JP4887434B2 - Remote sensor - Google Patents

Description

  The present invention relates to a separation type sensor that senses various monitoring targets such as a fire and a human body in a monitoring area.

  2. Description of the Related Art Conventionally, as one form of a smoke detector that detects smoke generated by a fire or the like, a light reduction type smoke detector that detects smoke based on a light reduction rate of detection light is known. Among such dimming smoke detectors, there is a photoelectric separation type smoke detector that can cover a relatively wide monitoring area.

FIG. 18 is a system configuration diagram of a conventional photoelectric separated smoke detector. This photoelectric separation type smoke detector 100 separates light transmitting units 101A to 101C that transmit detection light and light receiving units 102A to 102C that receive this detection light from each other across a monitoring region. It is configured to face each other. Then, the detection light transmitted from the light transmission units 01A to 101C is received by the light receiving units 102A to 102C arranged to face each other, and the light amount of the detection light is reduced by the light receiving units 102A to 102C. And calculate the fading rate. When the amount of light reduction is equal to or greater than a predetermined reference value, the light receiving units 102A to 102C determine that smoke has occurred (fire has occurred), and to the receiver 104 wired by the control line 103, Outputs an alarm signal indicating the occurrence of a fire.

  Here, in order to appropriately determine the light reduction amount of the detection light, the light transmission timing of the detection light by the light transmission units 101A to 101C and the light reception timing of the detection light by the light reception units 102A to 102C are mutually determined. Need to synchronize. For this reason, conventionally, the light transmitting units 101A to 101C and the light receiving units 102A to 102C are connected to each other by a control line 105, and the light transmitting units 101A to 101C to the light receiving unit 102A are connected via the control line 105. The control signal (synchronization signal) was output to -102C. The light receiving units 102A to 102C receive light at a predetermined synchronization interval based on the synchronization timing specified by the synchronization signal, thereby synchronizing the light transmitting units 101A to 101C and the light receiving units 102A to 102C. (For example, refer to Patent Document 1).

Japanese Unexamined Patent Publication No. 8-227489

  However, in the conventional method for establishing synchronization of the separated type sensor, since it is necessary to lay the control line for synchronization, the process for mounting the sensor is increased and the cost for laying the control line is required. The laying cost increases as the distance between the light transmitting unit and the light receiving unit increases or as the number of light transmitting 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 such a conventional problem, and provides a separation type sensor capable of performing mutual synchronization between a light transmitting unit and a light receiving unit without using a control line. With the goal.

  In order to solve the above-described problems and achieve the object, the separation type sensor according to claim 1 includes: a light transmission unit that transmits detection light to a monitoring region; and a light transmission unit that transmits the detection light. And a light receiving means for receiving the detected light and determining the presence or absence of a predetermined monitoring target in the monitoring area based on the amount of light received by the received detection light. One of the light transmitting means and the light receiving means is a synchronous light transmitting means for wirelessly transmitting synchronous light for synchronizing the light transmitting means and the light receiving means. And the other of the light transmitting means or the light receiving means is automatically pressed when the case cover provided on the light transmitting means or light receiving means is closed, thereby establishing the synchronization establishing operation. An instruction means for accepting a start instruction and whether or not the synchronization is established Based on the synchronization light received by the synchronization light receiving means, the storage means for storing the synchronization establishment flag for receiving the synchronization light transmitted from the synchronization light transmission means, and the synchronization light receiving means Synchronization establishment processing means for performing processing for establishing the synchronization, and the synchronization establishment processing means is instructed by the instruction means to start the operation for establishing synchronization because the housing cover is closed. When it is accepted and the synchronization establishment flag is not stored in the storage means, a process for establishing the synchronization is performed.

  According to the present invention, synchronization light can be transmitted from either one of the light transmitting means and the light receiving means, and this can be received by either one of the light transmission means and the light receiving means. Thus, it is not necessary to connect and transmit a synchronization signal, and the installation of the control line can be omitted, so that the installation work of the separation type sensor becomes easy and the installation cost can be reduced.

