical fire detectors and fire alarms. In addition, "installation object" is the object on which the fire detection device is installed, and is a concept that includes, for example, the ceiling and walls of a building. In addition, although the specific structure and type of "building" is arbitrary, for example, the concept includes detached houses, collective housing such as apartments and condominiums, office buildings, event facilities, commercial facilities, public facilities, etc. is. A "monitored area" is an area to be monitored, and is a concept including, for example, an area inside a building, an area outside the building, and the like. In addition, "notify" is a concept including, for example, outputting predetermined information to an external device, displaying or outputting predetermined information via output means (display means or audio output means), etc. be. In the following embodiments, the "fire detection device" is a "thermal and optical fire detector", the "installation target" is the "ceiling of an office building", and the "monitoring area" is A case of "an area inside an office building" will be described.

[II] Specific contents of the embodiment Next, specific contents of the embodiment will be described.

(Constitution)
First, the configuration of the fire detection device according to the embodiment will be described. FIG. 1 is a side view showing how the fire detection device according to the embodiment is mounted. 2 is an enlarged view of the area of the fire detection system of FIG. 1; FIG. FIG. 3 is a bottom view showing the fire detection device with a mounting base, which will be described later, removed. 4 is a cross-sectional view taken along the line AA in FIG. 3. FIG. In the following explanation, the X direction in FIG. 1 is the left-right direction of the fire detection device (+X direction is the left direction of the fire detection device, -X direction is the right direction of the fire detection device), and the Y direction in FIG. 3 is the fire detection device. The front and back direction (+Y direction is the front direction of the fire detection device, -Y direction is the rear direction of the fire detection device), the Z direction in FIG. The direction is referred to as the downward direction of the fire detector). Also, with the central position of the detection space in FIG. 3 as a reference, the direction away from the detection space is called "outside", and the direction toward the detection space is called "inside".

The fire detection device 1 is a device that detects heat in a monitored area, detects a substance to be detected (for example, smoke, etc.) contained in gas, and notifies the user. This fire detection device 1 is installed indoors in a building on an installation surface 2 under the ceiling of the building (object to be installed). As shown in FIGS. , an inner cover 30 , an inflow space 40 , an insect screen 50 , a detection space 60 , a detection part cover 70 , a detection part main body 80 , a terminal board 90 and a substrate 100 .

(Configuration - Mounting base)
Returning to FIG. 1 , the mounting base 10 is mounting means for mounting the outer cover 20 on the installation surface 2 . The mounting base 10 is configured using, for example, a known mounting base for a fire detection device (for example, a substantially plate-shaped mounting base made of resin) or the like, and as shown in FIGS. It is fixed to the installation surface 2 by a fixture or the like.

(Configuration - outer cover)
Returning to FIG. 2 , the outer cover 20 is a cover that covers the inner cover 30 , the inflow space 40 , the insect screen 50 , the detection space 60 , the detection section cover 70 , the detection section body 80 , the terminal board 90 , and the substrate 100 . The outer cover 20 is made of, for example, a light-shielding resin material. As shown in FIGS. 24.

Out of these, the outer cover main body 21 is the basic structure of the outer cover 20 . The outer cover main body 21 is formed of, for example, a substantially hollow columnar body with open top and bottom surfaces, and as shown in FIG. and fixed to the mounting base 10 by a fitting structure (or fixture) or the like.

Also, the top surface portion 22 is a partitioning means for partitioning the inflow space 40 . The top surface portion 22 is formed of, for example, a substantially circular plate-like body, and is provided substantially horizontally below the outer cover main body 21 as shown in FIGS. 2 to 4 .

Further, the first rib portion 23 is partitioning means for partitioning the inflow space 40 . The first rib portion 23 is formed of a substantially plate-like body, and is provided vertically between the outer cover main body 21 and the top surface portion 22. Specifically, as shown in FIGS. , a plurality of them are provided radially from the vicinity of the center of the outer cover 20 and are connected to the outer cover main body 21 and the top surface portion 22 .

Further, the second rib portion 24 is partitioning means for partitioning the inflow space 40 . The second rib portion 24 is formed of a substantially plate-like body and provided vertically between the outer cover main body 21 and the top surface portion 22. Specifically, as shown in FIGS. In addition, it is provided between the inner ends of adjacent first rib portions 23 and connected to the outer cover main body 21 and the top surface portion 22 . The details of the configuration of the outer cover 20 will be described later. The "outer cover 20" described above corresponds to the "casing" in the claims.

