RU2575206C2 - Smoke detection system of suction type - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: system comprises a pipeline facing one or a plurality of controlled areas, and sucking air in each of the controlled areas; a photoelectric smoke sensor attached to the pipeline in a position facing each of the controlled areas and detecting smoke admixed to the air, by sucking air from each of the controlled areas; a control device connected to the base end portion of the tube and sucking air from the controlled area, and electrically connected to the photoelectric smoke sensor so as to obtain and process the signal detected. The photoelectric smoke sensor comprises a portion of smoke detecting which detects smoke in the intake air, at that on the inlet side of the portion of smoke detection there is a suction opening which sucks air directly from the controlled area, and which is equipped with the base portion of the suction tube end, included in the controlled area, and a mounting port formed on the outlet side of the smoke detection portion, which is equipped with an end portion of the pipeline.

EFFECT: invention detects smoke quickly and precisely, and identifies quickly the location of the fire.

11 cl, 12 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a suction type smoke detection system that sucks air in a controlled area and detects smoke upon suction of air.

State of the art

A suction type smoke detection system is a system that draws air in a controlled area through a pipe routed to a controlled area and detects smoke mixed with air. Examples of suction type smoke detection systems include the device described in Patent Source 1. This system according to Patent Source 1 is described below.

In such a system, there is provided an air sampling tube having a plurality of drilled holes for sucking air and laid in the form of a network, an air suction device connected to this air sampling tube and sucking air into this sampling tube, a plurality of smoke sensors, distributed inside the tube for sampling air, and a display device for receiving a detection signal from any of the smoke sensors and displaying the result.

Patent Source 1: Published Japanese Patent Application No. 09-147255.

Disclosure of invention

Problems Solved by the Invention

In the above-described known suction type smoke detection system, air is widely sucked into the air sampling tube, which allows the smoke detector to detect the presence of smoke mixed with air, however, if the controlled area is segmented, etc., the optimal sampling becomes embarrassing.

For example, if there are a large number of small controlled areas, even if smoke is detected, the place of its appearance and the point of ignition is not easy to identify.

If the distance between the suction port of the air sampling tube and the smoke detector is large, the smoke is diluted and the detection of smoke is very difficult.

If there is a large difference in the distances between each of the plurality of suction openings of the air sampling tube and the smoke detector, the degree of dilution of the smoke will be different and the detection characteristics will be different.

If the area being monitored is large and the distance between the suction port of the air sampling tube and the smoke detector is large, smoke detection will take some time and early detection of fire becomes difficult.

In addition, in the case of special controlled areas where the amount of smoke generated by combustion is small, the detection of smoke with high accuracy is difficult.

The present invention has been completed in view of the above circumstances and provides a suction type smoke detection system that is capable of detecting smoke and identifying a flash point quickly and with high accuracy.

Means of solving the problem

The technical result achieved by using the proposed invention is to increase the accuracy of smoke / fire detection by attaching a smoke detector directly to the air intake pipe. To this end, a smoke detection system of the present invention is provided, comprising tubes that suck air in each controlled area, a photoelectric smoke detector that detects smoke mixed with air when air is sucked in each controlled area, and a control device that sucks air in the controlled area and is electrically connected to a photoelectric smoke detector for receiving and processing a detection signal. The photoelectric smoke detector contains a smoke detection element that detects smoke in the sucked air, a suction port located on the input side of the smoke detection element, directly sucks air in the controlled area and equipped with a base end portion of the suction tube passing into the controlled area, and an installation port located on the output side of the smoke detection element and equipped with an end portion of the tube.

Effect of the invention

According to the present invention, smoke can be detected quickly and with high accuracy. In addition, since it is possible to quickly identify the point of occurrence of a fire, response measures can be quickly taken.

Brief Description of the Drawings

FIG. 1 is a configuration diagram illustrating a suction type smoke detection system according to a first embodiment of the invention.

FIG. 2 is a sectional view illustrating a photoelectric smoke detector according to a first embodiment of the invention.

FIG. 3 is a configuration diagram illustrating an example configuration of a tube in a suction type smoke detection system according to the invention.

