JP6350934B2 - Combined fire detector - Google Patents

Description

  The present invention relates to a composite fire detector that detects a fire based on changes in carbon monoxide concentration, smoke concentration, and temperature.

  Conventionally, a composite sensor capable of detecting smoke concentration, temperature, and carbon monoxide has been proposed as this type of composite fire sensor (Patent Document 1).

  The composite sensor described in Patent Document 1 has a configuration in which a scattered light type smoke sensor, a heat sensor, and a carbon monoxide sensor are provided in one body.

Japanese Patent Laid-Open No. 7-254096

  Patent Document 1 does not describe a specific structure of the composite sensor.

  The present invention has been made in view of the above reasons, and an object of the present invention is to provide a composite fire detector capable of widening the detection area with a simple structure.

  The composite fire detector of the present invention includes a housing, a carbon monoxide detector that detects carbon monoxide, a smoke detector that detects smoke, and a heat detector that detects heat. In the composite fire detector of the present invention, the carbon monoxide detector, the smoke detector, and the heat detector are arranged at different heights in the casing. The casing has a circular outer peripheral shape. The casing has a plurality of carbon monoxide inlets formed at equal intervals in the outer peripheral direction of the casing. In the composite fire detector of the present invention, a plurality of smoke inlets are formed at equal intervals in the outer peripheral direction of the casing, and a plurality of heat inlets are formed at equal intervals in the outer peripheral direction of the casing.

  In this composite fire detector, the housing includes a base and a cover that is disposed on the lower side of the base and covers the carbon monoxide detector, the smoke detector, and the heat detector. The base includes a bottomed cylindrical base body made of synthetic resin. The cover is made of a synthetic resin. The cover includes a bottomed cylindrical upper cover part and a bottomed cylindrical lower cover part projecting downward from a peripheral part of an opening at a central part of the bottom wall of the upper cover part. The cover integrally includes a plurality of spacers that protrude upward from the upper end edge of the upper cover portion and maintain a distance between the upper end edge and the bottom wall of the base body at a specified distance. The plurality of spacers are formed at equal intervals in the circumferential direction of the upper end edge of the upper cover portion. In this composite fire detector, the two spacers adjacent to each other in the outer peripheral direction of the housing among the plurality of spacers, the upper end edge of the upper cover portion, and the bottom wall of the base body are surrounded. This space constitutes the carbon monoxide inlet.

  In this composite fire sensor, the base includes a plurality of reinforcing structures that reinforce the base body. The reinforcing structures are arranged radially.

  In this composite fire sensor, the total number of the plurality of carbon monoxide inlets is eight. In this composite fire sensor, the horizontal cross section of the casing including the plurality of carbon monoxide inlets is surrounded by both ends of the spacer between the adjacent carbon monoxide inlets and the center of the casing. The reinforcing structure is arranged in each of the eight fan-shaped regions.

  In the composite fire sensor of the present invention, a plurality of carbon monoxide inlets are formed in the casing at equal intervals in the outer peripheral direction of the casing. In the composite fire detector of the present invention, a plurality of smoke inlets are formed at equal intervals in the outer peripheral direction of the casing, and a plurality of heat inlets are formed at equal intervals in the outer peripheral direction of the casing. Therefore, the composite fire detector of the present invention can have a simple structure and a wide detection area.

FIG. 1 is a schematic cross-sectional view showing a composite fire sensor according to an embodiment. FIG. 2 is a schematic side view showing the composite fire sensor of the embodiment. FIG. 3 is a schematic perspective view showing the composite fire sensor of the embodiment. FIG. 4 is a schematic plan view showing the composite fire sensor of the embodiment. FIG. 5 is a schematic bottom view showing the composite fire sensor of the embodiment. FIG. 6 is a schematic cross-sectional view taken along the line XX of FIG. 5, showing the composite fire sensor of the embodiment. FIG. 7 is a schematic cross-sectional view taken along the line BB of FIG. 2, showing the composite fire sensor of the embodiment. FIG. 8 is a schematic cross-sectional view taken along the line C-C in FIG. 2, showing the composite fire sensor of the embodiment. FIG. 9 is a schematic cross-sectional view taken along the line D-D of FIG. 2, showing the composite fire sensor of the embodiment. Fig.10 (a) is the schematic perspective view which showed the attachment base in the composite fire sensor of embodiment, and was seen from the upper side. FIG.10 (b) is the schematic perspective view which showed the attachment base in the composite fire sensor of embodiment, and was seen from the lower side. FIG. 11 is a schematic perspective view of the composite fire sensor according to the embodiment with a cover removed. FIG. 12 is a schematic plan view of a cover in the composite fire sensor of the embodiment. FIG. 13 is a schematic bottom view of the main part of the composite fire sensor of the embodiment.

