JP4927619B2 - Smoke detection system and smoke detection method - Google Patents

Description

  The present invention relates to a smoke detection system and a smoke detection method for optically detecting contaminants such as smoke floating in the air, and more particularly to a smoke detection system and a smoke detection method using an ultra-sensitive smoke detector. It is about.

  Smoke detectors are used as detection systems for fire prevention and smoke generation, or in semiconductor manufacturing plants and food factories that require certain environmental conservation.

  This smoke detector is configured as follows (for example, see Patent Document 1). A plurality of air suction holes arranged at appropriate positions, a sampling pipe laid in a network shape, an air suction device for sucking air into the sampling pipe, and distributed inside the sampling pipe Sensitivity from a plurality of smoke detectors, a display device that receives and displays a detection signal from any one of the smoke detectors, and the smoke detectors that are disposed in proximity to the air suction device A smoke detector system having a high-capacity smoke detector.

Patent No. 3648307

  Conventional examples include a sampling pipe laid in a network, an air suction device for sucking air into the sampling pipe, a plurality of smoke detectors distributed in the sampling pipe, and any one of the above smokes A display device that receives and displays the detection signal from the detector is provided, but since the sampling tube is not shared, the occurrence of a fire can be detected, but the location of the fire cannot be specified It was. Therefore, it was difficult to effectively perform initial fire extinguishing.

  An object of this invention is to enable it to pinpoint a fire position in view of the said situation.

  The present invention relates to a sampling pipe laid in a monitoring space and provided with a suction hole, a switching valve connected to both ends of the sampling pipe, a smoke detector connected to the switching valve and sucking sampling air from the sampling pipe And a control unit that controls switching of the switching valve and discriminates a smoke detection level of the smoke detecting unit; when monitoring, opens one end of the switching valve and the sampling pipe. When the smoke detector detects smoke, switch the switching valve and the other end of the sampling pipe to the open state, and measure the time until the smoke detector detects smoke again to identify the fire occurrence position A smoke sensing system characterized by that.

  The present invention is a sampling pipe provided with a smoke detector having a smoke detecting section through which sampling air is sucked, a suction hole, and formed in a loop shape. In a smoke detection method of a smoke detection system, comprising: a sampling pipe connected to an inlet of a smoke part via a valve means; and a control part for controlling the valve means. The process of supplying sampling air into the smoke detector only from one end side with the other end opened and the other end closed, and at the time of smoke detection, the control unit opens and closes the valve means contrary to the fire monitoring. A process of supplying the sampling air into the smoke detector only from the other end side, and measuring a time from when the control unit switches the valve means to detecting smoke, and a fire occurrence position. The process of identifying Smoke sensing method using a smoke detection system characterized in that it comprises a a.

  The present invention is a sampling pipe provided with a smoke detector having a smoke detecting section through which sampling air is sucked, a suction hole, and formed in a loop shape. Since the sampling pipe connected to the inlet of the smoke part via the valve means and the control part for controlling the valve means are provided, the smoke is generated when the valve means is switched by switching the valve means. It is possible to determine the fire occurrence position based on the measurement time and the flow rate of the sampling air sucked into the sampling pipe.

  The present invention includes a sampling tube laid in a monitoring space and provided with a suction hole, a smoke detector smoke detector connected to each end of the sampling tube, and the sampling tube to the smoke detector. A control unit for controlling the suction force of the sampling air to be sucked and for determining the smoke detection level of the smoke detector, so that the balance of the suction force of the smoke detector of the smoke detector is changed. Thus, the boundary (branch point) of the sampling air can be obtained, and the fire occurrence position can be specified based on this branch point.

  The present invention relates to a loop-shaped sampling tube laid in a monitoring space and provided with a suction hole, a smoke detector having a smoke detection section disposed at two or more intervals in the sampling tube, and the sampling tube And a control unit for discriminating the smoke detection level of the smoke detection unit, as well as controlling the suction force of the sampling air sucked into the smoke detection unit from the smoke detection unit. While reducing the suction force, increase the suction force of the smoke detectors on the right side or on both sides of the smoke sensor, and increase the suction force from the nearest or both side of the smoke detectors. Measure the time required for one smoke detector to detect smoke, and identify the location of the fire based on the measurement time and suction force, that is, the flow rate of sampling air sucked into the sampling tube can do.

A first embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, a light emitting element 11 and a light receiving element 12 such as a photodiode are arranged in a dark box 21 of the smoke detector 2. A smoke detector 25 is provided at the center of the dark box 21, and the inlet 4 of the smoke detector 25 is connected to the looped sampling tube 1 via a three-way valve 30.

