JP7432679B2 - fire detection device - Google Patents

Description

The present invention relates to a fire detection device.

2. Description of the Related Art Conventionally, a technique has been proposed for smoke detectors that detect fires in monitoring areas, in which smoke flows into the interior of the smoke detector and light scattered by the smoke is detected. In this technology, for example, a casing, an inflow space provided inside the casing through which external gas flows in through an opening formed in the casing, and an inside of the casing. A detection space provided in the casing, comprising a detection space provided in parallel with the inflow space along the installation surface, a light emitting part and a light receiving part provided in the detection space, and a labyrinth provided inside the casing. A smoke detector is configured including a labyrinth including a plurality of labyrinth members that surround a detection space at intervals (for example, see Patent Document 1).

JP2006-267128A

However, in the above conventional technology, as described above, the inflow space and the detection space are arranged side by side along the installation surface, so that the disturbance light from outside the casing fills the gap between the labyrinth members. Since there is a possibility that the ambient light directly enters the detection space through the ambient light, it may become difficult to maintain the detection accuracy of a fire detection device such as a smoke detector due to the disturbance light. Therefore, there is room for improvement from the viewpoint of maintaining gas inflow properties and detection accuracy of the fire detection device.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a fire detection device that can maintain gas inflow properties and detection accuracy of the fire detection device.

In order to solve the above-mentioned problems and achieve the purpose, the fire detection device according to claim 1 is a fire detection device attached to the installation surface of an installation object, and is a fire detection device for detecting a fire in a monitoring area. A detection device, which includes an inflow space provided inside the fire detection device into which gas from outside the fire detection device can flow, a detection space for detecting a detection target, and a detection space for detecting a detection target. An incidence suppressing means for suppressing disturbance light from entering the detection space from outside the fire detection device, wherein the gas can flow into the detection space via the inflow space, and the disturbance light an incidence suppressing means that partitions the inflow space and the detection space, and an incident suppression means along the installation surface so that it is possible to suppress direct incidence of the inflow space into the detection space through the inflow space. an opening provided to send the gas flowing into the inflow space to the detection space; and a light emitting device provided inside the incidence suppressing device, the light emitting device being provided inside the incidence suppressing device, a light emitting means for emitting detection light into a space; and a light receiving means provided inside the incidence suppressing means, wherein the detection light emitted from the light emitting means is scattered by the detection target in the detection space. a light-receiving means for receiving scattered light generated by this, and a light-receiving suppressing means provided inside the incident suppressing means, for suppressing the disturbance light that has entered the detection space from being received by the light-receiving means. and a light reception suppressing means, the light reception suppressing means being a plurality of light shielding ribs arranged in parallel at intervals along the incident direction of the detection light, and an insertion opening through which the detection light passes. The detection space is provided on a side opposite to the installation surface with respect to the opening, and the insertion openings of the plurality of light shielding ribs are arranged such that the insertion openings of the plurality of light shielding ribs are arranged as the light shielding ribs extend toward the front side in the incident direction. The light shielding ribs are arranged closer to the outer circumference of the fire detection device than the outer circumference of the opening in the direction along the installation surface.

According to the fire detection device according to claim 1, the detection space for detecting the detection target is provided at a position closer to the installation surface than the inflow space inside the fire detection device. , an incidence suppressing means for suppressing disturbance light from entering the detection space from outside the fire detection device, wherein gas can flow into the detection space via the inflow space, and the disturbance light is prevented from entering the detection space through the inflow space. Since the present invention is equipped with an incidence suppressing means that partitions the inflow space and the detection space so that it is possible to suppress direct incidence into the detection space via the conventional technology (the detection space and the inflow space are on the installation surface) Compared to the technology in which the gas is installed in parallel along the same line, it is possible to suppress the disturbance light from directly entering the detection space through the inflow space while ensuring that the gas flows into the detection space. It becomes possible to maintain the detection accuracy of the fire detection device.
In addition, since the light reception suppressing means is provided inside the incident suppressing means and is for suppressing the light receiving means from receiving disturbance light that has entered the detection space, the light receiving suppressing means detects the disturbance light that has entered the detection space. It is possible to suppress the light receiving means from receiving disturbance light that has entered the space, and it becomes even easier to maintain the detection accuracy of the fire detection device.
In addition, since the insertion openings of the plurality of light-shielding ribs are made smaller toward the front side in the direction of incidence, compared to a case where the insertion openings of the plurality of light-shielding ribs are made larger toward the front side in the direction of incidence, it is easier to pass through these insertion holes. The detection light incident thereon can be suppressed from exiting to the outside through these insertion holes, making it even easier to maintain the detection accuracy of the fire detection device.

FIG. 2 is a side view showing how the fire detection device according to the embodiment is installed. FIG. 3 is a bottom view showing the fire detection device with the mounting base removed. 3 is a sectional view taken along the line AA in FIG. 2. FIG. FIG. 3 is a bottom view showing the main body of the detection section. 4 is a diagram illustrating a situation in which disturbance light enters a detection space from outside the fire detection device via an inflow space, and is a diagram illustrating a region corresponding to FIG. 3. FIG. FIG. 5 is an enlarged view of the region of the light reception suppressing section in FIG. 4;

EMBODIMENT OF THE INVENTION Below, embodiment of the fire detection apparatus based on this invention is described in detail based on drawing. First, [I] the basic concept of the embodiment will be explained, then [II] the specific contents of the embodiment will be explained, and finally [III] modifications to the embodiment will be explained. However, the present invention is not limited to the embodiments.

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

Here, in the embodiment, the "fire detection device" is a device that optically detects and notifies a fire in a monitoring area, and is a concept that includes, for example, an optical fire detector, a fire alarm, etc. . Furthermore, the term "installation object" refers to the object on which the fire detection device is installed, and includes, for example, the ceiling and walls of a building. Furthermore, the term "building" is a concept that includes any specific structure or type, but includes, for example, single-family houses, housing complexes such as apartments and condominiums, office buildings, event facilities, commercial facilities, public facilities, etc. It is. Furthermore, the term "monitoring area" refers to an area to be monitored, and is a concept that includes, for example, an area inside a building, an area outside a building, and the like. Furthermore, "notifying" is a concept that includes, for example, outputting predetermined information to an external device, displaying or audio outputting predetermined information via an output means (display means or audio output means), etc. be. In the following embodiments, the "fire detection device" is an "optical fire detector," the "installation target" is the "ceiling of an office building," and the "monitoring area" is the "office building ceiling." The case where the area is "internal area" will be explained.

