JP2019159460A - Fire detection system and fire-extinguishing system - Google Patents

Abstract

To provide a fire detection system which is inexpensive, can extend a maintenance interval than the conventional one, and can accurately identify a fire point even if there is a shield.SOLUTION: A fire detection system 87 includes a fire receiver 9 and a plurality of fire detectors 1 which include fire detection parts and transmission parts for transmitting a predetermined signal to the fire receiver 9 when the fire detection parts detect a temperature higher than a predetermined threshold, and are installed in a partition material which partitions a room 35 of a building 29 and outside of the room 35 at predetermined intervals.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a fire detection system and a fire extinguishing system, and more particularly to a sensor for detecting a fire.

  2. Description of the Related Art Conventionally, there is known a fire extinguishing system in which a fire point is specified using a thermal camera or a photoelectric separation type sensor and water is discharged from a water gun toward the fire point (see, for example, Patent Document 1).

Japanese Patent No. 3994355

  By the way, in the conventional fire extinguishing system, it is necessary to use at least two thermal cameras in order to specify the fire point. Thermal cameras are expensive and require maintenance once every few years, resulting in high initial costs and running costs (total costs).

  Further, even if an attempt is made to identify a fire point using a thermal camera or a photoelectric separation type sensor, if there is a shield, the fire point may not be accurately identified.

  The present invention has been made in view of the above problems, is inexpensive, can extend the maintenance interval more than the conventional one, and can accurately identify the fire point even if there is a shield. An object of the present invention is to provide a fire detection system and a fire extinguishing system that can detect fire efficiently with a smaller number of detectors.

  1st invention is equipped with a receiver, a fire detection part, and the transmission part which transmits a predetermined signal to the said receiver, and it is a predetermined space | interval in the partition material which partitions off the room of a building and the external world of this room In a plurality of fire detectors installed with an opening, when viewed in a direction orthogonal to the partition material, it is assumed that at least a part of the partition material is plane-filled with a plurality of regular hexagons of the same size In addition, each of the fire detectors is a fire detection system installed at a center of each regular hexagon.

  A second aspect of the invention is the fire detection system according to the first aspect of the present invention, wherein the fire detector from which the fire is detected to the receiver among the fire detectors is The at least one fire detector is configured to receive and transmit the predetermined signal.

  According to a third aspect of the present invention, in the fire detection system according to the first or second aspect of the invention, the transmitter is connected to the receiver when the fire detector detects a flame intensity higher than a predetermined threshold. A fire detection system configured to transmit a predetermined signal.

  4th invention is the fire detection system which concerns on any 1 of 1st invention-3rd invention, The said fire detection part is a thermoelectric which converts the heat energy of a heat collecting material and the said heat collecting material into electrical energy. The fire detection system is configured to transmit the predetermined signal to the receiver by electrical energy generated by the thermoelectric element.

  According to a fifth aspect of the present invention, in the fire detection system according to any one of the first to third aspects, the fire detector converts a flame radiant energy into an electric energy according to the intensity of the flame. It is a fire detection system comprised with.

  According to a sixth invention, in the fire detection system according to any one of the first to fifth inventions, each of the fire detectors is installed in a wiring outlet installation section of a free access floor of a building. It is a fire detection system configured in

  According to a seventh invention, in the fire detection system according to any one of the first invention to the fifth invention, a fire extinguishing agent discharge part that discharges a fire extinguishing agent toward a fire point and a predetermined one of the fire detectors. When the receiver receives a predetermined signal from the fire detector, a control for controlling the fire extinguishing agent discharge unit so that the fire extinguishing agent discharge unit emits the fire extinguishing agent toward the predetermined fire detector And a fire extinguishing system.

  According to the present invention, it is inexpensive, can extend the maintenance interval more than the conventional one, can accurately identify the fire point even if there is a shielding object, and efficiently with a smaller number of detectors. There is an effect that a fire can be detected.

It is sectional drawing which shows schematic structure of the fire detector which concerns on embodiment of this invention. It is a block diagram which shows schematic structure of the fire detector which concerns on embodiment of this invention. It is a perspective view showing a schematic structure of a fire detector concerning an embodiment of the present invention. It is a top view showing a schematic structure of a fire extinguishing system concerning an embodiment of the present invention. It is a flowchart which shows operation | movement of the fire extinguishing system which concerns on embodiment of this invention. It is a top view which shows the outline | summary of arrangement | positioning of the fire detector of the fire extinguishing system which concerns on a modification. It is a top view which shows schematic structure of the fire detector which concerns on a modification. It is a top view which shows the water discharge division of the water discharge gun of the fire extinguishing system which concerns on embodiment of this invention. It is sectional drawing which shows schematic structure of the fire detector which concerns on a modification. It is sectional drawing which shows schematic structure of the fire detector which concerns on a modification. It is sectional drawing which shows schematic structure of the fire detector which concerns on a modification. It is sectional drawing which shows schematic structure of the fire detector which concerns on a modification. It is sectional drawing which shows schematic structure of the fire detector which concerns on a modification.