  Below, the composite fire detector 1 of this embodiment is demonstrated based on FIGS. 1 is a schematic YY sectional view of FIG.

  The composite fire detector 1 includes a housing 3, a carbon monoxide detector 4 that detects carbon monoxide, a smoke detector 5 that detects smoke, and a heat detector 6 that detects heat. In the composite fire detector 1, the carbon monoxide detector 4, the smoke detector 5, and the heat detector 6 are arranged at different height positions in the housing 3. The casing 3 has a circular outer periphery. The casing 3 has a plurality of carbon monoxide inlets 37 formed at equal intervals in the outer peripheral direction of the casing 3. In the composite fire detector 1, a plurality of smoke inlets 38 are formed at equal intervals in the outer peripheral direction of the casing 3, and a plurality of heat inlets 39 are formed at equal intervals in the outer peripheral direction of the casing 3. Therefore, the composite fire detector 1 has a simple structure and can widen the detection area.

  Each component of the composite fire detector 1 will be described below.

  The composite fire detector 1 is an exposed type and can include an attachment base 2 (see FIGS. 3 and 10) that is fixed to a ceiling material or the like in a building with two first screws (not shown). The housing 3 can be detachably attached to the attachment base 2.

  As shown in FIG. 10, the mounting base 2 includes a mounting base body 20 formed in a disk shape. The mounting base body 20 is made of synthetic resin. A first hole 21 through which an electric wire led out from a through hole formed in a ceiling material or the like can be passed is formed in the central portion of the mounting base body 20.

  The mounting base 2 is integrally provided with an annular frame portion 20 b that protrudes downward from the peripheral portion of the lower surface 20 a of the mounting base body 20. The outer diameter of the frame portion 20 b is set smaller than the outer diameter of the mounting base body 20.

  In the mounting base 2, a first terminal block 23 a and a second terminal block 23 b are arranged on the lower surface 20 a of the mounting base body 20. The first terminal block 23a accommodates two quick connection terminals (not shown) to which electric wires are respectively connected. The second terminal block 23b accommodates two quick connection terminals to which electric wires are respectively connected. The first terminal block 23a and the second terminal block 23b are arranged with the first hole 21 in between.

  The attachment base 2 has four contact portions 25 to which the first connection pieces 35a of the four connection plates 35 (see FIGS. 1 and 4) provided on the housing 3 are connected to the lower surface 20a of the attachment base body 20 respectively. Has been placed. Each contact portion 25 is formed of a conductive plate. The four contact portions 25 are electrically connected to the two quick connection terminals of the first terminal block 23a, and the remaining two contact portions 25 are connected to the two speed connections of the second terminal block 23b. It is electrically connected to the terminal. The contact portion 25 includes a pair of leaf spring pieces 26, 26, and a first connection piece 35a inserted between the pair of leaf spring pieces 26, 26 is electrically and mechanically connected.

  In the mounting base 2, two insertion holes 22 through which the two first screws are passed are formed in the mounting base main body 20. The insertion hole 22 is continuously formed by a circular opening 22a through which the head of the first screw can pass and an arcuate slit 22b that passes through the shaft of the first screw and does not pass through the head. Has been.

  As shown in FIGS. 1 to 3 and 6, the housing 3 includes a base 31 and a cover 32 that is disposed below the base 31 and covers the carbon monoxide detector 4, the smoke detector 5, and the heat detector 6. .