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

(composition)
First, the configuration of a fire detection device according to an embodiment will be described. FIG. 1 is a side view showing how the fire detection device according to the embodiment is installed. FIG. 2 is a bottom view showing the fire detection device with a mounting base, which will be described later, removed. FIG. 3 is a cross-sectional view taken along the line AA in FIG. In the following explanation, the X direction in Fig. 1 is the left and 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. 2 is the direction of the fire detection device. The front and back direction (+Y direction is the front of the fire detection device, -Y direction is the rear direction of the fire detection device), the Z direction in Figure 1 is the vertical direction of the fire detection device (+Z direction is the top of the fire detection device, -Z The direction is called the downward direction of the fire detection device). Furthermore, with reference to the center position of the detection space (described later) in FIG. 3, the direction away from the detection space (described later) will be referred to as "outside", and the direction approaching the detection space (described later) will be referred to as "inside".

The fire detection device 1 is a device that detects a detection target (for example, smoke, etc.) contained in a gas and provides notification. This fire detection device 1 is installed indoors in a building on an installation surface 2 on the lower surface of the ceiling of the building, and as shown in FIGS. 1 to 3, includes a mounting base 10, an outer cover 20, an inner cover 30, It includes an inflow space 40, an insect screen 50, a detection space 60, a detection section cover 70, a detection section main body 80, a terminal board 90, and a substrate 100.

(Configuration - mounting base)
Returning to FIG. 1, the mounting base 10 is a mounting means for mounting the outer cover 20 onto 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), and as shown in FIG. It is fixed with a fixture etc.

(Configuration - outer cover)
The outer cover 20 is an incident suppression means for suppressing disturbance light from entering the detection space 60, and includes the inner cover 30, the inflow space 40, the insect net 50, the detection space 60, the detection part cover 70, and the detection part. This is a cover that covers the main body 80, the terminal board 90, and the board 100. Here, "disturbance light" is, for example, light that is incident on the detection space 60 other than the first detection light and the second detection light, which will be described later, and specifically includes sunlight, illumination, etc. This applies to equipment light, etc. The outer cover 20 is made of a light-shielding resin material, for example, and as shown in FIGS. It is equipped with 24.

Among these, the outer cover main body 21 is the basic structure of the outer cover 20. The outer cover main body 21 is formed, for example, of a substantially hollow cylindrical body with open upper and lower surfaces, and as shown in FIG. 1, the upper end of the outer cover main body 21 contacts the lower surface of the mounting base 10. It is arranged as follows and is fixed to the mounting base 10 by a fitting structure (or fixture) or the like.

Further, 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-shaped body, and is provided substantially horizontally below the outer cover main body 21, as shown in FIGS. 1 to 3. Further, as shown in FIG. 2, the top surface portion 22 is provided with a display hole 22a. The display hole 22a is a through hole for guiding light emitted from a display section, which will be described later, to the outside of the fire detection device 1 via the light guide 104a and the display hole 22a shown in FIG.

Further, the first rib portion 23 and the second rib 24 are ribs for partitioning the inflow space 40. These first rib portions 23 and second ribs 24 are each formed of a substantially plate-shaped body, and as shown in FIG. 3, a plurality of them are arranged between the outer cover body 21 and the top surface portion 22, It is connected to the cover main body 21 or the top surface part 22. Note that the above-mentioned "outer cover 20" corresponds to the "second incidence suppressing means" in the claims.

(Configuration - inflow space)
Returning to FIG. 1, the inflow space 40 is a space through which gas from outside the fire detection device 1 flows into the inside of the fire detection device 1. A plurality of these inflow spaces 40 are formed inside the outer cover 20, and specifically, as shown in FIGS. , the second rib portion 24 , and the inner cover 30 define an inflow space 40 .

(Configuration - inner cover)
The inner cover 30 is an incident suppressing means for suppressing disturbance light from entering the detection space 60, and covers the detection space 60, the detection section cover 70, the detection section main body 80, and the substrate 100, and also protects the inflow space. This is a cover for dividing 40. The inner cover 30 is, for example, a substantially hollow cylindrical body with an open top surface, and is made of a light-shielding resin material.As shown in FIG. A lower side portion of the outer cover 30 is provided so as to face the top surface portion 22 of the outer cover 20 with an inflow space 40 interposed therebetween. Further, as shown in FIG. 3, a first opening 30a is provided on the lower side of the inner cover 30. The first opening 30a is an opening for sending the gas flowing into the inflow space 40 to the detection space 60 (that is, an opening for flowing into the inside of the inner cover 30). The first opening 30a is formed to be smaller than the planar shape of the top surface portion 22, and is formed at approximately the center of the lower side of the inner cover 30 and the vicinity thereof, as shown in FIG. It is located. The above-mentioned "inner cover 30" corresponds to the "first incidence suppressing means" in the claims, and the above-mentioned "first opening 30a" corresponds to the "opening" in the claims. do.

(Configuration - detection space)
The detection space 60 is a space for detecting a detection target, and as shown in FIG. It is formed as.

(Configuration - detection unit cover)
The detection unit cover 70 is a partitioning means for partitioning the detection space 60 and is an incident suppression means for suppressing disturbance light from entering the detection space 60. The detection unit cover 70 is a substantially hollow cylindrical body with an open top surface, and is made of a light-shielding resin material. Further, as shown in FIG. 3, in this detection part cover 70, inside the inner cover 30, the lower side part of the detection part cover 70 passes through the first opening 30a and the inflow space 40 to the top of the outer cover 20. It is arranged so as to face the surface part 22 and is fixed to the detection part main body 80. Further, as shown in FIG. 3, a second opening 70a is formed in the lower side portion of the detection section cover 70. The second opening 70a is an opening for the gas sent from the first opening 30a to flow into the detection space 60, and as shown in FIG. 1 opening 30a.

(Composition - Insect net)
The insect net 50 is a net for preventing insects outside the fire detection device 1 from entering the detection space 60. The insect repellent net 50 is constructed using a mesh-like and circular net, and is attached to the detection section cover 70 as shown in FIG. 3.

(Configuration - detection unit main body)
The detection section main body 80 is a mounting means for attaching the detection section cover 70, and is an incident suppression means for suppressing disturbance light from entering the detection space 60. The detection unit main body 80 is a thick plate-shaped body (for example, a substantially circular plate-shaped body) formed of a resin material having light-shielding properties, and is closer to the substrate 100 than the detection unit cover 70 ( Specifically, as shown in FIG. 3, it is arranged to cover the upper surface of the detection unit cover 70, and is fixed to the board 100 with a fixture or the like. has been done.