  As shown in FIGS. 1 to 2, the fire detector 1 according to the embodiment of the present invention includes a heat collecting material 3, a thermoelectric element 5, and a transmission unit (wireless transmission unit) 7.

  The thermoelectric element 5 is provided integrally with the heat collecting material 3 and converts the heat energy of the heat collecting material 3 into electric energy. Here, you may grasp | ascertain the thing provided with the heat collecting material 3 and the thermoelectric element 5 as a fire detection part (temperature detection part).

  The transmission unit 7 transmits a predetermined signal to the fire receiver 9 (see FIG. 4) by the electric energy generated by the thermoelectric element 5. As the predetermined signal, for example, a signal indicating that a fire has occurred (a signal indicating that the temperature of the heat collecting material 3 has increased) and a signal indicating a unique ID of the fire detector (heat detector) 1 may be listed. it can.

  The heat collecting material (heat collecting plate) 3 is formed in a flat plate shape (for example, a rectangular flat plate shape) using a non-flammable or flame retardant material having high thermal conductivity such as metal or ceramics.

  A plurality of thermoelectric elements 5 are provided, and each thermoelectric element 5 is connected in series by electrodes (a high temperature side conductor 11 and a low temperature side conductor 13).

  Here, for convenience of explanation, a horizontal direction in the fire detector 1 is a horizontal direction, and another horizontal direction in the fire detector 1 and a direction perpendicular to the horizontal direction is a vertical direction. The direction perpendicular to the horizontal direction and the vertical direction is defined as the vertical direction.

  The thickness direction of the flat plate heat collecting material 3 is the vertical direction. Each thermoelectric element 5 is provided on one surface (lower surface) in the thickness direction of the plate-shaped heat collector 3, and has a predetermined interval in the vertical direction and the horizontal direction of the plate-shaped heat collector 3. It is in line.

  One thermoelectric element 5 includes, for example, a rectangular parallelepiped n-type semiconductor 15, a rectangular parallelepiped p-type semiconductor 17, and a rectangular flat plate-like high-temperature side conductor (high-temperature side electrode) 11. Yes. One n-type semiconductor 15 and one p-type semiconductor 17 are slightly separated from each other and adjacent to each other. The upper surface of one n-type semiconductor 15 and the upper surface of one p-type semiconductor 17 are connected by a rectangular flat plate-like high-temperature side conductor 11. The thickness direction of the high temperature side conductor 11 is also the vertical direction.

  Each thermoelectric element 5 is provided on the heat collector 3 such that the end surface on which the high temperature side conductor 11 is installed is on the upper side and the end surface opposite to the end surface on which the high temperature side conductor 11 is installed is on the lower side. It has been. In addition, between the high temperature side conductor 11 and the heat collecting material 3 of each thermoelectric element 5, there is a thin flat insulator (for example, ceramics having high thermal conductivity or the like and nonflammability or flame retardancy). An insulator 19 made of the provided material is provided. The thickness direction of the thin flat insulator 19 is also the vertical direction.

  Further, the upper surface of the thin flat insulator 19 is in surface contact with the lower surface of the heat collecting material 3, and the upper surface of the high temperature side conductor 11 of each thermoelectric element 5 faces the lower surface of the thin flat insulator 19. In contact.

  As shown in FIG. 1, in two thermoelectric elements (5A, 5B) adjacent to each other among the thermoelectric elements 5, the lower surface of the n-type semiconductor 15 of one thermoelectric element 5A and the other thermoelectric element 5B. The lower surface of the p-type semiconductor 17 is connected by a rectangular flat plate-like low-temperature side conductor 13 (13A). The thickness direction of the low temperature side conductor 13 is also the vertical direction.

  Thereby, each thermoelectric element 5 provided on the lower side of the heat collecting material 3 is connected in series by the low temperature side conductor 13 as shown in FIG.

  The transmission unit 7 includes a first control unit (control board; fire detector control unit) 21 and an antenna 23. The first control unit 21 includes a memory (not shown) and a CPU (microcomputer).

  Here, the wireless specification (wireless communication method) of the transmission unit 7 will be described. In the fire detector 1, since the antenna 23 is housed below the floor surface 37, the wireless transmission range may be limited. Therefore, in order to improve the reliability of information transmission, it is necessary to use a wireless communication method (Bluetooth, Zigbee, etc.) capable of mesh communication or multi-hop communication (method of transmitting information between wireless terminals like a bucket relay). desirable.