FIG. 4 is a configuration diagram illustrating an example configuration of a tube in a suction type smoke detection system according to the invention.

FIG. 5 is a configuration diagram illustrating an example of a tube configuration in a suction type smoke detection system according to the invention.

FIG. 6 is a side view illustrating a smoke detection element according to a first embodiment of the invention.

FIG. 7 is a top sectional view of the smoke detection element of FIG. 6.

FIG. 8 is a cross-sectional side view illustrating a smoke detection element according to a second embodiment of the invention.

FIG. 9 is a graph illustrating the characteristics of a light source of a light emitting element of a photoelectric smoke sensor according to the prior art.

FIG. 10 is a graph illustrating characteristics of a light source of a photoelectric smoke sensor according to a second embodiment of the present invention.

FIG. 11 is a top sectional view of a photoelectric smoke detector according to a first embodiment of the present invention.

FIG. 12 is a top sectional view of a photoelectric smoke detector according to a second embodiment of the present invention.

Items in the drawings

1 - suction type smoke detection system

2 - sampling tube

3 - photoelectric smoke detector

4 - control device

6 - smoke detection element

7 - suction hole

8 - mounting port

9 - suction tube

10 - connecting tube

12 - space

13 - space

14 - air inlet

16 - case

16a - inner wall of the side of the detection area

17 - light emitting element

18 - light receiving element

19, 20 - reflective element

19a, 20a - reflective surface

21 - socket for installing a light-emitting element

22 - section of the optical window

23 - socket for installing the light receiving element

23a - protruding section

24 - lens

25 - shielding plate

27, 28 - detail of the maze

27a - protruding section

31 - light emitting element

32 - light receiving element

33 - shielding plate

34 - lens

35 - plot for installing the light receiving element

35a - inclined element

35b - inclined surface

37 - reflective element

37a - reflective surface

38 - reflective element

38a - reflective surface

The implementation of the invention

(A) First option

The following is a description of a first embodiment of the present invention. The suction type smoke detection system of the present invention is a system that determines a controlled area and quickly and accurately detects smoke in that area. Such a suction type smoke detection system draws in air in each controlled area, respectively, and detects smoke during the intake of air.

The suction type smoke detection system 1 mainly comprises, as shown in FIG. 1, an air sampling tube 2, a photoelectric smoke sensor 3, and a control device 4. If a suction type smoke detection system 1 is specifically installed in each controlled area, a configuration other than described may be required, but since all such configurations are known, their description is omitted. . The same applies to the following.

Sampling tube 2 faces the controlled area to draw air from this controlled area. The sampling tube 2 is located in accordance with the controlled area. The number of monitored areas can be one or many. A sampling tube 2 is laid in accordance with these controlled areas. The sampling tube 2 is formed of a tubular element having a plurality of segments.

In addition, a suction tube 9 may extend from the sampling tube 2 to a controlled area (see FIG. 4). As a result, a sampling tube 2 is installed on each mounting port 8 of the photoelectric smoke sensor 3, which will be described later, and a suction pipe 9 is connected to the suction port 7 of the photoelectric smoke sensor 3, as described below, which allows you to create a suitable pipeline configuration in compliance with various controlled areas.

There are various configurations of such a sampling tube 2, and one of them is the L-shaped configuration shown in FIG. 1. The sampling tube 2 is connected to both ends of the L-shaped connecting pipe 10 and forms an L-shaped so as to obtain an L-shaped pipe configuration. The control device 4 is connected to the sampling tube 2 on the side of the base end of the connecting pipe 10. With the distal end of the connecting pipe 10, a sampling pipe 2 and a smoke photoelectric sensor 3 are alternately connected. More specifically, a sampling tube 2 is connected to each mounting port 8 of the photoelectric smoke sensor 3 so as to create a piping configuration in accordance with the monitored area. On the side of the distal end of the connection tube 10, a connection tube 10 or connection tubes having other angles can be used to lay the sampling tube 2 in accordance with the controlled area.

In addition, if the monitored area is a large space, as shown in FIG. 3, at certain intervals, a plurality (5 units of FIG. 3) of photoelectric smoke detectors 3 are connected by a sampling tube 2.

