JP4623608B2 - Fire detector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a fire detector that detects the occurrence of a fire by detecting a radiant energy obtained by observing a flame, and in particular, a translucent light provided on the front surface of a detection sensor. Automatic compensation function for window stainsFire detectorAbout.
[0002]
[Prior art]
Conventionally, various facilities are installed in a tunnel, such as a tunnel for a vehicle or a railway, in order to ensure traffic safety. A vehicle tunnel facility will be briefly described with reference to the drawings.
[0003]
As shown in FIG. 17, a tunnel 90 includes an illumination lamp 93 such as a sodium lamp that secures a view inside the tunnel 90, a fire detector 94 that detects a fire that has occurred in the tunnel 90, and when a fire is detected. A water spray head 95 that prevents the spread of fire by spraying water, a fire hydrant facility 96 that houses a water discharge nozzle, a hose, etc., a jet fan 97 that ventilates the inside of the tunnel 90, and an emergency passage and exit are recognized by the evacuees, Various facilities are provided such as a guidance indicator lamp 98 for guiding, an emergency telephone for reporting an emergency situation in the tunnel 90, and a radio rebroadcast guidance line for radio broadcasting.
In particular, the fire detector 94 detects a vehicle fire or the like in the tunnel 90 and promptly notifies the tunnel manager or the vehicle driver with a predetermined interval on the wall surface where the line of sight in the tunnel works, for example, They are arranged at intervals of 25 m.
[0004]
Next, an example of a conventional fire detector installed in the tunnel will be described with reference to the drawings.
FIG. 18 is a schematic configuration diagram of a fire detector generally used conventionally. The configuration of such a fire detector is described in, for example, Japanese Patent Application Laid-Open No. 7-175986.
As shown in FIG. 18, the fire detector 100 has a dome-shaped light receiving glass 101 in which light receiving elements (detection sensors) 102a and 102b for detecting radiation emitted from a flame are housed in the center of a casing (case). A dome-shaped glove 103 that contains a check lamp that is used when detecting the dirt state of the light receiving glass 101 and the like is arranged.
[0005]
The dome-shaped light receiving glass 101 in which the light receiving elements 102a and 102b are housed is installed so as to protrude from the tunnel inner wall surface 91, and each of the light receiving elements 102a and 102b has a center line perpendicular to the tunnel inner wall surface 91 as a boundary. The area AL on the left side of the drawing and the area AR on the right side of the drawing are individually monitored. Therefore, the light receiving elements 102a and 102b have a dome-shaped light receiving glass 101 at an angle of approximately 45 degrees with respect to the inner wall surface 91 of the tunnel in order to set a large detection area with respect to the longitudinal direction of the tunnel (the horizontal direction in the drawing). It is installed inside.
[0006]
An arrangement form of such a fire detector in the tunnel will be described with reference to the drawings.
FIG. 19 is a schematic diagram illustrating an arrangement form of the fire detector 100 in the tunnel 90 and a setting state of a monitoring area (detection area).
As shown in FIG. 19, the fire detectors 100a, 100b, 100c, 100d,... Are arranged on the side of one tunnel inner wall surface 91 on the side of the tunnel 90 at every constant separation distance (interval) L, as described above. The fire detectors 100a, 100b, 100c, 100d,... Have predetermined monitoring areas Ax, Ay, Az on the left and right sides in the tunnel longitudinal direction with reference to the respective installation center lines. Here, each monitoring area Ax, Ay, Az is set so as to include at least an arrangement position of the fire detectors arranged adjacent to each other, and each of the monitoring areas Ax, Ay, Az is adjacent to each other. The monitor is set to be monitored in a complementary manner.
[0007]
Specifically, each of the fire detectors 100a, 100b, 100c, 100d,... Is arranged on the tunnel inner wall surface 91 on one side, for example, at an interval of 25 m, and the monitoring area of the fire detector 100b is set to Ax and Ay. When the monitoring area of the fire detector 100c is set to Ay and Az, the monitoring area Ay is set to be a monitoring target by the fire detectors 100b and 100c in an overlapping manner (complementarily). ing.
According to such an arrangement form of the fire detector, it is possible to suppress the occurrence of a blind spot (shade) in the monitoring area of the fire detector due to a vehicle or the like (obstacle) stopped due to a vehicle failure or the like in the tunnel. Therefore, good fire monitoring can be performed.
[0008]
By the way, when the fire detector is installed on the inner wall surface of the tunnel, the light receiving glass 101 of the fire detector 100 projects from the inner wall surface 91 of the tunnel into the tunnel as described above. This is because the light receiving element housed in the light receiving glass 101 is inclined at an angle of approximately 45 degrees with respect to the wall surface in order to efficiently monitor the position where the adjacent fire detector 100 is disposed without generating a non-monitoring area. This is because the light receiving glass 101 inevitably protrudes greatly into the tunnel due to the installation.
[0009]
Therefore, as shown in FIG. 20, the light receiving glass 101 is always exposed to the airflow C generated in the tunnel due to traveling of the vehicle, ventilation of the jet fan, and the like. The airflow C generated in the tunnel includes an airflow that flows predominantly at about 2 m to 10 m / s in one direction in the longitudinal direction in the tunnel, an irregular turbulent airflow generated when the vehicle passes, and the like. There are various directions of airflow in the tunnel.
Here, various substances that cause dirt (hereinafter collectively referred to as dirt-causing substances) such as smoke, dust, earth and sand, chemical substances such as anti-freezing agents, etc. discharged from vehicles float in the tunnel. Therefore, these substances fly on the air current, and directly collide with the upstream side of the air flow of the dome-shaped light receiving glass 101 and adhere as dirt D. In addition, although dirt adheres other than the upstream side of the air flow of the light receiving glass 101, the degree of dirt is about a fraction of that of the upstream side where the air current directly collides. Such contamination of the light receiving glass 101 reduces the amount of light received by the light receiving elements 102a and 102b accommodated therein, thereby lowering the detection sensitivity. Therefore, in order to maintain the performance of the fire detector for a long period of time. Had the problem of having to perform frequent cleaning work.
[0010]
In order to solve such a problem, as shown in FIG. 20, a check lamp (glove 103) that emits test light for detecting the contamination state of the light receiving glass 101 is provided around the dome-shaped light receiving glass 101. There is known a method of contamination compensation processing that is arranged and periodically detects a contamination state to automatically compensate for a decrease in detection sensitivity by electrical processing and reduce the frequency of cleaning work. Note that the method for avoiding the influence of stain by the stain compensation process is described in detail in, for example, Japanese Patent Laid-Open Nos. 6-325274 and 5-314376.
[0011]
As a schematic configuration of a radiant fire detector to which the fouling compensation processing is applied, for example, as shown in FIG. 21, it is roughly classified into a pyroelectric type that detects radiant energy (particularly, infrared energy) from a flame or the like. A detection sensor 110 having a light receiving element, a pre-filter 120 that passes only a signal component Ap in a specific frequency band used for flame determination processing from a detection signal Sp detected and output by the light receiving element, and a pre-filter A preamplifier 130 that first amplifies the signal component Ap that has passed through the filter 120 to a predetermined signal level, a main amplifier 140 that amplifies the output from the preamplifier 130 to a signal level suitable for signal processing described later, and an output from the main amplifier 140 An analog-to-digital converter (hereinafter referred to as an A / D converter) that converts the amplified output (analog signal) Bp into a digital signal. ) And 150, based on the amplified output which is converted A / D, a signal processing unit which performs the detection judgment process of the flame such as the (fire determination processing unit) 160 is configured to have a. Here, a translucent window 111 for protecting the detection sensor 110 made of sapphire glass or the like is provided on the front surface (detection area side) of the detection sensor 110.
[0012]
In such a fire detector, when the flame FR is observed by the detection sensor 110, a detection signal Sp corresponding to the radiation energy of the flame FR is output, and only the signal component Ap in the frequency band used for fire determination is extracted. Amplified and input to the signal processing unit 160. That is, a fire determination process is executed based on signal components included in a specific frequency band.
In the stain compensation process, test light (pseudo flame light: flickering in a specific frequency band) is projected to the detection sensor 110 from the test light source 170 provided independently of the detection sensor 110 during the test. Then, the detection signal Sp corresponding to the contamination state of the translucent window 111 is output, and only the signal component Ap having a predetermined frequency band is extracted, amplified with a predetermined amplification factor, and input to the signal processing unit 160. Is done. At this time, the light receiving output level is determined by the signal processing unit 160, and when it is determined, for example, that the level is equal to or lower than a predetermined threshold value due to contamination of the translucent window, a signal level that does not hinder fire detection is determined. In this manner, the gain (gain) of the signal amplifier is changed and controlled. As a result, even if the translucent window 111 is stained, the received light output level is compensated by electrical processing to ensure the detection sensitivity as a fire detector and reduce the frequency of cleaning work. It was.
[0013]
[Problems to be solved by the invention]
However, the conventional technology as described above has the following problems.
(1) In the fire detector described above, as shown in FIG. 22, the signal component Ap included in a specific frequency band is detected from the detection signal Sp output from the detection sensor 110 as a signal amplifier (preamplifier 130 and When amplifying by the main amplifier 140), the noise component Np included in the frequency band is also amplified with a predetermined amplification factor together with the original fire detection component Dp. For example, in the conventional fire detector, the amplification factor of the signal amplification unit can be changed and controlled up to several tens of thousands of times according to the state of contamination of the translucent window. For this reason, the absolute level of the noise component Np ′ included in the amplified output Bp output from the main amplifier 140 to the signal processing unit 160 is also amplified, for example, up to several tens of thousands of times. It would have an impact, and there was a possibility that an accurate fire judgment could not be performed. FIG. 22 is not a measured value of the flame itself, but a conceptual diagram for facilitating the explanation.
[0014]
(2) Further, in the detection sensor 110, the detection area and the detection sensitivity over time due to deterioration in characteristics of the light receiving element provided in the detection sensor 110, contamination of the protective translucent window disposed in front of the light receiving element, and the like. If the detection sensitivity is adjusted automatically in response to changes in the level, or if the detection area or detection sensitivity is adjusted at the site where the fire detector is installed, the control range for changing the amplification factor in the signal amplification section is narrow. The amplification margin was low. For this reason, the detection performance of the fire detector is likely to vary, and there is a possibility that accurate fire determination may not be performed.
[0015]
  Therefore, in view of such problems, the present invention can greatly improve the performance of the automatic compensation function against the contamination of the translucent window provided on the front surface of the detection sensor with a simple configuration.Fire detectorThe purpose is to provide.