  By using mesh communication or multi-hop communication, the electric power used by the fire detector 1 can be reduced, and the electric power of the thermoelectric element 5 can be reduced, so that the thermoelectric element 5 can be reduced. Moreover, when using a battery, the battery to be used can be reduced in size and cheaply. Further, even in the case of the fire detector 1 driven by electric power of only the battery, at least one other fire detector 1 (this fire) is provided between the fire detector 1 that detects the fire and the receiver (fire receiver) 9. The detector 1 does not detect a fire but may detect it. (By receiving and transmitting a predetermined signal), it can be transmitted sufficiently far away with a small battery.

  When the temperature of the heat collecting material 3 rises due to the occurrence of a fire, the thermoelectric element 5 generates power by the heat of the heat collecting material 3, and the transmitter 7 (first control unit 21) uses the electric power generated by each thermoelectric element 5. ) Operates, and transmits a predetermined signal from the antenna 23 to the fire receiver 9 under the control of the first control unit 21.

  Note that power generation of the thermoelectric element 5 by the heat of the heat collecting material 3 is performed by a temperature difference between the high temperature side conductor 11 and the low temperature side conductor 13. The transmission of the predetermined signal by the transmission unit 7 is performed when the temperature of the heat collecting material 3 rises and exceeds the first temperature, and the power generation amount exceeds a predetermined threshold.

  Further, as shown in FIG. 1, the fire detector 1 has a bowl-shaped housing (cover member) 25 made of a material (for example, a flame-retardant synthetic resin) through which radio waves emitted from the transmitter 7 are transmitted. Is provided. The housing 25 is formed in, for example, a rectangular bowl shape, the opening portion faces upward, and the opening portion is covered with the heat collecting material 3.

  Thus, a closed space 27 is formed inside the housing 25 by the housing 25 and the heat collecting material 3, and in each of the closed spaces 27, each thermoelectric element 5, the thin flat plate insulator 19, A high temperature side conductor 11, a low temperature side conductor 13, and a transmission unit 7 are provided.

  When viewed in the vertical direction, the heat collecting material 3 is larger than the housing 25, and the housing 25 is located inside the heat collecting material 3. Thereby, the collar part 57 (refer FIG. 1) is formed in the outer side of the housing | casing 25 by being comprised with a part of heat collecting material 3. As shown in FIG.

  In addition, as shown in FIG. 1, the fire detector 1 is configured to be embedded and installed in, for example, a wiring outlet installation portion 33 of the free access floor 31 of the building 29. As the wiring outlet installation part 33, a part where a storage type outlet (inner outlet) is installed, a part where a storage type air conditioning device or the like is installed, and the like can be listed.

  The free access floor 31 is formed by, for example, laying and installing a plurality of floor panels 39 on the floor surface (floor) 37 of the room 35 of the building 29. The floor panel 39 includes a flat plate-like upper plate portion 41 and leg portions 43 protruding downward from the upper plate portion 41.

  By installing a plurality of floor panels 39 on the floor surface 37 of the room 35 of the building 29, the flat upper surface 45 of the free access floor 31 is formed on the upper surface of the upper plate portion 41 of each floor panel 39. A space 47 is formed between the floor surface 37 of the room 35 and the upper plate portion 41 of the floor panel 39. A wiring (not shown) such as an electric wire is installed in the space 47.

  The wiring outlet installation part 33 is formed by, for example, a through hole 49 provided in the upper plate part 41 of the floor panel 39. The through-hole 49 includes an upper part 51 and a lower part 53, and the lower part 53 exists inside the upper part 51 when viewed in the vertical direction.

  As a result, the bottom surface 55 of the upper part 51 located outside the lower part 53 is formed in an annular shape such as a “B” shape when viewed in the vertical direction. Further, the bottom surface 55 of the upper part 51 located outside the lower part 53 is parallel to the upper surface 45 of the upper plate part 41 of the floor panel 39, and from the upper surface 45 of the upper plate part 41 of the floor panel 39. Is also located slightly below.

  In a state where the fire detector 1 is installed in the wiring outlet installation portion 33 of the free access floor 31, the housing 25 of the fire detector 1 is below the through hole 49 of the upper plate portion 41 as shown in FIG. 1. The heat collecting material 3 of the fire detector 1 (the flange 57 on the outside of the casing 25) enters the upper portion 51 of the through hole 49 of the upper plate portion 41, and enters the portion 53 (space 47). The flange portion 57 of the heat collecting material 3 is in contact with the bottom surface 55 of the upper portion 51 of the through hole 49 of the upper plate portion 41.

  Further, in a state where the fire detector 1 is installed in the wiring outlet installation portion 33 of the free access floor 31, the upper surface 45 of the upper plate portion 41 and the upper surface of the heat collecting material 3 are located on the same plane, Furthermore, when the state in which the fire detector 1 is installed in the wiring outlet installation part 33 of the free access floor 31 is viewed in the vertical direction, the size of the heat collecting material 3 is the upper part of the through hole 49 of the upper plate part 41. The heat collecting material 3 is fitted into the upper portion 51 of the through hole 49 of the upper plate portion 41.