(Configuration - inflow space)
Returning to FIG. 2 , the inflow space 40 is a space for causing the gas outside the fire detection device 1 to flow into the fire detection device 1 . A plurality of inflow spaces 40 are formed inside the outer cover 20. Specifically, as shown in FIGS. , the second rib portion 24 , and the inner cover 30 form an inflow space 40 .

(Configuration - inner cover)
The inner cover 30 is a cover that covers the detection space 60 , the detection section cover 70 , the detection section main body 80 , and the substrate 100 , and also serves as partitioning means for partitioning the inflow space 40 . The inner cover 30 is, for example, a substantially hollow columnar body with an open upper surface, and is made of a light-shielding resin material. As shown in FIG. 30 is provided so as to face the top surface portion 22 of the outer cover 20 with the inflow space 40 interposed therebetween. In addition, as shown in FIG. 4, a first opening 30a is formed in the lower surface of the inner cover 30. As shown in FIG. The first opening 30a is an opening for sending the gas that has flowed into the inflow space 40 to the detection space 60. As shown in FIG. is provided.

(configuration - detection space)
The detection space 60 is a space for detecting a substance to be detected, and as shown in FIG. 60.

(Construction - detector cover)
The detection unit cover 70 is partitioning means for partitioning the detection space 60 and is incident suppressing means for suppressing disturbance light from entering the detection space 60 . The detector cover 70 is a substantially hollow columnar body with an open upper surface, and is made of a light-blocking resin material. 4, inside the inner cover 30, the detector cover 70 has a lower surface that is connected to the top surface 22 of the outer cover 20 via the first opening 30a and the inflow space 40. As shown in FIG. They are arranged so as to face each other and are fixed to the detection unit main body 80 by a fitting structure or the like. Further, as shown in FIG. 4, a second opening 70a is formed in the lower surface of the detector cover 70. As shown in FIG. The second opening 70a is an opening for allowing the gas sent from the first opening 30a to flow into the detection space 60. As shown in FIG. It is provided in a portion corresponding to 30a.

(Composition - insect screen)
The insect net 50 is a net for preventing insects outside the fire detection device 1 from entering the detection space 60 . The insect screen 50 is constructed using a mesh-like circular net, and is attached to the detection section cover 70 as shown in FIG.

(Construction - detector body)
The detector main body 80 is mounting means for mounting the detector cover 70 , and is incident suppressing means for suppressing disturbance light from entering the detection space 60 . The detector main body 80 is made of, for example, a light-shielding resin material, and as shown in FIG. etc. is fixed. Further, the detection unit main body 80 is provided with support portions (not shown) for supporting each of the first light emitting portion, which will be described later, the second light emitting portion, which will be described later, and the light receiving portion, which will be described later. Further, the detection unit main body 80 has an optical path hole (not shown) for forming an optical path between each of a first light emitting unit, a second light emitting unit, and a light receiving unit, which will be described later, and the detection space 60 . ) are formed respectively.

(Configuration - terminal board)
The terminal board 90 is housing means for housing the inner cover 30 , the detection section cover 70 , the detection section main body 80 , and the board 100 . The terminal board 90 has a substantially hollow columnar shape with an open lower surface, and is made of, for example, a light-shielding resin material. 4, the terminal board 90 is provided so as to cover the inner cover 30, the detection section cover 70, the detection section main body 80, and the substrate 100 from above, and has a fitting structure with respect to the outer cover 20. etc., and is fixed to the mounting base 10 by a fixture or the like through a first mounting hole (not shown) formed in the mounting member 91 .

(Configuration - substrate)
The substrate 100 is mounting means on which various electric circuits (not shown) are mounted. This substrate 100 is configured using, for example, a known flat circuit board or the like, and as shown in FIG. It is arranged substantially horizontally and fixed to the terminal board 90 by a fixture through a mounting hole (not shown) formed in the terminal board 90 and a second mounting hole (not shown) formed in the mounting member 91. there is

In addition to mounting known electronic components used in the conventional fire detection device 1 on the substrate 100, as shown in FIG. (illustration omitted), light receiving unit (illustration omitted), heat sensing unit 110, display unit (illustration omitted), communication unit (illustration omitted), power supply unit (illustration omitted), control unit (illustration omitted), and storage unit (illustration omitted) omitted) has been implemented.