  The base 31 includes a bottomed cylindrical base body 31a (see FIGS. 1 to 4 and 6 to 11) formed of a synthetic resin. The cover 32 is made of a synthetic resin. As shown in FIGS. 1 to 3, 5 and 6, the cover 32 protrudes downward from the peripheral portion of the bottomed cylindrical upper cover portion 32 a and the opening 32 c at the center of the bottom wall 32 b of the upper cover portion 32 a. And a bottomed cylindrical lower cover portion 32d. The cover 32 is integrally provided with a plurality of spacers 321 that protrude upward from the upper end edge 32aa of the upper cover portion 32a and that keep the distance between the upper end edge 32aa and the bottom wall 31aa of the base body 31a at a specified distance. The plurality of spacers 321 are formed at equal intervals in the circumferential direction of the upper end edge 32aa of the upper cover portion 32a. The composite fire detector 1 is surrounded by two spacers 321 adjacent to each other in the outer circumferential direction of the housing 3 among the plurality of spacers 321, an upper edge 32aa of the upper cover portion 32a, and a bottom wall 31aa of the base body 31a. This space constitutes a carbon monoxide inlet 37. Therefore, the composite fire sensor 1 is a slide for forming the carbon monoxide inlet 37 in the first molding die for molding the base body 31a and the second molding die for molding the cover 32. There is no need to provide a complicated structure such as a slide structure including a core. For this reason, the composite fire detector 1 can be reduced in cost. The carbon monoxide inlet 37 is an inlet through which carbon monoxide flows, but also functions as an outlet from which carbon monoxide flows out.

  In the cover 32, the outer diameter of the upper end edge 32aa of the upper cover portion 32a is substantially equal to the outer diameter of the base body 31a.

  In the housing 3, the base 31 and the cover 32 are joined by two second screws 33 (see FIG. 4).

  The base 31 has an insertion hole 317 (see FIG. 11) through which the second screw 33 is passed through the bottom wall of the bottomed cylindrical first boss 316 (see FIGS. 7 and 11) protruding downward from the bottom wall 31aa of the base body 31a. ) Is formed. The inner diameter of the first boss 316 is set larger than the outer diameter of the head of the second screw 33. Further, as shown in FIG. 12, the cover 32 is provided with a columnar second boss 325 in which a screw hole 326 into which the shaft portion of the second screw 33 is fitted is projected. The second boss 325 is integrally formed via a connecting piece 327 extending from the peripheral wall 32ab of the upper cover portion 32a of the cover 32 in the radial direction of the peripheral wall 32ab.

  The base 31 includes the above-described four connection plates 35 held by the base main body 31a. The four connection plates 35 are provided so as to penetrate the bottom wall 31aa of the base body 31a, and a portion protruding upward from the bottom wall 31aa of the base body 31a constitutes a first connection piece 35a. Each connection plate 35 is formed of a conductive plate.

  The inner diameter of the base body 31 a is slightly larger than the outer diameter of the frame portion 20 b of the mounting base 2. The outer diameter of the base body 31 a is preferably substantially the same as the outer diameter of the mounting base body 20 of the mounting base 2.

  The bottom wall 31aa of the base body 31a is formed in a shape that swells upward. Further, the base body 31a has a plurality of second holes 34 (see FIGS. 1, 4 and 8) extending over the bottom wall 31aa and the lower end of the peripheral wall 31ab. The plurality of second holes 34 are arranged at equal intervals in the circumferential direction of the base body 31a. The second hole 34 is provided as a discharge hole for discharging gas, water, and the like in the internal space of the base body 31a.

  As shown in FIG. 4, the base 31 includes one first protrusion 301 and two second protrusions for detachably attaching the housing 3 to the attachment base 2 on the inner peripheral surface of the peripheral wall 31ab of the base body 31a. Two protrusions 302 and three third protrusions 303 are provided. The first protrusion 301, the second protrusion 302, and the third protrusion 303 have different lengths in the circumferential direction of the peripheral wall 31ab of the base body 31a.

  On the other hand, as shown in FIG. 10, the mounting base 2 described above has a first recess 201 into which the first protrusion 301 can be inserted from below on the outer peripheral surface of the frame portion 20 b. In addition, the mounting base 2 is formed with two second recesses 202 on the outer peripheral surface of the frame portion 20b in which each of the second protrusions 302 can be inserted from below. Further, the mounting base 2 is formed with three third recesses 203 into which the respective third protrusions 303 can be inserted from below. In addition, the mounting base 2 has an arc shape on the outer peripheral surface of the frame portion 20b, on the upper side of the first recess portion 201, and communicates with the first recess portion 201 so that the first protrusion 301 can move along the circumferential direction of the frame portion 20b. The first groove 211 is formed. Further, the mounting base 2 moves on the outer peripheral surface of the frame portion 20b above the two second concave portions 202, and communicates with the second concave portions 202 and moves the second protrusions 302 along the circumferential direction of the frame portion 20b. An arcuate second groove 212 is formed. Further, the mounting base 2 moves along the circumferential direction of the frame portion 20b on the outer peripheral surface of the frame portion 20b, above the three third recess portions 203, and communicates with the respective third recess portions 203. An arcuate third groove (not shown) is formed.

