JP2009032049A - Light extinction type sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light extinction type sensor used for both a light extinction type separation sensor or a light extinction type reflection sensor. <P>SOLUTION: The light extinction type sensor 1 is provided with a light-projecting part 101 for projecting detection light toward a monitoring range, and a light-receiving part 102 for receiving the detection light for determining a predetermined monitoring object in the monitoring range based on the light quantity of the received detection light when the light-receiving part 102 receives the detection light. The sensor has a mode switching switch 12 that switches operation modes of the light extinction type sensor 1 between at least two of the operation modes among a light-projecting mode for operating the light-projecting part 101, a light-receiving mode for operating the light-receiving part 102, and a reflection mode for operating the light-projecting part 101 and the light-receiving part 102 at the same time. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a light-reducing sensor that detects the attenuation of light that has been projected from a light projecting unit and passed through a space that is a monitoring area and reached a light receiving unit, and senses the presence of smoke caused by a fire or the like.

  Conventionally, in order to detect the occurrence of a fire, a smoke detector that detects smoke generated with the fire has been used. One method of detecting smoke is to detect the attenuation of light intensity when light (for example, near-infrared rays) passes through the smoke. Sensors that use this method are called dimming sensors. ing.

  Among the light-reducing sensors, a relatively wide monitoring area can be covered, and a light projecting unit for projecting detection light and a light receiving unit for receiving detection light are separated from each other so as to face each other. There is a dimming separation type sensor that uses a region sandwiched between a light receiving unit and a light receiving unit as a monitoring region. In addition, a light projecting / receiving unit provided with one light receiving unit and one light projecting unit, and a reflection plate that reflects the detection light projected from the light projecting / receiving unit toward the light projecting / receiving unit, A dimming reflection type detector is also used, which is disposed opposite to each other on the wall surface and uses a region sandwiched between the light projecting / receiving unit and the reflection plate as a monitoring region. When smoke intervenes in the monitoring area of these dimming detectors, the smoke is present in the path from the detection light emitted from the light projecting unit to the light receiving unit. And the occurrence of a fire is detected based on this.

  Here, in the dimming separation type sensor, the light projecting unit intermittently projects the detection light in order to save power consumption. Therefore, in order to appropriately determine the light reduction amount of the detection light, it is necessary to synchronize the light projection timing of the detection light by the light projecting unit and the light reception timing of the detection light by the light receiving unit. For this reason, conventionally, the light projecting unit and the light receiving unit are connected to each other via a control line, and a control signal is output from the light receiving unit to the light projecting unit via the control line. The light projecting unit emits light in a pulse manner at the timing of receiving the control signal, and at the same time, the light receiving unit performs a predetermined light receiving process in synchronization with the light projecting timing (see, for example, Patent Document 1). ).

Japanese Patent Application Laid-Open No. 8-227489

  However, in the conventional dimming type separation type sensor, the configuration of the light projecting unit and the configuration of the light receiving unit are different from each other, so different production lines and different components are used for the light projecting unit and the light receiving unit. It was necessary to manufacture separately. Therefore, even when the production of dimming sensors increased, the merit of scale could not be fully utilized. In addition, because the configuration of the device is different from the dimming reflection type detector that is integrally equipped with the light emitting and receiving unit, the device cannot be shared even though the basic operating principle is common. I still couldn't make use of the merit of scale.

  In addition, in the conventional method for establishing synchronization of the dimming type separated type sensor, since it is necessary to lay the control line for synchronization, the number of steps for mounting the sensor is increased and the cost for laying the control line is increased. It was. This laying cost has increased as the distance between the light projecting unit and the light receiving unit is longer, or as the number of light projecting units and light receiving units is increased. In recent years, the use of high-quality cables for control lines is sometimes required by fire fighting standards and the like, and in this case, the cost of laying control lines has further increased.

  The present invention has been made in view of the above, and any use of a light projecting unit of a dimming separation type sensor, a light receiving unit of a dimming separation type sensor, or a dimming reflection type sensor However, the present invention provides a light-reducing sensor that can be used without using a control line when the light-emitting unit and the light-receiving unit are synchronized with each other. For the purpose.

  In order to solve the above-described problems and achieve the object, the light-reducing sensor according to claim 1 includes a light projecting unit that projects detection light onto a monitoring area, and a light receiving unit that receives the detection light. A light-reducing sensor that determines the presence or absence of a predetermined monitoring target in the monitoring area based on the amount of light received by the light receiving means when the light receiving means receives the detection light, The operation mode of the dimming sensor is selected from the light projection mode for operating the light projecting means, the light receiving mode for operating the light receiving means, and the reflection mode for operating the light projecting means and the light receiving means simultaneously. It is characterized by comprising mode switching means for switching between at least two operation modes.

  Further, the light-reducing sensor according to claim 2 is the light-reducing sensor according to claim 1, wherein the light-receiving unit detects the light-receiving mode when the light-receiving mode is selected by the mode switching unit. Synchronization establishment processing means for performing a predetermined process for establishing synchronization between the timing at which the light is irradiated and the timing at which the light receiving means performs light reception, and the synchronization establishment processing means includes the detection light received by the light receiving means. A predetermined process for establishing synchronization is performed based on the above.

  According to the first aspect of the present invention, the operation mode of the dimming sensor is switched by the mode switching means, so that the dimming sensor is connected to the light projecting / receiving unit in the dimming reflection type sensor. It can be arbitrarily operated as a light projecting unit in the optical separation type sensor or a light receiving unit in the dimming type separation sensor. Thereby, the dimming type sensor having the same configuration can be shared for a plurality of uses, so that the merit of scale can be utilized to the maximum and the cost can be reduced. In addition, even if there is a change in the installation environment, such as a change in the installation location of the dimming sensor or a design change on the building side, it can be flexibly handled by selecting an operation mode suitable for the environment. In addition, when two dimming sensors are used as dimming separation type sensors, if one dimming sensor fails, the failed dimming sensor can be used as a reflector. At the same time, by switching the operation mode of the normal dimming sensor to the reflection mode, monitoring by the dimming sensor can be resumed quickly.