  By the way, as shown in FIG. 2, the temperature around the fire detector 1 (for example, the temperature of the heat collecting material 3, the temperature of the space 47, or the temperature of the space on the free access floor 31) is added to the fire detector 1. A temperature measurement sensor (for example, a commercially available temperature sensor) 59 may be provided.

  Then, when the temperature measured by the temperature measurement sensor 59 exceeds a predetermined threshold (second temperature higher than the first temperature described above), the transmission unit 7 generates electric energy generated by the thermoelectric element 5. However, a predetermined signal may be transmitted to the fire receiver 9.

  In this case, the temperature sensor 59 is movable to the electric energy generated by the thermoelectric element 5, but the temperature sensor 59 may be operated by a battery (not shown) or commercial power. . In this case, the fire detector 1 including the controller 21 without the thermoelectric element 5 may be operated with a battery (not shown) or commercial power. In addition, a battery may be connected to the thermoelectric element 5 and charged by electric energy generated by the thermoelectric element 5, and the battery may be mounted on the control unit 21.

  In such a configuration, when the temperature measured by the temperature measurement sensor 59 exceeds the second temperature, the transmitter 7 transmits a predetermined signal to the fire receiver 9, so there is no malfunction and there is no fire. The occurrence can be reliably detected.

  Moreover, the fire detector 1 may have another configuration. For example, as shown in FIG. 12, in the fire detector 1, a flame sensor 91 may be provided instead of or in addition to the temperature measurement sensor. The flame sensor 91 is a flame detector that converts the radiant energy of the flame into electrical energy according to the intensity of the flame.

  When the radiant energy of a fire point flame (not shown in FIG. 12) detected by the flame sensor 91 exceeds the predetermined threshold using the electric energy generated by the thermoelectric element 5 (below the predetermined threshold). Under the control of the control unit 21, the transmission unit 7 may be configured to transmit a predetermined signal to the fire receiver 9 (not shown in FIG. 12). Note that the reference symbol θ shown in FIG. 12 indicates the spread angle of the monitoring area of the flame sensor 91.

  Further, in the configuration shown in FIG. 12, the flame sensor 91 is operated by electric energy generated by the thermoelectric element 5, but the flame sensor 91 is operated by a battery (not shown) or commercial power. It may be. In this case, the fire detector 1 including the controller 21 without the thermoelectric element 5 may be operated with a battery (not shown) or commercial power. In addition, a battery may be connected to the thermoelectric element 5 and charged by electric energy generated by the thermoelectric element 5, and the battery may be mounted on the control unit 21.

  Next, a fire extinguishing system (disaster prevention system) 61 using a plurality of fire detectors 1 will be described with reference to FIG.

  The fire extinguishing system 61 includes a fire detector 1, a fire extinguishing agent discharge unit (for example, a water discharge unit; water discharge gun) 63, a fire receiver 9, and a control panel (second control unit; control unit for fire extinguishing system) 65. It is configured.

  A plurality of fire detectors 1 are provided, and are installed in a room 35 of the building 29 with a predetermined interval. The water discharge gun 63 discharges (discharges water) a fire extinguisher (for example, water) toward the fire point 67.

  When the fire receiver 9 receives a predetermined signal from a predetermined fire detector 1 (1A) of the fire detectors 1, the second control unit 65 receives the predetermined fire detector 1A (fire point 67). The water discharge gun 63 is controlled so that the water discharge gun 63 releases the water discharge toward ().

  Each of the plurality of fire detectors 1 has a unique ID, and is installed on the floor 37 of the room 35 of the building 29 in the above-described manner, for example. When viewed in the vertical direction, each of the fire detectors 1 is installed at regular intervals (for example, at a pitch of 1 m) in the vertical direction and the horizontal direction. The heat collecting material 3 when viewed in the vertical direction has a size of about 10 cm × 10 cm, for example. That is, the flat heat collecting material 3 has a size of about 10 cm × 10 cm in the vertical and horizontal directions.

  Each of the fire detectors 1 may be directly embedded in, for example, the floor 37 of the building 29 without using the free access floor 31, or may be installed on the wall (horizontal wall) or ceiling of the building 29, for example. It may be embedded and installed. Furthermore, each of the fire detectors 1 may be installed in a structure other than the building (a structure to be extinguished by the fire extinguishing system 61).

  The water spray gun 63 is installed inside the room 35 of the building 29 or outside the room 35 of the building 29 (a place slightly away from the room 35 of the building 29) in a plan view. In view, it is installed at a location away from the floor surface 37 by a predetermined distance above the floor surface 37 of the room 35 of the building 29.

  The water discharge gun 63 includes a main body portion 69 and a cylindrical barrel portion 71. The main body 69 is rotatable and positionable around an axis extending in the vertical direction with respect to the building 29 as a rotation center. That is, it rotates in the horizontal direction. Further, the barrel portion 71 is rotatable and positionable with an axis extending in the horizontal direction with respect to the main body portion 69 as a rotation center. That is, it rotates up and down.