  When a contractor or the like attaches the housing 3 to the attachment base 2, first, the first protrusion 301, each second protrusion 302, and each third protrusion 303 are replaced with the first recess 201, each second recess 202, and Each third recess 203 is inserted into the first groove 211, the second groove 212, and the third groove. Then, the contractor or the like can attach the casing 3 to the mounting base 2 by rotating the casing 3 in the clockwise direction when viewed from the contractor or the like.

  In the composite fire detector 1, a circuit module 9 including a carbon monoxide detector 4, a smoke detector 5, and a heat detector 6 is housed in a housing 3.

  The circuit module 9 includes a fire detection circuit (not shown) that determines whether or not a fire has occurred based on the outputs of the carbon monoxide detector 4, the smoke detector 5, and the heat detector 6.

  The circuit module 9 includes a first printed circuit board 7 and a second printed circuit board 8 that are arranged apart in the vertical direction. In the circuit module 9, a second printed circuit board 8 is disposed below the first printed circuit board 7. In the circuit module 9, the first printed circuit board 7 is fixed to the base 31. In the circuit module 9, the first printed circuit board 7 and the second printed circuit board 8 are electrically connected by a plurality of lead wires 10 (see FIG. 7). The first printed circuit board 7 and the second printed circuit board 8 are double-sided printed circuit boards. The color of the lower surface 7a of the first printed circuit board 7 and the lower surface 8a of the second printed circuit board 8 is black.

  As shown in FIGS. 1, 7, 9 and 11, the above-described base 31 has an annular first rib 311 and an annular shape having a larger inner diameter than the first rib 311 on the lower surface of the bottom wall 31 aa of the base body 31 a. The second rib 312 is projected. The first printed circuit board 7 is disposed inside the first rib 311. The base 31 is formed with a fourth protrusion 313 for positioning the first printed circuit board 7 on the lower surface of the bottom wall 31aa of the base body 31a. A cutout 72 through which the fourth protrusion 313 passes is formed on the side surface of the first printed circuit board 7.

  The base 31 has two first posts 319 and two second posts 318 protruding from the lower surface of the bottom wall 31aa of the base body 31a. The two first posts 319 are in contact with both ends of the second printed circuit board 8 in the longitudinal direction (vertical direction in FIG. 13). The two second posts 318 are in contact with both ends of the second printed circuit board 8 in the short direction (left and right direction in FIG. 13). A part of the first post 319 is inserted into the through hole 82 (see FIG. 11) of the second printed circuit board 8.

  As shown in FIGS. 6 and 12, the cover 32 is integrally formed with an annular third rib 323 that protrudes upward from the upper surface of the bottom wall 32b of the upper cover portion 32a. In the circuit module 9, the second printed circuit board 8 is disposed inside the third rib 323.

  Further, the cover 32 protrudes upward from the upper surface of the bottom wall 32b of the upper cover portion 32a, and a positioning projection 324 for positioning the second printed circuit board 8 is integrally formed. On the side surface of the second printed circuit board 8, notches 83 (see FIG. 11) through which the positioning protrusions 324 pass are formed in two places.

  The four connection plates 35 described above are electrically connected to the first printed circuit board 7. Each of the four connection plates 35 is integrally provided with a first connection piece 35a, a second connection piece 35b, and an intermediate portion 35c between the first connection piece 35a and the second connection piece 35b. The second connection piece 35 b is disposed between the bottom wall 31 aa of the base body 31 a and the upper surface 7 b of the first printed circuit board 7. The first printed circuit board 7 and the second connection piece 35b are attached to the bottom wall 31aa of the base body 31a by a third screw 36 (see FIG. 7). The third screw 36 is provided for each second connection piece 35b. Thereby, as for the composite fire detector 1, the 1st printed circuit board 7 and each 2nd connection piece 35b are electrically connected. An intermediate portion 35 c of the connection plate 35 is bent in a U shape and is inserted into the through hole 7 c of the first printed circuit board 7.