  According to the second aspect of the present invention, when the mode switching means is set to the light receiving mode, the timing at which the detection light is irradiated and the light receiving means based on the detection light received by the light receiving means Since synchronization establishment processing means establishes synchronization with the timing to perform the light receiving operation, send and receive synchronization signals by connecting the light reducing sensor on the light emitting side and the light reducing sensor on the light receiving side via the control line There is no need to let them. Thereby, the installation of the control line can be omitted, the installation work of the dimming sensor can be facilitated, and the installation cost can be greatly reduced.

  Embodiments of the dimming sensor according to the present invention will be described below in detail with reference to the accompanying drawings. [I] First, the basic concept of each embodiment will be described, then [II] the specific contents of each embodiment will be described, and [III] Finally, modifications to each embodiment will be described. However, the present invention is not limited to each embodiment.

[I] Basic concept of each embodiment First, a basic concept common to each embodiment will be described. The dimming sensor according to each embodiment is intended to detect smoke generated with a fire.

  The target of installation of the dimming sensor according to each embodiment is arbitrary. For example, in a large-scale building such as a factory facility or a building, an underground mall, or a relatively wide space such as a gymnasium or a warehouse is monitored. Can be an area. Furthermore, you may install in rooms, such as a kitchen and a bedroom of a general house.

  One of the features of the light-reducing sensor according to each embodiment is roughly provided with a light projecting unit and a light receiving unit, and switching for switching the operation mode of these light projecting unit and light receiving unit. There is a means. That is, the dimming sensor can be operated arbitrarily as a light projecting / receiving unit in a dimming reflection type sensor, a light projecting unit in a dimming type separation sensor, or a light receiving unit in a dimming type separation sensor. Can be made. For this reason, the dimming sensor having the same configuration can be shared for a plurality of uses, so that the merit of scale can be maximized and the cost can be reduced.

  Another feature is that, when used as a dimming separation type sensor, synchronization between the light projecting unit and the light receiving unit is established wirelessly. Specifically, synchronization is established based on detection light projected and received between the light projecting unit and the light receiving unit. For this reason, it is not necessary to lay a control line for the synchronization signal between the light projecting unit and the light receiving unit, so that the installation workability of the dimming sensor can be improved and the installation cost including the wiring cost can be improved. Can be greatly reduced.

[II] Specific Contents of Each Embodiment Next, specific contents of each embodiment according to the present invention will be described.

[Embodiment 1]
First, the first embodiment will be described. In this mode, the operation mode of the dimming sensor is switched by the switching unit between the light projection mode, the light reception mode, and the reflection mode, and when the light projection unit is operated in the light projection mode, the light projection unit transmits the detection light. In the case of operating in the light receiving mode intermittently for a predetermined light projecting interval at every predetermined light projecting interval, the synchronization establishment processing means performs only a predetermined light receiving time for each predetermined light receiving interval different from the light projecting interval. This is a mode in which the light receiving means intermittently performs a light receiving operation (in this embodiment, when the light projecting mode and the light receiving mode are selected and operated as a dimming separation type sensor, respectively, the light projecting unit and the light receiving unit are operated. A method that does not use a control line in between is adopted).

(Configuration of dimming sensor)
First, an outline of the configuration of the dimming sensor will be described. FIG. 1 is a perspective view when the dimming sensor according to Embodiment 1 is used as a dimming separation type sensor, and FIG. 2 is a perspective view when it is used as a dimming reflection type sensor. is there.

  As shown in FIG. 1, when the dimming sensor 1 is used as a dimming separation type sensor, a plurality of the dimming sensors 1 are mutually connected across a region to be monitored for smoke generation. It arrange | positions so that it may oppose. Among the dimming sensors 1 arranged opposite to each other, one dimming sensor 1 projects detection light, and the other dimming sensor 1 receives the detection light. The dimming sensor 1 on the side that projects the detection light is connected to a local power source 3 through a power line 2 and is driven by electric power supplied from the local power source 3. However, when a battery is built in the dimming sensor 1, the power supply line 2 and the local power supply 3 can be omitted. Alternatively, when the light projecting side and the light receiving side are connected by a wired control line, power is supplied to the light projecting side light-reducing sensor 1 via the light-reducing sensor 1 on the side that receives the detection light. Also good. The light-reducing sensor 1 on the side that receives the detection light is connected to the receiver 5 through the control line 4 and receives power supply from the receiver 5 through the control line 4, and When smoke is detected by the dimming sensor 1 (or when it is determined that a fire has occurred based on the smoke detection result), a notification signal indicating that fact is sent via the control line 4. Output to the receiver 5. The receiver 5 performs a predetermined alarm operation when the alarm signal is received from the light receiving side dimming sensor 1. Examples of the alarm operation include outputting an alarm sound and outputting a transfer signal for notifying other disaster prevention devices (not shown) that smoke or fire has been detected.