  Water supplied from a water storage tank (not shown) is discharged from the tip of the barrel portion 71 into the room 35 of the building 29. More specifically, by appropriately setting the rotation angle of the main body portion 69 and the rotation angle of the barrel portion 71, water can be discharged toward a target location (fire point) 67 in the room 35 of the building 29. it can.

  In addition, you may make it the structure which discharges | emits water toward the fire point 67 in the room 35 of the building 29 by moving the water discharge gun 63 to the vertical / horizontal direction or the vertical direction.

  The second control unit 65 includes a CPU and a memory (not shown), and identifies the fire detector 1 (1A) that has transmitted a predetermined signal according to a predetermined signal received by the fire receiver 9. To do.

  For example, the ID of each fire detector 1 and the installation location (installation position in the horizontal direction, installation position in the vertical direction) of each fire detector 1 are associated with each other in the memory of the second control unit 65. It is remembered.

  Then, the position of the fire detector 1A is specified from the ID of the fire detector 1A that has transmitted the predetermined signal, and the second control unit 65 controls the water discharge gun 63, whereby the main body 69 And the barrel portion 71 are appropriately rotated and positioned, and water is discharged toward the specified fire detector 1A (fire point 67).

  The fire extinguishing system 61 is provided with an operation panel 73 having an output unit such as an LCD (not shown) and an input unit such as a touch panel. The operator can know the situation of the fire extinguishing system 61 and the situation of the room 35 of the building 29 using the operation panel 73, and can appropriately operate the fire extinguishing system 61.

  Further, as shown in FIG. 4, the fire extinguishing system 61 is provided with a photoelectric separation type fire detector 75 as a fire detection device that is obliged to be installed by law. The photoelectric separation type fire detector 75 includes a plurality of light transmitting parts (light emitting parts) 77 and a plurality of light receiving parts 79. In place of or in addition to the photoelectric separation-type fire detector 75, a fire detector that is obliged to be installed by law may be employed, such as a fire detector (NSF904EGA manufactured by Nippon Dry Chemical Co., Ltd.).

  Each light transmission part 77 is installed on the one wall surface of the horizontal direction of the room 35 of the building 29 at predetermined intervals in the vertical direction, for example. Moreover, each light transmission part 77 is installed in the up-down direction in the place away from the floor 37 of the room 35 of the building 29 by a predetermined distance.

  Each light receiving portion 79 is also installed at a predetermined interval in the vertical direction on the other wall surface in the horizontal direction of the room 35 of the building 29 in the same manner as each light transmitting portion 77, for example. Each light receiving unit 79 is also installed at a predetermined distance above the floor 37 of the room 35 of the building 29 in the vertical direction.

  In a normal state (when no fire has occurred in the room 35 of the building 29), each light receiving unit 79 receives light emitted from each light transmitting unit 77 toward each light receiving unit 79. To do.

  On the other hand, when a fire occurs in the room 35 of the building 29, at least a part of the light receiving units 79 among the light receiving units 79 cannot receive the light emitted from the light transmitting unit 77 due to smoke from the fire. Thereby, the occurrence of a fire in the room 35 of the building 29 is detected.

  Next, the operation of the fire extinguishing system 61 will be described with reference to FIG.

  When a fire occurs in the room 35 of the building 29 (S1), the photoelectric separation type fire detector 75 detects the occurrence of the fire (S3).

  Subsequently, the fire receiver 9 provided with a display unit (not shown) for indicating that a fire has occurred displays that a fire has occurred (S5).

  A fire information output unit that outputs information indicating that a fire has occurred may be provided in the fire receiver 9. For example, an alarm sound may be emitted when a fire occurs.

  Subsequently, the fire receiver 9 transmits a predetermined signal (a signal indicating that a fire has occurred and a signal indicating the ID unique to the fire detector 1A) to the second control unit 65 (S7), The control unit 65 receives a predetermined signal (S9).

  Subsequently, when the second control unit 65 receives a predetermined signal from the fire detector 1 (1A) via the fire receiver 9 (S11), the second control unit 65 identifies the fire point 67, The water discharge gun 63 discharges water toward the fire point 67 (S13).

  In the above description, in step S5, the fire receiver 9 displays that a fire has occurred, but the operation panel 73 displays that a fire has occurred. May be. Further, a receiver may be provided in the second control unit 65, and when a fire occurs, a predetermined signal may be received by the receiver of the second control unit 65 without going through the fire receiver 9. Further, in step 11, the control panel 65 receives the fire position information from the fire detector 1, but the fire receiver 9 receives the fire position information from the fire detector 1, and the control panel 65 receives the fire position information. Information may be transmitted.