In addition, if the controlled area is divided into small spaces 12, for example, a plurality of energy-receiving means, as shown in FIG. 4, a suction tube 9 is connected to the suction hole 7 of each photoelectric smoke sensor 3, and each suction pipe 9 enters each of the spaces 12.

If the monitored area has a stack configuration adjacent to the height and width of a plurality of small spaces 13, as shown in FIG. 5, a photoelectric smoke sensor 3 is installed in each space 13. More specifically, all photoelectric smoke sensors 3 are connected to each other by a sampling pipe 2, a suction pipe 9 is connected to the suction hole 7 of each photoelectric smoke sensor 3, and each suction pipe 9 is located in each space 13. In each suction tube 9, air inlets 14 are made at defined intervals.

In addition to the foregoing, various tube configurations are possible. Those. various tube configurations can be implemented by placing each photoelectric smoke detector 3 in accordance with a monitored area and connecting these photoelectric smoke detectors 3 and the control device 4 with sampling tubes 2 as necessary.

The photoelectric smoke sensor 3 is a device that detects mixing of smoke with air when the control device 4 draws air from each controlled area through a sampling tube 2. A photoelectric smoke sensor 3 is attached to the sampling tube 2 and faces each of the above-described controlled areas. In addition, the photoelectric smoke sensor 3 functions as a connecting means for connecting a plurality of sampling tubes 2 forming a conduit of the suction type smoke detection system 1, as necessary. Each of these photoelectric smoke detectors 3 is assigned an address. At this address, the control device 4 can accurately determine the position of each photoelectric smoke sensor 3. As a means of specifying the addresses of each of the photoelectric smoke sensors 3, any of the known means can be used.

The photoelectric smoke sensor 3 mainly comprises, as shown in FIG. 3, smoke detection element 6, a suction port 7, and a mounting port 8.

The smoke detection element 6 is a device for detecting smoke in the intake air.

The suction hole 7 is intended for direct intake of air from a controlled area. In addition, the suction hole 7 is a hole for mounting the base end of the suction tube 9, passing into a controlled area. A suction port is located on the inlet side of the smoke detection element 6.

The suction hole 7 is cylindrical, and one of its ends is open. This suction hole 7 is designed to open toward the controlled area and to suck in ambient air. If a suction pipe 9 is installed in the suction hole 7, air is drawn in around the distal end of the suction pipe 9. The suction hole 7 is connected to the smoke detection element 6. As a result, when air is sucked in from the side of the smoke detection element 6, air around the suction hole 7 or around the distal end opening of the suction tube 9 is sucked in and flows into the smoke detection element 6.

The mounting port 8 is a hole that is inserted into the end portion of the sampling tube 2 so as to create a piping configuration of the suction type smoke detection system 1. The mounting port 8 is located on the exhaust side of the smoke detection element 6. On the exhaust side of the smoke detection element 6, there may be one mounting port 8, but in the embodiment shown, there are two mounting ports located opposite each other. A suitable sampling tube 2 is attached to these two mounting ports 8 in an appropriate manner. In addition, the suction tube 9 is connected to the suction hole 7 in a suitable manner. As a result, the piping configuration can be assembled in accordance with various monitored areas, as shown in FIG. 3-5.

The control device 4 is a device that mainly draws air from the monitored areas and processes the detection signal. The control device 4 may perform other functions, but is intended primarily to perform the two functions described above. Those. the control device 4 mainly plays the role of a suction device (not shown) that is connected to a portion of the base end of the sampling tube 2 and draws in air from the controlled portion, and a smoke detection device that is electrically connected to the photoelectric smoke sensor 3 and detects the presence of smoke by receiving a detection signal. The control device 4 is electrically connected to the light receiving element 18 of the smoke detection element 6. More specifically, a signal line (not shown) extends separately from the sampling tube 2, and the light receiving element 18 of each smoke detection element 6 and the control device 4 are electrically connected. As a result, the control device 4 knows the position of each smoke detection element 6.

The smoke detection element 6 is a device that detects smoke accompanying a fire.