  In addition, as shown in FIG. 2, when the light-reducing sensor 1 is used as a light-reducing reflective sensor, the light-reducing sensor 1 is reflected from the light-reducing sensor 1 across a region where smoke generation is monitored. It arrange | positions so that the board 6 may mutually oppose. The dimming sensor 1 projects detection light, the reflection plate 6 reflects the detection light toward the dimming sensor 1, and the dimming sensor 1 receives the reflected detection light. The dimming sensor 1 is connected to the receiver 5 through the control line 4 in the same manner as when used as the light receiving side in the dimming separation type sensor. When the smoke is detected in the light-reducing sensor 1 (or when it is determined that a fire has occurred based on the smoke detection result) A notification signal indicating that is output to the receiver 5 via the control line 4.

  As described above, the dimming sensor 1 is used as a light projecting unit or a light receiving unit of a dimming separation type sensor, and when used as a dimming reflection type sensor. A dimming sensor 1 having the same configuration can be used.

  Next, components of the dimming sensor 1 will be described. FIG. 3 is a block diagram functionally conceptually showing the electrical configuration of the dimming sensor 1. As shown in FIG. 3, the dimming sensor 1 includes an optical unit 10, a control unit 11, a mode switch 12, a synchronization instruction switch 13, a storage unit 14, and a display unit 15.

(Configuration of dimming sensor-optical unit 10)
The optical unit 10 is a unit in which optical devices used for detecting smoke in the light-reducing sensor 1 are integrated into one unit, and includes a light projecting unit 101 and a light receiving unit 102.

  The light projecting unit 101 projects detection light and corresponds to the light projecting means in the claims. The specific configuration of the light projecting unit 101, the wavelength of light projected from the light projecting unit 101, and the like are arbitrary. For example, an LED 103 (Light Emitting Diode) that emits near infrared light is used as a light source, and the LED 103 emits light. The collected light can be condensed by the lens 104 and projected.

  The light receiving unit 102 is for receiving detection light, and corresponds to the light receiving means in the claims. The light receiving unit 102 includes a light receiving element 105 and an amplification unit 106.

  The light receiving element 105 receives the detection light and outputs a voltage or current corresponding to the amount of light received. Although the specific configuration of the light receiving element 105 is arbitrary, for example, a photodiode can be used. Similarly to the light projecting unit, the light receiving unit may be provided with a lens that collects the detection light.

  The amplifying unit 106 is an amplifying unit that amplifies the output from the light receiving element 105.

  The light projecting unit 101 and the light receiving unit 102 are fixed on the optical unit 10 in close proximity to each other. Further, the light projecting unit 101 and the light receiving unit 102 are arranged so that the light projecting direction of the light projecting unit 101 and the light receiving direction of the light receiving unit 102 coincide (each optical axis is parallel to each other). Yes.

(Configuration of dimming sensor-control unit 11)
The control unit 11 is for performing predetermined processing in the dimming sensor 1. The control unit 11 includes a light projection control unit 110 and a light reception control unit 111.

  The light projecting control unit 110 is for controlling the light projecting unit 101. Specifically, the light projecting control unit 110 drives the light source such as the LED 103 in the light projecting unit 101, and the light emission current supplied to the light projecting unit 101. Control.

  The light reception control unit 111 is a processing unit that performs various processes based on control of the light reception unit 102 and detection light received by the light reception unit 102. The light reception control unit 111 includes a light reduction calculation unit 112, a smoke determination unit 113, and a synchronization establishment unit 114. The light reduction calculation unit 112 calculates the light reduction of the detection light received by the light receiving element 105. The smoke determination unit 113 determines the presence or absence of smoke (or the presence or absence of a fire) in the monitoring area based on the light reduction amount calculated by the light reduction amount calculation unit 112, and is stored in the storage unit 14 described later. A predetermined threshold value is compared with the reduced light amount, and if the reduced light amount exceeds the threshold value, it is determined that smoke has been generated. The synchronization establishment unit 114 performs predetermined processing for establishing synchronization based on the detection light received by the light receiving element 105, and corresponds to synchronization establishment processing means in the claims.

  Although the specific configuration of the control unit 11 is arbitrary, for example, a control program such as an OS (Operating System), a program that defines various processing procedures, an internal memory for storing necessary data, and these And a CPU (Central Processing Unit) for executing the program.

(Structure of dimming sensor-mode switch 12)
The mode change switch 12 is a switching means for switching the operation mode of the dimming sensor 1, and corresponds to the mode switching means in the claims. By performing a predetermined input operation to the mode changeover switch 12, the operation mode of the light-reducing sensor 1 is changed to a light projection mode in which the light projecting unit 101 is operated to emit detection light, and the light receiving unit 102 is operated. Switching between the light receiving mode for receiving the detection light and the reflection mode for projecting the detection light and receiving the reflected detection light by operating the light projecting unit 101 and the light receiving unit 102 simultaneously. Can do. The specific configuration of the mode switch 12 is arbitrary, and can be configured using, for example, a dip switch.

(Configuration of dimming sensor-synchronization instruction switch 13)
When the sync instruction switch 13 is operated as a dimming-type separation type sensor using a pair of sensors each selected in the light projection mode and the light reception mode, the operator starts the operation of establishing the synchronization between the light projection and the light reception. It is an instruction means for instructing. As will be described later, this synchronization instruction is given on the light receiving side. Here, it is assumed that the synchronization instruction switch 13 is configured as a cover switch that is automatically pressed when a housing cover (not shown) provided in the housing of the dimming sensor 1 is closed.

(Configuration of dimming sensor-storage unit 14)
The storage unit 14 is for storing information used for processing in the dimming sensor 1. Examples of information stored in the storage unit 14 include a light projection interval and a light projection time when the light projecting unit 101 projects the detection light, or a smoke determination unit when the light receiving unit 102 receives the detection light. 113, a synchronization establishment flag referred to by the synchronization establishment unit 114, a light reception interval, a light reception time, a state of the dimming sensor 1, and the like. The specific configuration of the storage unit 14 is arbitrary, and includes, for example, an EEPROM (Electronically Erasable and Programmable Read Only Memory) or a RAM (Random Access Memory).