  The sampling tube 1 is disposed, for example, over approximately 50 m in a space where it is monitored whether or not a fire has occurred, that is, a monitoring space 32, and a plurality of sampling tubes 1 are arranged at appropriate intervals (for example, 50 cm pitch). A suction hole 34 is provided. Both ends of the sampling tube 1 are a first connection port 30a and a second connection port 30b, and the connection ports 30a and 30b leading to the smoke detector 25 are selectively provided by the three-way valve (switching valve) 30. It is opened and closed by switching to.

  The opening and closing operation of the three-way valve 30 is performed by a control unit (not shown). This control unit is connected to the light receiving element 12, determines a fire based on the output of the detection signal S of the light receiving element 12, and activates an alarm device.

  In FIG. 1, reference numeral 23 denotes an optical trap provided in the light shielding portion 22, 24 denotes a condenser lens, and 26 denotes an aperture.

Next, the operation of this embodiment will be described.
During fire monitoring:
As shown in FIG. 2, the three-way valve 30 is operated to open the first connection port 30a of the sampling tube 1 and close the second connection port 30b. When a fan (not shown) is driven in this state, the air A in the monitoring space 32 is sucked into the sampling tube 1 from the suction hole 34, introduced into the smoke detector 25 through the first connection port 30a, Thereafter, the smoke is exhausted from the smoke detector 25.

When smoke is detected:
As shown in FIG. 3, when a fire occurs and smoke is generated from the fire source 36, the smoke SM is sucked into the sampling pipe 1 together with the air A from the suction hole 34 p located directly above the fire source 36. The sampling air SA passes through the first connection port 30a and is sucked into the smoke detector 25. Therefore, the smoke particles in the sampling air SA hit the beam emitted from the light emitting element 11 passing through the smoke detecting section 25, and the scattered light generated thereby is received by the light receiving element 12.

  The light receiving element 12 that has received the scattered light outputs a detection output to the control unit. Then, the control unit determines whether or not the detection level is a fire level. When the control unit determines that the fire is detected, the control unit switches the three-way valve 30 in reverse to the time of fire monitoring, closes the first connection port 30a, and the second connection port 30b. Is opened (see FIG. 4).

  Before the three-way valve 30 is switched, the air in the monitoring space 32 is not sucked into the sampling pipe 1B on the second connection port 30b side, so the air accumulated here is in a clean state in which no smoke is mixed. The air.

  As shown in FIG. 4, when the three-way valve 30 is switched, the air A in the monitoring space 32 is sucked from the same suction hole 34p and is in the opposite direction to that at the time of fire monitoring, that is, through the suction hole 34p. And flows into the smoke detector 25 through the second connection port 30b (see FIG. 5).

  At this time, the air A staying in the sampling pipe 1B first is supplied to the smoke detector 25, and thereafter the sampling air SA mixed with smoke is supplied. Therefore, the smoke detector (smoke detector) 25 detects smoke after a while after switching the three-way valve 30 and issues an alarm.

  The control unit measures the time required from when the three-way valve 30 is switched until the smoke detector 2 detects smoke, that is, the time when there is no smoke, and based on this measurement time, the sampling tube 1 The position of the suction hole 34p that sucked in the smoke, that is, the position directly above the fire source 36 is calculated and specified.

For example, if the suction speed of the sampling air SA is v (m / s), and the time required from when the three-way valve 30 is switched until the smoke is detected is t (seconds), the smoke detection unit 25 determines that v × The position away from t (m) is the suction hole 34p directly above the fire source 36.
In this embodiment, the three-way valve 30 may always be open at both ends, and may be sucked from one end when a fire is detected and then sucked from the other end.

A second embodiment of the present invention will be described with reference to FIGS. 6 to 9. The same reference numerals as those in FIGS. 1 to 5 have the same names and functions. In addition, the control part of smoke detector 25A, 25B is connected with the receiver.
The difference between this embodiment and the first embodiment is that (1) the sampling tube 1 is a single straight tube instead of a loop, and (2) the smoke detector (smoke detector) ) Are respectively disposed at both ends of the sampling tube 1.

The operation of this embodiment will be described.
During fire monitoring:
The control unit (not shown) controls the suction force of the smoke detectors 25A and 25B of the smoke detector to the same strength. Then, the air A in the monitoring space 32 is sucked into the sampling tube 1 through the suction hole 34, but the air sucked from the monitoring space 32 with the intermediate position C of the sampling tube 1 as a boundary (branch point). A is divided into left and right, and flows into the smoke detecting sections 25A and 25B.