(Configuration - terminal board)
Returning to FIG. 3, the terminal board 90 is a 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 cylindrical shape with an open bottom surface, and is made of, for example, a light-shielding resin material. Further, as shown in FIG. 3, this 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. The mounting member 91 is fixed to the mounting base 10 through a first mounting hole (not shown) formed in the mounting member 91 using a fixture or the like.

(Configuration - board)
The board 100 is a mounting means on which various electric circuits (not shown) are mounted. This board 100 is configured using, for example, a known flat circuit board, and as shown in FIG. It is arranged approximately horizontally and is 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 on the board 100 known parts (electrical parts) used in the conventional fire detection device 1, the board 100 also includes a first light emitting section, a second light emitting section, a light receiving section, a display section, and a communication section. A power supply unit, a control unit, and a storage unit are mounted (all not shown).

(Configuration - board - first light emitting section, second light emitting section, light receiving section)
Among these, the first light emitting unit is a light emitting unit that irradiates the detection space 60 with detection light (hereinafter referred to as "first detection light"), and uses, for example, a known light emitting element (an example is an infrared LED). It is composed of Further, the second light emitting unit is a light emitting unit that irradiates the detection space 60 with detection light having a different wavelength from the first detection light (hereinafter referred to as “second detection light”), and is, for example, a known light emitting element (for example, It is configured using blue LEDs, etc.). The light receiving section receives the first detection light emitted from the first light emitting section and is scattered by smoke, outputs a first light reception signal corresponding to the received scattered light, and outputs the first detection light emitted from the second light emitting section. It is a light receiving means that receives scattered light of the second detection light with respect to smoke and outputs a second light reception signal corresponding to the received scattered light, for example, using a known light receiving element (for example, a photodiode etc.). It is configured. Furthermore, although the method of installing the first light emitting section, the second light emitting section, and the light receiving section is arbitrary, in the embodiment, the first detection light emitted from the first light emitting section or the second light emitting section or the second detection light emitted from the first light emitting section or the second light emitting section is The arrangement is such that detection light is prevented from directly reaching the light receiving section via various prism lens sections to be described later. 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 approximately 135 degrees. A first light emitting section and a light receiving section are installed at the position. In addition, the second light emitting section and the light receiving section are installed at a position where the angle between the optical axis of the second light emitting section (hereinafter referred to as "second light emitting side optical axis") and the light receiving side optical axis is about 90 degrees. ing.

(Configuration - board - display section, communication section, power supply section)
Further, the display section is configured to display predetermined information (for example, information indicating whether or not a fire has been detected) by emitting light (hereinafter referred to as "display light") toward the outside of the fire detection device 1. This is a display means, and is configured using, for example, a known display means (LED etc.). Furthermore, the method of projecting light from this display section is arbitrary, but for example, the insertion holes (not shown) provided in each of the detection section cover 70, the detection section main body 80, and the inner cover 30, and the outer cover described later. This includes projecting display light from the display section by guiding it toward the outside of the fire detection device 1 through the light guide 104a inserted into the display hole 22a of the 20 display holes 22a. Further, the communication unit is a communication means for communicating with an external device (for example, a receiver, etc.). Further, the power supply unit is a power supply unit that supplies power supplied from a commercial power supply or a battery (not shown) to each part of the fire detection device 1.

(Configuration - board - control section, storage section)
Further, the control unit is a control means for controlling the fire detection device 1. Specifically, this control unit includes a CPU, various programs that are interpreted and executed on the CPU (including basic control programs such as the OS, and application programs that are started on the OS and realizes specific functions), and programs. A computer is equipped with an internal memory such as a RAM for storing various data. Further, the storage unit is a storage means that stores 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 for example, a nonvolatile recording medium such as a flash memory can be used.

(Configuration - Details of the configuration of the detection unit body)
Next, details of the configuration of the detection section main body 80 will be explained. FIG. 4 is a bottom view showing the detection unit main body 80. However, unless otherwise specified, the detection section main body 80 can be manufactured in any shape, method, and material.

In the embodiment, as shown in FIG. 4, the detection section main body 80 is provided with a first prism lens section 81a, a second prism lens section 81b, a third prism lens section 81c, and a chamber section 82. .

(Configuration - Details of the configuration of the main body of the detection unit - 1st prism lens section, 2nd prism lens section, 3rd prism lens section)
The first prism lens section 81a is for changing the direction of the first detection light from the first light emitting section so that the first detection light enters the detection space 60 (specifically, the first prism lens section 81a (The direction of the detection light is changed so that it is approximately parallel to the side surface of the detection section main body 80 on the detection space 60 side.) The first prism lens section 81a is configured using, for example, a known prism lens (the same applies to the second prism lens section 81b and the third prism lens section 81c), as shown in FIG. , is provided in a first chamber section 83, which will be described later. Further, the second prism lens section 81b is for changing the direction of the second detection light from the second light emitting section so that the second detection light enters the detection space 60, as shown in FIG. It is provided in a second chamber section 84, which will be described later. Further, the third prism lens section 81c is for changing the direction of the scattered light received from the detection space 60 so that the scattered light enters the light receiving section, as shown in FIG. 4, as will be described later. It is provided in the third chamber section 85.

(Configuration - Details of the configuration of the detection unit main body - Chamber part)
Returning to FIG. 3, the chamber section 82 is for supporting the first prism lens section 81a, the second prism lens section 81b, the third prism lens section 81c, and the detection section cover 70. As shown in FIGS. 3 and 4, this chamber section 82 is provided on the lower surface of the detection section main body 80, and includes a first chamber section 83, a second chamber section 84, and a third chamber section 85. .

Among these, the first chamber part 83 supports a part of the first prism lens part 81a and the detection part cover 70, and is formed, for example, of a hollow body with an open top and bottom surface. , the same applies to the second chamber section 84 and the third chamber section 85), and is provided at a position corresponding to the first light emitting section, as shown in FIG. Further, as shown in FIG. 4, the first chamber part 83 includes a first entrance port (not shown) for making the first detection light irradiated from the first light emitting part enter the prism lens part 81a, and A first insertion opening 83b is provided through which the first detection light whose direction has been changed by the 1-prism lens portion 81a is inserted into the detection space 60.