FIG. 1 is a system configuration diagram of a sensor according to the first embodiment. FIG. 2 is a block diagram conceptually showing main electrical configurations of the light transmitting unit and the light receiving unit. FIG. 3 is a flowchart of start-up processing of the light transmission unit. FIG. 4 is a flowchart of the startup process of the light receiving unit. FIG. 5 is a flowchart of the synchronization establishment process of the light receiving unit. FIG. 6 is a flowchart illustrating the basic concept of the synchronization timing specifying process of the light receiving unit. FIG. 7 is a timing chart showing the timing of the light transmitting operation of the light transmitting unit and the light receiving operation of the light receiving unit in the synchronization timing specifying process. FIG. 8 is a flowchart showing the basic concept of the light receiving time adjustment processing of the light receiving unit. FIG. 9 is a timing chart showing the timing of the light transmission operation of the light transmission unit and the light reception operation of the light reception unit in the light reception time adjustment processing. FIG. 10 is a flowchart showing the synchronization timing specifying process in detail. FIG. 11 is a timing chart showing in detail the operation timing of each part of the light receiving unit in the synchronization timing specifying process. FIG. 12 is a flowchart showing in detail the light reception time adjustment processing. FIG. 13 is a timing chart showing in detail the operation timing of each part of the light receiving unit in the light receiving time adjustment processing. FIG. 14 is a flowchart of the synchronization correction process. FIG. 15 is a timing chart showing in detail the operation timing of each part of the light receiving unit in the synchronization correction processing. FIG. 16 is a block diagram conceptually showing main electrical configurations of the light transmitter and the light receiver of the sensor according to the second embodiment. FIG. 17 is a timing chart showing the timing of the light transmitting operation of the light transmitting unit and the light receiving operation of the light receiving unit in the synchronization timing specifying process. FIG. 18 is a system configuration diagram of a conventional photoelectric separated smoke detector.

  Hereinafter, the best embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings. [I] After explaining the basic concept common to each embodiment, [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 common to the embodiments First, the basic concept common to the embodiments will be described. Each embodiment relates to a separate sensor. This separation-type sensor relates to a separation-type sensor that senses various monitoring objects such as a fire and a human body in a monitoring area.

  Here, the specific content of the monitoring area by the separation type sensor is arbitrary, but in particular, a relatively wide area such as a gymnasium, a warehouse, and a shopping mall can be obtained by disposing the light transmitting section and the light receiving section facing each other. Can be set as a monitoring area. Moreover, the specific content of the monitoring object by a separation type sensor is arbitrary, For example, you may comprise as a fire sensor which detects a fire, or you may comprise as a human sensor which detects a human body. In the following description, a photoelectric separation type smoke detector that determines the presence / absence of smoke based on the amount of light reduced by smoke of detection light transmitted by the light transmitting unit and received by the light receiving unit will be described as an example.

  One of the features of this separation type sensor is that the synchronization between the light transmitting unit and the light receiving unit is established wirelessly. That is, synchronization is established by transmitting and receiving synchronized light, which is an optical signal for synchronization, between the light transmitting unit and the light receiving unit. For this reason, it is not necessary to lay a control line for a synchronization signal between the light transmitting unit and the light receiving unit, so that the installation workability of the separation type sensor can be improved and the installation cost can be reduced.

  Here, as the synchronization light, in addition to the case of transmitting and receiving dedicated light used only for synchronization, it is also possible to use detection light used for smoke detection as the synchronization light. In the latter case, a component for transmitting and receiving dedicated light is not necessary, so that the separation type sensor can be configured more simply. In each of the following embodiments, the case where the detection light is used as the synchronization light is illustrated, and the detection light and the synchronization light are simply referred to as detection light without being distinguished from each other unless otherwise specified.