  According to the fire detector 1, since the thermoelectric element 5 which is cheaper and has a longer life than the thermal camera is used, the initial cost and the running cost can be reduced, and the maintenance interval can be extended.

  In addition, according to the fire detector 1, the fire detector 1 is configured to wirelessly transmit a predetermined signal by the electrical energy generated by the thermoelectric element 5. (Electric wires for supplying power and wiring for sending signals) can be eliminated, and the fire detector 1 can be easily installed.

  In addition, according to the fire detector 1, the transmitter 7 is operated by the electric energy generated by the thermoelectric element 5, so that a battery is unnecessary and low energy consumption can be achieved. The maintenance interval can be further extended.

  In addition, according to the fire detector 1, the thermoelectric element 5 generates power via the heat collection material 3 having good thermal conductivity, so the heat collection material 3 is made larger than the installation area of the thermoelectric element 5. By doing so, it is possible to detect the occurrence of a fire in a wide range with a small number of thermoelectric elements 5.

  Moreover, according to the fire detector 1, since the fire detector 1 is configured to be installed in the wiring outlet installation portion 33 of the free access floor 31 of the building 29, the building 29 or a commercially available free access floor is provided. The fire detector 1 can be easily installed without modifying the 31.

  By the way, in the conventional fire extinguishing system, even if an attempt is made to identify a fire point using a thermal camera or a photoelectric separation type sensor, if there is a shield, the fire point may not be accurately identified.

  On the other hand, in the fire extinguishing system 61, since the several fire detector 1 is installed in the floor 37, even if there exists a shield on the floor panel 39, the fire point 67 can be pinpointed correctly.

  Furthermore, in the fire extinguishing system 61, since the plurality of fire detectors 1 are installed on the floor 37, the position of the fire point 67 is detected more accurately than when a thermal camera or a photoelectric separation type detector is used. be able to.

  That is, the position of the flame at the fire point 67 is likely to change due to, for example, fluctuations or the flow of air in the room 35, and the smoke generated at the fire point 67 is also affected by, for example, fluctuations or the flow of air in the room 35. The position is easy to change. Thereby, the thermal camera or the photoelectric separation type detector may not be able to accurately detect the position of the fire point 67.

  On the other hand, in the fire extinguishing system 61, since the plurality of fire detectors 1 are installed on the floor 37, the position of the fire point 67 is accurately detected even if there is fluctuation or air flow in the room 35. be able to.

  In addition, by accurately identifying the fire point 67, when performing fire extinguishing using the water gun 63 in a large facility space, the amount of water discharged can be reduced, the water storage facility can be downsized, and the overall cost can be reduced. Can be reduced.

  For example, the amount of water stored in a water storage tank (a water storage tank that supplies water to a water discharge gun) can be reduced. This will be further described.

  Moreover, according to the fire extinguishing system 61, it is cheap, can extend the maintenance interval more than the conventional one, and can efficiently arrange the fire detector 1 that accurately identifies the fire point even if there is a shield. Can do.

  First, a water storage amount of a water storage tank (a water storage tank that supplies water to a water discharge gun) in a conventional fire extinguishing system will be described.

The area of the water discharge section defined by law is 4 m × 5 m = 20 m ^{2 as shown} in FIG. As shown in FIG. 8, the area of the water discharge section where the safety factor is set is (4 m + 2 m) × (5 m + 2 m) = 42 m ² . The area of the water discharge section in which the detection accuracy error of the fire detector 1 is set is (6 m + 2 m) × (7 m + 2 m) = 72 m ² as shown in FIG.

Here, if the water discharge flow rate per 1 m ² of the water discharge section (floor area) of the water discharge gun is qL / m ² · min (for example, 5 L / m ² · min), the water discharge amount per minute of the water discharge gun 63 is qL / m ² · min × 72 m ² = 72 qL / min (for example, 5 L / m ² · min × 72 m ² = 360 L / min).

Furthermore, since it is necessary to discharge water for 20 minutes from the water discharge gun, the amount of water stored in the water storage tank is 72 qL / min × 20 min = 1440 qL (for example, 360 L / min × 20 min = 7200 L (7.2 m ³ )).

According to the fire extinguishing system 61 according to the embodiment of the present invention, by accurately specifying the fire point, the area of the water discharge section can be, for example, 6 m × 7 m = 42 m ² , and the water storage capacity is 7.2 m ^3. The tank can be a water storage tank with a capacity of 5 L / m ² · min × 42 m ² × 20 min = 4200 L (4.2 m ³ ), and the cost can be reduced by reducing the size of the water storage tank and the amount of water stored. Become.

  By the way, in FIG. 4, each thermoelectric element 5 is arrange | positioned at predetermined intervals in the vertical direction and the horizontal direction, but as shown in FIG. 6, each thermoelectric element 5 is closest packed (hexagonal close packed). May be arranged.