Further, the second chamber section 84 supports the second prism lens section 81b and the other part of the detection section cover 70, and is provided at a position corresponding to the second light emitting section, as shown in FIG. ing. Further, as shown in FIG. 4, the second chamber section 84 includes a second entrance port (not shown) for allowing the second detection light emitted from the second light emitting section to enter the second prism lens section 81b. , a second insertion opening 84b for allowing the second detection light whose direction has been changed by the second prism lens portion 81b to enter the detection space 60 by passing through the second detection light.

Further, the third chamber section 85 supports the third prism lens section 81c and the other part of the detection section cover 70, and is provided at a position corresponding to the light receiving section, as shown in FIG. . Further, as shown in FIG. 4, the third chamber part 85 includes a third insertion opening 85a for passing the scattered light from the detection space 60 and making it incident on the third prism lens part 81c, and a third prism lens part 81c. A third entrance port (not shown) is provided for allowing the scattered light whose direction has been changed by the lens portion 81c to enter the light receiving portion.

Although the method for forming the chamber section 82 is arbitrary, for example, the chamber section 82 and the detecting section main body 80 may be integrally formed by injection molding of a resin material having a light-shielding property.

The first prism lens section 81a, the second prism lens section 81b, the third prism lens section 81c, and the detection section cover 70 may be attached in any manner, but for example, from the first prism lens section 81a to the third prism lens section After inserting the lens parts 81c vertically into the first chamber part 83 and the third chamber part 85, a part of the upper part of the detection part cover 70 is fitted into the third chamber part 85 from the first chamber part 83. This also applies to installation, etc.

(Configuration - Incidence suppression structure)
Next, the incidence suppression structure of the fire detection device 1 will be explained. FIG. 5 is a diagram showing a situation in which disturbance light enters the detection space 60 from the outside of the fire detection device 1 via the inflow space 40, and is a diagram showing a region corresponding to FIG. 3. In addition, in FIG. 5, disturbance lights L1 and L2, which will be described later, are shown with imaginary lines. In the embodiment, the characteristics of the incidence suppression structure for suppressing disturbance light from directly entering the detection space 60 are as shown below.

(Configuration - Incidence suppression structure - First feature)
First, regarding the first feature of the incidence suppression structure, at least the outer cover 20 and the inner cover 30 allow gas to flow into the detection space 60 from the outside of the fire detection device 1 via the inflow space 40, and The inflow space 40 and the detection space 60 are partitioned so that disturbance light from outside the device 1 can be prevented from directly entering the detection space 60 via the inflow space 40 . Specifically, as shown in FIG. 5, the outer cover 20 and the inner cover 30 prevent the disturbance light L1 and L2 from entering the detection space 60 through the inflow space 40 and the first opening 30a. It is configured such that L1 and L2 can be reflected multiple times against the outer cover 20 or the inner cover 30. Here, the disturbance light L1 shown on the left side of FIG. 5 will be described as being reflected by the outer cover 20 and the inner cover 30 and incident on the detection space 60, and the disturbance light L2 shown on the right side of FIG. The explanation will be made assuming that the light is reflected by the inner cover 30 and exits the fire detection device 1. However, the present invention is not limited to this, and the disturbance light may have a predetermined incident angle different from the incident angles of the disturbance lights L1 and L2. In the embodiment, the outer cover 20 and the inner cover 30 are configured so that these disturbance lights can be reflected to the outer cover 20 or the inner cover 30 multiple times.

In this case, the specific configuration of the outer cover 20 is arbitrary, but in the embodiment, it is as follows. That is, first, in the configuration of the top surface section 22, the size of the planar shape of the top surface section 22 is set to a length that allows the disturbance light incident on the inflow space 40 at a predetermined angle to be reflected multiple times by the top surface section 22. For example, the size is set to be slightly smaller than the planar size of the outer cover main body 21. Furthermore, regarding the installation method of the top section 22, it is installed at a position corresponding to the lower open end of the outer cover main body 21, and a predetermined amount of gas is introduced from the outside of the fire detection device 1 through the inflow space 40. It is installed at a gap from the lower side of the inner cover 30 so that it can flow into the detection space 60 . Note that the length of this gap may be set based on, for example, experimental results (the same applies to the length of the gap between the first rib portions 23, which will be described later).

Further, the configurations of the first rib portion 23 and the second rib portion 24 are as follows.

That is, first, as shown in FIGS. 3 and 5, the first rib portion 23 and the second rib portion 24 extend in the inflow space 40 along a direction perpendicular to the installation surface 2 (vertical direction in the figure). each is placed. With such a configuration, when the disturbance light enters the detection space 60 via the inflow space 40, the disturbance light can be reflected multiple times against the first rib portion 23 and the second rib portion 24, and the detection Disturbing light incident on the space 60 can be attenuated. In particular, it is possible to prevent disturbance light incident on the installation surface 2 in a direction substantially parallel to the first opening 30a from being reflected multiple times.

Further, the first rib portion 23 and the second rib portion 24 are arranged so that the gas flowing into the inflow space 40 is not obstructed by the first rib portion 23 and the second rib portion 24 from flowing into the first opening portion 30a. It is configured. Specifically, the first rib portion 23 and the second rib portion 24 are arranged radially from near the center of the inner cover 30. In this case, at least one of the first rib part 23 and the second rib part 24 may be arranged at a distance from each other, or may be arranged so as to be in contact with each other, In the embodiment, the first rib portions 23 are arranged at intervals from each other, and the second rib portions 24 are arranged so as to contact each other (specifically, the first rib portions 24 are arranged so as to be in contact with each other). (The ends on the part 30a side are arranged so as to be in contact with each other.) Further, the size of the second rib portion 24 is set to such a size that disturbance light that enters the inflow space 40 at a predetermined angle can be reflected by the second rib portion 24 . For example, the length of the second rib portion 24 in the vertical direction is set to such a length that the tip of the second rib portion 24 is located near the first opening 30a, as shown in FIG. Further, the length of the second rib portion 24 in the front-rear direction is set shorter than the diameter of the top surface portion 22. Further, the thickness of the second rib portion 24 is desirably set to be as thin as possible so as not to narrow the first opening 30a. With the above configuration, it is possible to ensure that the gas flowing into the inflow space 40 flows into the first opening 30a, and it becomes easier to maintain the detection accuracy of the fire detection device 1.