(Configuration of dimming sensor-display unit 15)
The display unit 15 is for displaying an operation state (for example, a monitoring state, a failure state, a fire state, etc.) of the dimming sensor 1, and is controlled by the control unit 11. The specific configuration of the display unit 15 is arbitrary, and a plurality of LEDs that emit light in colors corresponding to each state (for example, monitoring state: green, fault state: yellow, fire state: red) may be used, or Alternatively, characters may be displayed using a liquid crystal display device. Further, as the above-described operation state, an operation mode, the amount of light received by the light receiving unit 102, various guidance displays, and the like can be displayed.

(Damping type sensor startup process)
Next, a startup process for raising the dimming sensor 1 to the monitoring state will be described. FIG. 4 is a flowchart showing the startup process of the dimming sensor 1. Note that the monitoring operation by the light-reducing sensor 1 after the start-up process described here is the same as that of the conventional light-reducing sensor, and thus the description thereof is omitted.

  As shown in FIG. 4, when the light-reducing sensor 1 is turned on by a predetermined input operation, the controller 11 checks the state of the mode switch 12 (step SA-1). When the mode selector switch 12 is set to the light projection mode (step SA-1, light projection mode), the light projection control unit 110 calls the light projection interval and the light projection time from the storage unit 14, and sets the light projection interval. By controlling the light source based on the detection light, the detection light is projected for a predetermined light projecting time every light projecting interval (step SA-2). Although the specific content of the light projection interval and the light projection time is arbitrary, the light projection interval is, for example, 1 to 10 seconds, and one pulse of a predetermined light projection time. Thus, the start-up process of the dimming sensor 1 in the light projection mode is completed.

  When the mode switch 12 is set to the light reception mode (step SA-1, light reception mode), the light reception control unit 111 waits until the synchronization instruction switch 13 is pressed (step SA-3). For example, when the dimming sensor 1 is initially installed, the worker turns on the light of the dimming sensor 1 by a predetermined method, and the dimming sensors 1 arranged opposite to each other across the monitoring area. After adjusting the mutual installation direction or the installation direction of the dimming sensor 1 with respect to the reflecting plate 6, the casing cover of the dimming sensor 1 is closed. By closing the housing cover, the synchronization instruction switch 13 is automatically pressed. In addition, when the power of the light-reducing sensor 1 whose installation adjustment has already been completed is cut off, the worker turns on the light-reducing sensor 1 to turn on the light-reducing sensor 1 again. to start. In this case, the installation adjustment has already been completed, and the casing cover of the light-reducing sensor 1 is closed, so that the synchronization instruction switch 13 is always in the pressed state.

  When the synchronization instruction switch 13 is in the pressed state as described above (step SA-3, Yes), the light reception control unit 111 determines whether or not the synchronization establishment flag is stored in the storage unit 14 (step SA- 4). If the synchronization establishment flag is stored (step SA-4, Yes), it is determined that synchronization has already been established and it is not necessary to newly execute the synchronization establishment process, and the synchronization establishment process is performed. The start-up process is terminated without any change, and the normal monitoring state using the synchronization condition stored in the storage unit 14 is entered. On the other hand, if the synchronization establishment flag is not stored (step SA-4, No), it is determined that synchronization has not yet been established and the synchronization establishment process needs to be executed, and the synchronization establishment process is executed. (Step SA-5). Then, after the synchronization establishment process is completed, the process shifts to a normal monitoring state using the synchronization condition specified in the synchronization establishment process. Thus, the start-up process of the dimming sensor 1 in the light receiving mode is completed.

  When the mode switch 12 is set to the reflection mode (step SA-1, reflection mode), the light projection control unit 110 calls the light projection interval and the light projection time from the storage unit 14, and sets the light projection interval. Based on the control of the light source, the detection light is projected for a predetermined light projecting time every light projecting interval (step SA-6). Furthermore, the light reception control unit 111 calls the light reception interval and the light reception time for the reflection mode from the storage unit 14, and controls the light receiving element 105 based on the light reception interval, so that the detection light is transmitted for each predetermined light reception interval. Only light is received (step SA-7). In the reflection mode, the light reception interval is the same as the light projection interval, and the light reception time is the same as or longer than the light projection time. Accordingly, by simultaneously operating the light projecting unit 101 and the light receiving unit 102 at the beginning of startup, it is possible to synchronize the timing of projecting light to the light projecting unit 101 and the timing of receiving light of the light receiving unit 102 thereafter. The detection light projected from the unit 101 can be received by the light receiving unit 102. This completes the start-up process of the dimming sensor 1 in the reflection mode.

  Next, the synchronization establishment process of the light receiving unit 102 in step SA-5 will be described. FIG. 5 is a flowchart showing the flow of synchronization establishment processing of the light receiving unit 102. This synchronization establishment process includes a synchronization timing specifying process (step SB-1) for specifying the synchronization timing, and a light receiving time adjusting process (step SB) for shortening the light receiving time with the synchronization timing specified in the synchronization timing specifying process as a center. -2).

  First, the basic concept of the synchronization timing specifying process in step SB-1 will be described. FIG. 6 is a flowchart showing a basic concept of the synchronization timing specifying process of the light receiving unit 102, and FIG. 7 is a timing showing the irradiation timing of the detection light to the dimming sensor 1 and the timing of the light receiving operation of the light receiving unit 102 in the synchronization timing specifying process. It is a chart. As shown in FIG. 7, it is assumed that the detection light is irradiated to the dimming sensor 1 set in the light receiving mode for a predetermined light projecting time every predetermined light projecting interval Te. .