  The carbon monoxide detector 4 is mounted on the first printed circuit board 7 and disposed on the lower surface 7 a side of the first printed circuit board 7. The plurality of carbon monoxide inflow ports 37 of the housing 3 communicate with the first space 41 around the carbon monoxide detector 4 between the first printed circuit board 7 and the second printed circuit board 8 in the housing 3. doing.

  The carbon monoxide detector 4 is constituted by an electrochemical CO sensor. The electrochemical CO sensor preferably has a characteristic that the output current increases in proportion to the concentration of carbon monoxide. As this type of electrochemical CO sensor, for example, TGS5042 (product number) manufactured by Figaro Giken Co., Ltd. can be employed.

  The smoke detector 5 and the heat detector 6 are mounted on the second printed circuit board 8 and arranged on the lower surface 8a side of the second printed circuit board 8.

  The smoke detector 5 includes an optical base 50, a light emitting element 51, a lens 52, and a light receiving element 53 that are disposed on the lower surface 7 a side of the first printed circuit board 7.

  The light emitting element 51 is preferably constituted by a bullet-type LED (light emitting diode). The light receiving element 53 is preferably composed of a photodiode.

  The optical base 50 is preferably formed of a black synthetic resin. The optical base 50 includes a disk-shaped pedestal portion 50a and a labyrinth portion 50b provided to protrude downward from the pedestal portion 50a. A first opening (not shown) through which the light emitting element 51 is passed, a second opening (not shown) through which the light receiving element 53 is passed, and a heat detecting part 6 are passed through the pedestal 50a of the optical base 50. 3 openings (not shown) are formed. The optical base 50 includes a U-shaped first wall portion 50 c that protrudes downward from the pedestal portion 50 a and surrounds the side and rear of the light emitting element 51. The optical base 50 includes a U-shaped second wall 50e that protrudes downward from the pedestal 50a and surrounds the side of the lens 52 and the light receiving element 53 and the rear of the light receiving element. The optical base 50 includes a cylindrical portion 50f that protrudes downward from the pedestal portion 50a and through which the heat detection unit 6 is inserted.

  The optical base 50 includes a peripheral wall portion 50g extending downward from the outer peripheral edge of the pedestal portion 50a and a flange portion 50h extending laterally from the lower end edge of the peripheral wall portion 50g.

  The optical base 50 is detachably attached to the second printed circuit board 8. The optical base 50 includes two first hooks 50i (see FIG. 11) protruding upward from the flange portion 50h, and two cutout portions 81 (see FIG. 11) formed on the side surface of the second printed circuit board 8. It is attached to the second printed circuit board 8 by being hooked on the periphery.

  The smoke detector 5 includes a cap 56 that is detachably attached to the optical base 50. The cap 56 is formed in a bottomed cylindrical shape. The cap 56 is attached to the optical base 50 so as to cover the labyrinth portion 50b, the first wall portion 50c, the light emitting element 51, the second wall portion 50e, the lens 52, the light receiving element 53, and the cylindrical portion 50f.

  The cap 56 is preferably formed of a black synthetic resin or the like. The cap 56 includes a bottom wall 56a that faces the pedestal 50a of the optical base 50, and a lattice-shaped side wall 56b that surrounds the labyrinth 50b.

  The cap 56 can be hooked on a second hook 50j (see FIG. 6) protruding downward from the flange 50h of the optical base 50 at the upper end of the side wall 56b (see FIG. 6). Projecting outward. Thereby, the cap 56 can be detachably attached to the optical base 50.

  The cap 56 includes, from the upper surface of the bottom wall 56a, a first protrusion (not shown) for positioning the light emitting element 51 and a second protrusion (not shown) for positioning the lens 52 and the light receiving element 53. , Is provided protruding.

  As shown in FIG. 11, the side wall 56 b of the cap 56 is formed in a lattice shape and includes a plurality of openings 57. The plurality of openings 57 are formed at equal intervals in the circumferential direction and the vertical direction of the cap 56. In the smoke detector 5, each opening 57 constitutes a smoke inlet 38 through which smoke flows. Each of the openings 57 also functions as a smoke outlet from which smoke flows out.

  In the composite fire detector 1, the second space 54 surrounded by the base portion 50 a of the optical base 50, the labyrinth portion 50 b, and the bottom wall 56 a of the cap 56 constitutes a smoke detection chamber.