Further, the specific configuration of the inner cover 30 is arbitrary, but in the embodiment, it is as follows. That is, first, the shape and size of the lower side part of the inner cover 30 are set so that the disturbance light incident on the inflow space 40 at a predetermined angle can be reflected multiple times by the lower side part of the inner cover 30. It is set. For example, the planar size of the lower side portion of the inner cover 30 is set to be approximately the same as the planar size of the top surface portion 22. Regarding the side surface shape of the lower side part of the inner cover 30, as shown in FIG. 5, at least part of the lower side part of the inner cover 30 (in FIG. , a portion corresponding to an outer portion of the inlet space 40 (to be described later) is set to be inclined upwardly toward the outside of the inner cover 30. Furthermore, the inner cover 30 is installed at a position where the disturbance light incident on the inflow space 40 at a predetermined angle can be reflected multiple times by the lower side portion of the inner cover 30 and the top surface portion 22. For example, as shown in FIG. 5, the entire lower side portion of the inner cover 30 is installed at a position where it substantially overlaps the top surface portion 22 when viewed from the plane.

Due to this first feature, compared to the conventional technology (technology in which the detection space and the inflow space are arranged side by side along the installation surface), it is possible to ensure that the gas flows into the detection space 60 while allowing the disturbance light to flow in. Direct entry into the detection space 60 via the space 40 can be suppressed, and the detection accuracy of the fire detection device 1 can be maintained. Further, when the disturbance light enters the detection space 60 via the inflow space 40, the disturbance light is transferred to the inner cover 30 (specifically, the lower side of the inner cover 30) or the outer cover 20 (specifically, the lower side of the inner cover 30). , the top surface portion 22, and the second rib portion 24). Therefore, the disturbance light that enters the detection space 60 can be effectively attenuated, and the gas inflow property and the detection accuracy of the fire detection device 1 can be easily maintained.

(Configuration - Incidence suppression structure - Second feature)
Returning to FIG. 3, the second feature of the incidence suppression structure is that the length in the direction (vertical direction) perpendicular to the installation surface 2 in the inner part of the inflow space 40 is uniform, and The inner cover 30 and the outer cover 20 are configured such that the length in the direction perpendicular to the installation surface 2 in the outer portion thereof becomes longer toward the outside. Here, in the embodiment, the "inner part of the inflow space 40" refers to the part of the inflow space 40 that is located from the center to the outside of the outer edge of the first opening 30a (in FIG. This will be explained as a portion extending to a portion corresponding to a portion slightly outside the intermediate portion between the center portion and the outer edge portion of the surface portion 22. In addition, in the embodiment, the "outer portion of the inflow space 40" is described as a portion of the inflow space 40 that extends from a portion located outside the outer edge of the first opening 30a to the outer edge. .

Specifically, as shown in FIG. 3, the top surface portion 22 of the outer cover 20 is formed of a flat plate-shaped body. Further, a portion of the lower side portion of the inner cover 30 corresponding to the inner portion of the inflow space 40 is formed in a flat shape and parallel to the top surface portion 22 . Further, the outer side portion of the inflow space 40 of the lower side portion of the inner cover 30 is formed in an inclined shape that slopes upward toward the outer side of the inner cover 30, as described above. In this case, the first opening 30a is arranged such that the entire first opening 30a faces the inner side of the inflow space 40, and the lower side of the top surface 22 and the inner cover 30 It is arranged parallel to a portion corresponding to the inner portion of the inflow space 40 .

Due to such a second feature, gas flows into the first opening 30a more easily than when the length of the inner portion of the inflow space 40 in the direction orthogonal to the installation surface 2 becomes shorter as it goes inward. It becomes easier to secure sex. Moreover, compared to the case where the length of the inner part of the inflow space 40 in the direction orthogonal to the installation surface 2 becomes longer as it goes inward, the disturbance light is transmitted through the inflow space 40 and the first opening 30a to the detection space. 60 can be suppressed from entering directly. Therefore, it becomes easier to maintain the gas inflow property and the detection accuracy of the fire detection device 1.

(Configuration - light reception suppression structure)
Next, the light reception suppression structure of the fire detection device 1 will be explained. FIG. 6 is an enlarged view of a region of the light reception suppressing section 110 described later in FIG. 4. As shown in FIG. In addition, in FIG. 6, the light-receiving side optical axis LL is shown by an imaginary line. In the embodiment, the features of the light reception suppressing structure for suppressing the disturbance light incident on the detection space 60 from being received by the light receiving unit are as shown below.

That is, as shown in FIG. 6, a light reception suppressing section 110 is provided inside the inner cover 30. Here, the light reception suppressing section 110 is a light reception suppressing means for suppressing the disturbance light that has entered the detection space 60 from being received by the light receiving section. As shown in FIGS. 4 and 6, the light reception suppressing section 110 is provided in the third chamber section (specifically, a portion inside the third prism lens section 81c in the third chamber section). A first light shielding rib 111, a second light shielding rib 112, and a third light shielding rib 113 are provided.

Among these, the first light-shielding rib 111 , the second light-shielding rib 112 , and the third light-shielding rib 113 are ribs for forming the light reception suppressing section 110 . As shown in FIG. 6, these first light-shielding ribs 111, second light-shielding ribs 112, and third light-shielding ribs 113 are generally concave bodies having the third insertion opening 85a substantially orthogonal to the light-receiving side optical axis LL. They are arranged in parallel at intervals along the incident direction of the scattered light (the first detection light or the second detection light) (that is, the axial direction of the light-receiving side optical axis LL). Specifically, the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 are arranged in parallel in this order from the front side toward the back side in the incident direction. Regarding the length of the above-mentioned interval, in the embodiment, it is assumed that the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 allow the light receiving unit to receive the disturbance light having a predetermined incident angle. The length is set to a length that can be suppressed, and may be set based on, for example, experimental results. Note that the above-mentioned "third insertion port 85a" corresponds to the "insertion port" in the claims.

Further, although the specific configuration of the third insertion opening 85a of the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 is arbitrary, in the embodiment, It is set so that it gets smaller as you move towards it. That is, the third insertion hole 85a of the second light shielding rib 112 is set smaller than the third insertion hole 85a of the third light shield rib 113, and the third insertion hole 85a of the first light shield rib 111 is set smaller than the third insertion hole 85a of the second light shield rib 112. It is set smaller than the third insertion opening 85a. As a result, compared to the case where the third insertion holes 85a of the first light shielding rib 111, the second light shielding rib 112, and the third light shielding rib 113 are made larger toward the front side in the incident direction, these third insertion holes 85a are The detection light incident thereon can be suppressed from going out through these third insertion ports 85a, making it easier to maintain the detection accuracy of the fire detection device 1.