  As shown in FIGS. 6 and 7, the synchronization establishing unit 114 causes the light receiving unit 102 to perform a predetermined light receiving operation for receiving the detection light at every predetermined light receiving interval different from the light projecting interval (step SC-1). . Thus, even if light projection or light reception is performed intermittently by performing a light reception operation at a light reception interval different from the light projection interval, the detection light has a timing corresponding to a common multiple of the light projection interval and the light reception interval. Can be received. In particular, in the first embodiment, the light reception interval is shorter than the light projection interval, for the following reason. That is, in the first embodiment, since the light projection interval is maintained at the same interval even in the smoke monitoring state after synchronization is established, the light projection interval needs to be an appropriate interval for performing smoke detection. . Here, in order to reduce the power consumption in the light projecting unit 101, it is preferable to set the light projecting interval to be long as long as smoke detection is not hindered. On the other hand, if the light receiving unit 102 receives light by setting the light receiving interval to be longer than the light projecting interval, the time required for establishing synchronization is likely to be long. Therefore, in the first embodiment, while the light projection interval is set to be an interval suitable for smoke detection, the light reception interval is made shorter than the light projection interval to speed up the establishment of synchronization.

  Further, in each light receiving operation, the synchronization establishing unit 114 causes the light receiving unit 102 to receive the detection light continuously for a predetermined light receiving time (step SC-2), and determines whether or not the light is received (step SC-3). . Specifically, the synchronization establishment unit 114 determines whether or not the detection light is received by comparing the output from the light receiving element 105 with a predetermined value in each light receiving operation. For example, when the light projection interval is 3 seconds, each light receiving operation causes the light receiving unit 102 to perform the light receiving operation continuously for several hundred milliseconds. FIG. 7 shows an example in which the light receiving unit 102 performs five light receiving operations N1 to N5. If the synchronization establishment unit 114 determines that the detection light is received during any of the light reception operations (Yes in step SC-3), the synchronization establishment unit 114 uses a predetermined synchronization interval (in this case, the light projection) The timing that arrives at the same interval) is specified as the synchronization timing (step SC-4). For example, in FIG. 7, since the detection light is received for the first time in the fifth light receiving operation N5, the synchronization establishing unit 114 specifies the synchronization timing based on the light receiving time in the light receiving operation N5. This completes the synchronization timing specifying process. These initial light receiving intervals and light receiving times are stored in the storage unit 14 so that they can be referred to from the control unit 11 before the dimming sensor 1 is shipped from the factory, or are internal parameters of the synchronization establishment processing program. Can be incorporated as (This also applies to the following second light reception time and other time data).

  Next, the basic concept of the light reception time adjustment process in SB-2 of FIG. 5 will be described. FIG. 8 is a flowchart showing the basic concept of the light receiving time adjustment process of the light receiving unit 102, and FIG. 9 is a timing chart showing the timing of the light projecting operation of the light projecting unit 101 and the light receiving operation of the light receiving unit 102 in the light receiving time adjusting process. . As shown in FIG. 9, the synchronization establishing unit 114 has a predetermined second light receiving time shorter than the previous light receiving time with the continuous light receiving time of the detected light centered on the synchronization timing specified in the synchronization timing specifying process. (Step SD-1). FIG. 9 shows three light receiving operations N5 to N7 (the light receiving operation N5 is the same as the light receiving operation N5 in FIG. 7). Here, the light receiving time in the light receiving operation N6 is changed to the second light receiving time. ing. For example, if the previous light reception time is several hundred milliseconds, the second light reception time is set to several tens of milliseconds. Thereafter, the synchronization establishment unit 114 stores the synchronization establishment flag in the storage unit 14 (step SD-2). This completes the light reception time adjustment process, and the synchronization establishment process ends. In the normal monitoring state thereafter, by causing the light receiving unit 102 to receive the detection light only at the synchronization timing specified by the synchronization timing specifying process and for the second light reception time changed by the light reception time adjustment process, The timing at which the detection light is projected onto the dimming sensor 1 and the light reception timing by the light receiving unit 102 are synchronized. The synchronization establishment flag stored in the storage unit 14 is deleted when the light-reducing sensor 1 is turned off. Therefore, when the mode switch 12 is set to the light receiving mode when the power is turned on again, the synchronization establishment process is automatically started on the condition that the synchronization instruction switch 13 is pressed.

(Effect of Embodiment 1)
As described above, according to the first embodiment, the operation mode of the dimming sensor 1 is switched by the mode changeover switch 12, so that the dimming sensor 1 is changed to the light projecting / receiving unit in the dimming reflection type sensor. It can be arbitrarily operated as a light projecting unit in the dimming type separation type sensor or a light receiving unit in the dimming type separation type sensor. As a result, the dimming sensor 1 having the same configuration can be shared for a plurality of uses, so that the merit of scale can be maximized and the cost can be reduced. In addition, even if the installation environment is changed, such as a change in the installation location of the dimming sensor 1 or a design change on the building side, it can be flexibly handled by selecting an operation mode suitable for the environment. Further, when one of the dimming sensors 1 fails when two dimming sensors 1 are used as the dimming separation type sensors, the failed dimming sensor 1 is replaced. By replacing the reflection plate 6 and switching the normal operation mode of the dimming sensor 1 to the reflection mode, the monitoring by the dimming sensor 1 can be resumed quickly.

  In addition, when the mode switch 12 is set to the light receiving mode, the timing at which the detection light is irradiated and the timing at which the light receiving unit 102 performs the light receiving operation are synchronized based on the detection light received by the light receiving unit 102. Since the synchronization establishment unit 114 is established, it is not necessary to connect the light-emitting-side light-reducing sensor 1 and the light-receiving-side light-reducing sensor 1 via a control line to transmit and receive a synchronization signal. Thereby, the installation of the control line can be omitted, the installation work of the dimming sensor 1 can be facilitated, and the installation cost can be greatly reduced.