  That is, when it is assumed that at least a part (for example, all) of the floor 37 is planarly filled with a plurality of regular hexagons of the same size in plan view, each of the fire detectors 1 has a center of each regular hexagon. It may be installed in each place (the position of each center of each fire detector 1 and the position of each center of each regular hexagon may coincide with each other). Alternatively, each of the fire detectors 1 may be installed at each vertex of each regular hexagon.

  Furthermore, a planar surface of a partition material (for example, at least one of a floor 37, a ceiling, and a wall) that partitions the room 35 of the building 29 from the outside of the room 35 and has each fire detector 1 installed. When assuming that at least a part of the partition material is plane-filled with a plurality of regular hexagons of the same size as viewed in a direction perpendicular to each other, each fire detector 1 has a center of each regular hexagon. It may be installed in each.

  In this way, by arranging each fire detector 1 with hexagonal close-packing, it is possible to detect a fire point efficiently and without bias using a smaller number of fire detectors 1.

  In addition, as fire detectors 1 arranged in a hexagonal close-packed shape with regular hexagons, heat detectors (differential spot type detectors, constant temperature spot type detectors), smoke detectors (photoelectric spot type detectors), Flame detectors (ultraviolet spot detectors, infrared spot detectors) may be employed, and detectors including a thermal sensor, a smoke sensor, and an optical sensor that detect fire may be employed.

  In the above description, one fire detector 1 </ b> A detects the fire point 67, but a plurality of predetermined fire detectors among the fire detectors 1 may detect the fire point 67.

  In this case, when a predetermined signal is received from a plurality of predetermined fire detectors in each of the fire detectors 1, a water spray gun is directed toward the center of the region where the predetermined plurality of fire detectors are disposed. 63 discharges water.

  Note that when the fire receiver 9 receives a predetermined signal from a plurality of predetermined fire detectors 1, the fire point may be specified according to the reception time from each fire detector 1. For example, a predetermined signal is received from the first fire detector 1 at the time t1, and a predetermined signal is received from the second fire detector 1 at the time t2 (time ta after the time t1). At this time, a location closer to the first fire detector 1 than the central portion between the first fire detector 1 and the second fire detector 1 may be specified as the fire point 67.

  Moreover, you may provide a receiving part in the fire detector 1. FIG. And the fire detector which detected the fire of each fire detector 1 between the fire detector 1A which detected the fire of each fire detector 1 to the receiver like the multihop communication mentioned above. At least one fire detector 1 other than 1A may be configured to receive and transmit the predetermined signal.

  That is, one or a plurality of fire detectors 1 other than the fire detector 1 </ b> A that has detected a fire may be relayed to send the predetermined signal to the fire receiver 9.

  Next, the case where the fire detector 1 employs the flame sensor 91 as a detection unit (fire detection unit) will be described with reference to FIG. The flame sensor 91 has a monitoring area having a predetermined spread angle θ. For example, a plurality of flame sensors 91 are provided, and the monitoring area of the first flame sensor 91 (91A) overlaps with the monitoring area of the adjacent second flame sensor 91 (91B).

  By disposing the flame sensor 91 in this way, when the flame sensor 91B detects a flame at a fire point 67 (67B) (a flame intensity higher than a predetermined threshold) in the monitoring area of the flame sensor 91B, the flame sensor 91B It is possible to control the water discharge of the water discharge gun 63 (see FIG. 4) by specifying the position of the fire point 67B on the assumption that a flame is generated at the position where it is disposed.

  In the case of a fire point 67 (67A) as shown in FIG. 13, the flame sensor 91A and the flame sensor 91B detect the fire point 67A. Thereby, the position where the monitoring area of the flame sensor 91A and the monitoring area of the flame sensor 91B overlap each other can be specified as the fire point 67A position, and the water discharge of the water discharge gun 63 (see FIG. 4) can be controlled.

  In addition, the flame sensor 91 (91A, 91B) shown in FIG. 13 is installed in the partition material 89 using the flame sensor support body 93, for example. As the partition member 89, a wall surface of the building 29 shown in FIGS. 4 and 6 can be raised, and a floor, a ceiling, and the like can be further raised.

  Next, inspection of the fire extinguishing system 61 using a heating tester (not shown) will be described.

  The heating tester includes a heater, and at the time of inspection, the fire extinguishing system 61 is switched to the inspection mode by operating the operation panel 73, for example.

  The fire extinguishing system 61 is switched to the inspection mode (for example, the mode in which the water gun 63 does not operate), and the heat collecting material 3 of one fire detector 1 to be inspected is heated for a predetermined time by the heater of the heating tester. As a result, if it can be confirmed by the operation panel 73 that the predetermined signal from the heated fire detector 1 can be received, it is confirmed that one fire detector 1 to be inspected is normal. be able to.

  This check is performed on the other fire detectors 1 in order to check all the fire detectors 1 of the fire extinguishing system 61.