The smoke detection element 6 is configured to control special devices, increasing sensitivity to smoke. More specifically, the smoke detection element 6 can be installed not only in ordinary residential buildings and in places where people gather, such as public buildings, but also in special installations, for example, semiconductor manufacturing plants, machine tools, electrical switchboards, industrial controllers and etc.in enterprises. In particular, the smoke detection element 6 is configured to control devices that, when ignited, do not generate or almost do not generate smoke.

The smoke detection element 6 detects smoke flowing into the body of the smoke sensor 3 by light. Since the photoelectric smoke sensor 3 is located in a controlled area and a sampling tube 2 is connected to it, its size should be small. Therefore, the smoke detection element 6 is small. More specifically, the smoke detection element 6 mainly comprises a housing 16, a light emitting element 17, a light receiving element 18, and reflective elements 19 and 20, as shown in FIG. 6 and 7.

The housing 16 is an element that allows the air to which smoke is mixed to flow inward. The housing 16 is provided with a light emitting element 17 located inside it, a light receiving element 18 and a reflecting element 19. In the upper part of the housing 16 there is a ventilation hole 16e in communication with the suction hole 7. In addition, in the lower part of the housing 16 there is a ventilation hole 16f in communication with the mounting port 8.

The light emitting element 17 is an element that emits control light to the smoke detection region AR. The light emitting element 17 faces the smoke detection region AR in the housing 16. The light emitting element 17 is located in the upper part (top left in FIG. 6) of the interior of the housing 16 in the socket 21. The light emitting element 17 is located in the socket 21 so that the control light is emitted from light emitting element 17 only forward. The optical window portion 22 is located in front of the socket 21 for the light-emitting element.

The light receiving element 18 is an element that detects smoke by receiving light scattered when the control light from the light emitting element 17 enters the smoke. The light receiving element 18 is in a position offset from the optical path of the control light from the light emitting element 17, and faces the smoke detection region AR. More specifically, the light receiving element 18 is in the lower left position in the interior of the housing 16 and is mounted in the socket 23 for the light receiving element. In the lower part of the socket 23 there is a light-receiving element 18, and a lens 24 is fixed above it. On the open part of the socket 23 for the light-receiving element there is a protruding section 23a that prevents diffused light from entering the light-receiving element 18.

The light receiving element 18 receives the light scattered when the control light enters the smoke, and detects smoke. More specifically, the optical axis of the light emitting element 17 and the optical axis of the light receiving element 18 are arranged so as to intersect at an angle of substantially 120 °, and the region adjacent to the intersection is the light detection region AR. As a result, if there is smoke in the smoke detection region AR, the control light from the light emitting element 17 is scattered by the smoke and the scattered light is incident on the light receiving element 18, whereby the presence of smoke is detected.

The light-receiving element 18 detects smoke due to the incident light scattered on it, but more specifically, when the amount of the incident light incident on it exceeds a threshold value, a control signal is transmitted to the control device 4, notifying of the presence of smoke. The light receiving element 18 allows you to adjust the threshold value using the control device 4. As a result, the light receiving element 18 can be set in the range from the usual threshold value for detecting smoke with high accuracy to an increased threshold value and low accuracy for detecting smoke with low accuracy. Such an adjustment function can be incorporated into the control device 4. More specifically, a threshold value is set in the control device 4, and if the amount of stray light incident on the light receiving element 18 is changed, a control signal is transmitted to the control device 4, regardless of the amount of incident light. Then, the control device 4 detects the generation of smoke, emitting a detection signal from the light receiving element 18 by a threshold value. Then this threshold value becomes adjustable.

A shielding plate 25 is located between the light emitting element 17 and the light receiving element 18 (to the left of the smoke detection region AR), and this shielding plate 25 prevents the control light from directly entering the light receiving element 18 without diffusion.

Two labyrinth parts 27 and 28 are located to the right of the socket 23 for the light-receiving element 18. The labyrinth part 27 is formed with an inclination in the up and right directions so as to direct the air flow from the bottom along its lower side in the up and right directions. In addition, the end portion in the upper direction of the labyrinth part 27 is bent upward to the left. The labyrinth piece 28 is inclined upward to the left and is located on the top left with respect to the labyrinth part 27. These labyrinth pieces 27, 2 8 prevent ambient light from entering.