Although the method for forming the light reception suppressing section 110 is arbitrary, for example, the light reception suppressing section 110 and the detection section main body 80 may be integrally formed by injection molding of a resin material having light blocking properties. . However, the present invention is not limited to this. For example, the light reception suppressing section 110 and the detecting section main body 80 may be formed separately, and then the light receiving suppressing section 110 may be fixed to the detecting section main body 80 using a fixture or the like.

With such a light reception suppressing structure, the light receiving suppressing section 110 can suppress the light receiving section from receiving the disturbance light that has entered the detection space 60, making it easier to maintain the detection accuracy of the fire detection device 1.

(About the action of fire detection device)
Returning to FIG. 5, the operation of the fire detection device 1 configured in this way will be described next. The fire detection device 1 has two effects: one in response to ambient light (hereinafter referred to as “disturbing light effect”) and the other in response to gas outside the fire detection device 1 (hereinafter referred to as “gas effect”). It is broadly divided into. The disturbance light effect and the gas effect will be explained below.

(About the action of the fire detection device - disturbance light effect)
First, the disturbance light effect will be explained.

That is, for example, when the fire detection device 1 is attached to the installation surface 2 and the disturbance lights L1 and L2 try to enter the detection space 60 via the inflow space 40, as shown in FIG. L1 and L2 are reflected multiple times by the inner cover 30 (specifically, the lower side portion of the inner cover 30) or the outer cover 20 (specifically, the top surface portion 22 and the second rib portion 24). As a result, these disturbance lights L1 and L2 are suppressed from directly entering the detection space 60, compared to the conventional technology (technology in which the detection space and the inflow space are arranged side by side along the installation surface). Thus, the detection accuracy of the fire detection device 1 can be maintained. Further, even if the disturbance light L1 that has been reflected multiple times flows into the detection space 60, the disturbance light L1 is attenuated by the reflection, so even if the disturbance light L1 is received by the light receiving section, the fire detection device 1 The effect on detection accuracy can be reduced.

Furthermore, for example, even if the disturbance light that is not reflected by the inner cover 30 or the outer cover 20 (or the disturbance light that has been reflected multiple times) flows into the detection space 60, the light reception suppressing section 110 (specifically, the The first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113) suppress the disturbance light from entering the light receiving section, making it easier to maintain the detection accuracy of the fire detection device 1.

(About the action of fire detection equipment - gas action)
Next, gas action will be explained.

That is, for example, when the fire detection device 1 is attached to the installation surface 2 and gas from outside the fire detection device 1 attempts to flow into the detection space 60 via the inflow space 40, the inner cover 30 (specifically The inflow space 40 and the first opening are surrounded by the lower side portion of the inner cover 30) and the outer cover 20 (specifically, the top surface portion 22, the first rib portion 23, and the second rib portion 24). 30a and the second opening 70a, a predetermined amount of gas flows into the detection space 60. This makes it possible to maintain the inflow of gas into the detection space 60, similar to the prior art described above.

(Effects of embodiment)
According to the embodiment, the detection space 60 for detecting a detection target is provided at a position closer to the installation surface 2 than the inflow space 40 inside the fire detection device 1. 60, an incidence suppressing means for suppressing disturbance light from entering the detection space 60 from outside the fire detection device 1, which allows gas to flow into the detection space 60 via the inflow space 40; In addition, since it is provided with an incidence suppressing means that partitions the inflow space 40 and the detection space 60 so that it is possible to suppress the disturbance light from directly entering the detection space 60 via the inflow space 40, the conventional technology (Technology in which the detection space and the inflow space are arranged in parallel along the installation surface) This makes it possible to maintain gas inflow properties and the detection accuracy of the fire detection device 1. In addition, the inner cover is configured such that when the disturbance light enters the detection space 60 through the inflow space 40 and the first opening 30a, the disturbance light can be reflected multiple times to the inner cover 30 or the outer cover 20. 30 and the outer cover 20, when the disturbance light enters the detection space 60 via the inflow space 40, the disturbance light can be reflected to the inner cover 30 or the outer cover 20 multiple times. Therefore, the disturbance light that enters the detection space 60 can be effectively attenuated, and the detection accuracy of the fire detection device 1 can be easily maintained.

In addition, the first rib portion 23 and the second rib portion 24 provided in the outer cover 20 are plate-shaped, and the first ribs are respectively arranged along the direction orthogonal to the installation surface 2 in the inflow space 40. Since the section 23 and the second rib section 24 are provided, when the disturbance light enters the detection space 60 via the inflow space 40, the disturbance light is directed against the first rib section 23 and the second rib section 24 multiple times. It can be reflected, and the disturbance light incident on the detection space 60 can be attenuated. In particular, it is possible to prevent disturbance light incident on the installation surface 2 in a direction substantially parallel to the first opening 30a from being reflected multiple times. In addition, the first rib portion 23 and the second rib portion 24 are arranged so that the gas flowing into the inflow space 40 is not obstructed by the first rib portion 23 and the second rib portion 24 from flowing into the first opening 30a. With this configuration, it is possible to ensure that the gas flowing into the inflow space 40 flows into the first opening 30a, and it becomes easier to maintain the detection accuracy of the fire detection device 1.

Further, the first opening 30a is arranged such that the entire first opening 30a faces the inner part of the inflow space 40, and the length of the inner part of the inflow space 40 in the direction perpendicular to the installation surface 2 is Since the inner cover 30 and the outer cover 20 are configured so that the length of the inner cover 30 and the outer cover 20 are uniform and the length in the direction orthogonal to the installation surface 2 in the outer part of the inflow space 40 becomes longer toward the outside, the inner cover of the inflow space 40 Compared to a case where the length of the portion in the direction orthogonal to the installation surface 2 becomes shorter as it goes inward, it is easier to ensure gas flow into the first opening 30a. Moreover, compared to the case where the length of the inner part of the inflow space 40 in the direction orthogonal to the installation surface 2 becomes longer as it goes inward, the disturbance light is transmitted through the inflow space 40 and the first opening 30a to the detection space. 60 can be suppressed from entering directly. Therefore, it becomes easier to maintain the gas inflow property and the detection accuracy of the fire detection device 1.

