JP2008102575A - Fire alarm - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce any false report due to rising steam, in a fire alarm which detects the concentration of smoke, and issues the alarm of a fire. <P>SOLUTION: A sensor housing 12 housing a smoke sensor is formed on a front face 11a of a main body case 11. The main body case 11 is installed on a wall or the like. A first barrier plate 15a is installed at the lower part of the sensor housing 12. The concentration of the smoke in the atmosphere flowing in the sensor housing 12 is detected by the smoke sensor, and an alarm is output. The panel 13 is held by a first barrier plate 15a and bosses 15b and 15c for attachment, and the front face of the sensor housing 12 is covered with the panel 13. The flow of the air flow (steam or the like) of the atmosphere rising from the lower part to the sensor housing 12 is controlled by the first barrier plate 15a. Also, a second barrier plate is installed between the first barrier plate 15a and the sensor housing 12. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a fire alarm that is installed in a house or the like and outputs a fire alarm signal to the outside when a fire occurs in the room or the like, and in particular, detects or alarms a fire by detecting smoke concentration. It is about fire alarm to perform.

  Conventionally, as smoke detectors for detecting smoke due to a fire or the like, for example, Japanese Patent Application Laid-Open No. 2001-34862 (Patent Document 1), Japanese Patent Application Laid-Open No. 9-153187 (Patent Document 2), and Japanese Patent Application Laid-Open No. 2005-293548 (Patent Document). There are those disclosed in Document 3). These smoke detectors are installed on the ceiling of the room and detect the smoke concentration on the ceiling surface by the smoke detector, and output a fire occurrence signal when the concentration exceeds a certain level.

  Also, these conventional smoke detectors reduce false alarms due to cigarette smoke and water vapor. In particular, Patent Documents 1 and 2 use the fact that smoke and water vapor are viscous fluids to reduce the inflow of cigarette smoke and water vapor into the smoke sensing unit. Moreover, in the thing of patent document 3, the adapter which formed the flow path which discharges the water droplet by water vapor | steam is attached to a smoke detector.

  Further, Patent Document 3 discloses that a photoelectric smoke sensor is used. However, in a photoelectric fire alarm using such a smoke sensor, an alarm taken in the housing of the alarm device is disclosed. The measurement light is irradiated to the atmosphere of the installation space by a light emitting element such as an LED, and the diffused light diffused by the fine particles present in the atmosphere is received directly or via a prism or the like by a light receiving element such as a photodiode. The presence or absence of a fire in the alarm device installation space is detected based on the level of the amount of light received corresponding to the concentration of fine particles present in the atmosphere.

  Furthermore, in the case of photoelectric fire alarms, when a fire occurrence is detected in the alarm installation space, a fire alarm signal with a voice or display for notifying the person in the alarm installation space, a remote monitoring center, etc. A fire alarm signal is output by communication to notify the occurrence of a fire.

FIG. 14 is a perspective view showing an example of a conventional photoelectric fire alarm, and this photoelectric fire alarm is a wall-hanging type. In the photoelectric fire alarm 10, a photoelectric smoke sensor (not shown) is arranged in a sensor housing 10 b protruding from the main body case 10 a. When smoke generated by a fire or the like rises through a wall due to convection, the smoke is taken into the sensor housing 10b from the slit 10c and detected.
JP 2001-34862 A JP-A-9-153187 JP 2005-293548 A

  The conventional wall-mounted photoelectric fire alarm senses smoke rising along the wall due to convection, so it has the advantage of being able to catch smoke quickly compared to a conventional smoke detector that senses smoke crawls on the ceiling. have. However, in this conventional photoelectric fire alarm, the sensor housing 10b incorporating the smoke sensor has a protruding shape. For this reason, the flow of water vapor comes into direct contact with the sensor housing 10b. Thereby, there exists a problem that water vapor | steam tends to enter into the smoke sensor in the sensor housing 10b directly, and the misreport by water vapor | steam tends to generate | occur | produce. This becomes more noticeable as the flow velocity of the rising air flow increases.

  Therefore, an object of the present invention is to reduce false alarms due to rising water vapor or the like in a wall-mounted photoelectric fire alarm.