[0016]
[Means for Solving the Problems]
  The invention described in claim 1 has one or more light receiving elements, respectively.In addition, it has a detection sensitivity that can be combined in combination to correspond to the contamination compensation stage by combining detection sensitivity, which is planned according to the degree of contamination of the translucent window.The detection sensitivity of at least one detection group among multiple detection groups is,The detection sensitivity of other detection groupsDifferent, saidBased on the contamination state of the translucent window, the contamination compensation processing is performed by monitoring the fire by changing the summation synthesis pattern of the output signals from the plurality of detection groups.
[0017]
  Claim 2The inventionThe fire detector according to claim 1,The detection sensitivity is set to be different depending on the number of the light receiving elements included in the detection group.
[0018]
  Claim3DescribedThe inventionClaim1 or 2In the fire detector described,The detection sensitivity is set to be different depending on the size of the light receiving element.
[0019]
  According to a fourth aspect of the present invention, in the fire detector according to any one of the first to third aspects, the fouling is performed for every set state of the detection sensitivity.compensationIt is characterized by performing processing.
[0020]
  Claim5DescribedThe inventionClaim1 to 4In the fire detector described,A light source for testing and a light transmissive window for protecting the light source that protects the light source, and the light transmissive window for protecting the light source is located above the position where the light transmissive window is installed when the fire detector is installed. And disposed so as to form a flat surface parallel to the longitudinal direction of the tunnel, irradiated from the light source for testing, and transmitted through the light-transmissive window for protecting the light source and the light-transmissive window. The contamination compensation process is performed based on the intensity of the test light received by the light receiving element or the test light receiving element.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
  First, the overall configuration of the fire detector according to the present invention will be described with reference to the drawings.
  FIG. 1 is a schematic block diagram showing an example of the overall configuration of a fire detector according to the present invention.
  As shown in FIG. 1, the fire detector according to the present invention is roughly divided into a first detection unit DET1 for monitoring the first fire monitoring area and a second detection unit for monitoring the second fire monitoring area. From DET2, the first detection unit DET1 and the second detection unit DET2ofA signal processing unit PRO that determines the occurrence of a fire based on the output signal and controls the operating states of the first detection unit DET1 and the second detection unit DET2 is configured. In addition, a plurality of fire detectors are connected to the disaster prevention monitoring panel DC installed in the disaster prevention center where the disaster prevention manager is stationed. Information on the detected fire, instructions during the test operation, etc. via the signal processing unit PRO Are sent and received.
[0036]
The first detection unit DET1 and the second detection unit DET2 have substantially the same configuration. For example, when installed in a tunnel, the first fire monitoring is performed on one side (for example, the right side) in the tunnel longitudinal direction. The other side (for example, the left side) is set as a second fire monitoring area, and each fire monitoring area is monitored individually, or some areas are overlapped to monitor the occurrence of fire.
Hereinafter, each configuration will be described in detail.
The first detection unit DET1 and the second detection unit DET2 (hereinafter referred to as “DET” by integrating symbols) are sensor units (detection sensors and detection sensors for detecting the degree of contamination) SEN1, SEN2 (hereinafter referred to as symbols). Integrated and described as “SEN”), filter units FLT1 and FLT2 (hereinafter referred to as “FLT”), and addition amplifiers (amplifying means) AMP1 and AMP2 (hereinafter referred to as symbols) "AMP"), A / D converters 50a and 50b (hereinafter referred to as "50" by integrating the symbols), and switch control units (output number variable control means) 70a and 70b (hereinafter referred to as symbols). Integrated and described as "70"), test light source control units (test light source control means) 80a and 80b (hereinafter referred to as "80"), test light sources LGT1 and LGT2 (hereinafter referred to as "reference numerals"). Combined and described as “LGT” When, to protect the sensor unit SEN1, SEN2 respectively, translucent window TG1 for transmitting infrared energy, TG2 (hereinafter, integrating code referred to as "TG") has a, a. As described above, since the first detection unit DET1 and the second detection unit DET2 have the same configuration, the following description refers to a configuration common to both unless otherwise specified. Shall.
[0037]
The sensor unit SEN includes a plurality of light receiving elements to be described later, converts the infrared energy (light energy) of the flame into an electrical signal, and outputs the detection signal individually for each light receiving element.
The filter unit FLT is a frequency filter provided for each of a plurality of light receiving elements provided in the sensor unit SEN, and has a function of allowing only a signal component of a predetermined frequency band to pass from each detection signal output from each light receiving element. have.
The addition amplification unit AMP performs addition (integration) processing on each detection signal that has passed through the filter unit FLT, and further amplifies the detection signal subjected to the addition processing at a predetermined amplification factor. Here, the addition amplifying unit AMP is configured to be able to arbitrarily change and set the number of detection signals to be added (the number of outputs of the light receiving elements to be amplified).
[0038]
The A / D converter 50 converts the amplified output obtained by the addition amplification by the addition amplification unit AMP from the analog signal to a digital signal suitable for the fire determination process in the signal processing unit PRO at the subsequent stage and outputs the digital signal.
Based on a control command sent from the signal processing unit PRO, the switch control unit 70 controls the number of outputs of the light receiving elements to be added in the addition amplification unit AMP to a predetermined setting state.
During the test, the test light source control unit 80 controls the test light source LGT to blink based on a control command sent from the signal processing unit PRO, and detects predetermined test light (pseudo flame light: blinking in a specific frequency band). Light is emitted to the unit SEN.
In a normal fire monitoring operation (fire monitoring mode), the signal processing unit PRO determines the occurrence of a fire based on the light reception output level output from the addition amplification unit AMP via the A / D converter 50. Perform fire judgment processing.
[0039]
  Further, in the test operation (test mode) associated with the stain compensation process, a control command is sent to the test light source control unit 80 to control blinking of the test light source LGT, and based on the detection signal output from the sensor unit SEN at that time. Then, the contamination state of the translucent window TG arranged in front of the sensor unit SEN (front surface) is detected, and a control command is sent to the switch control unit 70 based on the contamination state and the like, and the addition amplification unit AMP The addition processing in is switched to a predetermined setting state, and the detection sensitivity as a fire detector is adjusted to be within a predetermined level range.
  Furthermore, the result of the fire determination process and the contamination state of the translucent window TG (for example, when the contamination compensation limit is reached)of(Stainage abnormality signal) is notified to the disaster prevention monitoring panel DC. Note that the transition to the test mode is performed periodically or at an arbitrary timing based on a test command from the outside of the fire detector, for example, the disaster prevention monitoring panel DC.
  That is, the signal processing unit PRO constitutes a stain compensation unit, a stain degree detection unit, and a stain abnormality signal sending unit according to the present invention.
[0040]
<First Embodiment>
Next, a specific configuration of the first or second detection unit applied to the above-described fire detector will be described with reference to the drawings.
FIG. 2 is a schematic configuration diagram illustrating a first embodiment of a detection unit applied to the fire detector according to the present invention, and FIG. 3 illustrates a sensor unit applied to the fire detector according to the present embodiment. FIG. 4 is a diagram illustrating a configuration example, and FIG. 4 is a diagram illustrating an arrangement example of light receiving elements in a sensor unit applied to the fire detector according to the present embodiment. Here, the same components as those described above will be described with the same reference numerals.
First, each configuration of the fire detector according to the present embodiment will be specifically described with reference to FIG.
[0041]
(A) Sensor unit SEN / Filter unit FLT
  The sensor unit SEN has substantially the same detection area and is configured to include a plurality of light receiving elements 10a to 10h that detect infrared energy from a heat source such as a flame FR substantially simultaneously, and the filter unit FLT From the detection signals Sa to Sh output from each of the light receiving elements 10a to 10h, there are frequency filters (pre-filters) 20a to 20h that pass only signal components Aa to Ah in a specific frequency band used for the fire determination process. Configured. In front of the sensor unit SEN, a translucent window TG disposed in the housing and an optical wavelength filter (not shown) disposed in the sensor module are provided.
  Here, the sensor unit SEN specifically includes, for example, as shown in FIG. 3, a substrate 11 on which a plurality of light receiving elements 10 a to 10 h are formed, and a substrate for supporting the substrate 11 on the base 13. Mounting portion 12 and substrate mounting portion 12From the back sideExtends and is fixed to the base 13Terminal 14 andA sensor module is packaged by a cover member 16 having a protective translucent window 15 as an optical wavelength filter in front of the light receiving elements 10a to 10h.
[0042]
As an arrangement example of the light receiving elements 10a to 10h applied to such a sensor unit SEN, for example, as shown in FIGS. 4A to 4C, the same element dimensions ( Size), that is, a plurality of light receiving elements 10a to 10h having the same detection sensitivity (eight in the present embodiment), a matrix shape (FIG. 4A), and a linear shape (FIG. 4B). Or what was formed in the array form by arbitrary arrangement | sequences, such as zigzag form (FIG.4 (c)), can be applied. Here, the array shape means a group of light receiving elements formed by the same manufacturing process on the same substrate.
Each of the light receiving elements 10a to 10h is set to monitor substantially the same detection area substantially simultaneously, and is configured to output the detection signals Sa to Sh individually to the frequency filters 20a to 20h. .
[0043]
In FIGS. 2 and 4, for convenience of explanation, the sensor unit SEN including the eight light receiving elements 10a to 10h is shown. However, the number of light receiving elements installed, the arrangement method, the element dimensions, etc. It is not limited. In general, since the detection output level is substantially proportional to the area of the light receiving element, a larger detection output level can be obtained as the element dimensions and total element dimensions of the respective light receiving elements are increased.
As described above, the light receiving elements 10a to 10h are formed in an array and packaged as a sensor module, whereby the configuration of the sensor unit SEN can be reduced in size and the detection sensitivity characteristics of the light receiving elements 10a to 10h. And the output detection signals Sa to Sh can be made substantially equivalent (Sa≈Sb≈Sc≈Sd≈Se≈Sf≈Sg≈Sh). Only the fire detection component can be clearly revealed. A specific operation of the addition amplification process will be described later.
[0044]
Here, another configuration example of the sensor unit SEN described above will be described with reference to the drawings.
FIG. 5 is a schematic diagram illustrating another configuration example of the sensor unit SEN. Note that FIG. 5 shows a configuration example in which four sensor modules 10A are arranged for convenience of illustration.
As shown in FIG. 5, as another configuration example of the sensor unit SEN, for example, a sensor module 10A of the same type in which only a single light receiving element 10 having a predetermined element size is formed on a substrate 11 and packaged. It is also possible to apply a configuration in which a plurality of these are prepared and arranged in a predetermined arrangement on the attachment member 17 in proximity to each other.
In this way, by arranging a plurality of sensor modules 10A of the same type individually packaged in close proximity to each other, the configuration of the sensor unit SEN can be made as compared with the above-described arrayed light receiving elements 10a to 10h. Although problems such as an increase in size or a limited installation space occur, on the other hand, a relatively inexpensive general-purpose sensor module can be applied, so that the sensor unit SEN can be configured inexpensively and simply. it can. In addition, also by such a structure, the detection sensitivity characteristic of each light receiving element 10 can be made substantially uniform, and each detection signal can be made substantially the same as in the above-described structure.