Further, since the light reception suppressing section 110 provided inside the inner cover 30 is provided to suppress the disturbance light incident on the detection space 60 from being received by the light receiving section, the light reception is suppressed. The part 110 can suppress the disturbance light that has entered the detection space 60 from being received by the light receiving part, making it even easier to maintain the detection accuracy of the fire detection device 1.

Moreover, since the third insertion openings 85a of the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 are made smaller toward the front side in the incident direction, the first light-shielding rib 111, the second light-shielding rib 112 and the third insertion opening 85a of the third light-shielding rib 113 are enlarged toward the front side in the direction of incidence. This makes it easier to maintain the detection accuracy of the fire detection device 1.

[III] Modifications to the Embodiments The embodiments of the present invention have been described above, but the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. can be arbitrarily modified and improved. Hereinafter, such a modified example will be explained.

(About the problems to be solved and the effects of the invention)
First of all, the problems to be solved by the invention and the effects of the invention are not limited to the above-mentioned contents, but may differ depending on the implementation environment of the invention and the details of the configuration, and only some of the problems described above can be solved. In some cases, the above-mentioned effects may be solved or only some of the above-mentioned effects may be achieved.

(About fire detection device)
In the above embodiment, it has been described that the fire detection device 1 includes the inner cover 30, but the present invention is not limited to this, and for example, the inner cover 30 may be omitted. In this case, for example, a portion of the lower side of the outer cover 20 may be configured to function similarly to the lower side of the inner cover 30. That is, the shape and size of a portion of the lower side of the outer cover 20 are substantially the same as those of the lower side of the inner cover 30, so that the disturbance light incident on the inflow space 40 at a predetermined angle is The lower side portion may be configured to allow multiple reflections.

Further, in the above embodiment, it has been described that the fire detection device 1 includes the light reception suppressing section 110, but the present invention is not limited to this, and for example, the light receiving suppressing section 110 may be omitted.

Further, in the above embodiment, it has been explained that the fire detection device 1 includes the first light emitting section and the second light emitting section, but the invention is not limited to this, and for example, either the first light emitting section or the second light emitting section or one may be omitted.

(About the first rib part and the second rib part)
In the embodiment described above, the first rib portion 23 and the second rib portion 24 are described as being provided on the outer cover 20, but the present invention is not limited thereto, and they may be provided on the inner cover 30, for example.

(About the detection unit body)
In the embodiment described above, it has been explained that the detection section main body 80 is provided with the first prism lens section 81a, the second prism lens section 81b, the third prism lens section 81c, and the chamber section 82, but the present invention is not limited to this. First, for example, the first prism lens section 81a, the second prism lens section 81b, the third prism lens section 81c, and the chamber section 82 may be omitted. In this case, although the specific configuration of the detection unit main body 80 is arbitrary, for example, the detection unit main body 80 has a support portion for supporting each of the first light emitting unit, the second light emission unit, and the light receiving unit. may be provided respectively. Further, optical path holes for forming optical paths between each of the first light emitting section, the second light emitting section, and the light receiving section and the detection space 60 may be formed in the detection section main body 80. With such a configuration, it is possible to detect a detection target in substantially the same way as in the above embodiment.

(About the light reception suppressor)
In the embodiment described above, it has been described that the light reception suppressing section 110 includes three light shielding ribs (the first light shielding rib 111, the second light shielding rib 112, and the third light shielding rib 113), but the present invention is not limited thereto. For example, two or less light-shielding ribs may be provided, or four or more light-shielding ribs may be provided.

Further, in the above embodiment, the third insertion openings 85a of the first light shielding rib 111, the second light shielding rib 112, and the third light shielding rib 113 are set to become smaller toward the front side in the incident direction. However, it is not limited to this. For example, the third insertion openings 85a of the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 may be set to become larger toward the front side in the incident direction. Alternatively, the third insertion openings 85a of the first light-shielding rib 111, the second light-shielding rib 112, and the third light-shielding rib 113 may be set uniformly large.

(Additional note)
The fire detection device in Appendix 1 is a fire detection device that is attached to the installation surface of an installation object, and is a fire detection device for detecting fire in a monitoring area, and is a fire detection device that detects fire in a monitoring area. The space includes an inflow space into which gas from outside the fire detection device can flow, and a detection space for detecting a detection target, the installation surface being larger than the inflow space inside the fire detection device. a detection space provided at a side position; and an incidence suppressing means for suppressing disturbance light from entering the detection space from outside the fire detection device, the gas passing through the inflow space into the detection space. an incidence suppressing means that partitions the inflow space and the detection space so that the disturbance light can flow into the detection space and can suppress the disturbance light from directly entering the detection space via the inflow space; , the incidence suppression means is a first incidence suppression means that accommodates the detection space and is configured to partition a part of the inflow space; A second incidence suppressing means that accommodates an incidence suppressing means and is configured to partition another part of the inflow space, and a side portion of the first incident suppressing means. an opening provided on a side opposite to a side on the installation surface side for causing the gas that has flowed into the inflow space to flow into the first incidence suppressing means; and when the disturbance light enters the detection space through the inflow space and the opening, the disturbance light can be reflected multiple times to the first incidence suppression means or the second incidence suppression means. The first incidence suppressing means and the second incidence suppressing means were configured so that

Further, the fire detection device according to Supplementary note 2 is the fire detection device according to Supplementary note 1, in which a plurality of plate-shaped ribs are provided on the first incidence suppression means or the second incidence suppression means, and in the inflow space. comprising a plurality of ribs respectively arranged along a direction perpendicular to the installation surface, so that the gas flowing into the inflow space is not obstructed by the plurality of ribs from flowing into the opening; The plurality of ribs were configured.

Further, in the fire detection device according to appendix 3, in the fire detection device according to appendix 1 or 2, the opening is arranged so that the entire opening faces the inner part of the inflow space, and The length of the inner part in the direction perpendicular to the installation surface is uniform, and the length of the outer part of the inflow space in the direction perpendicular to the installation surface becomes longer toward the outside. The first incidence suppression means and the second incidence suppression means were configured.

Further, the fire detection device according to appendix 4 is a light emitting means provided inside the first incident suppressing means in the fire detection device according to any one of appendices 1 to 3, and the fire detection device is a light emitting means provided inside the first incident suppressing means, and which detects light in the detection space. a light emitting means for emitting light; and a light receiving means provided inside the first incidence suppressing means, wherein the detection light emitted from the light emitting means is scattered by the detection target within the detection space. a light receiving means for receiving scattered light generated in the detection space; and a light reception suppressing means provided inside the first incident suppressing means, the light receiving suppressing means suppressing the disturbance light that has entered the detection space from being received by the light receiving means. and a light reception suppressing means.