  The fire alarm device according to claim 1 has a sensor housing in which a smoke sensor for measuring the smoke concentration in the atmosphere is housed and a slit for taking in the atmosphere is formed on the peripheral surface, and the sensor housing faces the installation wall. In the fire alarm formed to protrude from the main body case, the partition that regulates the flow of atmosphere to the sensor housing at a position below the sensor housing in a state where the fire alarm is installed A feature is provided.

  The fire alarm device according to claim 2 is the fire alarm device according to claim 1, further comprising a current plate provided so as to face the main body case and sandwich the sensor housing together with the main body case. And

  A fire alarm device according to claim 3 is the fire alarm device according to claim 2, wherein the partition wall portion also serves as a support member that supports the current plate from the main body case.

  A fire alarm device according to a fourth aspect is the fire alarm device according to any one of the first to third aspects, wherein the partition wall portion is composed of a plurality of members.

  A fire alarm device according to a fifth aspect is the fire alarm device according to the second aspect, wherein the rectifying plate is detachable.

  In the fire alarm device according to claim 1, an alarm is output when the smoke concentration detected by the smoke sensor is equal to or higher than a certain value (concentration threshold). On the other hand, since the flow of the atmosphere to the sensor housing containing the smoke sensor is regulated by the partition wall, the flow velocity of the atmosphere flowing into the sensor housing (hereinafter also referred to as “sensor inflow speed”) does not have the partition wall. Smaller than. Further, the change width of the sensor inflow speed corresponds to the change width of the flow velocity of the atmosphere outside the alarm device (hereinafter also referred to as “alarm device ambient flow velocity”). Furthermore, if the change width of the alarm device ambient flow rate is constant, the change width of the sensor inflow speed becomes smaller as the sensor inflow speed becomes smaller. Therefore, even if the flow velocity around the alarm is greatly fluctuated due to the upward flow of water vapor outside the alarm device, the large sensor inflow speed (that is, the change in concentration) can be kept small, and the large flow velocity around the alarm device. Against false alarms.

  According to the fire alarm device of claim 1, since the flow of the atmosphere to the sensor housing containing the smoke sensor is regulated by the partition wall, the flow velocity of the atmosphere flowing into the sensor housing can be reduced, such as water vapor It is possible to prevent misinformation due to the rising airflow.

  According to the fire alarm device of the second aspect, in addition to the effect of the first aspect, the sensor housing that houses the smoke sensor is covered with the rectifying plate (panel), so that the water vapor rising obliquely from below is directly applied to the sensor housing. By avoiding hitting, false alarms due to water vapor can be further reduced. In addition, it is possible to conceal the sensor housing and the partition wall from the appearance, and further, by forming the partition wall integrally with the rectifying plate, there is an effect that the addition of parts for the partition wall becomes unnecessary. It is done.

  According to the fire alarm device of the third aspect, in addition to the effect of the second aspect, since the partition wall also serves as a support member for the rectifying plate, an increase in the number of parts can be prevented.

  According to the fire alarm device of the fourth aspect, in addition to the effect of any one of the first to third aspects, the function of the partition wall can be set by a plurality of members.

  According to the fire alarm device of claim 5, in addition to the effect of claim 2, the rectifying plate is detachable, so that the alarm device can be easily assembled and disassembled after the alarm device is collected.

  Next, embodiments of the present invention will be described with reference to the drawings. 1 is a front view (FIG. 1 (A)), a side view (FIG. 1 (B)), a bottom view (FIG. 1 (C)), and FIG. 2 of the fire alarm according to the first embodiment of the present invention. It is a partially broken perspective view of a fire alarm. FIG. 2 shows a state broken along the line AA in FIG. The fire alarm device 1 of this embodiment includes a main body case 11, a cylindrical sensor housing 12 that is formed to protrude from the front surface portion 11 a of the main body case 11, and faces the main body case 11 so as to sandwich the sensor housing 12 together with the main body case 11. The panel 13 is provided as a rectifying plate. The fire alarm 1 is wall-mounted, and is installed with the back surface portion 11b of the main body case 11 in close contact with the wall W of the room and the sensor housing 12 side up.