The reflecting elements 19, 20 are elements that deflect and reflect the control light emitted by the light emitting element 17 so that it does not fall on the light receiving element 18. The reflecting elements 19 and 20 are located on the inner wall 16a on the side of the detection area of the housing 16 in positions opposite to the light emitting element 17, spanning the detection region AR (see FIG. 6). Reflecting elements 19, 20, as shown in FIG. 6 extend across the entire region in a vertical direction on the inner wall 16 a on the side of the detection region. In addition, the reflective elements 19 and 20, as shown in FIG. 7 are provided with reflective surfaces 19a and 20a having a flat shape and inclined to create a V-shape. The reflective surfaces 19a and 20a are surfaces that deflect and reflect the control light from the light emitting element 17 away from the light receiving element 18. The reflective surface 19a is made larger than the reflective surface 20a. The reflecting surface 19a is located on one surface 16c of the side wall of the housing 16 and occupies a wide area. The reflective surface 20a is located on another surface 16d of the side wall of the housing 16 and occupies a smaller area than the reflective surface 19a. As a result, the control light emitted by the light emitting element 17 is reflected asymmetrically from two reflective surfaces. In case of asymmetric reflection of light from two reflective surfaces 19a and 20a, the reflected light is reflected not towards the light receiving element 18 (deviates from the light receiving element 18), as shown in FIG. 7. The areas and angles of inclination of the two reflective surfaces 19a and 20a relative to the light emitting element 17 are set so that the reflected light does not fall on the light receiving element 18.

Part of the reflected light is reflected from the reflecting surfaces 19a and 20a twice, since they are located in the form of the letter V, and changes direction by 180 °. However, if the control light is reflected twice, its brightness decreases sharply and the amount of light decreases sharply. Thus, even if the light is reflected twice (hereinafter referred to as "secondary reflected light") and gets on the light receiving element 18, this will not be a problem, since such light is extremely weak.

In addition, the details, in addition to the above, are practically unlimited. Configurations that can be integrated into a known photoelectric smoke sensor (peripheral configuration of known photoelectric smoke sensors) can also be used in the present invention.

The suction type smoke detection system 1 configured as described above operates as follows.

When the control device 4 is operating, air from the controlled area is sucked from the suction port 7 through the sampling tube 2. If a suction tube 9 is connected to the suction port 7, air is inside the switchboard, and the like. is sucked through the distal end of the suction tube 9. The sucked air flows into the smoke detection element 6.

In the smoke detection element 6, the control light emitted by the light emitting element 17 towards the detection region AR penetrates the detection region AR and irradiates the reflecting elements 19 and 20. In addition, part of the control light irradiates the side wall surfaces 16c and 16d, but this light is reflected by the surfaces 16c and 16d of the side wall and irradiates the reflective elements 19 and 20.

The reflecting elements 19 and 20 reflect light asymmetrically with the reflecting surfaces 19a and 20a forming a V-shape and do not allow the reflected light to hit the light receiving element 18. A part of the reflected light is directed towards the light receiving element 18, but this is not a problem since such light has been reflected twice or more, as described above, and is greatly attenuated.

The light reflected by the reflective surfaces 19a and 20a irradiates the side wall surfaces 16c and 16d. Most of the reflected light reflected by the reflective surfaces 19a and 20a irradiates the side wall surfaces 16c and 16d and is reflected by the side wall surfaces 16c and 16d. In addition, most of the light reflected by the side wall surfaces 16c and 16d also irradiates the opposite side wall surfaces 16c and 16d and is reflected again. As a result, the reflected light is collected at the periphery of the detection portion AR and repeats the reflection, and most of the light no longer enters the light receiving element 18.

If in this state smoke enters from the outside, which reaches the detection region AR, the control light from the light emitting element 17 is incident on the smoke and scattered, and the diffused light is incident on the light receiving element 18, which determines the presence of smoke. At this time, since the reflected light is also distributed around the periphery of the detection portion AR, scattered light is also generated in this region, and the amount of scattered light in the housing 16 is increased.