  In addition, when the mode switch 12 is set to the light projection mode, the detection light is intermittently projected from the light projecting unit 101, so that the power consumption of the light projecting unit 101 can be reduced. In addition, when the mode switch 12 is set to the light receiving mode, not only the normal monitoring state but also the light receiving unit 102 intermittently performs the light receiving operation during the execution of the synchronization establishing process. The power consumption of the light receiving unit 102 can also be reduced.

  In addition, after specifying the synchronization timing, the light receiving time of the detection light by the light receiving unit 102 is shortened and changed to the second light receiving time, so that the power consumption of the light receiving unit 102 in the normal monitoring state can be further reduced. it can.

[Embodiment 2]
Next, a second embodiment will be described. This form is a form provided with the integrated determination processing means.

(Configuration of dimming sensor)
First, the configuration of the dimming sensor according to the second embodiment will be described. FIG. 10 is a block diagram functionally conceptually showing the electrical configuration of the dimming sensor according to the second embodiment. The configuration of the second embodiment is substantially the same as the configuration of the first embodiment except where otherwise specified, and the same configuration as that of the first embodiment is used in the first embodiment. The same reference numerals and / or names are attached as necessary, and the description thereof is omitted.

(Configuration of dimming sensor-signal line)
As shown in FIG. 10, in the second embodiment, two dimming detectors 1 are arranged to face each other across a monitoring region and are connected to each other via a signal line 7. Although the specific content of the information transmitted through the signal line 7 is arbitrary, at least the output value from the light receiving unit 102 of one of the light-reducing sensors 1 is transmitted through the signal line 7 to the other of the other. This is input to the control unit 11 of the dimming sensor 1. Further, the specific configuration of the signal line 7 is arbitrary, and a wired line such as a copper wire or an optical cable can be used, or radio using radio waves or light can be used.

(Configuration of dimming sensor-control unit 11)
The control unit 11 includes an integrated determination unit 115. The integrated determination unit 115 is configured to select the two light-reducing sensors when a light-emitting / receiving mode (to be described later) is selected as the operation mode of both of the two light-reducing light sensors 1 arranged to face each other. It is an integrated determination processing means for performing a predetermined determination process based on information output from both of the one light receiving unit. Both of the integrated determination units 115 provided in each of the two dimming sensors 1 arranged to face each other may be operated, or one integrated determination unit by a predetermined selection means (not shown). Only 115 may be selected and operated. In addition, as a result of the processing executed by the integration determination unit 115, for example, an alarm signal at the time of a fire can be output to the receiver 5 through the control line 4 from at least one integration determination unit 115. . Specific contents of the processing executed by the integrated determination unit 115 will be described later.

(Structure of dimming sensor-mode switch 12)
By performing a predetermined input operation on the mode changeover switch 12 of the second embodiment, in addition to the above-described light projection mode, light reception mode, and reflection mode, the operation mode of the dimming sensor 1 is It is also possible to switch to a light projecting / receiving mode in which the light projecting unit 101 and the light receiving unit 102 are operated independently of each other.

(Damping type sensor startup process)
Next, a startup process for raising the dimming sensor 1 to the monitoring state will be described. FIG. 11 is a flowchart showing the start-up process of the dimming sensor 1.

  As shown in FIG. 11, when the light-reducing sensor 1 is turned on by a predetermined input operation, the control unit 11 checks the state of the mode switch 12 (step SE-1). When the mode switch 12 is set to the light projection mode (step SE-1, light projection mode), when the mode switch 12 is set to the light reception mode (step SE-1, light reception mode), and Since the process (step SE-1 to step SE-7) executed when the mode changeover switch 12 is set to the reflection mode (step SE-1, reflection mode) is the same as that of the first embodiment, description will be given. Is omitted.

  When the mode selector switch 12 is set to the light projecting / receiving mode (step SE-1, light projecting / receiving mode), the light projecting control unit 110 calls the corresponding light projecting interval and light projecting time from the storage unit 14, By controlling the light source based on the light interval, the detection light is projected for a predetermined light projecting time for each light projecting interval (step SE-8). The light reception control unit 111 stands by until the synchronization instruction switch 13 is pressed (step SE-9). When the synchronization instruction switch 13 is in the pressed state (step SE-9, Yes), the light reception control unit 111 determines whether a synchronization establishment flag is stored in the storage unit 14 (step SE-10). If the synchronization establishment flag is stored (step SE-10, Yes), it is determined that synchronization has already been established and it is not necessary to newly execute the synchronization establishment process, and the synchronization establishment process is performed. The start-up process is terminated without any change, and the normal monitoring state using the synchronization condition stored in the storage unit 14 is entered. On the other hand, if the synchronization establishment flag is not stored (step SE-10, No), it is determined that synchronization has not yet been established and the synchronization establishment process needs to be executed, and the synchronization establishment process is executed. (Step SE-11). Then, after the synchronization establishment process is completed, the process shifts to a normal monitoring state using the synchronization condition specified in the synchronization establishment process. Thus, the start-up process of the light-reducing sensor 1 in the light projecting / receiving mode is completed. Note that the synchronization establishment process of the light receiving unit 102 in step SE-11 is the same as that in the first embodiment, and thus the description thereof is omitted. In this way, the monitoring operation is performed by establishing synchronization between the light projecting unit on the other side and the light receiving unit disposed opposite to each other.