  A smoke sensor 14 is accommodated in the sensor housing 12. As shown in FIG. 2, the sensor housing 12 is composed of a plurality of ring-shaped rims 12a and a plurality of blades 12b, 12b,. The blades 12b, 12b,... Each have an S-shaped cross section, and the gap between the blades 12b, 12b forms a passage that rotates in one direction toward the inside of the sensor housing 12. The smoke sensor 14 is a sensor that can measure smoke concentration, such as a photoelectric type, an ionization type, or a semiconductor type. In some cases, an insect screen is arranged between the rim 12a and the blade 12b (not shown). That is, a net-like metal plate (stainless steel or the like) or a resin member may be provided for the purpose of suppressing the invasion of insects, dust, and the like.

  The main body case 11 incorporates a circuit component such as a microcomputer (not shown) that performs calculation of smoke concentration, comparison with a threshold value of detected concentration, output processing of a fire alarm, etc., a speaker for notifying an alarm, and the like. . Then, the concentration signal detected by the smoke sensor 14 gives an alarm when the smoke concentration exceeds a preset threshold value. Note that the smoke density corresponds to the light attenuation rate in a standard dimming densitometer, and this attenuation rate is expressed in units of [% / m].

  A panel 13 that covers the sensor housing 12 is attached to the end portions of three columnar mounting bosses 15 a, 15 b, and 15 c erected from the front surface portion 11 a of the main body case 11. One of the three mounting bosses 15a is formed below the sensor housing 12, and this mounting boss 15a also serves as a "partition wall". Also referred to as “first partition 15a”. If the mounting bosses 15a, 15b, and 15c of the panel 13 are constituted by claws and the panel 13 is detachable from the main body case 11, the sensor housing 12 and the smoke sensor 14 are assembled and the alarm device is recovered. Is easy to disassemble.

  That is, the sensor housing 12 is disposed between the front surface portion 11 a of the main body case 11 and the panel 13, and the first partition wall 15 a is disposed at a position spaced apart from the sensor housing 12 by a predetermined distance. Yes. And the flow path (gap) of atmosphere is formed by the front part 11a of the main body case 11 and the panel 13, and the 1st partition 15a regulates the flow of the atmosphere which flows into this flow path from the downward direction.

  In the above example, the mounting bosses (first partition walls) 15a, 15b, and 15c are formed on the main body case 11 side. However, as shown in FIG. 3, the mounting boss (first partition wall) 15a. , 15b, 15c may be formed integrally with the panel 13 on the panel 13 side, and the ends of the mounting bosses (first partition walls) 15a, 15b, 15c may be attached to the main body case 11 side. Also in this case, the first partition 15 a disposed below the sensor housing 12 also serves as a “partition”.

  FIG. 4 is a velocity vector diagram of the ascending current of water vapor (atmosphere) with respect to the fire alarm 1 of the first embodiment. As shown in this figure, it can be seen that the rising water vapor hits the first partition wall 15a before hitting the sensor housing 12, and its flow is regulated. The speed of the atmosphere flowing into the sensor housing 12 is referred to as “sensor inflow speed”.

  FIG. 5 is a diagram for explaining the relationship between the position and size of the sensor housing 12 and the first partition 15a. As shown in FIG. 5A, “D” indicates the diameter of the sensor housing 12, “W” indicates the width of the first partition 15a, and “L” indicates the distance from the lower end of the sensor housing 12 to the first partition 15a. Yes. As shown in the figure, when the first partition 15a is a flat plate, “W” indicates the width.

  FIG. 5B is a diagram showing the relationship between the sensor inflow speed and the width W of the first partition 15a. As shown in the figure, as W / D increases, the first partition wall 15a acts in a direction to block the inlet to the sensor housing 12, and the sensor inflow speed decreases.

  FIG. 5C is a diagram showing the relationship between the sensor inflow speed and the distance L from the lower end of the sensor housing 12 to the first partition 15a. As shown in the figure, when L / D is small, that is, when the distance between the sensor housing 12 and the first partition wall 15a is small, the first partition wall 15a works in the direction of blocking the inlet to the sensor housing 12, and the sensor inflow speed also increases. descend.