  The light emitting element 51 and the light receiving element 53 are arranged so that the light emitting element 51 and the light receiving element 53 do not face each other. The composite fire detector 1 includes a light emitting element 51, a lens 52, and a light receiving element 53 so that the optical axis of the light emitting element 51 and the optical axis of the light receiving element 53 intersect in the smoke detection chamber by the optical base 50 and the cap 56. Is positioned.

  The labyrinth portion 50b is configured to allow smoke to flow into the second space 54 from the outside of the housing 3 and to prevent external light from entering the second space 54 from the side of the housing 3. Yes. Specifically, as shown in FIG. 13, the labyrinth portion 50b is formed by arranging a plurality of protruding walls 50bb side by side in the circumferential direction of the pedestal portion 50a. Most of the plurality of protruding walls 50bb are formed in a V shape.

  The smoke detector 5 is configured such that each third space surrounded by the base 50a of the optical base 50, the bottom wall 56a of the cap 56, and the two protruding walls 50bb adjacent in the circumferential direction of the base 50a is smoke. It becomes this flow path. In the smoke detector 5, one end of the flow path forms a vent and the other end of the flow path communicates with the smoke detection chamber. Therefore, the smoke detection unit 5 is provided with a plurality of vent holes at substantially equal intervals in the outer peripheral direction of the housing 3.

  Each opening 57 in the side wall 56 b of the cap 56 is preferably provided with a net 58. The color of the net 58 is black. The mesh 58 is preferably set to have a mesh size so that insects, dust and the like do not pass therethrough.

  In the smoke detection unit 5, the flange portion 50h of the optical base 50 is placed on the upper end edge of the lower cover portion 32d. In addition, the smoke detection unit 5 is placed on a support piece 32j provided with a peripheral part of the cap 56 protruding from the bottom wall 32e of the lower cover part 32d.

  In the smoke detection unit 5, the light emitted from the light emitting element 51 is applied to the smoke detection chamber. In the composite fire detector 1, when smoke enters the smoke detection chamber, the scattered light from the smoke particles enters the light receiving element 53 through the lens 52, and the output of the light receiving element 53 increases.

  The bottom wall 56a of the cap 56 is formed with a hole 56aa (see FIG. 11) through which the heat detection unit 6 is inserted. The heat detection part 6 is comprised with the thermistor.

  The heat detection unit 6 detects the temperature by the detection element 6a disposed between the bottom wall 56a of the cap 56 and the bottom wall 32e of the lower cover portion 32d.

  A plurality of openings 32g are formed in the side wall 32f of the lower cover portion 32d. The plurality of openings 32g are preferably formed at equal intervals in the circumferential direction of the lower cover portion 32d. In the composite fire detector 1, each of the plurality of openings 32 g constitutes a heat inlet 39. The heat inlet 39 is an inlet through which heat flows in, but also functions as an outlet through which heat flows out.

  Therefore, the temperature detection value of the heat detection unit 6 changes due to a change in the ambient temperature. The composite fire detector 1 has the same number of openings 32g arranged in the outer peripheral direction of the casing 3 in the lower cover portion 32d and the number of openings 57 arranged in the outer peripheral direction of the casing 3 in the cap 56. The openings 32g and the openings 57 are preferably arranged in a plurality of radial directions of the body 3. In other words, in the composite fire detector 1, the opening 32g and the heat inlet 39 are arranged in a plurality of radial directions of the housing 3, and heat to the heat inlet 39 is blocked by the side wall 32f of the lower cover portion 32d. Is preferably suppressed.

  The circuit components of the fire detection circuit are mounted on the upper surface 8b side of the second printed circuit board 8. The fire detection circuit includes a first current-voltage conversion circuit that outputs the output signal of the carbon monoxide detection unit 4 by current-voltage conversion, and an analog-digital conversion of the output signal of the first current-voltage conversion circuit for output. 1A / D conversion circuit. In addition, the fire detection circuit converts the output signal of the light receiving element 53 of the smoke detector 5 from current to voltage and outputs the converted signal, and the output signal of the second current voltage conversion circuit is converted from analog to digital. And a second A / D conversion circuit for outputting. The fire detection circuit includes a third A / D conversion circuit that performs analog-digital conversion on the output signal of the heat detection unit 6 and outputs the converted signal. The fire detection circuit determines whether or not a fire has occurred based on output signals of the first A / D conversion circuit, the second A / D conversion circuit, and the third A / D conversion circuit.