  Moreover, various patterns can be mentioned as a synchronous light transmission / reception pattern. In each embodiment, in such a wireless synchronization establishment, a synchronization pattern that can complete the transmission and reception of light and radio waves between the light transmitting unit and the light receiving unit in a short time is adopted, This reduces the power required for light transmission / reception.

[II] Specific contents of each embodiment Next, specific contents of each embodiment will be described in detail.

  First, Embodiment 1 according to the present invention will be described. In the first embodiment, detection light is intermittently transmitted for a predetermined light transmission time every predetermined light transmission interval, and this detection light is transmitted for a predetermined light reception time every predetermined light reception interval different from the light transmission interval. It is related only to the form of receiving light intermittently.

  First, the configuration of the photoelectric separation type smoke detector (hereinafter referred to as a detector) will be described. FIG. 1 is a system configuration diagram of a sensor according to the first embodiment. This sensor 1 has light transmitters 10A to 10C and light receivers 20A to 20C, and these light transmitters 10A to 10C and light receivers 20A to 20C are connected to each other by several tens to several hundreds of meters. It is configured to be separated and arranged so as to be separated from each other by a certain distance and to face each other across the monitoring area. The light transmitting units 10A to 10C transmit detection light for detecting smoke, the light receiving unit 20A is detection light from the light transmitting unit 10A, and the light receiving unit 20B is detection light from the light transmitting unit 10B. 20C receives the detection light from the light transmitter 10C. In addition, since each light transmission part 10A-10C is comprised similarly to mutual, and light-receiving part 20A-20C is comprised similarly, mutual, below, light transmission part 10A-10C is referred to as light transmission part 10, The light receiving units 20A to 20C will be described as the light receiving unit 20.

  Each light transmission unit 10 transmits detection light. Each light transmitting unit 10 is connected to a local power source 3 via a power line 2 and is driven by electric power supplied from the local power source 3. However, when a battery is built in each light transmitter 10, the power supply line 2 and the local power supply 3 can be omitted. Alternatively, power may be supplied to each light transmitting unit 10 via each light receiving unit 20.

  Each light receiving unit 20 receives detection light. Each light receiving unit 20 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 detects smoke in the light receiving unit 20 (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. The receiver 5 performs a predetermined alarm operation when receiving a notification signal from the light receiving unit 20. 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.

  FIG. 2 is a block diagram conceptually showing main electrical configurations of the light transmitter 10 and the light receiver 20. The light transmission unit 10 is configured by accommodating a light source 12, a storage unit 13, and a light transmission control unit 14 inside a housing 11. Although the specific configuration of the light source 12 is arbitrary, for example, an LED (Light Emitting Diode) or an incandescent lamp can be used. In particular, in the first embodiment, this detection light is used as synchronization light for establishing synchronization. Therefore, the light source 12 transmits synchronized light wirelessly, and corresponds to the synchronized light transmitting means in the claims. The storage unit 13 is a storage unit that stores information such as a program and various parameters necessary for performing the light transmission operation of the light transmission unit 10, and includes, for example, an EEPROM (Electronically Erasable and Programmable Read Only Memory), It has a RAM (Random Access Memory). Examples of information stored in the storage unit 13 include a light transmission interval and a light transmission time. The light transmission control unit 14 controls light transmission by the light source 12, and transmits the detection light toward the monitoring region by blinking the light source 12.

  On the other hand, the light receiving unit 20 receives detection light. Inside the housing 21, a light receiving element 22, an amplification unit 23, a peak hold unit 24, an A / D conversion unit 25, a storage unit 26, a synchronization instruction switch. 27 and the light reception control unit 28 are accommodated.

  The light receiving element 22 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 22 is arbitrary, for example, a photodiode can be used. As described above, in the first embodiment, since the detection light is used as the synchronization light for establishing synchronization, the light receiving element 22 receives the synchronization light, and the synchronization in the scope of claims. Corresponds to the light receiving means.