Further, in the fire detection device according to appendix 5, in the fire detection device according to appendix 4, the light reception suppressing means includes a plurality of light shielding ribs arranged in parallel at intervals along the incident direction of the detection light. A plurality of light-shielding ribs are provided, each having an insertion opening through which the detection light passes, and the insertion openings of the plurality of light-shielding ribs are made smaller toward the front side in the incident direction.

(Effect of appendix)
According to the fire detection device described in Supplementary note 1, a detection space for detecting a detection target, which is provided inside the fire detection device at a position closer to the installation surface than the inflow space; An incidence suppressing means for suppressing disturbance light from entering the detection space from outside the fire detection device, wherein gas can flow into the detection space via the inflow space, and the disturbance light can enter the detection space through the inflow space. Since the present invention is equipped with an incidence suppressing means that partitions the inflow space and the detection space so that it is possible to suppress direct incidence into the detection space through the conventional technology (the detection space and the inflow space are Compared to technology that is installed in parallel at It becomes possible to maintain the detection accuracy of the detection device. Furthermore, when the disturbance light enters the detection space via the inflow space and the opening, the first incident Since the suppression means and the second incidence suppression means are configured, when the disturbance light enters the detection space via the inflow space, the disturbance light is reflected multiple times to the first incidence suppression means or the second incidence suppression means. be able to. Therefore, the disturbance light that enters the detection space can be effectively attenuated, making it easier to maintain the detection accuracy of the fire detection device.

According to the fire detection device described in Supplementary note 2, the plurality of plate-shaped ribs provided on the first incidence suppression means or the second incidence suppression means extend along the direction orthogonal to the installation surface in the inflow space. Since a plurality of ribs are arranged respectively, when the disturbance light enters the detection space via the inflow space, the disturbance light can be reflected multiple times against the plurality of ribs, and the disturbance light enters the detection space. Disturbing light can be attenuated. In particular, disturbance light incident in a direction substantially parallel to the installation surface can be prevented from being reflected multiple times and entering the opening. In addition, the multiple ribs are configured so that the gas flowing into the inflow space is not obstructed by the multiple ribs, ensuring that the gas flowing into the inflow space can flow into the opening. This makes it easier to maintain the detection accuracy of the fire detection device.

According to the fire detection device described in Appendix 3, the opening is arranged so that the entire opening faces the inner part of the inflow space, and the length in the direction perpendicular to the installation surface in the inner part of the inflow space is Since the first incidence suppressing means and the second incidence suppressing means are configured so that the direction perpendicular to the installation surface in the outer part of the inflow space becomes uniform, and the length in the direction perpendicular to the installation surface in the outer part of the inflow space becomes longer toward the outside, the inflow space Compared to a case where the length in the direction perpendicular to the installation surface of the inner portion becomes shorter toward the inner side, it is easier to ensure gas flow into the opening. In addition, compared to a case where the length of the inside part of the inflow space in the direction orthogonal to the installation surface becomes longer as it goes inward, the disturbance light directly enters the detection space through the inflow space and the opening. can be suppressed. Therefore, it becomes easier to maintain the gas inflow property and the detection accuracy of the fire detection device.

According to the fire detection device described in Supplementary note 4, the light reception suppressing means provided inside the first incident suppressing means is a light receiving means for suppressing the light receiving means from receiving disturbance light that has entered the detection space. Since the suppressing means is provided, the light reception suppressing means can suppress the light receiving means from receiving the disturbance light that has entered the detection space, making it easier to maintain the detection accuracy of the fire detection device.

According to the fire detection device described in Appendix 5, the insertion openings of the plurality of light shielding ribs were made smaller as they went toward the front in the direction of incidence, and the insertion openings of the plurality of light shielding ribs were made larger as they went toward the front in the direction of incidence. Compared to the case where the detection light enters through these insertion holes, it can be suppressed from going out through these insertion holes, and the detection accuracy of the fire detection device can be maintained even more easily.

1 Fire detection device 2 Installation surface 10 Mounting base 20 Outer cover 21 Outer cover body 22 Top section 22a Display hole 23 First rib section 24 Second rib section 30 Inner cover 30a First opening 40 Inflow space 50 Insect screen 60 Detection space 70 Detection section cover 70a Second opening 80 Detection section main body 81a First prism lens section 81b Second prism lens section 81c Third prism lens section 82 Chamber section 83 First chamber section 83b First insertion port 84 Second chamber section 84b 2nd insertion port 85 3rd chamber portion 85a 3rd insertion port 90 Terminal board 91 Mounting member 100 Board 104a Light guide 110 Light reception suppressing portion 111 1st light shielding rib 112 2nd light shielding rib 113 3rd light shielding rib L1, L2 Ambient light LL Receiving side optical axis

Claims (1)

A fire detection device that is attached to the installation surface of an installation target, and is a fire detection device for detecting fire in a monitoring area,
an inflow space provided inside the fire detection device, into which gas from outside the fire detection device can flow;
a detection space for detecting a detection target;
An incidence suppressing means for suppressing disturbance light from entering the detection space from outside the fire detection device, wherein the gas can flow into the detection space via the inflow space, and the disturbance light is prevented from entering the detection space from outside the fire detection device. an incidence suppressing means that partitions the inflow space and the detection space so that light can be suppressed from directly entering the detection space through the inflow space;
an opening provided along the installation surface in the incidence suppressing means, the opening for sending the gas flowing into the inflow space to the detection space;
a light emitting means provided inside the incidence suppressing means, the light emitting means irradiating the detection space with detection light;
a light receiving means provided inside the incidence suppressing means, the light receiving means receiving scattered light generated when the detection light irradiated from the light emitting means is scattered by the detection target in the detection space; ,
A light reception suppressing means provided inside the incident suppressing means, the light receiving suppressing means for suppressing the disturbance light incident on the detection space from being received by the light receiving means,
The light reception suppressing means includes a plurality of light shielding ribs arranged in parallel at intervals along the incident direction of the detection light, each of which has an insertion opening through which the detection light passes. ,
The detection space is provided on a side opposite to the installation surface with respect to the opening,
The insertion openings of the plurality of light shielding ribs are made smaller toward the front side in the incident direction,
The plurality of light shielding ribs are arranged closer to the outer circumference of the fire detection device than the outer circumference of the opening in the direction along the installation surface.
Fire detection device.

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