[0045]
(B) Summing amplifier AMP
The summing amplifier AMP preamplifies (preamplification means) 30a for amplifying the signal components Aa to Ah of the detection signals Sa to Sh individually input through the frequency filters 20a to 20h at a predetermined amplification factor, respectively. To 30h and switches (switching means) SW1 and SW2 for setting the output lines La to Lh of the preamplifiers 30c to 30h to the connection state or the cutoff state with respect to the contact NA, and the output lines La of the preamplifiers 30a to 30h A main amplifier (main amplifying means) 40 for amplifying an added output obtained by coupling and adding (adding) in a predetermined state to a signal level suitable for signal processing to be described later. .
[0046]
Specifically, the output line LAa in which the output lines La and Lb from the preamplifiers 30a and 30b are connected at the contact na is always connected to the main amplifier 40 through the contact NA, and the outputs from the preamplifiers 30c and 30d. The output line LAb in which the lines Lc and Ld are connected at the contact nb is connected to the contact NA via the switch SW1, and the output line LAc from the preamplifiers 30e to 30h is connected to the contact nc in the switch nc. It is connected to the contact NA via SW2.
Here, the preamplifiers 30a and 30b (that is, the light receiving elements 10a and 10b) corresponding to the output lines La and Lb connected to the contact na constitute one group, and the output lines connected to the contact nb. The preamplifiers 30c and 30d corresponding to Lc and Ld (that is, the light receiving elements 10c and 10d) form one group, and further, the preamplifiers 30e to 30h corresponding to the output lines Le to Lh connected to the contact nc (that is, , The light receiving elements 10e to 10h) constitute one group. Note that the switch control unit 70 switches and controls the connection state or the cutoff state of the output lines LAa to LAc for each group by the switches SW1 and SW2 based on a command from the signal processing unit PRO.
[0047]
Accordingly, the amplified outputs from the preamplifiers 30a and 30b are added and synthesized at the contact na, the amplified outputs of the preamplifiers 30c and 30d are added and synthesized at the contact nb, and the amplified outputs of the preamplifiers 30e to 30h are added at the contact nc. Additive synthesis. Further, the respective addition outputs are output via the output lines LAa to LAc, and are added and synthesized at the contact point NA in accordance with the ON / OFF states of the switches SW1 and SW2, and input to the main amplifier 40 at the subsequent stage.
Here, each amplification output output from the preamplifiers 30a to 30h via the output lines La to Lh is a signal based on a detection signal obtained under substantially the same conditions (monitoring substantially the same detection area substantially simultaneously). Therefore, by connecting these output lines La to Lh at the contacts na to nc and NA, the amplified outputs are integrated and an output with improved S / N can be obtained.
On the other hand, the main amplifier 40 amplifies the signal component added and synthesized at the contact NA with a predetermined amplification factor. Here, the amplification factor of the main amplifier 40 is based on the number of installed light receiving elements (that is, the number of preamplifiers), the amplification factor of the preamplifier, and the signal level required for signal processing in the signal processing unit PRO in the subsequent stage. Is set. Details will be described later.
[0048]
(C) A / D converter 50
The A / D converter 50 converts the analog signal output from the main amplifier 40 into a digital signal suitable for the fire determination process in the subsequent signal processing unit PRO and outputs the digital signal. The A / D converter 50 is necessary only when the subsequent fire determination processing unit 60 performs digital signal processing, and is omitted in the case of a processing circuit that directly compares an analog signal level with a reference value. be able to.
[0049]
(D) Signal processor PRO
The signal processing unit PRO includes a fire determination processing unit 60 that performs a fire determination process based on the A / D converted addition amplification output (light reception output level).
The fire determination processing unit 60 performs a predetermined fire determination process based on the added amplification output from the A / D converter 50 (or the main amplifier 40). As a specific method of the fire determination process, for example, a method of comparing the integration level of the added amplification output with a predetermined fire determination level can be applied. As other fire determination methods, various methods such as a method for determining whether or not a flicker frequency peculiar to a flame can be obtained and a combination with the above-described level comparison can be applied. Further, the signal processing unit PRO has a stain compensation processing unit.
[0050]
(E) Switch control unit 70
  For example, the switch control unit 70 controls the ON / OFF states of the switches SW1 and SW2 in the summing amplifier AMP based on a command from the signal processing unit PRO, and outputs the output lines La to Lh from the preamplifiers 30a to 30h.(Ie, output lines LAa to LAc)Are switched and controlled (hereinafter referred to as the setting state of the addition amplification process). An example of a specific setting state in the addition amplification process will be described later.
[0051]
(F) Test light source controller 80
The test light source control unit 80 controls, for example, the blinking state of the test light source LGT based on a control command from the signal processing unit PRO, and sends a predetermined test light (pseudo flame light: blinking in a specific frequency band) to the sensor unit Flood light on SEN. In addition, although illustration was abbreviate | omitted, the translucent window for light source protection is arrange | positioned ahead of the test light source LGT. Therefore, the test light projected from the test light source LGT is once emitted to the outside of the fire detector through the protective translucent window, and then the translucent window TG and the sensor arranged in front of the sensor unit. The light enters the light receiving elements 10a to 10h via an optical wavelength filter (not shown) of the module. Here, according to the configuration shown in the application example of the fire detector, which will be described later, it is possible to suppress the contamination-causing substance from adhering to the light source protecting transparent window as much as possible. The received light output level of the test light can be handled as having a correlation with the contamination state of the translucent window.
[0052]
As described above, in the fire detector according to the present embodiment, the amplified outputs from the preamplifiers 30a to 30h are added, and the fire determination process is executed using the added amplified output amplified by the main amplifier 40. In addition, a test operation for detecting a fouling state of the translucent window TG disposed in front of the detection sensor is performed periodically or based on a test command from the outside, and an addition amplification unit is executed according to the fouling state. The setting state of the addition amplification process in the AMP is switched and the detection sensitivity as a fire detector is always set appropriately.
The detection sensitivity inside the fire detector does not depend only on the addition amplification setting state in the addition amplification unit AMP, but the number of outputs of the light receiving elements (installation number), the amplification factor in the addition amplification unit, and the fire determination processing unit It is determined based on various conditions such as the fire judgment level at 60.
[0053]
Here, the difference in amplification effect between the fire detector according to the present embodiment and the fire detector shown in the prior art will be described in detail with reference to the drawings.
FIG. 6 is a conceptual diagram for explaining the addition amplification operation in the addition amplification unit applied to the fire detector according to the present invention. Here, description will be made with reference to the prior art shown in FIGS. 21 and 22 as appropriate. 6 is not a measured value of the flame itself, but a conceptual diagram for facilitating the explanation, similarly to FIG.
First, the above-described conventional technology will be described.
As shown in FIG. 21, when a signal component Ap in a predetermined frequency band is extracted from the detection signal Sp output from the detection sensor 110 having a single light receiving sensor, and is amplified by the preamplifier 130 and the main amplifier 140. For example, when the amplification factor of the preamplifier 130 is 10 times and the amplification factor of the main amplifier 40 is 100 times, as shown in FIGS. 22A and 22B, the original fire detection included in the signal component Ap is detected. Along with the component Dp, a noise component Np based on the element characteristics of the light receiving element, the external environment, and the like is also amplified 1000 times. For this reason, the absolute level of the noise component Np ′ included in the amplified output Bp output to the signal processing unit 160 may increase, making it impossible to make an accurate fire determination.
[0054]
On the other hand, in the fire detector (FIG. 2) according to the present embodiment, the light receiving elements 10a to 10h provided in the sensor unit SEN have substantially uniform detection sensitivity characteristics and substantially the same detection. Since the areas are monitored substantially simultaneously, the detection signals Sa to Sh output from the respective light receiving elements 10a to 10h are obtained as substantially equivalent signals (Sa≈Sb≈Sc≈Sd≈Se≈Sf≈Sg≈Sh). When the signal components Aa to Ah in a predetermined frequency band are extracted from the detection signals Sa to Sh and amplified by the preamplifiers 30a to 30h and the main amplifier 40, for example, the amplification factor of each of the preamplifiers 30a to 30h is 10 times. Then, the signal components Aa to Ah are each amplified by 10 times. At this time, the noise components Na to Nh included in the signal components Aa to Ah are also amplified together with the original fire detection components Da to Dh, and are output via the output lines La to Lh.
[0055]
Here, when the switches SW1 and SW2 are in the OFF state, the output lines La and Lb of the preamplifiers 30a and 30b are coupled and connected at the contact na, so that the amplified outputs from the preamplifiers 30a and 30b are added. As shown in FIG. 6, the output levels of the original fire detection components Da and Db appearing in substantially the same band are approximately doubled as shown in FIG. 6, and the contact NA (or The added output at the contact na) corresponds to a signal level of each detection signal Sa, Sb detected by each light receiving element 10a, 10b amplified 20 times (= 2 × Sa × 10).
Therefore, as in the case of the above-described prior art, if the amplification factor of 1000 times is necessary for the original fire detection component, the main amplifier 40 increases the amplification factor of 50 times with respect to the added output. If you have it.
[0056]
  On the other hand, the noise components Na and Nb included in the signal components Aa and Ab amplified by the preamplifiers 30a and 30b with a predetermined amplification factor are added by the configuration in which the output lines La and Lb are coupled and connected at the contact na. Compared to the original signal level of the fire detection component D, the rate of increase appears to be relatively suppressed. The noise component Nx included in the added output by the main amplifier 40 is also amplified together with the original fire detection component D. However, since the amplification factor of the main amplifier 40 is set low (50 times), the noise component Nx is originally As compared with the fire detection component D, the signal level is relatively greatly suppressed, and the influence of the noise component on the original fire detection component D in the subsequent fire determination processing can be greatly suppressed.
  Thus, the addition amplification unit AMP shown in the present embodiment can increase only the original fire detection component D and relatively suppress the noise component Nx.For one thing,The original fire detection components Da to Dh in each of the light receiving elements 10a to 10h have a close correlation by detecting the same detected object (flame) at the same time, whereas the noise component Na This is based on the fact that there is relatively little correlation between .about.Nh.
[0057]
As will be described in detail later, when the translucent window TG in front of the sensor unit SEN progresses (deteriorates) due to adhesion of the contamination-causing substance and becomes below a predetermined light reception detection level, the switch SW1. Since the output lines La to Ld of the preamplifiers 30a to 30d are coupled and connected at the contact NA via the contacts na and nb, the amplified outputs from the preamplifiers 30a to 30d are switched. Is added and synthesized (integrated), and the output level of the original fire detection component is increased approximately four times as in the case shown in FIG. 6, and is detected by each of the light receiving elements 10a to 10d. This corresponds to a signal level of each detection signal Sa to Sd amplified by 40 times (= 4 × Sa × 10).