(Configuration - substrate - first light emitting part, second light emitting part, light receiving part)
Among these, the first light emitting section is a first light emitting means for irradiating detection light (hereinafter referred to as "first detection light") into the detection space 60, and is, for example, a known light emitting element (an example of which is an infrared LED). is configured using Further, the second light emitting unit is second light emitting means for irradiating the detection space 60 with detection light having a wavelength different from that of the first detection light (hereinafter referred to as "second detection light"). (Blue LED etc. as an example) is used. Further, the light receiving unit receives scattered light due to smoke of the first detection light emitted from the first light emitting unit, outputs a first light receiving signal according to the received scattered light, and emits light from the second light emitting unit. light receiving means for receiving the scattered light of the second detection light from the smoke and outputting a second light receiving signal corresponding to the received scattered light, for example, using a known light receiving element (such as a photodiode as an example) It is configured. In addition, the method of installing the first light emitting unit, the second light emitting unit, and the light receiving unit is arbitrary, but in the embodiment, the first detection light emitted from the first light emitting unit or the second light emitting unit or the second It is installed so as to prevent the detection light from directly entering the light receiving section through various optical path holes of the detection section main body 80 . For example, the angle between the optical axis of the first light emitting section (hereinafter referred to as "first light emitting side optical axis") and the optical axis of the light receiving section (hereinafter referred to as "light receiving side optical axis") is about 135°. A first light emitting unit and a light receiving unit are installed at the positions. Further, the second light emitting unit and the light receiving unit are installed at a position where the angle between the optical axis of the second light emitting unit (hereinafter referred to as "second light emitting side optical axis") and the light receiving side optical axis is about 90°. ing.

(Construction - substrate - thermal sensing part, display part, communication part, power supply part)
Returning to FIG. 2, the heat sensing unit 110 is heat sensing means for detecting fire. The heat sensing unit 110 is configured using, for example, a known heat sensing element (eg, a thermistor, etc.), and as shown in FIGS. A part of the heat sensing part 110 is arranged to be exposed to the outside of the fire detection device 1 through an insertion hole (not shown) provided in each of the main bodies 80 and an insertion hole 120 of the outer cover 20 which will be described later. . In addition, the display unit emits light (hereinafter referred to as “display light”) toward the outside of the fire detection device 1 to display predetermined information (for example, information indicating whether or not a fire has been detected). This is display means, and is configured using, for example, known display means (LED, etc.). Moreover, although the method of projecting light from the display unit is arbitrary, for example, insertion holes (not shown) provided in each of the inner cover 30, the detection unit cover 70, and the detection unit main body 80 and the outer cover 20 described later can be used. Light is projected by guiding the display light from the display unit toward the outside of the fire detection device 1 through the light guide 104a inserted through the insertion hole 120 of the fire detection device 1, or the like. Also, the communication unit is communication means for communicating with an external device (for example, a receiver, etc.). The power supply unit is power supply means for supplying electric power supplied from a commercial power supply or a battery (not shown) to each unit of the fire detection apparatus 1 .

(Configuration - substrate - control unit, storage unit)
Also, the control unit is control means for controlling the fire detection device 1 . Specifically, this control unit includes a CPU, various programs interpreted and executed on the CPU (including a basic control program such as an OS, and an application program that is started on the OS and realizes a specific function), programs, and It is a computer configured with an internal memory such as a RAM for storing various data. The storage unit is storage means for storing programs and various data necessary for the operation of the fire detection device 1 . This storage unit is configured using a rewritable recording medium, and can use, for example, a non-volatile recording medium such as a flash memory.

(Composition - details of the composition of the outer cover)
Returning to FIG. 2, next, the details of the configuration of the outer cover 20 will be described. However, the outer cover 20 can be manufactured in any shape, method, and material, unless otherwise specified.

In the embodiment, as shown in FIGS. 2 to 4, the top surface portion 22, which is the side portion opposite to the side portion on the installation surface 2 side of the outer cover 20 (opposite side portion), has , an insertion hole 120 and a guard portion 130 are provided.

(Structure - Details of Structure of Outer Cover - Insertion Hole)
Returning to FIG. 3 , the insertion hole 120 is a through hole for exposing a part of the heat sensing part 110 to the outside of the fire detection device 1 and for irradiating the display light from the display part to the outside of the fire detection device 1 . be.