As a result, the incidence of reflected light, which becomes noise, on the light emitting element 17 can decrease sharply and at the same time the amount of light scattered by the smoke can increase, and therefore, the light receiving element can detect the presence of smoke with greater accuracy.

If the sensitivity of the smoke detection element 6 is reduced, smoke will be detected when a large amount of smoke is generated as a result of the fire.

When the smoke detection element 6 determines the presence of smoke, a detection signal is transmitted to the control device 4.

Since the control device 4 knows the position of the smoke detection element 6, which detected the presence of smoke, at its address, upon receipt of the detection signal, the control device 4 identifies a fire and a fire position. After that, the control device 4 displays or transmits information about the fire and, if necessary, the position of the fire.

As a result, the smoke detection element 6 with a sensitivity set in accordance with the situation in the controlled area can detect the presence of smoke generated directly in the controlled area and detects ignition at an early stage.

In a smoke detection system using a sampling tube known in the art, if the number of sampling openings is increased, the smoke is diluted and time elapses from the moment smoke is generated until the smoke is detected. In addition, if the length of the laid sampling tube is large, it takes time for the smoke to reach the smoke detector, and the presence of smoke is delayed.

For example, if the threshold sensitivity of the warning system is set to 0.2% / m, and the illustrative smoke detection system has 30 sampling openings, smoke will not be detected and an alarm will not be issued even if the smoke is very close to the sensor, while through 6 holes the concentration of 0.75% / m will not be sucked. In the final section farthest from the smoke detector, the number of holes needed to detect smoke was further increased. In particular, in the case of a total tube length of 45 m, 8 holes were required to issue an alarm, and smoke was detected only after a very long time - 1 min 20 s.

On the other hand, when using the suction type smoke detection system 1 of the present embodiment, since the sampling holes in the sampling tube are replaced by a photoelectric smoke sensor 3, it becomes possible to directly detect smoke at a place of its generation by a nearby photoelectric smoke sensor 3. Thus, there is no problem of smoke dilution arising from an increase in the number of sampling openings, or a detection delay caused by elongation of the sampling tube. When lengthening the sampling tube, there is no problem with detection delay. In addition, since each photoelectric smoke detector has its own address, the place where smoke was generated can be easily identified.

Those. smoke can be detected with great accuracy and quickly, and the place where the smoke is generated can be identified.

In addition, if the controlled area is, for example, an enterprise or the like, where a certain amount of smoke can occur during normal operation, it becomes possible to respectively detect smoke depending on the location of the controlled area, increasing the above threshold value so as to reduce the sensitivity of the element 6 smoke detection.

As a result, smoke can be detected with high accuracy and quickly, and the place where the fire occurred can be identified, while at the same time maintaining the small size of the device, like the well-known photoelectric smoke sensor.

(B) Second Embodiment

The following is a description of a second embodiment of the invention.

In this embodiment, the smoke detection element 6 of the photoelectric smoke sensor 3 is improved. More specifically, the light source, the shielding plate and the protruding portion of the maze and other details of the smoke detection element 6 are improved.

In this embodiment, as shown in FIG. 8, the amount of light from the above light emitting element 31, which is the light source, is increased. In addition, the directivity of the light source has been improved. The output angle of the pilot light is narrowed. More specifically, directivity is improved, as shown in FIG. 10, compared with a light source known in the art, the characteristics of which are shown in FIG. 9 to get a thin ray of light. Those. the pilot light beam became thinner and stronger than the pilot light in the prototype.

The shield plate 33 in FIG. 8 is an element mounted between the light emitting element 31 and the light receiving element 32, and prevents the control light from the light emitting element 31 from directly reaching the light receiving element 32.

The shielding plate 33 is located on the side of the light emitting element 31 so as to be closer to this light emitting element 31 and further from the light receiving element 32.

The light receiving element 32 is retracted from the shielding plate 33 by reducing the focal length of the lens 34 so that the total length of the socket 35 for the light receiving element is small. As a result, the front of the light receiving member 32 is expanded and the angle of incidence of the light is expanded. This angle of incidence of light is the angle at which light can enter, i.e. the angle of incidence of the scattered light that enters the light-receiving element 32. By expanding this angle of incidence, it is possible to increase the amount of scattered light that can reach the light-receiving element, that is, to increase the signal strength.