Similarly, by switching the switches SW1 and SW2 to the ON state, the output lines La to Lh of the preamplifiers 30a to 30h can be coupled and connected at the contact point NA. Are amplified and synthesized (integrated), and the output level of the original fire detection component is increased approximately eight times, and the detection signals Sa to Sh detected by the respective light receiving elements 10a to 10h are increased. This corresponds to a signal level amplified by 80 times (= 8 × Sa × 10).
[0058]
Therefore, the light receiving output amplified to a desired signal level without changing (increasing) the amplification factor of the main amplifier 40 by switching the switches SW1 and SW2 according to the contamination state of the translucent window TG. You can get a level.
Further, the signal-to-noise ratio (SN ratio; hereinafter referred to as S / N) when such signal components Aa to Ah are added and amplified has the following characteristics.
That is, when m signal components Ai from the i-th light receiving element are added, the result is expressed by the following equation using the average amplitude S of the fire detection component.
ΣSi = m · S (1)
On the other hand, since the noise intensity can be evaluated by the square average of its variance, it is expressed as follows using the average amplitude N of the noise component.
√ (ΣNi²) = N · √m (2)
Therefore, the final S / N is expressed by the following equation, and the S / N is improved by √m times by adding and synthesizing (integrating) the outputs from the m light receiving elements.
m · S / (N · √m) = (S / N) · √m (3)
[0059]
Therefore, by adding and amplifying the detection outputs from the plurality of light receiving elements, the amplification factor required for the main amplifier 40 in order to realize a signal amplification factor (for example, 1000 times) equivalent to the conventional one can be reduced. It is possible to amplify only the original fire detection component satisfactorily (for example, 1000 times) to make the original fire detection component more obvious, and the S / of the added amplification output input to the signal processing unit PRO N can be greatly improved, and more accurate fire determination processing can be performed.
In the above description, the amplification factor of the detection signal to be amplified in the addition amplification unit AMP is 1000 times for convenience of explanation. However, in an actual fire detector, for example, several thousand times Since an extremely high amplification factor of several tens of thousands of times is required, the configuration including the sensor unit SEN including the plurality of light receiving elements 10a to 10h and the addition amplification unit AMP as described above can be used. The amplification factor can be greatly reduced.
[0060]
Next, an operation process in the fire detector according to the present embodiment described above will be described with reference to the drawings.
FIG. 7 is a flowchart showing a procedure for shifting from the fire monitoring process applied to the fire detector according to the present embodiment to the stain compensation process, and FIG. 8 is applied to the fire detector according to the present embodiment. FIG. 9 is a flowchart showing a procedure of stain compensation processing, FIG. 9 is a state diagram showing a setting state in an addition amplification unit applied to the fire detector according to the present embodiment, and FIG. 10 is a fire according to the present embodiment. It is a conceptual diagram which shows the relationship between the contamination compensation process in a detector, and the expansion of a detection area. Here, the configuration of the fire detector shown in FIG. 1 and FIG. 2 will be described with reference as appropriate.
The operation process in the fire detector according to the present embodiment is constituted by an initial value registration process, a fire monitoring process, and a stain compensation process. Hereinafter, each process will be described individually.
[0061]
<Initial value registration process>
In the initial value registration process, in a state where the translucent window TG is not fouled (manufacturing, factory shipment, installation, etc.), the test light source LGT is controlled to blink, and the light receiving elements 10a to 10a for the test light to be projected The received light output level at 10h is stored as an initial value in, for example, a storage unit (first storage unit) in the signal processing unit PRO. In this case, the setting state of the addition amplification processing in the addition amplification unit AMP (that is, the connection state of the output lines La to Lh of the light receiving elements 10a to 10h) is, for example, all the light reception by setting both the switches SW1 and SW2 to the ON state. The signal level of the output signal subjected to the addition amplification processing based on the detection signals Sa to Sh from the elements 10a to 10h is stored (see FIG. 9C).
[0062]
It should be noted that the light receiving element used for storing the light receiving output level as the initial value needs to be the same as the light receiving element used for the contamination compensation process, as will be described later. Here, the same light receiving element means that the light receiving element itself is the same, as well as the output state of the light receiving element (the output line connected to the contact NA) according to the setting state in the summing amplifier AMP. It means that there is. In other words, by setting the connection state of the light receiving element at the initial value registration and the connection state of the light receiving element at the time of stain compensation processing (when the stain degree is detected) to be the same condition, the process of calculating the light attenuation rate in the stain compensation process described later Can be performed properly.
[0063]
Therefore, the setting state of the addition amplification unit AMP when the light reception output level is stored and registered in the storage unit does not necessarily have to be a state in which the output lines of all the light receiving elements are connected. In short, it is only necessary that the initial value stored in the storage unit and the light receiving output level detected during the test are output from the same light receiving element. For example, both the switches SW1 and SW2 are turned off. The signal level of the output signal added and amplified based only on the detection signals from the light receiving elements 10a and 10b may be stored in the storage unit, or all setting states that are set and controlled in the addition amplifier unit AMP. The received light output level at 1 may be stored in a table format in association with each setting state as an initial value.
[0064]
In particular, according to the initial value registration process in which the received light output levels in all setting states of the summing amplifier AMP are set as initial values and registered in a table format, the setting state of the summing amplifier AMP at the time of shifting to the test mode is maintained as it is. Utilizing this, it is possible to extract the initial value in the set state from the table and easily execute a stain compensation process (calculation and determination of the light reduction rate) described later. Further, since it is not necessary to control the switches SW1 and SW2 every time the test mode is entered and to switch to the setting state (initial value registration state) when the initial value is stored, the transition from the fire monitoring mode to the test mode, In some cases, the return from the test mode to the fire monitoring mode can be easily performed without performing the switching control of the switches SW1 and SW2.
Furthermore, each received light output level in all setting states of the summing amplifier AMP is stored as an initial value, and when the initial value is recorded in the test mode, the initial value is extracted from the table for every setting state. Then, by performing the stain compensation process (calculation and determination of the light attenuation rate), a more reliable stain compensation process can be performed.
[0065]
<Fire monitoring process>
When a fire detector is installed at a predetermined installation position and normal fire monitoring processing is executed (when operation is started), first, the switches SW1 and SW2 are turned off and the setting state of the addition amplification unit is set to the initial state. The fire determination process is executed using the light reception output level obtained by adding and amplifying the detection signals detected using only the light receiving elements 10a and 10b (see FIG. 9A).
When the contamination state due to the contamination-causing substance adhering to the translucent window TG disposed in front of the light receiving elements 10a to 10h deteriorates with time, the switches SW1 and SW2 are subjected to contamination compensation processing described later. Are sequentially turned on, and the internal detection sensitivity is increased by a factor of two or four, for example, and the light reception output level is compensated according to the contamination state of the translucent window, thereby increasing the detection sensitivity as a fire detector. Keep fire monitoring in good condition within the specified level range.
Here, the transition from the fire monitoring process to the pollution compensation process is performed when, for example, a test command is received from the disaster prevention monitoring panel DC in a state where the normal fire monitoring process is executed (S101) as shown in FIG. (S102), the signal processor PRO temporarily stops the fire monitoring process and starts the test process (S103). On the other hand, if there is no test command during execution of the fire monitoring process, the current fire monitoring process is continued.
[0066]
<Fouling compensation processing>
As described above, the fire detector receives a test command from the outside of the fire detector, for example, the disaster prevention monitoring panel DC, or a timer at a predetermined period from a built-in timer or the like provided in the fire detector. Based on the output, the process shifts to a test mode for executing the stain compensation process. Here, the test command output from the disaster prevention monitoring panel DC is a timer output that is built in the disaster prevention monitoring panel DC, or is output every predetermined period from an attached timer, or an operation for performing a test operation by the administrator. Based on the output. In addition, as a period which performs a stain | pollution | contamination compensation process, it sets to a 24-hour period etc., for example.
[0067]
Hereinafter, a specific processing procedure of the stain compensation processing will be described with reference to the flowchart shown in FIG.
(Procedures S201 and S202)
As shown in FIG. 8, first, when a test process is started by receiving a test command, the test mode is switched from the fire monitoring mode. As a result, a control signal is sent from the signal processing unit PRO to the switch control unit 70, and both the switches SW1 and SW2 of the addition amplification unit AMP are controlled to be turned on, and all (eight) light receiving elements 10a to 10a are controlled. The output state of 10h is set to the same setting state as the initial value registration state obtained by adding and combining at the contact NA.
(Procedure S203)
When the setting state of the summing amplifier AMP is set to the initial value registration state, the test light source controller 80 controls the test light source LGT to blink for a predetermined time. Thereby, the test light (pseudo flame light) projected from the test light source LGT is transmitted through the light source protecting light-transmitting window (not shown), the light-transmitting window TG in front of the light receiving element, and the optical wavelength filter. It is incident on the light receiving elements 10a to 10h.
[0068]
(Procedures S204, S205)
Each of the light receiving elements 10a to 10h outputs a detection signal corresponding to the irradiation level of the incident test light, adds the signal components from all the light receiving elements 10a to 10h in the addition amplification unit AMP, and has a predetermined amplification factor. Addition amplification processing to be amplified is performed, and the received light output level is taken into the signal processing unit PRO through the A / D converter 50 for a predetermined time. At this time, the light reception level of the test light incident on the light receiving elements 10a to 10h depends on the contamination level of the translucent window TG in front of the light receiving element (the light reception level of the original test light is contaminated). Attenuation is more than Therefore, the light reception output level taken into the signal processing unit PRO has a magnitude reflecting the contamination state of the translucent window TG in front of the light receiving elements 10a to 10h. When the light reception output level is captured for a predetermined time by the signal processing unit PRO, the test light source LGT is controlled to be turned off by the test light source control unit 80.
[0069]
(Procedures S206 and S207)
  Next, the initial value stored in advance in the storage unit is read out by the above-described initial value registration process, and the ratio of the received light output level to the initial value, that is, the light reduction rate (stain degree) is calculated.
  Then, based on the calculated dimming rate, it is determined whether or not the received light reception output level is dimmed by 50% or more with respect to the initial value.
(Procedures S208, S209, S210)
  Calculated dimming rate is 50%Less thanIn this case, the switches SW1 and SW2 are both switched to the OFF state, and as shown in FIG. 9A, the same setting as the initial setting state in which only the detection signals from the light receiving elements 10a and 10b are added and amplified. Switch to the state, end the test mode, and return to the fire monitoring process described above.