Here, the specific shape and size of the insertion hole 120 are arbitrary, but in the embodiment, the planar shape of the insertion hole 120 is set to a substantially elliptical shape as shown in FIG. (Alternatively, it may have a polygonal shape such as a square shape). In addition, the diameter of the insertion hole 120 is set to a size that allows only a part of the heat sensing part 110 to be exposed to the outside and that the display light can be emitted to the outside of the fire detection device 1. For example, it is set longer than the sum of the diameter of the heat sensing portion 110 and the diameter of the light guide 104a.

Although the insertion hole 120 may be formed by any method, it is formed in a portion other than the central portion of the top surface portion 22. Specifically, as shown in FIG. are doing. In this case, for example, the heat sensing part 110 and the display part may be installed in the part of the substrate 100 corresponding to the insertion hole 120 or in the vicinity thereof. Compared to the case where the insertion hole 120 is formed in the central portion of the top surface portion 22, such a forming method makes it less likely that the heat sensing portion 110 and the display portion will be attached to the heat sensing portion 110 and the display portion. can maintain the mountability of

With such an insertion hole 120, a part of the heat sensing part 110 is accommodated inside the outer cover 20, and another part of the heat sensing part 110 is exposed to the outside of the fire detection device 1 through the insertion hole 120. In addition, the display light from the display unit can be irradiated toward the outside of the fire detection device 1 through the insertion hole 120 .

(Configuration - Details of configuration of outer cover - Guard section)
Returning to FIG. 2, the guard part 130 is guard means for protecting the heat sensing means, and as shown in FIGS. A side rib 133 , a fourth guard side rib 134 , and a guard side connecting portion 135 are provided.

(Structure-Details of structure of outer cover-Guard part-1st guard side rib to 4th guard side rib)
Returning to FIG. 2 , the first guard-side rib 131 , the second guard-side rib 132 , the third guard-side rib 133 , and the fourth guard-side rib 134 are the basic structure of the guard section 130 . The first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 are formed of long plate-like bodies, and are shown in FIGS. As shown, it is provided so as to cover the part of the heat sensing part 110 exposed to the outside of the fire detection device 1 and the periphery of the insertion hole 120 . Specifically, the longitudinal direction of each of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 is provided substantially along the vertical direction. (in FIG. 3, it is provided with a slight inclination), and is erected against the lower surface of the top surface portion 22 .

(Configuration - Details of outer cover configuration - Guard section - Guard side connecting section)
Returning to FIG. 2 , the guard-side connecting portion 135 is connecting means for connecting the first guard-side rib 131 , the second guard-side rib 132 , the third guard-side rib 133 , and the fourth guard-side rib 134 . The guard-side connecting portion 135 is made of, for example, the same material as the outer cover 20, and as shown in FIGS. It is connected to portions near the upper ends of the guard side rib 133 and the fourth guard side rib 134 .

With such a configuration, the insertion hole 120 can be prevented from being exposed to the outside of the fire detection device 1 by the guard portion 130, and the design of the fire detection device 1 can be improved without impairing the inflow of airflow to the guard portion 130. can be maintained.

(Configuration-details of configuration of outer cover-guard section-details of configuration from first guard-side rib to fourth guard-side rib)
Next, details of configurations of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 will be described.

First, the material of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 is arbitrary, but in the embodiment, the first guard-side rib 131 , the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134, the material of some of the ribs is different from the material of the other part of the ribs. Specifically, the first guard-side rib 131 is made of a translucent material (eg, translucent resin material, glass material, etc.), the second guard-side rib 132, the third guard-side rib 133, and the The fourth guard side rib 134 is made of the same material as the outer cover 20 .

With such a configuration, by forming only the first guard-side rib 131 with a light-transmitting material, the display portion housed inside the outer cover 20 can be viewed through the first guard-side rib 131 and the insertion hole 120 . It becomes possible to guide the illuminated display light to the outside of the fire detection device 1 . Therefore, there is no need to provide a display hole in the outer cover 20 for guiding the display light to the outside. 1 can be maintained.