  Since the intermediate position (branch point) C is the middle of the sampling tube 1 in the length direction, the distance L from the smoke detector 25A to the branch point C is equal to the distance L from the smoke detector 25B to the branch point C. (See FIG. 6).

When smoke is detected:
When a fire is generated and smoke SM is generated from the fire source 36, the smoke SM is sucked into the sampling tube 1 together with the air A. However, since the fire source 36 is close to the smoke detector 25A, the air A is at an intermediate position. C is sucked into the sampling tube 1 from the suction hole 34 closer to the smoke detector 25A than C. The sampling air SA that has flowed into the sampling tube 1 enters the smoke detector 25A of the smoke detector, and smoke is detected (see FIG. 7).

  When the smoke detector 25A detects smoke, the smoke detector sends a smoke detection signal to a control unit (not shown). The control unit determines whether or not the fire is based on the detection level of the smoke detection signal. When it is determined that the fire is detected, the suction force P of the smoke detecting unit 25A is reduced or left as it is, and the suction of the smoke detecting unit 25B is determined. The force P is increased. For example, the suction force of the smoke detector 25A is set to P−ΔP1, and the suction force of the smoke detector 25B is set to P + ΔP1 (see FIG. 8).

  Note that at the stage where the smoke detector 25A detects smoke, it can be seen that a fire has occurred on the smoke detector 25A side from the intermediate position C, but the specific position is not known.

  When the balance of the suction force of the smoke detectors 25A and 25B is changed as described above, the position of the branch point C1 changes to the position of the suction hole 34a (see FIG. 8). At this time, for example, the distance from the branch point C1 to the smoke detector 25A is L-ΔL1, and the distance from the branch point C1 to the smoke detector 25B is L + ΔL1. At this time, the smoke SM is sucked from the branch portion C1 through the suction hole 34 on the smoke detecting portion 25A side, and does not flow into the smoke detecting portion 25B side.

  Next, the balance of the suction force of the smoke detectors 25A and 25B is further changed, and the suction force of the smoke detector 25A is further reduced or left unchanged, and the suction force of the smoke detector 25B is further increased. . For example, the suction force of the smoke detector 25A is set to P−ΔP2, and the suction force of the smoke detector 25B is set to P + ΔP2.

  When the suction force of the smoke detector 25B is made stronger than that of the smoke detector 25A as described above, the position of the branch point C2 changes to the position of the suction hole 34b (see FIG. 9). At this time, for example, the distance from the branch point C2 to the smoke detector 25A is L-ΔL2, and the distance from the branch point C2 to the smoke detector 25B is L + ΔL2. At this time, the smoke SM is sucked from the suction hole 34b of the branch part C2 and flows into the smoke detection part 25B, so that the smoke detector of the detection part 25B detects smoke and sends a detection signal to the control part. To do.

  The control unit calculates the position of the branch point C2 when the smoke detector of the smoke detector 25B detects smoke, and specifies the position of the fire source 36. In this embodiment, it can be seen that the fire source 36 exists immediately below the position of the distance L−ΔL2 from the smoke detector 25A or the position of the distance L + ΔL2 from the smoke detector 25B.

  6 to 9, the sampling tube 1 is one system, but the sampling tubes 1 may be arranged in parallel as a plurality of systems. Alternatively, three or more smoke detectors may be provided, and the sampling tube 1 may be disposed between the smoke detectors on both sides.

A third embodiment of the present invention will be described with reference to FIGS. 10 and 11. The same reference numerals as those in FIGS. 1 to 5 have the same names and functions. In addition, the control part of smoke detection part (smoke detector) 25A-25D is provided in the receiver which is not shown in figure.
The difference between this embodiment and the first embodiment is that two or more smoke detectors (smoke detectors) are provided at a predetermined interval, for example, four, and the sampling tube 1L is provided in a loop shape. In addition, smoke detectors 25A, 25B, 25C, and 25D of each smoke detector are provided in each branch pipe 1S branched from the sampling pipe 1L.

The operation of this embodiment will be described.
During fire monitoring:
The suction force P of each smoke detector (smoke detector) 25A, 25B, 25C, 25D is adjusted to be the same. Therefore, a boundary (branch point) exists at each intermediate position of each smoke detector 25A, 25B, 25C, 25D.