[0070]
(Procedures S211, S212, S210)
  On the other hand, if the dimming rate has reached 50% or higher in step S207, it is further determined whether or not the dimming rate has reached 75% or higher. Dimming rate is 75%Less thanIn this case, only the switch SW2 is switched to the OFF state and switched to a setting state in which only the detection signals from the four light receiving elements 10a to 10d are added and amplified as shown in FIG. Exit test mode and return to fire monitoring process.
(Procedures S213 and S210)
  If the dimming rate has reached 75% or higher in step S211, it is further determined whether or not the dimming rate has reached 85% or higher. Dimming rate is 85%Less thanIn this case, the switches SW1 and SW2 are not switched to the current ON state, and the detection signals from all (eight) light receiving elements 10a to 10h are added and amplified as shown in FIG. 9C. Continue the current settings, exit test mode, and return to fire monitoring process.
[0071]
(Procedure S214)
On the other hand, in the above step S213, when the light attenuation rate reaches 85% or more, the degree of contamination of the translucent window cannot be normally monitored (contamination compensation limit; as a fire detector). It is judged that the detection sensitivity has deteriorated to a level outside the predetermined level), and a fault abnormality signal is sent to the outside of the fire detector, for example, the disaster prevention monitoring panel DC, to notify the manager etc. of the abnormality. And encourage appropriate measures such as early implementation of cleaning work.
That is, in the contamination compensation process according to the present embodiment, the attenuation rate obtained by observing the test light in the initial value registration state (the number of outputs of the light receiving element is 8) in which both the switches SW1 and SW2 are in the ON state is For example, in the case of 50% to 75%, the switch SW2 is turned off and only the switch SW1 is controlled to be turned on, so that the detection sensitivity is double the initial setting state (the number of outputs of the light receiving element is 2). (The number of outputs of the light receiving element is 4).
In the initial value registration state (light receiving element output number 8), when the light attenuation rate is 75% to 85%, the detection sensitivity is initially set by controlling both the switches SW1 and SW2 to the ON state. It is set to 4 times (the number of light receiving element outputs 8) of the set state (light receiving element output number 2).
[0072]
  Such a contamination compensation process in the signal processing unit PRO is performed every time the dimming rate is calculated, the dimming rate stored in the reference table format in advance in the storage unit (second storage unit) in the signal processing unit PRO. And by referring to the correspondence table of the light receiving elements that output with respect to the dimming rate, specifically, the ON / OFF states of the switches SW1, SW2, the ON of the switches SW1, SW2 corresponding to the dimming rate This is executed by determining a state or an OFF state and sending control signals of the switches SW1 and SW2 to the switch control unit 70.
  Specifically, for example, as shown in FIG. 10A, when the fire detectors 100A to 100C according to the present embodiment are installed on the tunnel inner wall surface 91 at a predetermined interval (for example, L = 25 m), In a state where the translucent window TG disposed in front of the light receiving elements 10a to 10h is clean, the addition amplification unit AMP of the fire detector 10A is set and controlled to an initial setting state in which the switches SW1 and SW2 are turned off. By two light receiving elements 10a and 10b, a distance approximately 1.5 times (on the right side in the figure) in the tunnel longitudinal direction (to the right in the figure)1.5× L =37.5m)more thanThe detection sensitivity is set so that it is possible to monitor to a distant position (the shaded area), and the fire monitoring process is executed.
[0073]
  As the time elapses, a stain-causing substance adheres to the translucent window TG of the fire detector 100A to deteriorate the contamination state, and the light attenuation rate obtained by observing the test light in the above-described contamination compensation processing is initial. When it becomes 50% or more with respect to the value, as shown in FIG.RoughlyInstallation position of the next fire detector 100B (minimum limit)AbbreviationL = 25 m). At this time, by switching the setting state of the summing amplifier AMP so that the switch SW1 is turned on, the light receiving elements 10a to 10d that are twice as large as the case of the two light receiving elements 10a and 10b are used. Again, the detection sensitivity is set so that it can be monitored up to the position of the initial detection area (the hatched area in FIG. 10A), and the fire monitoring process is continuously executed.
[0074]
  Similarly, in the fire monitoring process using the four light receiving elements 10a to 10d, when the contamination state of the translucent window TG is further deteriorated and the light attenuation rate becomes 75% or more with respect to the initial value, FIG. ), The detection sensitivity decreases and the detection areaRoughlyInstallation position of the adjacent fire detector 100B (AbbreviationL = 25 m). At this time, by switching the setting state of the summing amplifier AMP so that both the switches SW1 and SW2 are turned on, the light receiving elements 10a to 10h that are twice as many as those in the case of the four light receiving elements 10a to 10d are used. Then, again, the detection sensitivity is set so that it can be monitored up to the position of the initial detection area (the hatched area in FIG. 10A), and the fire monitoring process is continuously executed.
[0075]
Therefore, the distant monitoring limit of the detection area set by the fire detector according to this embodiment is always in a range exceeding 25 m, and the fire monitoring area to the adjacent fire detector is well monitored for fire monitoring. can do. Strictly speaking, the detection sensitivity inside the fire detector is determined based on the amplification factor of the amplifier, the fire determination level, etc. in addition to the number of outputs of the light receiving element, but the addition amplification unit (preamplifier, main amplifier) When the amplification factor and the fire determination level in 40) are set to be constant, the detection sensitivity can be set substantially in association with (in proportion to) the number of outputs of the light receiving element.
[0076]
As described above, according to the fire detector and the contamination compensation method thereof according to the present embodiment, a plurality of light receiving elements monitor substantially the same detection area substantially simultaneously, and the output lines from which the detection signals are output are coupled to each other. Thus, by adding and synthesizing, it is possible to obtain the same effect as signal amplification of only the original fire detection component by the number of outputs of the light receiving element, and it is possible to reduce the amplification factor of the main amplifier at the subsequent stage. The S / N of the added amplification output input to the signal processing unit PRO can be greatly improved, and more accurate fire determination processing can be performed. Further, since the amplification factor of the main amplifier is set low, even when a larger amplification factor is required, it is possible to cope with it well and to improve the amplification margin.
Furthermore, according to the fouling state of the translucent window arranged in front of the light receiving element, the setting state in the addition amplification processing, that is, the connection state of the output lines from which each detection signal is output is switched and controlled. Since the detection sensitivity as a detector can be optimally adjusted, a predetermined fire monitoring area can be satisfactorily monitored over a long period of time.
[0077]
<Another configuration example of the first embodiment>
Next, another configuration example of the fire detector according to the present embodiment will be described.
(Configuration example 1)
In the above-described embodiment, the case where the switches SW1 and SW2 are individually provided on the output line LAb that combines the outputs of the light receiving elements 10c and 10d and the output line LAc that combines the outputs of the light receiving elements 10e to 10h has been described. However, it is also possible to adopt a configuration in which a switch is provided for each of the output lines La to Lh of the light receiving elements 10a to 10h.
According to the fire detector having such a configuration, by controlling each switch individually, the number of outputs of the light receiving element in the above-described embodiment can be adjusted in increments of one unit, so fine sensitivity adjustment is possible. Based on the fouling compensation processing, it can be realized. In the above-described embodiment, the number of switches can be reduced compared to the present configuration example, so that it is possible to reduce the possibility of failure of a switch that is frequently switched, and the switching control process Can be simplified. Further, current consumption required for switch control can be suppressed.
[0078]
(Configuration example 2)
In the embodiment described above, when the number of outputs to be added and combined among the outputs of the light receiving elements 10a to 10h is set to 2, 4, and 8, and the light attenuation rate reaches 50% and 75%, respectively. In the above description, the detection sensitivity is compensated by switching the number of outputs. However, it is also possible to employ a configuration in which the detection sensitivity is compensated by addition synthesis with other output numbers.
According to the fire detector having such a configuration, it is possible to arbitrarily set the number of outputs to be added and combined, and to perform a stain compensation determination process for an arbitrary attenuation rate. It is possible to improve the degree of design freedom and realize an appropriate pollution compensation process according to the environment where the fire detector is installed.
[0079]
(Configuration example 3)
In the embodiment described above, the element dimensions of the light receiving elements 10a to 10h are set to be the same as shown in FIG. 4, and the detection sensitivity characteristics of the light receiving elements 10a to 10h are set to be substantially the same. In the above description, the detection signals from 10h are added and synthesized by a switch to obtain the same effect as signal amplification. However, it is also possible to adopt a configuration in which the element dimensions of the individual light receiving elements are formed differently. .
For example, as shown in FIGS. 11A and 11B, the light receiving elements 10 i and 4 times that have a doubled element area on the same substrate 11 on the basis of the element areas of the light receiving elements 10 a and 10 b, for example. The light receiving elements 10j and 10k are formed.
According to the fire detector having such a configuration, the detection sensitivity of the light receiving element 10i is set to twice that of the light receiving elements 10a and 10b, and the detection sensitivity of the light receiving elements 10j and 10k is set to four times. The detection signals output from the light receiving elements with different output levels can be added and synthesized, and while realizing the same fouling compensation processing as in the above-described embodiment, the sensor unit SEN and the addition amplification unit AMP The number of outputs can be halved. Further, by forming the light receiving element with an arbitrary element size, it is possible to give more diversity to the setting of addition synthesis.
[0080]
In the above-described embodiment, the stain compensation processing is described in the case where the stain degree of the translucent window TG disposed in front of the light receiving elements 10a to 10h is unilaterally increased. However, the stain degree is reduced. The fire detector according to the present invention can be applied even when performing or increasing or decreasing.
That is, for example, even when the contamination state of the translucent window is cleaned from the previous test due to the watering of the cleaning vehicle by cleaning work or the like, or by running water due to condensation, etc., as shown in FIG. Based on the stain compensation process, the number of outputs of the light receiving element can be increased or decreased to adjust the detection sensitivity, and the fire monitoring process can be executed satisfactorily.
[0081]
<Second Embodiment>
Next, a second embodiment of the fire detector according to the present invention will be described with reference to the drawings.
FIG. 12: is a schematic block diagram which shows 2nd Embodiment of the detection part applied to the fire detector which concerns on this invention. Here, about the structure equivalent to embodiment mentioned above, the same code | symbol is attached | subjected and the description is simplified.
As shown in FIG. 12, the fire detector according to the present embodiment includes a sensor unit SEN including a plurality (four in the figure) of light receiving elements 10a to 10d and each light receiving element 10a by observing the flame FR. From the detection signals Sa to Sd output from 10 to 10d, the filter unit FLT that passes only the signal components Aa to Ad in a predetermined frequency band and the signal components Aa to Ad are added and combined in a predetermined combination, An addition amplification unit AMP that amplifies at an amplification factor, and a fire determination processing unit 60 that performs fire determination based on the amplified output that is output from the addition amplification unit AMP and converted into a digital signal by the A / D converter 50 Based on a control command from the signal processing unit PRO and the signal processing unit PRO, a switch for switching and controlling a combination for adding and combining the signal components Aa to Ad in the addition amplification unit AMP A pitch control unit 70, based on the test instruction from the signal processing unit PRO, and the test light source control unit 80 for lighting control test light source LGT, is configured to have a.