Further, the specific configurations of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 are arbitrary, but in the embodiment, The emitted display light is guided to the outside of the fire detection device 1 through the first guard-side rib 131 . More specifically, it is configured such that, under predetermined conditions, a person can visually recognize the display light when looking up at the fire detection device 1 . Here, the "predetermined condition" is arbitrary, but in the embodiment, as shown in FIG. the person HM is within a predetermined distance D (for example, within 3.0 m) from the fire detection device 1; It corresponds to being lower than the height H1 (eg, 1.8 m).

Specifically, first, the first guard-side rib 131 , the second guard-side rib 132 , the third guard-side rib 133 , and the fourth guard-side rib 134 are provided adjacent to the insertion hole 120 . More specifically, as shown in FIG. 3 , the first guard-side rib 131 is arranged on the right side of the insertion hole 120 , and the second guard-side rib 132 is arranged on the left side of the insertion hole 120 . The third guard-side rib 133 is arranged forward and to the right of the insertion hole 120 , and the fourth guard-side rib 134 is arranged to the rear and right of the insertion hole 120 .

With such a configuration, it becomes possible for a person to visually recognize the display light when looking up at the fire detection device 1 under the predetermined conditions. In particular, the first guard-side rib 131 can function as a light guide while ensuring the strength of the guard portion 130, and display light can be easily viewed in various directions.

Also, the shape of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 (specifically, the shape and size of the rib) is arbitrary. However, in the embodiment, among the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134, some of the ribs have a different shape. It is set to be different from the shape of the rib of the part. Specifically, the vertical lengths of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 are as shown in FIGS. In addition, the vertical length of the portion of the heat sensing portion 110 exposed to the outside of the fire detection device 1 is set longer. Further, with respect to the widths of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134, in the embodiment, they It is set based on experimental results, etc., so that the airflow can be made uniform. As an example, as shown in FIGS. 2 and 4, the width of the second guard side rib 132 may be set smaller than the diameter of the insertion hole 120 and narrower than the other ribs. In the embodiment, the thicknesses of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 are set to It is set based on volume or flow direction. For example, it may be set based on experimental results or the like so that the air currents flowing toward the guard section 130 from each direction can be made uniform. As an example, the thickness of the second guard side rib 132 may be set thinner than the other ribs. Also, the thickness of the third guard-side rib 133 and the fourth guard-side rib 134 may be set thicker than the thickness of the second guard-side rib 132 . Also, the thickness of the first guard-side rib 131 may be set thicker than the other ribs.

With such a configuration, compared to the case where a plurality of ribs have the same shape, it becomes easier to equalize the amount of air flowing into the guard section 130 from each direction according to the installation situation of the fire detection device 1. . Therefore, it becomes possible to improve the inflow property of the airflow of the fire detection device 1 . In addition, the thickness of a plurality of ribs can be set according to the inflow amount or inflow direction of the airflow flowing into the guard portion 130, and the inflow of airflow into the guard portion 130 can be ensured while maintaining the durability of the guard portion 130. can do. In addition, since the first guard-side rib 131 is thicker than the thinnest rib among the plurality of ribs (specifically, it is the thickest rib), the first guard-side rib 131 The display light emitted from the display unit can be easily guided to the outside of the fire detection device 1 while suppressing damage to the fire detection device 1 while improving the durability of the first guard side rib 131. It becomes possible to further maintain the function. In particular, since the first guard-side rib 131 is arranged at the farthest position from the central portion of the top surface portion 22, the thickness of the first guard-side rib 131 is set as described above, so that the guard portion 130 It can contribute to equalization of the inflow amount of the airflow flowing in from each direction, improvement in the design of the fire detection device 1, and improvement in the durability of the guard portion 130. In addition, the second guard-side rib 132 is a rib that is thinner than the thickest rib among the plurality of ribs (specifically, it is the thinnest rib) and is wider than the widest rib. Since each rib has a narrow width (specifically, the rib has the narrowest width), when the insertion hole 120 is provided in a portion other than the central portion of the top surface portion 22, the guard portion 130 can be blocked from each direction. Since it becomes easier to equalize the inflow amount of the inflowing airflow, the inflow of the airflow to the guard portion 130 can be improved.

Although the method for forming the guard portion 130 as described above is arbitrary, in the embodiment, the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, the fourth guard-side rib The rib 134 and the guard-side connecting portion 135 are formed separately. Specifically, the first guard-side ribs 131 are formed by injection-molding a translucent resin material, and the outer cover 20, the second guard-side ribs 132, The third guard-side rib 133, the fourth guard-side rib 134, and the guard-side connecting portion 135 are integrally formed. After that, the first guard-side rib 131 is formed by connecting to the outer cover 20 and the guard-side connecting portion 135 by a fitting structure or the like.