When smoke is detected:
When a fire occurs and smoke SM is generated from the fire source 36, the smoke detector 25B (smoke detector) closest to the fire source 36 detects smoke and sends a smoke detection signal to the controller. The control unit determines whether or not the received smoke detection signal is at a fire level.

  When the control unit determines that there is a fire, the suction force of the smoke detection unit 25B that detects smoke is lowered, and the suction force of the smoke detection units 25A and 25C on both sides of the smoke detection unit 25B is increased. For example, the suction force of the smoke detector 25B is P−ΔP or zero, and the suction force of the smoke detectors 25A and 25C is P + ΔP.

  Then, as in the second embodiment, the smoke detector 25A closer to the fire source 36 quickly detects smoke and sends a smoke detection signal to the controller. The control unit measures the time from when the suction force P + ΔP is changed until the smoke detection unit 25A detects smoke, and calculates the position of the fire source 36 from the measurement time.

  That is, assuming that the flow velocity of the sampling air SA at the suction force P + ΔP is v (m / s) and the measurement time is t (seconds), the suction hole 34c at a position v × t (m) away from the smoke detector 25A. There will be a fire source 36 just below. Note that the movement amount of the boundary (branch point) may be calculated as in the second embodiment.

  In 2nd Embodiment and 3rd Embodiment, although the suction power P of smoke detection part 25A, 25B, 25C, 25D of each smoke detector at the time of fire monitoring was shown in the example, it showed the example, Each suction force may not be the same. Thereby, the branch point C in the sampling tube 1 can be set freely.

The embodiment of the present invention is not limited to the above, and may be as follows, for example.
A smoke detection system includes a loop-shaped sampling tube laid in a monitoring space and provided with a suction hole, a smoke detector having a smoke detection unit disposed at a predetermined interval on the sampling tube, and the sampling And a control unit that controls the suction force of sampling air sucked from the tube to the smoke detector and determines the smoke detection level of the smoke detector.

  The smoke detector detects the smoke when one of the smoke detectors (one of the smoke detectors) detects a fire by setting the suction force of the smoke detector of each smoke detector to a predetermined value and monitoring the fire. The suction force of the most recent smoke detector (the other smoke detector) is made larger than the suction force of the smoke detector (the other smoke detector) that detects the smoke.

  When the most recent smoke detector (the other smoke detector) detects smoke, the time it takes for the smoke detector to detect smoke from when the suction force of the smoke detector is increased. And identify the location of the fire.

It is an expanded vertical sectional view which shows the smoke detector of 1st Embodiment of this invention. It is a top view which shows 1st Embodiment of this invention. It is a top view which shows the other state of FIG. It is a top view which shows the other state of FIG. It is a top view which shows the other state of FIG. It is a top view which shows 2nd Embodiment of this invention. It is a top view which shows the other state of FIG. It is a top view which shows the other state of FIG. It is a top view which shows the other state of FIG. It is a top view which shows 3rd Embodiment of this invention. It is a top view which shows the other state of FIG.

Explanation of symbols

1 Sampling tube 1L Sampling tube 2 Smoke detector 21 Dark box 25 Smoke detector 30 Three-way valve 34 Suction hole SA Sampling air

Claims (2)

A sampling pipe laid in the monitoring space and provided with a suction hole, a switching valve connected to both ends of the sampling pipe, a smoke detector connected to the switching valve and sucking sampling air of the sampling pipe, and the switching A smoke sensing system comprising: a control unit that controls switching of the valve and determines a smoke detection level of the smoke detection unit;
When monitoring, the switching valve and one end of the sampling tube are opened, and when the smoke detector detects smoke, the switching valve and the other end of the sampling tube are switched to open, and the smoke detector detects smoke again. A smoke detection system, characterized by measuring the time to fire and identifying the location of the fire. A smoke detector having a smoke detector for sucking sampling air, and a sampling tube provided with a suction hole and formed in a loop shape, which is arranged in a monitoring space and is provided at the entrance of the smoke detector in the smoke sensing method of the smoke sensing system comprising a sampling pipe which is connected via a valve means, and a control unit for controlling said valve means,
At the time of fire monitoring, opening one end of the connection part of the sampling pipe, closing the other end and supplying sampling air into the smoke detection part only from the one end side,
At the time of smoke detection, the control unit opens and closes the valve means contrary to the time of fire monitoring, and the process of supplying the sampling air into the smoke detection unit only from the other end side;
The control unit measures the time from when the valve means is switched until it detects smoke, and the process of identifying the fire occurrence position,
Smoke method of smoke detection system characterized that you have provided a.

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