  The amplifying unit 23 is an amplifying unit that amplifies the output from the light receiving element 22. The amplifying unit 23 is turned on or off by a control signal from a synchronization establishing unit described later.

  The peak hold unit 24 receives the analog output amplified by the amplification unit 23, detects and holds the maximum value of the output voltage while receiving this output (peak hold), and according to the maximum value. Output an analog signal of the correct voltage.

  The A / D conversion unit 25 converts the analog output output from the peak hold unit 24 into a digital signal by a predetermined number of times at a predetermined A / D conversion interval.

  The storage unit 26 is a storage unit that stores information such as a program and various parameters necessary for performing the light receiving operation of the light receiving unit 20, for example, an EEPROM (Electronically Erasable and Programmable Read Only Memory) or a RAM (Random Access). Memory). Information stored in the storage unit 26 includes, for example, a threshold value used for smoke determination of the smoke determination unit 28b described later, a synchronization establishment flag referred to in a synchronization establishment unit described later, a light reception interval, a light reception time, a second Light reception time, synchronization correction interval, and the like.

  The synchronization instruction switch 27 is an instruction means for an operator to instruct the start of a synchronization establishment operation. Here, it is assumed that the synchronization instruction switch 27 is configured as a cover switch that is automatically pressed when a housing cover (not shown) provided in the housing of the light receiving unit 20 is closed.

  The light receiving control unit 28 is a processing unit that performs various processes in the light receiving unit 20, and includes, for example, an IC (Integrated Circuit) and a processing program that operates on the IC. Although details of the processing contents by the light reception control unit 28 will be described later, the light reception control unit 28 includes a reduced light amount calculation unit 28a, a smoke determination unit 28b, a synchronization establishment unit 28c, and a synchronization correction unit 28d in terms of functions. It is prepared for. The light reduction amount calculation unit 28 a calculates the light reduction amount of the detection light received by the light receiving element 22. The smoke determination unit 28b 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 28a, and the light reduction amount is stored in the storage unit 26. If the amount of light reduction exceeds the threshold, it is determined that smoke has been generated. The synchronization establishment unit 28c performs a predetermined process for establishing synchronization based on the detection light received by the light receiving element 22, and corresponds to the synchronization establishment processing means in the claims. The synchronization correction unit 28d corrects the synchronization timing when a predetermined correction interval elapses after synchronization is established, and corresponds to the synchronization correction processing means in the claims.

Next, a startup process for raising the sensor 1 to the monitoring state will be described. First, the startup process of the light transmission unit 10 will be described. FIG. 3 is a flowchart of start-up processing of the light transmitter 10. Personnel is turned at a constant process where the power of the light transmitting unit 10, the startup process is executed by the sending controller 14 of the light transmitting unit 10. In this start-up process, the light transmission control unit 14 calls the light transmission interval and the light transmission time from the storage unit 13, and controls the light source 12 based on the light transmission interval, whereby the detection light is transmitted to the predetermined light transmission interval. Each time, light is transmitted for a predetermined light transmission time (step SA-1). The specific contents of the light transmission interval and the light transmission time are arbitrary, but the light transmission interval is, for example, 1 to 10 seconds, and the light transmission time is 1 pulse. Thus, the start-up process of the light transmitting unit 10 is completed.

  Next, the startup process of the light receiving unit 20 will be described. FIG. 4 is a flowchart of start-up processing of the light receiving unit 20. When the operator turns on the light receiving unit 20 by a predetermined method, the light receiving control unit 28 of the light receiving unit 20 waits until the synchronization instruction switch 27 is pressed (step SB-1). For example, when the sensor 1 is initially installed, the worker turns on the light receiving unit 20 in a predetermined method and adjusts the optical axis of the detection light between the light transmitting unit 10 and the light receiving unit 20 by a predetermined method. Then, the housing cover of the light receiving unit 20 is closed. Then, by closing the housing cover in this way, the synchronization instruction switch 27 of the light receiving unit 20 is automatically pressed with this operation. When the power of the light receiving unit 20 that has already been installed is shut off, the worker restarts the light receiving unit 20 by turning on the power of the light receiving unit 20. In this case, since the optical axis adjustment has already been completed and the housing cover of the light receiving unit 20 has already been closed, the synchronization instruction switch 27 is always in the pressed state.