The tilt element 35a is located inside the lens 34 in the socket 35 of the light receiving element. The tilt member 35a is positioned so as to internally cover a portion of the peripheral edge of the lens 34. On the surface of the tilt member 35a there is a conical tilt surface 35b. The conical (inclined) surface 35b is a reflective surface for reflecting reflected light incident on the socket 35 of the light receiving element. If the control light from the light-emitting element 31 is reflected in the housing 16, most of the reflected light is shielded by a shielding plate 33 and the like, but part of such light can enter the socket 35 of the light-receiving element. Such reflected light in many cases falls on the periphery of the lens 34. Therefore, the inclined surface 35b located on the periphery of the lens 34 reflects the reflected light from the receptacle 35 of the light receiving element back out and prevents the light receiving element 32 from being illuminated. It is only necessary that the inclined surface 35b can reflect light, but it can be mirrored for more effective reflection.

In addition, the protruding part 27a of the labyrinth part 27 and the protruding part 23a in the hole of the light receiving element 18 are removed. This is because there is a possibility that these protruding portions 27a, 23a will reflect the control light and allow it to reach the light receiving element 32.

In addition, since the light receiving element 32 has a wider angle of incidence of light, it receives more diffused light and detects smoke.

As a result, the amount of reflected light incident on the light receiving element 32, which generates noise, can be sharply reduced, and the amount of diffused light incident on the light receiving element 32 can be increased, and therefore, the presence of smoke can be determined with greater accuracy.

As a result, the operation and effect are similar to the first embodiment of the invention.

(C) Option

In each of the above embodiments, the smoke detection element 6 contains components such as reflective elements 19 and 20 and the like, but the smoke detection element 6 according to the first and second embodiments does not limit the present invention, since all smoke detection element configurations are the first embodiment and the second embodiment can be combined. Other combinations may also exist. Any of the two or more components that make up the described invention in each of the above options can be combined to configure the smoke detection element 6 as necessary. In this case, the work and effects are similar to those described above.

In the first embodiment, the reflective surfaces 19a and 20a form a V-shape created by the reflective elements 19 and 20 of the smoke detection element 6, but as shown in FIG. 11, one large reflective surface 37a can be used on one large reflective element 37. As a result, the control light is reflected by the reflective surface 37a and irradiates the entire side wall surface 16d, and is reflected from this side wall surface 16d. Therefore, the second reflected light is sharply attenuated. In this case, the work and effects are similar to those described above for the first embodiment of the invention.

Furthermore, as shown in FIG. 12, a curved reflective surface 38a may be located on the reflective element 38. The reflective surface 38a may be formed so that reflected light is collected in the detection region AR and at its periphery, for example, in the form of a concave mirror of a reflecting telescope. Those. the reflective surface 38a may be curved so that the control light and reflected light are collected in the detection region AR and at its periphery, and that more diffused light generated by the smoke entering the housing 16 can be generated. In this case, the reflective surface 38a can be formed as mirror surface. By forming surface 38a as a mirror surface in the detection region AR and at its periphery, more reflected light can be collected.

With such a configuration, smoke can be detected with greater accuracy.

In each of the above embodiments, an example is provided in which there are a plurality of photoelectric smoke sensors 3, however, the suction type smoke detection system 1 of the present invention can be applied even with one photoelectric smoke sensor 3.

In each of the above options, since the sensitivity of each of the photoelectric smoke sensors 3 can be individually adjusted, the optimal sensitivity can be set in accordance with the situation in each controlled area. For example, in a place where smoke may be generated that is not associated with a fire, sensitivity is lowered. In a place in which smoke not associated with the fire does not occur at all, sensitivity is increased. In particular, in places where even during a fire there is little smoke, sensitivity increases to a maximum. If in one place there are many controlled areas and the situations in each of the controlled areas are different from each other, the sensitivity of each of the photoelectric smoke sensors 3 is adjusted in accordance with the corresponding situation in the controlled areas. As a result, an optimal smoke detection system can be created.