  In addition, you may comprise so that confirmation that the predetermined | prescribed signal from the heated fire detector 1 was able to be received can be performed with a heating tester. Further, when the inspection mode is set, for example, the operation panel 73 may be used to continuously issue a warning that the inspection mode is set.

  By the way, as shown in FIGS. 7A to 7D, in the plan view, the heat collecting material 3 is enlarged with respect to the portion 81 (the portion indicated by hatching) where the thermoelectric element 5 is provided, so that the heat collecting material 3 is wide. You may comprise so that it can collect heat.

  In FIG. 7, the outer diameter of the heat collecting material 3 with respect to the outer diameter of the portion 81 where the thermoelectric element 5 is provided is about five times larger, but the outer diameter of the portion 81 where the thermoelectric element 5 is provided. The outer diameter of the heat material 3 may be 1.5 times to 10 times, 2 times to 8 times, or 2 times to 6 times.

  Further, as shown in FIG. 9, the thermoelectric element 5 may be formed in a mode in which the p-type semiconductor 17 and the n-type semiconductor 15 are directly joined without providing the high temperature side conductor 11. In this case, a portion where the p-type semiconductor 17 and the n-type semiconductor 15 are directly joined is installed on the heat collecting material 3 with a thin flat-plate insulator 19 interposed therebetween.

  Further, as shown in FIG. 10, a heat storage material 83 may be provided on the low temperature side conductor 13 side. The heat storage material 83 is in contact with, for example, the low temperature side conductor 13. The heat storage material 83 is solid at room temperature, and melts and liquefies when the temperature reaches about 100 ° C., for example. Therefore, even when the temperature of the heat collection material 3 rises to 100 ° C. or more due to a fire and the temperature in the space 27 exceeds 100 ° C., the heat storage material 83 is about 100 ° C. due to the heat of fusion (latent heat) of the heat storage material 83. The temperature is maintained for a predetermined time.

  Thereby, each thermoelectric element 5 generates electric power for a longer time than the case where the heat storage material 83 is not provided.

  Moreover, as shown in FIG. 11, the heat collecting material 3 is composed of a plurality of members (for example, the first member 3A and the second member 3B), and the portions 3A and 3B separated from each other are thermally conductive. It may be connected with a high connecting material 85.

  Furthermore, the above described content may be grasped as a fire detection system 87 having a fire receiver and a plurality of fire detectors 1. In this case, a commercially available fire detector 1 may be adopted.

DESCRIPTION OF SYMBOLS 1 Fire detector 3 Heat collecting material 5 Thermoelectric element 7 Transmission part 29 Building 31 Free access floor 33 Outlet installation part for wiring 35 Room 61 Fire extinguishing system 63 Extinguishing agent discharge part 65 Control part 67 Fire point 87 Fire detection system

Claims (7)

A receiver,
A plurality of fire detectors provided with a fire detector and a transmitter for transmitting a predetermined signal to the receiver, and installed at predetermined intervals on a partition material that partitions the building room and the outside of the room In the vessel
When it is assumed that at least a part of the partition material is plane-filled with a plurality of regular hexagons of the same size when viewed in a direction orthogonal to the partition material, each of the fire detectors A fire detection system that is installed at each center of a regular hexagon. In the fire detection system according to claim 1,
At least one fire detector of each of the fire detectors receives and transmits the predetermined signal between the fire detector that detected the fire of each of the fire detectors and the receiver. The fire detection system is characterized by being configured. In the fire detection system according to claim 1 or claim 2,
The said detection part is comprised so that a predetermined signal may be transmitted to the said receiver, when the said fire detection part detects the flame intensity higher than a predetermined threshold value, The fire detection system characterized by the above-mentioned. In the fire detection system according to any one of claims 1 to 3,
The fire detection unit includes a heat collector and a thermoelectric element that converts thermal energy of the heat collector into electrical energy,
The said detection part is comprised so that the said predetermined signal may be transmitted to the said receiver with the electrical energy produced | generated by the said thermoelectric element, The fire detection system characterized by the above-mentioned. In the fire detection system according to any one of claims 1 to 3,
The fire detection unit is configured to include a flame detector that converts radiant energy of a flame into electric energy according to the intensity of the flame. In the fire detection system according to any one of claims 1 to 5,
Each said fire detector is comprised so that it may be installed in the outlet installation part for wiring of the free access floor of a building, The fire detection system characterized by the above-mentioned. The fire detection system according to any one of claims 1 to 6,
A fire extinguisher discharge part for discharging the fire extinguisher toward the fire point
When the receiver receives a predetermined signal from a predetermined fire detector of each of the fire detectors, so that the fire extinguisher discharge unit emits a fire extinguisher toward the predetermined fire detector, A control unit for controlling the extinguishing agent discharge unit;
A fire extinguishing system characterized by comprising:

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