  That is, if the distance L is too short, the flow past the first partition wall 15a hardly flows into the sensor housing 12. On the contrary, if the distance L is too long, the effect of the first partition wall 15a is weakened. As described above, since the diameter D of the sensor housing 12, the distance L from the sensor housing 12 to the first partition 15a, and the width W of the first partition 15a are in a contradictory relationship. A well-balanced adjustment is important. In the first embodiment, for example, D = 34 mm, L = 5 mm, and W = 8 mm, and FIG. 4 described above is based on simulations and experiments with these dimensions.

  FIG. 6 is a diagram showing the result of simulating the speed (sensor inflow speed) flowing into the sensor housing 12 in the fire alarm device 1 of the embodiment when there is no first partition 15a (for example, a conventional product as shown in FIG. 14). . 15 cm / s, 20 cm / s, and 40 cm / s in the figure indicate the flow velocity of the air current in the atmosphere around the fire alarm. When the velocity of the atmospheric airflow is high, the sensor inflow velocity tends to increase. There is a correlation between the sensor inflow speed and the response of the fire alarm. When the sensor inflow speed is small, the response of the fire alarm also decreases. The detection lower limit level is set to the level shown in FIG. Here, the “detection lower limit level” is an attenuation within 1 minute after the fire alarm is turned on in an air current of 20 cm / s at a concentration of 15% / m with a light reduction rate of the amount of light received by the smoke sensor 14. It is the sensor inflow speed corresponding to the case where it is performed.

  In the case of the relatively high flow rate of the conventional product indicated by “a” in FIG. 6, the flow into the sensor housing is too good, and non-fire-causing substances such as water vapor are likely to enter, and the possibility of misreporting increases. On the other hand, in the fire alarm device of the embodiment, the sensor inflow velocity close to the detection lower limit level is realized by the partition wall portion (first partition wall 15a) regardless of whether the air flow in the atmosphere such as smoke is low speed or high speed. While suppressing the flow of water vapor having a relatively high flow rate, an alarm for smoke or the like can be issued.

  FIG. 7 is a diagram showing airflow characteristics in eight directions with respect to the sensor housing 12 in the embodiment. As shown in this figure, there is no adverse effect due to the provision of the partition wall portion (first partition wall 15a) in each direction. That is, even when the flow rate is 15 cm / s, the response is made within about 30 seconds, and even under the first partition 15a, the response is made within 40 seconds.

  FIG. 8 is a partially broken perspective view (FIG. 8 (A)) and a bottom view (FIG. 8 (B)) of the fire alarm device according to the second embodiment of the present invention. In the following embodiments, elements similar to those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. In this embodiment, two plate-like second partition walls 16 and 16 are formed between the sensor housing 12 and the first partition wall 15a. The second partition walls 16, 16 are formed at a height that abuts against the back surface of the panel 13 from the front surface portion 11 a of the main body case 11, and the second partition walls 16, 16 are separated by a predetermined distance. In this embodiment, the first partition wall 15a and the second partition walls 16 and 16 correspond to “partition wall portions”.

  FIG. 9 is a velocity vector diagram of the rising airflow of water vapor (atmosphere) with respect to the fire alarm 1 of the second embodiment. As shown in this figure, the rising water vapor hits the first partition 15a before hitting the sensor housing 12, and then hits the second partition 16 so that the flow is restricted.

  FIG. 10 is a partially broken perspective view of a fire alarm according to a third embodiment of the present invention. In this embodiment, the second partition walls 17 and 17 are provided at two positions obliquely below the sensor housing 12. The second partition walls 17, 17 are formed at a height that makes contact with the back surface of the panel 13 from the front surface portion 11 a of the main body case 11. With this configuration, it is possible to obtain a more effective partition wall action against water vapor coming obliquely from below. In this embodiment, the first partition wall 15a and the second partition walls 17 and 17 correspond to “partition wall portions”.

  FIG. 11 is a partially broken perspective view of a fire alarm according to a fourth embodiment of the present invention. In this embodiment, a plurality of plate-like partition walls 18, 18,... Are provided so as to surround substantially the lower half of the sensor housing 12. A slit 18 a is provided between the partition walls 18 and 18. These partition walls 18, 18,... Are formed at a height that makes contact with the back surface of the panel 13 from the front surface portion 11a of the main body case 11. Even in this configuration, a more effective partition wall action can be obtained with respect to water vapor coming obliquely from the bottom as in the third embodiment. In this embodiment, the partition walls 18, 18,... Correspond to “partition walls”. Instead of the configuration of the plurality of partition walls 18, 18,... And the slit 18a, a plurality of through holes may be provided in a series of circular partition walls.