[0082]
Then, the summing amplifier AMP includes preamplifiers 30a to 30d that first amplify signal components Aa to Ad individually input via the filter unit FLT at a predetermined amplification rate, and output lines La and preamplifiers 30a and 30b, An output line LA in which Lb is coupled and connected at the contact na, an output line Lc of the preamplifier 30c, and a switch SW1 and SW2 for setting the output line Ld of the preamplifier 30d to the contact state NB or the cutoff state, A main amplifier (main amplification means) 40 for amplifying an added output obtained by coupling (adding) the output lines LA, Lc, Ld from the preamplifiers 30a to 30d in a predetermined state with a predetermined amplification factor; Configured.
Here, a circuit configuration including the light receiving elements 10a and 10b and the preamplifiers 30a and 30b is a detection group G11, a circuit configuration including the light receiving element 10c and the preamplifier 30c is a detection group G12, and a circuit configuration including the light receiving elements 10d and the preamplifier 30d. The detection group G13 is configured such that the detection groups G11, G12, and G13 have different detection sensitivities.
[0083]
Specifically, based on the detection sensitivity of the detection group G11, the detection group G12 is set to substantially the same detection sensitivity as the detection group 11, and the detection group G13 is set to double the detection sensitivity of the detection group 11. ing.
In such a configuration, when the light receiving elements 10a to 10d have substantially the same element size, the signal amplification factor of the detection group G11 (that is, the amplification factor of the preamplifiers 30a and 30b and the addition effect at the contact point na). The signal amplification factor of the detection group G12 (that is, the amplification factor of the preamplifier 30c) is set to be substantially the same, and the signal amplification factor of the detection group G13 (that is, the preamplifier 30d). This is realized by setting the amplification factor of the second time to approximately twice.
[0084]
According to the fire detector having such a configuration, the switches SW1 and SW2 are both turned off in the same manner as the contamination compensation processing procedure in the above-described embodiment, and the amplified output by the detection signals from the light receiving elements 10a and 10b is obtained. Based on this, the fire monitoring state is set to the initial setting state, and the switch SW1 is turned on and controlled in accordance with the deterioration of the contamination state of the translucent window TG, whereby the detection signal from the light receiving element 10c is sent to the contact NB. It is possible to perform fire monitoring with a detection sensitivity twice as high as that in the initial setting state by combining and adding in.
Further, when the contamination state of the translucent window TG deteriorates, the detection signal from the light receiving element 10d is coupled and added at the contact NB by controlling the switch SW2 to be turned on in addition to the switch SW1. Thus, fire monitoring can be performed with a detection sensitivity four times that of the initial setting state.
Such a contamination compensation process in the signal processing unit PRO is performed by a light attenuation rate stored in a reference table format in advance in the storage unit (second recording unit) in the signal processing unit PRO every time the light attenuation rate is calculated. By referring to a correspondence table of detection groups to be output for the dimming rate, specifically, correspondence between ON and OFF states of the switches SW1 and SW2, the ON state of the switches SW1 and SW2 with respect to the dimming rate or This is executed by determining the OFF state and sending control signals of the switches SW1 and SW2 to the switch control unit 70.
[0085]
Here, in the operation processing of the fire detector according to the present embodiment, the initial value registration processing is performed in a state where the translucent window TG is not soiled (manufacturing, factory shipment, installation, etc.). For example, a storage unit (first storage unit) in the signal processing unit PRO with the output level in a predetermined connection combination of each detection group G11, G12, and G13 for the test light to be projected as an initial value. And so on. In this case, the setting state of the addition amplification processing in the addition amplification unit AMP (that is, the connection state of the output lines LA, Lc, and Ld of the detection groups G11, G12, and G13) is, for example, that both the switches SW1 and SW2 are in the ON state. In this case, the signal level of the added amplification output may be the signal level of the added amplification output when both the switches SW1 and SW2 are turned off. Further, the signal level of the addition amplification output in all the setting states of the detection groups G11, G12, and G13, which is set and controlled in the addition amplification unit AMP, is stored as an initial value in association with each setting state in a table format. There may be.
[0086]
However, it is necessary that the light receiving element (detection group) used when storing the signal level of the addition amplification output as the initial value is the same as the light receiving element (detection group) used for the stain compensation process. Here, the same light receiving element (detection group) means that the light receiving elements included in the detection group are the same, and the number of light receiving elements and other configurations included in the detection group are also the same. It means that. In other words, by making the connection state of the light receiving element (detection group) at the time of initial value registration and the connection state of the light receiving element (detection group) at the time of stain compensation processing (at the time of stain detection) the same condition, the reduction in the stain compensation process is reduced. In the light rate calculation process, an appropriate light reduction rate calculation process can be performed.
The other operation processing is substantially the same as the first embodiment described above except that the detection operation of the light reception output level in units of light receiving elements is the detection operation of the output level in units of detection groups. The detailed explanation is omitted.
[0087]
In the present embodiment, when the element dimensions of the light receiving elements 10a to 10d are formed substantially the same, the detection groups G11, G12, and G13 have different detection sensitivities. Although the case where the amplification factors of the preamplifiers 30a to 30d are set to be different has been described, the present invention is not limited to this form. Therefore, if the detection groups G11, G12, and G13 are set to have different detection sensitivities, for example, as shown in FIGS. 11A and 11B, the element area of the light receiving element 10a or 10b is used. , The light receiving element 10c (light receiving element 10i in FIG. 11) is doubled, and the light receiving element 10d (light receiving elements 10j, 10k in FIG. 11) has a four times larger area. It may be a thing. In other words, the detection sensitivity of each detection group is determined based on the number of outputs of the light receiving elements provided in each detection group, the element dimensions, and the amplification factor of the amplifier. Therefore, a desired detection sensitivity can be realized.
[0088]
<Third Embodiment>
Next, a third embodiment of the fire detector according to the present invention will be described with reference to the drawings.
FIG. 13: is a schematic block diagram which shows 3rd Embodiment of the detection part applied to the fire detector which concerns on this invention. Here, about the structure equivalent to embodiment mentioned above, the same code | symbol is attached | subjected and the description is simplified.
As shown in FIG. 13, the fire detector according to the present embodiment is output from the sensor unit SEN including the light receiving elements 10a to 10d and the light receiving elements 10a to 10d, as in the second embodiment described above. From each detection signal Sa to Sd, a filter unit FLT that passes only signal components Aa to Ad in a predetermined frequency band and signal components Aa to Ad are added and combined in a predetermined combination, and are amplified at a predetermined gain. An addition amplification unit AMP, a signal processing unit PRO including a fire determination processing unit 60 that performs fire determination based on the amplification output output from the addition amplification unit AMP via the A / D converter 50, and addition amplification A switch control unit 70 that switches and controls a combination for adding and combining signal components Aa to Ad in the unit AMP, and a test light source control unit 80 that controls blinking of the test light source LGT. It has been.
[0089]
Then, the summing amplifier AMP includes preamplifiers 30a to 30d that first amplify signal components Aa to Ad individually input via the filter unit FLT at a predetermined amplification rate, and output lines La and preamplifiers 30a and 30b, A main amplifier 40a that amplifies the added output of the output line LA obtained by coupling Lb at the contact na at a predetermined amplification factor, a main amplifier 40b that amplifies the output from the preamplifier 30c at a predetermined amplification factor, and a preamplifier 30d. The main amplifier 40c for amplifying the output from the main amplifier 40a, the output line LBa of the main amplifier 40a, the output line LBb of the main amplifier 40b, and the output line LBc of the main amplifier 40c connected to the contact NC, Alternatively, the switch SW1 and the switch SW2 that are set to the cutoff state are included.
Here, a circuit configuration including the light receiving elements 10a and 10b, the preamplifiers 30a and 30b, and the main amplifier 40a is a detection group G21, and a circuit configuration including the light receiving element 10c, the preamplifier 30c and the main amplifier 40b is a detection group G22, and the light receiving element 10d. The circuit configuration including the preamplifier 30d and the main amplifier 40c is a detection group G23, and the detection groups G21, G22, and G23 are configured to have different detection sensitivities.
[0090]
Specifically, based on the detection sensitivity of the detection group G21, the detection group G22 is set to substantially the same detection sensitivity as the detection group 21, and the detection group G23 is set to twice the detection sensitivity of the detection group 21. ing.
In such a configuration, when the element dimensions of the light receiving elements 10a to 10d are formed substantially the same, and the amplification factors of the preamplifiers 30a to 30d are set to be approximately equal, the signal amplification factor ( That is, the signal amplification factor of the detection group G22 (that is, the amplification factor of the main amplifier 40b) is set to be substantially the same with reference to the substantial amplification factor considering the addition effect at the contact na and the amplification factor of the main amplifier 40a. In addition, this is realized by setting the signal amplification factor of the detection group G23 (that is, the amplification factor of the main amplifier 40c) to approximately double.
[0091]
According to the fire detector having such a configuration, the switches SW1 and SW2 are both turned off in the same manner as the contamination compensation processing procedure in the above-described embodiment, and the amplified output of the detection signals from the light receiving elements 10a and 10b ( Based on the output of the detection group G21), the fire monitoring state is set to the initial setting state, and the switch SW1 is turned on and controlled according to the deterioration of the contamination state of the translucent window TG. The detection signal amplification output (detection group G22 output) is coupled and added at the contact NC, and fire monitoring can be performed with detection sensitivity twice that of the initial setting state.
Further, when the contamination state of the translucent window TG deteriorates, the switch SW2 is switched to the ON state in addition to the switch SW1, thereby performing amplification output (detection group G23) of the detection signal from the light receiving element 10d. Can be combined and added at the contact NC to perform fire monitoring with a detection sensitivity four times that of the initial setting state.
Here, since each operation process of the fire detector according to the present embodiment is substantially the same as that of the first and second embodiments described above, detailed description thereof is omitted.
[0092]
In the present embodiment, when the element dimensions of the light receiving elements 10a to 10d are formed substantially the same and the amplification factors of the preamplifiers 30a to 30d are set to be approximately equal, the detection of the detection groups G21, G22, and G23 is detected. As a configuration for making the sensitivity different, the case where the individual main amplifiers 40a to 40c are provided for each detection group and the amplification factors of these main amplifiers 40a to 40c are set to be different has been described, but the present invention is in this form. It is not limited. Therefore, as in the second embodiment described above, for example, as shown in FIGS. 11A and 11B, the detection groups G21, G22, and G23 have different detection sensitivities. Thus, the structure which changes and sets the element area of light receiving element 10a-10d, and the structure which changes and sets the amplification factor of preamplifier 10a-10d may be sufficient. In other words, the detection sensitivity of each detection group is determined based on the number of outputs of the light receiving elements provided in each detection group, the element dimensions, and the amplification factor of the amplifier. Therefore, a desired detection sensitivity can be realized.