  When the synchronization instruction switch 27 is in the pressed state (step SB-1, Yes), the light reception control unit 28 determines whether or not the synchronization establishment flag is stored in the storage unit 26 (step SB-). 2). When the synchronization establishment flag is stored (step SB-2, 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 changing to the normal monitoring state using the synchronization condition stored in the storage unit 26. On the other hand, when the synchronization establishment flag is not stored (step SB-2, 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 SB-3). 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 startup process of the light receiving unit 20 is completed.

  Next, the synchronization establishment process of the light receiving unit 20 in step SB-3 will be described. FIG. 5 is a flowchart of the synchronization establishment process of the light receiving unit 20. This synchronization establishment process includes a synchronization timing specifying process (step SC-1) for specifying the synchronization timing and a light receiving time adjusting process (step SC) 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 SC-1 will be described. FIG. 6 is a flowchart showing the basic concept of the synchronization timing specifying process of the light receiving unit 20, and FIG. 7 is a timing chart showing the timing of the light transmitting operation of the light transmitting unit 10 and the light receiving operation of the light receiving unit 20 in the synchronization timing specifying process. As shown in FIG. 7, the light transmission control unit 14 of the light transmission unit 10 transmits detection light for a predetermined light transmission time every predetermined light transmission interval Te after the start-up process, as described above.

  On the other hand, as shown in FIGS. 6 and 7, the synchronization establishing unit 28c of the light receiving unit 20 performs a predetermined light receiving operation for receiving the detection light at a predetermined light receiving interval different from the light transmission interval (step SD-1). ). In this way, by performing a light reception operation at a light reception interval different from the light transmission interval, even when light transmission or light reception is performed intermittently, detection light is received at a timing corresponding to a common multiple of these light transmission intervals and light reception intervals. it can. In particular, in the first embodiment, the light reception interval is shorter than the light transmission interval (light reception interval <light transmission interval). For example, when the light transmission interval is 3 seconds, light is received at intervals of 1 to 2 seconds. This is due to the following reason. That is, in the first embodiment, since the light transmission interval is premised on maintaining the same interval even in the smoke monitoring state after synchronization is established, the light transmission interval needs to be an appropriate interval for smoke detection. There is. Here, it is preferable that the light transmission interval for performing smoke detection is set to be relatively long as long as smoke detection is not hindered in order to reduce power consumption in the light transmission unit 10. On the other hand, it is not preferable to perform light reception at a light reception interval longer than the light transmission interval because there is a high possibility that the time for establishing synchronization will be long. Therefore, in the first embodiment, the light transmission interval is set to a relatively long interval suitable for smoke detection, while the light receiving time is made shorter than the light transmission interval to speed up the establishment of synchronization.

  Further, the synchronization establishment unit 28c determines whether or not to receive detection light continuously for a predetermined light reception time in each light reception operation (step SD-2). That is, in each light receiving operation, the synchronization establishing unit 28c compares the output from the light receiving element 22 (actually, a converted value by the A / D converting unit 25 as described later) with a predetermined value, thereby detecting the detected light. The presence or absence of light reception is determined (step SD-3). For example, when the light transmission interval is 3 seconds, the light receiving operation is continuously performed for several hundred milliseconds in each light receiving operation. FIG. 7 shows an example in which light receiving operations N1 to N5 for five times are performed. If the synchronization establishing unit 28c determines that the detection light is received during any of the light receiving operations (step SD-3, Yes), a predetermined synchronization interval (in this case, the transmission is performed) The timing which arrives at the same optical interval is specified as the synchronization timing (step SD-4). For example, in FIG. 7, since the detection light can be received for the first time in the fifth light receiving operation N5, the synchronization timing is specified with reference to the time of light receiving in this light receiving operation N5. This completes the synchronization timing specifying process. These initial light reception intervals and light reception times can be stored in the storage unit 26 so that they can be referred to before shipment of the sensor 1 from the factory, or can be incorporated as internal parameters of the synchronization establishment processing program (this The same applies to the following second light reception time and other time data).