(Monitoring operation of dimming sensor)
Next, the operation of the light-reducing sensor 1 that has been set to the light projecting / receiving mode and has been started up will be described. FIG. 12 is a flowchart showing the integrated determination process performed by the control unit 11 in the light projection / reception mode.

(Monitoring operation of dimming sensor-integrated judgment processing)
In the integrated determination process, the fire determination and the state determination are independently performed in each of the two dimming smoke detectors 1, and then the determination results of both are combined and the integrated determination unit 115 of each dimming sensor 1. Is a process of making an integrated determination. Hereinafter, the flow of the integrated determination process executed in the integrated determination unit 115 of one of the two dimming sensors 1 will be described with reference to FIG. Note that the same processing is executed in the integrated determination unit 115 of the other light-reducing sensor 1.

  As shown in FIG. 12, when the integration determination process is started, the integration determination unit 115 waits for an input from the light receiving unit 102 (step SF-1). When the input from the light receiving unit 102 to the control unit 11 is confirmed (step SF-1, Yes), the integration determining unit 115 supplies the reduced light amount of the detection light received by the light receiving unit 102 to the reduced light amount calculating unit 112. Calculate (step SF-2). Subsequently, the smoke determination unit 113 determines the presence or absence of smoke in the monitoring region based on the light reduction amount calculated in step SF-2 (step SF-3). When the amount of light reduction is within the range indicating that it is in a fire state (step SF-3, Yes), the smoke determination unit 113 determines that a fire has occurred. In this case, the integrated determination unit 115 performs a process of transmitting a display indicating that a fire has occurred on the display unit 15 and a determination result to the integrated determination unit 115 of the other light-reducing sensor 1 (Step S1). SF-4). Here, the dimming amount calculation unit 112 may calculate a dimming rate with respect to a predetermined reference received light amount, and may make a series of determinations based on the dimming rate calculation result.

  When the calculated light reduction amount is out of the range indicating the fire state (step SF-3, No), the integrated determination unit 115 performs state determination processing for determining the light reception state of the light receiving unit 102. Execute (step SF-5). In this state determination process, it is determined whether the light receiving unit 102 is in a normal state in which detection light detection by the light receiving unit 102 can be continued, or a failure state in which a failure has occurred due to the occurrence of contamination or disturbance light. If it is determined that the state is a failure state (step SF-6, No), the display indicating the failure state and the determination result to the integrated determination unit 115 of the other dimming sensor 1 are displayed. Transmission processing is performed (step SF-7). If it is determined that the state is normal (step SF-6, Yes), a determination result transmission process to the integrated determination unit 115 of the other light-reducing sensor 1 is performed (step SF-8).

  Subsequently, the integrated determination unit 115 waits for an input of a determination result from the integrated determination unit 115 of the other light-reducing sensor 1 (step SF-9). When the determination result is input (step SF-9, Yes), the integrated determination unit 115 stores the determination result in step SF-3 or step SF-5 and the input determination result in the storage unit 14. The integrated determination table is collated and integrated determination is performed (step SF-10).

  FIG. 13 shows an example of the integrated determination table. FIG. 13A shows an integrated determination table when priority is given to fire determination, and FIG. 13B shows an integrated determination table when priority is given to failure determination. Only one of these tables may be stored in the storage unit 14, or either table may be stored in the storage unit 14 so that either one can be selected by a predetermined input operation or the like. It may be.

  As a result of the integration determination, when it is determined that a fire state is present (step SF-11, fire), the integration determination unit 115 performs fire processing such as alarm output (step SF-12). When it is determined that the state is a failure state (step SF-11, failure), the integrated determination unit 115 performs a failure process such as displaying a failure state (step SF-13). If it is determined that the state is normal (step SF-11, normal), the integration determination unit 115 returns to step SF-1 and executes the integration determination process again.

(Effect of Embodiment 2)
As described above, according to the second embodiment, the mode selector switch 12 can select the light projecting / receiving mode in which both the light projecting unit 101 and the light receiving unit 102 in the dimming sensor 1 are operated. Accordingly, when the light projecting / receiving mode is selected as the operation mode of the light-reducing sensor 1 that is disposed opposite to each other and connected to each other via the signal line 7, the light is projected from the two light projecting units 101. Each of the detection lights can be received by the two light receiving units 102, and the fire can be determined by the integrated determination unit 115 after integrating the information output from each smoke determination unit 113. As a result, an alarm can be generated only when a fire determination is made in each of the two systems of smoke determination unit 113, so that the occurrence of a false alarm can be suppressed and the reliability of the light-reducing sensor 1 can be improved. Can be improved. Further, even when a failure occurs in one of the two systems of the light projecting unit 101 and the light receiving unit 102, monitoring can be continued by the light projecting unit 101 and the light receiving unit 102 of the other system. The integrated determination unit 115 may be provided in an external device, for example, the receiver 5. In this case, each sensor 1 transmits information necessary for the integrated determination to the receiver 5.

[III] Modifications to Each Embodiment While each embodiment according to the present invention has been described above, the specific configuration and means of the present invention are the same as the technical idea of each invention described in the claims. Modifications and improvements can be arbitrarily made within the range. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved. For example, even if the light-reducing sensor 1 cannot be operated as a light-reducing reflective sensor, the present invention can be applied to the present invention as a light-removable separation-type sensor. As long as this can be improved, the problem of the present application is solved. In addition, when producing in advance for the purpose of use as a light projecting part of a dimming type separation type sensor, or when producing in advance for use as a light receiving part of a dimming type separation type sensor, Costs can be further reduced, for example, by not mounting components that do not need to perform the function, such as a light receiving lens or light receiving element in the former case, or a light projecting lens or LED in the latter case.