[0093]
<Fourth Embodiment>
Next, a fourth embodiment of the fire detector according to the present invention will be described with reference to the drawings.
FIG. 14: is a schematic block diagram which shows 4th Embodiment of the detection part applied to the fire detector which concerns on this invention. Here, about the structure equivalent to embodiment mentioned above, the same code | symbol is attached | subjected and the description is simplified.
As shown in FIG. 14, the fire detector according to this embodiment is output from the sensor unit SEN including the light receiving elements 10a to 10d and the light receiving elements 10a to 10d, as in the third embodiment described above. From each detection signal Sa to Sd, a filter unit FLT that passes only signal components Aa to Ad in a predetermined frequency band and signal components Aa to Ad are added and combined in a predetermined combination, and are amplified at a predetermined gain. A signal processing unit PRO including a summing amplifier AMP, a fire determination processing unit 60 for determining a fire based on the amplified output output from the summing amplifier AMP via the A / D converter 50, and a test light source And a test light source control unit 80 that controls the blinking of the LGT.
[0094]
The summing amplifier AMP outputs pre-amplifiers 30a to 30d that amplify individually input signal components Aa to Ad and output lines La and Lb of the pre-amplifiers 30a and 30b at the contact na to output the output lines. A main amplifier 40a that amplifies the added output of LA with a predetermined amplification factor, a main amplifier 40b that amplifies the output from the preamplifier 30c with a predetermined amplification factor, and a main amplifier that amplifies the output from the preamplifier 30d with a predetermined amplification factor 40c. Output lines LBa to LBc from the main amplifiers 40a to 40c are output to the signal processing unit PRO via the A / D converters 50a to 50c.
Here, a circuit configuration including the light receiving elements 10a and 10b, the preamplifiers 30a and 30b, and the main amplifier 40a is a detection group G21, and a circuit configuration including the light receiving element 10c, the preamplifier 30c and the main amplifier 40b is a detection group G22, and the light receiving element 10d. The circuit configuration including the preamplifier 30d and the main amplifier 40c is a detection group G23, and the detection groups G21, G22, and G23 are configured to have different detection sensitivities.
[0095]
The signal processing unit PRO performs an internal process of combining and adding each amplified output input through the output lines LBa to LBc, that is, outputs from the detection groups G21 to G23, and determines the added output as a fire. It outputs to the process part 60 and performs a fire determination process. That is, the signal processing unit PRO has a software function corresponding to the switches SW1 and SW2 and the switch control unit 70 in the above-described embodiment, and based on the result of the contamination compensation process, the output lines LBa to LBc Detection sensitivity is adjusted by switching the setting state of the combined addition in software.
[0096]
According to the fire detector having such a configuration, the amplified output of the detection signal from the light receiving elements 10a and 10b (the output of the detection group G21) in the signal processing unit PRO, similarly to the procedure of the stain compensation process in the above-described embodiment. ) Is extracted, the state in which the fire monitoring is performed is set as the initial setting state, and the setting state of the coupling addition between the output lines LBa to LBc is switched in software according to the deterioration of the contamination state of the translucent window TG. Thus, the amplified output of the detection signal from the light receiving element 10c (the output of the detection group G22) can be combined and added, and fire monitoring can be performed with detection sensitivity twice that of the initial setting state.
Further, when the contamination state of the translucent window TG deteriorates, the detection output from the light receiving element 10d is amplified by switching the setting state of the coupling addition between the output lines LBa to LBc by software ( The fire monitoring can be performed with the detection sensitivity four times that in the initial setting state by combining and adding the outputs of the detection group G23.
[0097]
<Application example>
Next, an application example when the fire detector according to the present invention is applied to a fire detector installed on the inner wall surface of a tunnel will be described with reference to the drawings.
FIG. 15 is a schematic configuration diagram illustrating an application example of the fire detector according to the present invention, and FIG. 16 is a schematic diagram illustrating a relationship between the fire detector and the airflow in the application example.
As shown in FIGS. 15 (a) and 15 (b), the fire detector 200 has a sensor storage portion 202 provided on the upper portion of the housing 201 and a curved surface having a predetermined radius of curvature at least in both longitudinal directions of the tunnel. The inclined curved surfaces 209a and 209b formed on the inclined curved surfaces 209a and 209b, the individual translucent windows 204a and 204b provided on the respective inclined curved surfaces 209a and 209b, and the detection sensor 205a housed in each of the translucent windows 204a and 204b. 205b, a test light source storage part 206 formed so as to protrude in the tunnel in the installed state, and individual light sources provided in the test light source storage part 206 corresponding to the translucent windows 204a and 204b, respectively. Protective translucent windows 207a and 207b, and test light sources 208a and 208b housed in the respective light source protective translucent windows 207a and 207b. That.
[0098]
The sensor storage portion 202 is formed on the upper portion of the housing 201 with inclined curved surfaces 209a and 209b so as to protrude from the tunnel inner wall surface 91 in the tunnel inner direction (upward in FIG. 15B) in the installed state. The inclined curved surfaces 209a and 209b are formed by a single curved surface having a predetermined radius of curvature, and each of the tunnels in one longitudinal direction (FIG. 15 (b) left side) and the other side (FIG. 15 (b) right side). Is formed with a predetermined inclination (a protruding curved surface).
The translucent windows 204a and 204b are the translucent windows TG according to the above-described embodiment, and are housed in the sensor housing unit 202. It is composed of a flat transparent plate that prevents and protects damage and is provided on the inclined curved surfaces 209a and 209b in front of the detection sensors 205a and 205b housed in the sensor housing 202.
In addition, in the case of having an embedded type configuration, only the front portion of the fire detector protrudes from the tunnel inner wall surface 91a, but the mounting box containing the fire detector is directly installed on the tunnel inner wall surface. In some cases. In this case, the mounting box and the front portion of the fire detector protrude from the inner wall surface of the tunnel.
[0099]
Similar to the sensor storage unit 202, the test light source storage unit 206 is at the top of the housing 201 and has a predetermined radius of curvature from the tunnel inner wall surface 91 to the tunnel internal direction (upward in FIG. 15B) in the installed state. The light source protecting light-transmitting windows 207a and 207b can see through the light-transmitting windows 204a and 204b (detection sensors 205a and 205b), and the detection sensors 205a and 207b Within the range of each detection area ARa, ARb set by 205b, specifically, it is arranged at a position where it does not become an obstacle of the detection area set to actually perform fire monitoring. Here, the light-source protecting translucent windows 207a and 207b are disposed completely above the installation positions of the translucent windows 204a and 204b when the fire detector 200 is installed on the inner wall surface 91 of the tunnel. In other words, it is provided so as to form a flat surface parallel to the longitudinal direction of the tunnel, in other words, the airflow C generated in the tunnel.
[0100]
According to the fire detector 200 having such a configuration, as shown in FIGS. 16 (a) and 16 (b), the inclined curved surfaces 209a and 209b constituting the sensor storage portion 202 are formed so as to protrude toward the inside of the tunnel, Further, since the translucent windows 204a and 204b have an inclination angle of approximately 5 ° to 30 ° with respect to the inner wall surface of the tunnel, the airflow C flowing from the upstream side follows the shape of the inclined curved surface 209a. Since the airflow C in the upper layer (forward direction of the fire detector 200) is pushed up and flows in parallel with the inclination of the translucent window 204a, the pollutant causing the airflow C to fly on the translucent window 204a. Direct adhesion can be greatly suppressed.
On the other hand, the protective translucent windows 207a and 207b provided on the lower surface of the test light source storage unit 206 projecting in the inner direction of the tunnel are located above the inclined curved surfaces 209a and 209b provided with the translucent windows 204a and 204b. Since the airflow C is positioned so as to form a flat surface parallel to the airflow C, the airflow C hardly collides directly with the light-transmitting windows 207a and 207b for protecting the light source. Since there is almost no accumulation of contamination-causing substances, the adhesion and accumulation of contamination-causing substances on the light source protecting transparent windows 207a, 207b is greatly reduced.
[0101]
Therefore, a plurality of light receiving elements provided in the detection sensors 205a and 205b with the test light CK projected through the light source protecting transparent windows 207a and 207b in accordance with the stain compensation processing according to the above-described embodiment. By observing at approximately the same time, the contamination state of the translucent windows 204a and 204b can be accurately grasped. Based on the contamination state, the number of outputs of the light receiving element is switched and adjusted to an appropriate detection sensitivity. Therefore, the fire monitoring process can be performed well over a long period of time.
In the above-described embodiment, the detection sensor for detecting the degree of contamination (sensor unit SEN) is used as the contamination degree detection sensor, and the sensor unit SEN is configured simply and inexpensively. You may make it arrange | position the detection sensor for exclusive use of the contamination degree separate from the detection sensor for fire monitoring in a translucent window.
In addition, the fire detector according to each of the above-described embodiments can be installed in any space as long as it determines fire occurrence by detecting radiant energy obtained by observing a flame. However, the present invention is not limited to the fire detector installed on the inner wall surface of the tunnel described above.
[0102]
【The invention's effect】
  The present inventionAccording to the present invention, the output signal from the detection sensor disposed in the translucent window is amplified to determine the fire, and the test light projected from the test light source is contaminated through the translucent window. In a fire detector that has a function of detecting the degree of contamination of the translucent window by automatically detecting the degree of contamination of the translucent window by making the detection sensor for detection detect the degree of contamination of the translucent window. Since the number of outputs of the element is controlled, the same effect as when the output signal from the detection sensor is amplified to a predetermined signal level can be obtained according to the number of outputs of the light receiving element. The set amplification factor can be lowered. Therefore, the S / N of the amplified output used for fire determination can be greatly improved, and more accurate fire determination processing can be performed. Further, since the amplification factor of the signal amplification means can be set low, even when a larger amplification factor is required, it is possible to cope with it well, and the amplification margin can be improved.
[0103]
  In particular, the present inventionAccording to the present invention, the output signal from the detection sensor disposed in the translucent window is amplified to determine the fire, and the test light projected from the test light source is contaminated through the translucent window. In a fire detector having a function of detecting the degree of contamination of the translucent window and automatically compensating for contamination by causing the detection sensor to detect light, the output of a predetermined number of light receiving elements and the predetermined amplification factor It is composed of amplifying means with different detection sensitivities, each of which has a plurality of detection groups, and the number of outputs of the plurality of detection groups is controlled according to the degree of contamination of the translucent window. Depending on the number, it is possible to obtain the same effect as when each output signal is amplified to a predetermined signal level, and the amplification factor set in the signal amplification means can be lowered. Therefore, the S / N of the amplified output used for the fire determination can be improved, and an accurate fire determination process can be performed.