In each of the above embodiments of the invention, the control device 4 is described as a device that performs the function of detecting smoke and the like, however, in addition, the control device 4 may include a display unit for displaying information about the occurrence of a fire and the location of the fire. As a result, the operator can easily find out about the place of occurrence of the fire and quickly take measures to extinguish the fire.

In addition, the control device 4 may include alarm notification means for notification of a fire. There may be a transmitter to send the notification to another location. This allows you to quickly take measures to extinguish the fire.

Claims (11)

1. A suction type smoke detection system comprising:
a pipeline located facing one or a plurality of controlled areas, and suction air from each of the controlled areas;
a photoelectric smoke detector attached to the pipe in a state in which it is facing each of the monitored areas, and detecting smoke mixed with air when air is sucked from each of the monitored areas, the photoelectric smoke sensor being additionally configured as a transmission signal for the detection signal;
a control device connected to the base end portion of the suction tube passing into the controlled area, and suction air from the controlled area, and electrically connected to the photoelectric smoke sensor so as to receive and process the detection signal and identify the position of occurrence of the fire by the detection signal, while
photoelectric smoke detector contains:
a smoke detection element that detects smoke in the intake air;
a suction port provided on the input side of the smoke detection element through which air is directly sucked from the controlled area and into which the base end portion of the suction tube passing to the controlled area is inserted; and
at least one mounting port provided on the outlet side of the smoke detection element to which an end portion of the pipeline is connected. 2. The system of claim 1, wherein
two mounting ports of the photoelectric smoke detector installed opposite each other on the exhaust side of the smoke detection element
a pipeline is connected to each of the mounting ports, and the suction pipe is connected to the suction port accordingly to arrange the configuration of the pipeline in accordance with different controlled areas. 3. The system of claim 1, wherein
the control device identifies the position of the occurrence of fire according to the position information of the photoelectric smoke sensor, which is contained in the detection signal. 4. The system of claim 1, wherein
the sensitivity of the smoke detection element of the photoelectric smoke sensor located in each of the plurality of controlled areas is adjusted to the optimum sensitivity in accordance with the situation in each controlled area. 5. The system of claim 1, wherein
the smoke detection element of the photoelectric smoke sensor further comprises:
a housing into which air flows with mixed smoke;
a light emitting element facing the detection area in the housing and emitting control light to the detection area;
a light receiving element facing the detection region at a position offset from the optical path of the control light of the light emitting element, receiving light scattered when the control light enters the smoke, and detecting smoke; and
a reflective element located in the housing and deflecting and reflecting the control light emitted by the light emitting element so that the control light does not fall on the light receiving element. 6. The system of claim 5, wherein
the reflecting element is located opposite the light-emitting element and the light-receiving element, covering the detection area, and reflects the control light of the light-emitting element not towards the light-receiving element. 7. The system of claim 5, wherein
the reflective element is located opposite the light emitting element and the light receiving element, covering the detection area, and reflects the control light of the light emitting element in a direction converging to the detection area. 8. The system of claim 5, wherein
the amount of light of the radiation source of the light emitting element is increased and its directivity is enhanced. 9. The system of claim 5, wherein
a shielding plate that is installed between the light-emitting element and the light-receiving element and prevents the control light from falling from the light-emitting element directly onto the light-receiving element, is located closer to the side of the light-emitting element, and, in addition, the focal length of the lens of the light-receiving element is made short to move the light-receiving element from the shielding element plate and expand the angle of incidence of light on the light receiving element. 10. The system of claim 5, wherein
a labyrinth is made in the housing to prevent spurious light from entering and smoke to enter, and the protruding part of the labyrinth and the protruding part of the hole in the light receiving element are removed. 11. The system of claim 5, wherein
the light-receiving element is attached together with the lens to the socket for the light-receiving element, an inclined element is made inside the lens in the socket of the light-receiving element, the inclined element having an inclined surface that reflects the reflected light incident on the periphery of the lens in the socket for the light-receiving element, outward from the socket for the light-receiving element .

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