(Connection of dimming sensor)
In each of the above embodiments, the case where the dimming sensor is connected wirelessly is shown, but these may be connected to each other by wire, and in this case, by transmitting and receiving the synchronization signal by wire, The synchronization establishment process can be further simplified.

(About integrated judgment processing)
In the second embodiment, in the integrated determination process, each of the two light-reducing smoke detectors 1 performs fire determination and state determination independently, and then combines the results of both determinations. In the above description, one integrated determination unit 115 performs an integrated determination. However, based on the outputs from the light receiving units 102 of both the light-reducing sensors 1, either one of the integrated determination units 115 performs the integrated determination. May be performed. Further, the integration determination table referred to at the time of integration determination is not limited to the example shown in FIG. For example, when there is a contradiction in the determination results of both the dimming sensors, the integrated determination table for determining all faults may be stored in the storage unit 14. As a result, when the determination result of the dimming sensor 1 does not match due to some trouble or the influence of disturbance light, it is possible to promptly notify that fact and to prompt the countermeasure.

  In addition, after the start-up process of the dimming sensor 1 in the light emitting / receiving mode, when the dimming sensor 1 shifts to the normal monitoring state, first, after determining the state of the dimming sensor 1, An integrated determination process or a single determination process may be selected. Specifically, as shown in FIG. 14, the integrated determination unit 115 refers to the storage unit 14 and confirms the state of the two light-reducing sensors 1 connected to each other via the signal line 7. (Step SG-1). In addition, although the specific content of the information memorize | stored in the memory | storage part 14 about the state of the dimming sensor 1 is arbitrary, for example, the light reception mounted in each of the two dimming sensors 1 Whether the state of the unit 102 is in a normal state where a fire determination is possible by receiving detection light or a failure state where a fire determination is impossible due to insufficient detection light intensity, etc. Information is stored.

  If only one of the two dimming sensors 1 is in a normal state (step SG-1, one is normal), the integrated determination unit 115 executes a single determination process. (Step SG-2). If both of the two light-reducing sensors 1 are normal (step SG-1, both are normal), the integrated determination unit 115 executes an integrated determination process (step SG-3). If the two dimming sensors 1 are both in a fault state (step SG-1, both faults), an alarm signal is transmitted to the receiver 5 and a display unit 15 indicates that it is in a fault state. The failure process to be displayed is executed to prompt the administrator or the like to recover (step SG-4).

  The dimming sensor according to the present invention detects the attenuation of light that has been projected from the light projecting means and passed through the space that is the monitoring area to reach the light receiving means, and senses the presence of smoke due to a fire or the like. The present invention can be applied to a dimming sensor, and can be used for either a dimming separation type sensor or a dimming reflection type sensor.

It is a perspective view at the time of using the dimming type sensor which concerns on Embodiment 1 as a dimming type separation type sensor. It is a perspective view at the time of using the dimming type sensor as a dimming type reflection type sensor. 2 is a block diagram functionally conceptually showing the electrical configuration of the dimming sensor 1. FIG. 5 is a flowchart showing a startup process of the dimming sensor 1. 5 is a flowchart showing a flow of synchronization establishment processing of the light receiving unit 102. 3 is a flowchart showing a basic concept of synchronization timing specifying processing of the light receiving unit 102. 6 is a timing chart showing detection light irradiation timing with respect to the light-reducing sensor 1 and timing of light receiving operation of the light receiving unit 102 in the synchronization timing specifying process. 4 is a flowchart illustrating a basic concept of light reception time adjustment processing of the light receiving unit 102. 6 is a timing chart showing timings of a light projecting operation of a light projecting unit 101 and a light receiving operation of a light receiving unit 102 in a light receiving time adjustment process. FIG. 5 is a block diagram functionally conceptually showing an electrical configuration of a dimming sensor according to a second embodiment. 5 is a flowchart showing a startup process of the dimming sensor 1. It is the flowchart which showed the flow of the integrated determination process. FIG. 13A is an example of an integrated determination table, FIG. 13A is an integrated determination table when priority is given to fire determination, and FIG. 13B is an integrated determination table when priority is given to failure determination. It is a flowchart in the case of performing state determination after transition to a normal monitoring state.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Dimming type sensor 2 Power supply line 3 Local power supply 4 Control line 5 Receiver 6 Reflector 7 Signal line 10 Optical unit 11 Control part 12 Mode change switch 13 Synchronization instruction switch 14 Memory | storage part 15 Display part 101 Light projection part 102 Light reception Part 103 LED
DESCRIPTION OF SYMBOLS 104 Lens 105 Light receiving element 106 Amplifying part 110 Light projection control part 111 Light reception control part 112 Light reduction amount calculation part 113 Smoke determination part 114 Synchronization establishment part 115 Integrated determination part

Claims (2)

A light projecting means for projecting detection light to the monitoring area; and a light receiving means for receiving the detection light; and when the light receiving means receives the detection light, based on the amount of the detected light received A dimming sensor for determining the presence or absence of a predetermined monitoring target in the monitoring area,
The operation mode of the dimming sensor is selected from among a light projection mode for operating the light projecting means, a light receiving mode for operating the light receiving means, and a reflection mode for operating the light projecting means and the light receiving means simultaneously. , Comprising mode switching means for switching between at least two operation modes;
This is a dimming sensor. When the light receiving mode is selected by the mode switching means, synchronization for performing a predetermined process for establishing synchronization between the timing at which the detection light is applied to the light receiving means and the timing at which the light receiving means receives light An establishment processing means,
The synchronization establishment processing means performs a predetermined process for establishing synchronization based on the detection light received by the light receiving means;
The light-reducing sensor according to claim 1.

Images