  The circuit module 9 includes two display LEDs 92 that are turned on when a fire is detected by the fire detection circuit. The two LEDs 92 are mounted on the upper surface 8 b of the second printed circuit board 8. The composite fire detector 1 includes two light guide members 93 that guide light emitted from the respective LEDs 92. One end surface of the light guide member 93 faces the light emitting surface of the LED 92, and the other end surface is exposed from a through hole 32bb formed in the peripheral portion of the bottom wall 32b of the upper cover portion 32a. Each light guide member 93 is formed of a transparent synthetic resin. The two light guide members 93 are arranged on a straight line. The emission color of each LED 92 is red, but is not particularly limited. Each LED 92 is controlled to be turned on and off by a fire detection circuit. The composite fire detector 1 is not limited to a configuration in which each LED 92 is turned on when a fire is detected by the fire detection circuit, and may be configured to blink each LED 92, for example.

  The composite fire detector 1 is a communication for transmitting a signal notifying the occurrence of a fire to a fire alarm device (not shown) or receiving a signal from the fire alarm device when a fire is detected by a fire detection circuit. The circuit module 9 is preferably provided with a circuit (not shown). Moreover, it is preferable that the composite fire detector 1 includes an address setting unit that sets its own unique address.

  The fire detection circuit can be configured, for example, by installing an appropriate program in a microcomputer or the like.

  In the composite fire detector 1 described above, a plurality of carbon monoxide inflow ports 37 are formed at equal intervals in the outer peripheral direction of the housing 3 in the housing 3 attached to the attachment base 2. In the composite fire detector 1, a plurality of smoke inlets 38 are formed at equal intervals in the outer peripheral direction of the housing 3, and a plurality of heat inlets 39 are formed at equal intervals in the outer peripheral direction of the housing 3. Therefore, the composite fire detector 1 has a simple structure and can widen the detection area. The composite fire detector 1 has a simple structure of the housing 3 and can detect carbon monoxide, smoke, and heat without depending on the mounting direction, and without depending on the mounting direction. It becomes possible to detect a fire. The composite fire detector 1 is required to have no directionality for each detection target in the directionality test specified in the European standard (prEN54-31) on which the international standard is drafted. It becomes possible to be satisfied. In short, the composite fire detector 1 can suppress the occurrence of direction dependency in the detection characteristics of carbon monoxide, smoke, and heat with a simple structure of the housing 3.

  In the composite fire sensor 1, it is preferable that the protruding dimension of the second rib 312 and the protruding dimension of the spacer 321 are set to be the same. Thereby, the composite fire detector 1 can suppress the space inside the second rib 312 from being seen from the side of the housing 3 and can improve the appearance. Further, as shown in FIG. 1, it is preferable that the outer peripheral surface of the second rib 312 is an inclined surface 312a so that the outer diameter gradually decreases as the distance from the bottom wall 31aa of the base body 31a increases. Furthermore, it is preferable that an inclined surface substantially parallel to the inclined surface 312a of the second rib 312 is formed on the upper end edge 32aa of the peripheral wall 32ab of the upper cover portion 32a. Thereby, the composite fire sensor 1 can easily guide carbon monoxide from the carbon monoxide inlet 37 to the first space 41.

  By the way, the base 31 constitutes a reinforcing structure in which each of the two first bosses 316 mentioned above reinforces the base body 31a. Each first boss 316 is formed integrally with the base body 31a. As shown in FIG. 9, the base 31 includes four first protrusions 314 and two second protrusions 315 that are integrally formed with the second rib 312 and protrude downward from the bottom wall 31aa of the base body 31a. ing. The second protrusion 315 has a larger protruding dimension than the first protrusion 314, and the lower end edge is in contact with the light guide member 93.

  The first protrusion 314 and the second protrusion 315 are arranged so as to overlap and overlap with only one of the plurality of spacers 321. In other words, the plurality of spacers 321 are arranged such that any one of the first protrusion 314 and the second protrusion 315 is close to and overlapped. In the base 31, each first protrusion 314 and each second protrusion 315 constitute a reinforcing structure that reinforces the base body 31a. In the housing 3, of the eight spacers 321, the upper and lower two spacers 321 in FIG. 9 are fitted to the second protrusion 315, and the left and right two spacers 321 in FIG. 9 are fitted to the first protrusion 314. . Thereby, the housing 3 can increase the relative positional accuracy between the base 31 and the cover 32.