(About the action of the fire detection device)
Next, the operation of the fire detection device 1 configured in this manner will be described.

That is, for example, when the fire detection device 1 is attached to the installation surface 2 , the insertion hole 120 is covered with the guard portion 130 , so that the insertion hole 120 can be prevented from being exposed to the outside of the fire detection device 1 .

Further, for example, in a state where the fire detection device 1 is attached to the installation surface 2, when display light is emitted from the display unit, the display light emitted from the display unit passes through the first guard-side rib 131 to detect fire. Since it is guided to the outside of the device 1, the first guard-side rib 131 can function as the light guide 104a.

(Effect of Embodiment)
As described above, according to the embodiment, among the first guard-side rib 131 to the fourth guard-side rib 134, the material of the first guard-side rib 131 is made different from the material of some of the other ribs. By forming only the first guard-side rib 131 with a light-transmitting material, the light emitted from the display unit housed inside the outer cover 20 through the first guard-side rib 131 and the insertion hole 120 can be blocked. It becomes possible to lead to the outside of the detection device 1 . Therefore, since there is no need to provide a display hole in the outer cover 20 for guiding the light illuminated from the display unit to the outside, the conventional technology (technology in which the protector and the display hole are provided so as to be exposed to the outside) is eliminated. As a result, the design of the fire detection device 1 can be maintained. Further, among the first guard-side rib 131 to the fourth guard-side rib 134, the shape of the first guard-side rib 131 is made different from the shape of some of the other ribs. Compared to the case where the ribs 134 have the same shape, it becomes easier to equalize the amount of air flowing into the guard section 130 from each direction according to the installation situation of the fire detection device 1 . Therefore, it becomes possible to improve the inflow property of the airflow of the fire detection device 1 .

In addition, only the first guard-side rib 131 is formed of a translucent material, and the first guard-side rib 131 is formed so that the light emitted from the display portion is guided to the outside of the fire detection device 1 through the first guard-side rib 131 . Since the fourth guard-side rib 134 is formed from the guard-side rib 131, the first guard-side rib 131 can be made to function as the light guide 104a while ensuring the strength of the guard portion 130, and the light emitted from the display portion can be controlled. can be easily viewed in various directions.

In addition, since the thicknesses of the first guard-side ribs 131 to the fourth guard-side ribs 134 are set based on the inflow amount or the inflow direction of the airflow flowing into the guard section 130, the inflow amount of the airflow flowing into the guard section 130 is Alternatively, the thickness of the first guard-side rib 131 to the fourth guard-side rib 134 can be set according to the inflow direction, and the inflow of airflow to the guard portion 130 can be ensured while maintaining the durability of the guard portion 130. can be done.

Further, since the first guard-side rib 131 is thicker than the thinnest rib among the first guard-side rib 131 to the fourth guard-side rib 134, the first guard-side rib 131 is prevented from being damaged. Since the light emitted from the display unit can be easily guided to the outside of the fire detection device 1 while suppressing the becomes possible.

In addition, since the insertion hole 120 is provided in a portion other than the central portion of the top surface portion 22, compared to the case where the insertion hole 120 is formed in the central portion of the top surface portion 22, the heat sensing portion 110 and the display portion are more easily separated. Since it is less likely to be subject to mounting restrictions, it is possible to maintain the mountability of the heat sensing section 110 and the display section.

The second guard-side rib 132 is thinner than the thickest rib among the first guard-side rib 131 to the fourth guard-side rib 134, and is narrower than the widest rib. Since it is a rib, when the insertion hole 120 is provided in a portion other than the central portion of the top surface portion 22, it becomes easier to equalize the inflow amount of the airflow flowing in from each direction in the guard portion 130. It is possible to improve the inflow of airflow to.

[III] Modifications to the Embodiments Although the embodiments according to the present invention have been described above, specific configurations and means of the present invention are within the scope of the technical ideas of each invention described in the claims. In can be optionally modified and improved. Such modifications will be described below.

(Problem to be solved and effect of invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the contents described above, and may differ depending on the details of the implementation environment and configuration of the invention. or only part of the effects described above.

(About fire detection device)
Although the fire detection device 1 has the inner cover 30 in the above embodiment, the present invention is not limited to this, and the inner cover 30 may be omitted, for example.