  In addition, the present inventionAccording to the above, when the detection sensor for fire monitoring is also used as the contamination degree detection sensor, the sensor unit can be configured simply and inexpensively.
  In addition, the present inventionSince the detection sensor has a configuration in which a plurality of light receiving elements are arranged and integrally packaged, the configuration of the detection sensor can be greatly reduced, and sensitivity characteristics can be reduced. A substantially uniform light receiving element group can be formed.
[0104]
  In addition, the present inventionSince the detection sensor has a configuration in which a plurality of light receiving elements of the same type are individually packaged and arranged close to each other, a relatively inexpensive general-purpose light receiving element can be applied. Therefore, the sensor unit can be configured easily and inexpensively.
  In addition, the present inventionAccording to the above, since the plurality of light receiving elements are configured to have the same size, it is possible to form a light receiving element group having substantially uniform sensitivity characteristics. The detection component can be revealed, and the accuracy of the signal used for the fire determination process can be increased.
  In addition, the present inventionAccording to the above, since the plurality of light receiving elements include ones configured in different sizes, it is possible to form a light receiving element group that is set by changing the sensitivity characteristics step by step, and the number of outputs of the light receiving elements By adding or subtracting, the detection sensitivity setting method can be further varied.
[0105]
  In addition, the present inventionAccording to the above, the detection sensor includes a plurality of groups in which a predetermined number of output lines are connected in advance among the output lines of the plurality of light receiving elements. The detection sensitivity can be adjusted stepwise in accordance with the sensitivity characteristic preset for each group.
  In addition, the present inventionAccording to the above, since the number of outputs of the light receiving element or the detection group is controlled so that the detection sensitivity as a fire detector is within a predetermined level range, within a predetermined allowable fluctuation range, The fire monitoring area can be monitored well.
[0106]
  In addition, the present inventionAccording to the above, since processing for compensation for contamination is performed at predetermined intervals or when a test command is received from the outside of the fire detector, it can be transmitted periodically or at an arbitrary timing. An appropriate detection sensitivity can be set for the fire detector by detecting the fouling state of the light window, and a good fire monitoring process can be maintained over a long period of time.
  In addition, the present inventionAccording to the present invention, the contamination compensation means includes a test light source control means for controlling the blinking of the test light source, a contamination degree detection means for detecting the contamination degree of the translucent window, and the contamination degree detected by the contamination degree detection means. Accordingly, the output number variable control means for variably controlling the output number of the light receiving element or the detection group is provided, so that the test light source is controlled to blink by the test light source control means, and the translucent window is detected by the contamination degree detection means. The contamination compensation means can manage the test operation for detecting the contamination degree of the sensor and the sensitivity adjustment operation for controlling the output number of the light receiving element or the detection group by the output number variable control means according to the pollution degree. The pollution compensation process can be executed in an integrated manner.
[0107]
  In addition, the present inventionAccording to the above, since the contamination degree detection means detects the contamination degree of the translucent window based on the light attenuation rate with respect to the predetermined initial value, it is possible to execute an appropriate contamination compensation process.
  In addition, the present inventionAccording to the above, prior to the stain compensation process, the output level of the stain degree detection detection sensor when the test light source is turned on in the state where the transparent window is not soiled is stored in the first storage means as the initial value. Thus, the contamination state of the light receiving window can be relatively detected with reference to the detection level in a state where the translucent window is clean.
[0108]
  In addition, the present inventionAccording to the present invention, in the pollution compensation process, the output level of the detection sensor for detecting the degree of contamination when the test light source is turned on is detected, and the light attenuation rate with respect to the initial value is calculated. Alternatively, since the number of outputs of the detection group is variably controlled, the contamination state of the light receiving window can be relatively detected with reference to the output level in a state where the translucent window is clean. Accordingly, it is possible to set an appropriate detection sensitivity by controlling the number of outputs of the light receiving elements or detection groups.
  In addition, the present inventionAccording to the present invention, the light receiving element of the contamination degree detection detection sensor used for storing the initial value is the same as the light receiving element used for the contamination compensation process, so that an appropriate light attenuation rate is obtained. Can be calculated.
[0109]
  In addition, the present inventionAccording to the present invention, the correspondence between the light attenuation rate with respect to the initial value and the light receiving element or the detection group output with respect to the light attenuation rate is stored in the second storage unit, and the light attenuation calculated in the stain compensation process Based on the rate, the correspondence between the light attenuation rate and the output light receiving element or detection group is referred to, the light receiving element or detection group to be output is determined, and the number of outputs of the light receiving element or detection group is variably controlled. Therefore, when the light attenuation rate is calculated in the stain compensation process, the output of the light receiving element or detection group to be output can be immediately determined by referring to the correspondence relationship, and the transition to the stain compensation process is performed. Can be executed quickly with a simple process.
  In addition, the present inventionAccording to the present invention, when the attenuation rate calculated by the contamination degree detection means becomes equal to or greater than a predetermined value, it is determined that the contamination compensation limit is reached, and the contamination abnormality signal is output to the outside of the fire detector, for example, the disaster prevention monitoring panel. By sending the message, it is possible to notify the disaster prevention manager etc. of the abnormality and prompt appropriate measures such as early implementation of cleaning work.
[0110]
  In addition, the present inventionAccording to the above, the amplifying means includes a preamplifying means and a main amplifying means, and by adding an arbitrary output line among the output lines from each preamplifying means and outputting to the main amplifying means, the addition is performed. Since it is configured to amplify, it is possible to amplify the output signal to a predetermined signal level with a simple configuration in which the output lines from each light receiving element are connected. Can be set low.
  In addition, the present inventionAccording to the above, since the amplifying means includes switching means for switching and connecting the output lines from the respective pre-amplifying means, the output level of the main amplifying means is controlled by controlling the conduction / cutoff state of the switching means. It can be arbitrarily switched and adjusted.
  In addition, the present inventionAccording to the present invention, the amplifying unit includes a preamplifying unit and a main amplifying unit, and outputs an arbitrary output among outputs of a predetermined number of light receiving elements and an output line of a detection group configured to include the preamplifying unit. Since it is configured to obtain the addition amplification effect by connecting the lines, the output signal can be amplified to a predetermined signal level with a simple configuration of connecting the output lines from each detection group. Compared with the main amplification means amplification factorLowerCan be set.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram showing an example of the overall configuration of a fire detector according to the present invention.
FIG. 2 is a schematic configuration diagram showing a first embodiment of a detection unit applied to a fire detector according to the present invention.
FIG. 3 is a diagram illustrating a configuration example of a sensor unit applied to the fire detector according to the first embodiment.
FIG. 4 is a diagram illustrating an arrangement example of light receiving elements in a sensor unit applied to the fire detector according to the first embodiment.
FIG. 5 is a schematic view showing another configuration example of a sensor unit applied to the fire detector according to the first embodiment.
FIG. 6 is a conceptual diagram for explaining an addition amplification operation in an addition amplification unit applied to a fire detector according to the present invention.
FIG. 7 is a flowchart showing a procedure for shifting from a fire monitoring process to a stain compensation process applied to the fire detector according to the first embodiment.
FIG. 8 is a flowchart showing a procedure of stain compensation processing applied to the fire detector according to the first embodiment.
FIG. 9 is a state diagram showing a setting state in an addition amplification unit applied to the fire detector according to the first embodiment.
FIG. 10 is a conceptual diagram showing the relationship between the contamination compensation process and the detection area expansion in the fire detector according to the first embodiment.
FIG. 11 is a schematic view showing another configuration example of the fire detector according to the first embodiment.
FIG. 12 is a schematic configuration diagram showing a second embodiment of a detection unit applied to the fire detector according to the present invention.
FIG. 13 is a schematic configuration diagram showing a third embodiment of a detection unit applied to the fire detector according to the present invention.
FIG. 14 is a schematic configuration diagram showing a fourth embodiment of a detection unit applied to the fire detector according to the present invention.
FIG. 15 is a schematic configuration diagram showing an application example of a fire detector according to the present invention.
FIG. 16 is a schematic diagram showing a relationship between a fire detector according to this application example and an airflow generated in the tunnel.
FIG. 17 is a conceptual diagram showing a tunnel facility for a vehicle.
FIG. 18 is a schematic configuration diagram of a fire detector in the prior art.
FIG. 19 is a schematic diagram showing the arrangement of fire detectors in a tunnel and the setting state of a monitoring area in the prior art.
FIG. 20 is a conceptual diagram showing the relationship between a fire detector and airflow generated in a tunnel in the prior art.
FIG. 21 is a block diagram showing a schematic configuration of a fire detector in the prior art.
FIG. 22 is a conceptual diagram for explaining the amplification effect of the detection signal in the fire detector shown in the prior art.
[Explanation of symbols]
SEN, SEN1, SEN2 Sensor unit
FLT, FLT1, FLT2 Filter section
AMP, AMP1, AMP2 Summing amplifier
PRO signal processor
SW1, SW2 switch
LGT, LGT1, LGT2 Test light source
TG translucent window
10a-10h light receiving element
20a-20h frequency filter
30a-30h preamplifier
40, 40a-40c Main amplifier
50, 50a, 50b A / D converter
60 Fire judgment processing part
70, 70a, 70b Switch control unit
80, 80a, 80b Test light source controller

Claims (5)

Each possess one or more light-receiving elements, are scheduled in accordance with the pollution degree of the translucent window, the plurality of detection groups having a detection sensitivity can be synthesized by combining to correspond to the contamination compensation step by synthesis detection sensitivity Among them, the detection sensitivity of at least one detection group is different from the detection sensitivity of the other detection groups, and the output signals from the plurality of detection groups are added based on the contamination state of the translucent window. A fire detector that performs pollution compensation processing by monitoring fires with different composite patterns.   The fire detector according to claim 1, wherein the detection sensitivity is set to be different depending on the number of the light receiving elements included in the detection group.   The fire detector according to claim 1, wherein the detection sensitivity is set to be different depending on a dimension of the light receiving element. The fire detector according to any one of claims 1 to 3, wherein the stain compensation process is performed for every setting state of the detection sensitivity.   A light source for testing and a light transmissive window for protecting the light source that protects the light source, and the light transmissive window for protecting the light source is located above the position where the light transmissive window is installed when the fire detector is installed. And disposed so as to form a flat surface parallel to the longitudinal direction of the tunnel, irradiated from the light source for testing, and transmitted through the light-transmissive window for protecting the light source and the light-transmissive window. 5. The fire detector according to claim 1, wherein the stain compensation process is performed based on an intensity of test light received by the light receiving element or the test light receiving element.

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