  The base 31 preferably includes a plurality of reinforcing structures that reinforce the base body 31a, and the reinforcing structures are preferably arranged radially. Thereby, the composite fire detector 1 can reinforce the housing 3.

  In the composite fire sensor 1, the total number of the plurality of carbon monoxide inlets 37 is preferably eight. As shown in FIG. 9, the composite fire sensor 1 includes both ends of the spacer 321 and the housing between the adjacent carbon monoxide inlets 37 in the horizontal section of the housing 3 including the plurality of carbon monoxide inlets 37. It is preferable that a reinforcing structure is arranged in each of the eight fan-shaped regions surrounded by the center O of the body 3. Thus, in the composite fire detector 1, each reinforcing structure can also serve as a guide wall for guiding carbon monoxide to the first space 41, and the direction dependency occurs in the detection characteristics of carbon monoxide. It becomes possible to suppress more. In FIG. 9, only two fan-shaped areas out of the eight fan-shaped areas are schematically shown by alternate long and short dash lines.

  Each figure explained in the above-mentioned embodiment etc. is typical, and the ratio of each size and thickness of each component does not necessarily reflect the actual size ratio. In addition, the materials, numerical values, and the like described in the embodiments and the like are merely preferable examples and are not limited thereto. Furthermore, the present invention can be appropriately modified in configuration without departing from the scope of its technical idea.

DESCRIPTION OF SYMBOLS 1 Composite fire detector 3 Housing | casing 4 Carbon monoxide detection part 5 Smoke detection part 6 Heat detection part 31 Base 31a Base main body 31aa Bottom wall 32 Cover 32a Upper cover part 32aa Upper end edge 32b Bottom wall 32c Opening part 32d Lower cover part 37 Carbon monoxide inlet 38 Smoke inlet 39 Heat inlet 314 First protrusion (reinforcement structure)
315 Second protrusion (reinforcing structure)
316 First boss (reinforced structure)
321 Spacer O Center

Claims (4)

A housing, a carbon monoxide detector that detects carbon monoxide, a smoke detector that detects smoke, and a heat detector that detects heat;
In the housing, the carbon monoxide detector, the smoke detector and the heat detector are arranged at different height positions, respectively.
The casing has a circular outer peripheral shape,
The casing has a plurality of carbon monoxide inlets formed at equal intervals in the outer peripheral direction of the casing, a plurality of smoke inlets formed at equal intervals in the outer peripheral direction of the casing, and a plurality of heat inlets It is formed at equal intervals in the outer peripheral direction of the housing,
A composite fire detector. The housing includes a base and a cover that is disposed below the base and covers the carbon monoxide detector, the smoke detector, and the heat detector,
The base includes a bottomed cylindrical base body formed of a synthetic resin,
The cover is formed of a synthetic resin,
The cover includes a bottomed cylindrical upper cover part, and a bottomed cylindrical lower cover part projecting downward from a peripheral part of the opening of the central part of the bottom wall of the upper cover part,
The cover integrally includes a plurality of spacers that protrude upward from the upper end edge of the upper cover part and maintain a distance between the upper end edge and the bottom wall of the base body at a specified distance,
The plurality of spacers are formed at equal intervals in the circumferential direction of the upper end edge of the upper cover portion,
A space surrounded by the two spacers adjacent to each other in the outer peripheral direction of the housing, the upper edge of the upper cover portion, and the bottom wall of the base body among the plurality of spacers is the carbon monoxide flow. Constituting the entrance,
The composite fire detector according to claim 1. The base includes a plurality of reinforcing structures that reinforce the base body, and the reinforcing structures are arranged radially.
The composite fire sensor according to claim 2. The total number of the plurality of carbon monoxide inlets is eight, and both ends of the spacer between the adjacent carbon monoxide inlets in a horizontal cross section of the housing including the plurality of carbon monoxide inlets. The eight fan-shaped regions surrounded by the center of the housing, and the reinforcing structure is disposed in each of the eight fan-shaped regions,
The composite fire detector according to claim 3.

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