(About insertion hole)
In the above-described embodiment, the insertion hole 120 is formed in a portion other than the central portion of the top surface portion 22. However, the present invention is not limited to this. good too.

(Regarding the guard part)
In the embodiment described above, the number of ribs installed in the guard section 130 is four, but the number is not limited to this. For example, there may be only two or only three, or five or more.

Further, in the above embodiment, the material of some of the plurality of ribs is made different from the material of the other part of the ribs, and the shape of some of the plurality of ribs is changed to that of the other part. Although it has been explained that the shape is different from that of the rib, the present invention is not limited to this. For example, the material of some of the ribs may be different from the material of the rest of the ribs, and the ribs may have the same shape. Alternatively, the plurality of ribs may be made of the same material, and the shape of some of the ribs may be different from the shape of the rest of the ribs.

Also, in the above-described embodiment, only the first guard-side rib 131 is made of a translucent material, but the present invention is not limited to this. For example, ribs other than the first guard-side ribs 131 may be made of a translucent material. As an example, at least one of the second guard-side rib 132, the third guard-side rib 133, or the fourth guard-side rib 134 may be made of a translucent material. Alternatively, only two or three of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, or the fourth guard-side rib 134 are formed of a translucent material. You may

Further, in the above-described embodiment, the thicknesses of the first guard-side rib 131, the second guard-side rib 132, the third guard-side rib 133, and the fourth guard-side rib 134 are the same as the thicknesses of the airflow flowing into the guard portion 130. Although it has been explained that the setting is based on the amount or the inflow direction, this is not limiting, and for example, the setting is based on parameters other than the inflow amount and the inflow direction of the airflow (for example, the length of the installation interval of the ribs). may

Although the first guard-side rib 131 is the thickest rib in the above embodiment, it is not limited to this, and may be a rib thinner than the thickest rib, for example.

Further, in the above-described embodiment, the second guard-side rib 132 is the rib with the thinnest thickness and the narrowest width, but it is not limited to this. For example, it may be either the thinnest rib or the narrowest rib. Alternatively, the rib may be thicker than the thinnest rib and wider than the narrowest rib.

(Appendix)
The fire detection device of Supplementary Note 1 is a fire detection device that is attached to an installation surface of an installation target, and is a fire detection device for detecting a fire in a monitoring area. A heat sensing means, wherein part of the heat sensing means is accommodated inside the housing, and a side portion of the housing opposite to the side portion on the installation surface side of the side portion of the housing. a heat sensing means provided so that another part of the heat sensing means is exposed to the outside of the fire detection device through an insertion hole formed in a side portion; guard means provided to cover another part of the means and the periphery of the insertion hole, the guard means having a plurality of ribs, wherein some of the plurality of ribs are made of a material The material of some of the other ribs is made different, or the shape of some of the plurality of ribs is made different from the shape of the other part of the ribs.

Further, the fire detection device of Supplementary Note 2 is, in the fire detection device of Supplementary Note 1, display means provided inside the housing, wherein Display means for displaying predetermined information by irradiating light is provided, only the partial ribs are formed of a translucent material, and the light emitted from the display means is formed of the translucent material. The plurality of ribs are configured to lead to the outside of the fire detection device through the ribs.

Further, in the fire detection device according to appendix 3, in the fire detection device according to appendix 1 or 2, the thickness of the plurality of ribs is set based on the inflow amount or the inflow direction of the airflow flowing into the guard means.

Further, in the fire detection device according to appendix 4, in the fire detection device according to any one of appendices 1 to 3, the rib formed of the translucent material is the thinnest among the plurality of ribs. The rib is thicker than the rib.

Further, in the fire detection device according to appendix 5, in the fire detection device according to any one of appendices 1 to 4, the insertion hole is provided in a portion of the opposite side portion other than the central portion.

Further, the fire detection device according to Supplementary Note 6 is the fire detection device according to Supplementary Note 5, wherein the rib on the central portion side of the opposite side portion among the plurality of ribs is the thickest rib among the plurality of ribs. The rib is thinner than the rib, or the rib is narrower than the widest rib.