  FIG. 12 is a partially broken perspective view of a fire alarm according to a fifth embodiment of the present invention. In this embodiment, a plurality of plate-like partition walls 18, 18,... Are provided so as to surround substantially the lower half of the sensor housing 12, and the mesh plate 19 is fitted into the grooves inside the partition walls 18, 18,. is doing. The partition walls 18, 18,... And the mesh plate 19 are formed at a height that contacts the back surface of the panel 13 from the front surface portion 11 a of the main body case 11. In this case as well, the partition walls 18, 18,... And the mesh plate 19 can prevent water vapor from reaching the sensor housing 12. If the mesh plate 19 is a metal plate, it is effective in condensing water vapor, but may be a synthetic resin or the like. In this embodiment, the partition walls 18, 18,... And the mesh plate 19 correspond to “partition walls”.

  FIG. 13 is a diagram showing a test result when a water vapor test is performed on the fire alarm device of the embodiment and a conventional product assuming a water heater pot or a rice cooker, and the horizontal axis represents a progress after the generation of water vapor. The time and the vertical axis indicate the detected concentration [% / m] at each time. As can be seen from the figure, the conventional product sometimes exceeds the alarm point output (in the case of a false alarm), but in the embodiment, the detected concentration can be lowered below the alarm point output, and the effect of the partition wall is obtained. Further, since the sensor housing 12 is covered with the panel 13 (rectifying plate), the water vapor rising obliquely below does not directly hit the sensor housing 12. Therefore, it is possible to further reduce misinformation due to water vapor.

It is the front view, side view, and bottom view of the fire alarm which concern on 1st Embodiment of this invention. It is a partially broken perspective view of the fire alarm. It is a partially broken perspective view which shows the other example of the mounting boss | hub and panel in embodiment. It is a velocity vector diagram of the updraft of water vapor with respect to the fire alarm device of the first embodiment. It is a figure explaining the relationship between the position and size of the sensor housing and 1st partition in 1st Embodiment. It is a figure which shows the result of having simulated the sensor inflow speed in the fire alarm device of a conventional product and embodiment. It is a figure which shows the airflow characteristic of 8 directions with respect to the sensor housing in embodiment. It is the partially broken perspective view and bottom view of the fire alarm which concerns on 2nd Embodiment of this invention. It is a velocity vector diagram of water vapor rising airflow with respect to the fire alarm device of the second embodiment. It is a partially broken perspective view of the fire alarm which concerns on 3rd Embodiment of this invention. It is a partially broken perspective view of the fire alarm which concerns on 4th Embodiment of this invention. It is a partially broken perspective view of the fire alarm which concerns on 5th Embodiment of this invention. It is a figure which shows the test result of the water vapor | steam test with respect to the fire alarm device of an embodiment, and a conventional product. It is a perspective view which shows an example of the conventional photoelectric fire alarm.

Explanation of symbols

1 Fire alarm 11 Body case 12 Sensor housing 13 Panel (rectifier plate)
14 Smoke sensor 15a First partition (partition wall)
16, 17, 18 Second partition (partition wall)
19 Mesh plate (partition wall)

Claims (5)

It has a sensor housing that houses a smoke sensor that measures the smoke concentration of the atmosphere and has a slit for taking in the atmosphere on the peripheral surface. In the formed fire alarm,
A fire alarm device characterized in that a partition wall for restricting the flow of atmosphere to the sensor housing is provided at a position below the sensor housing in a state where the fire alarm device is installed.   The fire alarm device according to claim 1, further comprising a current plate that faces the main body case and is provided so as to sandwich the sensor housing with the main body case.   The fire alarm device according to claim 2, wherein the partition wall also serves as a support member that supports the current plate from the main body case.   The fire alarm device according to any one of claims 1 to 3, wherein the partition wall portion includes a plurality of members.   The fire alarm according to claim 2, wherein the rectifying plate is detachable.

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