(Effect of Supplementary Note)
According to the fire detection device described in Supplementary Note 1, the material of some of the plurality of ribs is made different from the material of some of the other ribs. , it becomes possible to guide the light emitted from the display means accommodated inside the housing to the outside of the fire detection device through the partial rib and the insertion hole. Therefore, since there is no need to provide a display hole in the housing for guiding the light illuminated from the display means to the outside, the conventional technology (technology in which the protector and the display hole are provided so as to be exposed to the outside) can be eliminated. Therefore, it is possible to maintain the design of the fire detection device. In addition, since the shape of some ribs among the plurality of ribs is made different from the shape of the other part of the ribs, compared to the case where the plurality of ribs are made to have the same shape, depending on the installation situation of the fire detection device, This makes it easier to equalize the inflow amount of the airflow that flows into the guard means from each direction. Therefore, it becomes possible to improve the inflow property of the airflow of the fire detection device.

According to the fire detection device described in Supplementary Note 2, only some of the ribs are made of a translucent material, and the light emitted from the display means passes through the ribs made of the translucent material to detect the fire. Since a plurality of ribs are formed so as to guide light to the outside of the detection device, some ribs of the guard means can be made to function as light guides while ensuring the strength of the guard means. It becomes possible to make it easy to visually recognize light in various directions.

According to the fire detection device described in Supplementary Note 3, the thickness of the plurality of ribs is set based on the inflow amount or inflow direction of the airflow flowing into the guard means. The thickness of a plurality of ribs can be set according to the direction, and the inflow of airflow to the guard means can be ensured while maintaining the durability of the guard means.

According to the fire detection device described in appendix 4, the rib formed of the translucent material is thicker than the thinnest rib among the plurality of ribs. The light emitted from the display means can be easily guided to the outside of the fire detection device while suppressing the damage of the ribs formed. However, it is possible to further maintain the display function of the fire detection device.

According to the fire detection device described in Supplementary Note 5, since the insertion hole is provided in a portion other than the central portion of the opposite side portion, compared to the case where the insertion hole is formed in the central portion of the opposite side portion. Therefore, it is possible to maintain the mountability of the heat sensing means and the display means, because the heat sensing means and the display means are less likely to be attached.

According to the fire detection device according to appendix 6, the rib on the central portion side of the opposite side portion among the plurality of ribs is thinner than the thickest rib among the plurality of ribs, or is the thickest rib. Since the ribs are narrower than the ribs with a wide width, when the insertion hole is provided in a portion other than the center portion of the opposite side portion, the inflow amount of the airflow flowing in from each direction in the guard means is uniform. Therefore, the inflow of airflow to the guard means can be improved.

Reference Signs List 1 fire detection device 2 installation surface 10 mounting base 20 outer cover 21 outer cover body 22 top surface 23 first rib 24 second rib 30 inner cover 30a first opening 40 inflow space 50 insect screen 60 detection space 70 detector Cover 70a Second opening 80 Detection unit body 81 Base unit 90 Terminal board 91 Mounting member 100 Board 104a Light guide 110 Heat sensing unit 120 Insertion hole 130 Guard unit 131 First guard rib 132 Second guard rib 133 Third guard Side rib 134 4th guard side rib 135 Guard side connecting portion D Predetermined distance H1 Ceiling height H2 Human eye height HM Person

Claims (1)

A fire detection device that is attached to an installation surface of an installation target, and is a fire detection device for detecting a fire in a monitoring area,
a housing;
a heat sensing means arranged so that at least a part thereof protrudes from a surface of the housing on the monitoring area side and is exposed to the monitoring area side, the heat sensing means for detecting heat associated with the fire;
guard means having a plurality of ribs erected on a surface of the housing on the monitoring area side so as to cover a portion of the heat sensing means exposed to the monitoring area side; guard means for protecting the heat sensing means;
a display means provided inside the housing for displaying predetermined information toward the monitoring area by emitting light;
Of the plurality of ribs of the guard means, some of the ribs are made of a translucent material and some of the ribs are made of a non-translucent material, thereby by guiding the light emitted from the display means to make the predetermined information visible from the monitoring area side ,
The heat sensing means and the guard means are provided on the outer peripheral side from the central portion of the surface on the monitoring area side,
The part of the ribs made of the translucent material is arranged in a portion of the surface on the monitoring area side closer to the outer periphery than the other part of the ribs made of the non-translucent material. ,
The thickness of the part of the ribs made of the translucent material is thicker than the thickness of the other part of the ribs made of the non-translucent material;
Fire detection device.

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