  Next, the basic concept of the light reception time adjustment process in step SC-2 in 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 20, and FIG. 9 is a timing chart showing the timing of the light transmitting operation of the light transmitting unit 10 and the light receiving operation of the light receiving unit 20 in the light receiving time adjusting process. As illustrated in FIG. 9, the synchronization establishing unit 28c sets a predetermined second light reception time shorter than the previous light reception time, with the continuous light reception time of the detection light centered on the synchronization timing specified in the synchronization timing specification processing. Change to time (step SE-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 28c stores the synchronization establishment flag in the storage unit 26 (step SE-2). This completes the light reception time adjustment process, and the synchronization establishment process ends.

  In the normal monitoring state thereafter, the detection light of the light transmitting unit 10 is received by performing detection light reception at the synchronization timing specified by the synchronization timing specification processing and only for the second light reception time changed by the light reception time adjustment processing. The light transmission timing and the light reception timing of the light receiving unit 20 can be synchronized. The synchronization establishment flag stored in the storage unit 26 is deleted when the light receiving unit 20 is powered off. Therefore, when the power is turned on again, as described in the startup process, the synchronization establishment process is automatically started on the condition that the synchronization instruction switch 27 is pressed.

  The effects of such synchronization establishment processing are as follows. That is, as one simple method for establishing synchronization by radio, detection light is transmitted from the light transmitting unit 10 at a predetermined light transmission interval, and the light receiving unit 20 continues for a longer time than this light transmission interval. It is conceivable to establish the synchronization timing with reference to the timing when the detection light is received. However, when light is continuously received for a long time as described above, power consumption of an amplifier or the like that amplifies the output from the light receiving element 22 in the light receiving unit 20 increases. In order to solve this problem, the power consumption of the light receiving unit 20 is reduced by intermittently receiving the light of the light receiving unit 20 at a light receiving interval shorter than the light transmission interval in the synchronization timing specifying process.

Further, in the case of intermittently receiving light in this way, the probability that the detection light can be received can be improved and the synchronization can be quickly established as the light receiving time in each light receiving operation is increased. However, if the length of the light receiving time is maintained as it is even after the synchronization is established, the time during which the detection light is not actually received becomes longer during each light receiving operation, and the power consumption of the light receiving unit 20 increases unnecessarily. To do. To eliminate this problem, in the light reception time adjustment process, the light reception time is set to a relatively long time until synchronization is established, and after synchronization is established, the time is as short as possible as long as the detection light can be received at the synchronization timing. By changing to (that is, the second light receiving time), the power consumption of the light receiving unit 20 is made efficient.

  Next, the synchronization establishment process of the light receiving unit 20 performed as described above will be described in more detail. First, details of the synchronization timing specifying process will be described. FIG. 10 is a flowchart showing in detail the synchronization timing specifying process, and FIG. 11 is a timing chart showing in detail the operation timing of each part of the light receiving unit 20 in the synchronization timing specifying process.

  The synchronization establishing unit 28c of the light receiving unit 20 turns on the amplification unit 23 and sets the amplification factor to the maximum (step SF-1), and then a predetermined time during which the amplification unit 23 is electrically stabilized (hereinafter referred to as the amplification unit). Wait for the stabilization time to elapse (step SF-2). Then, after the amplification unit stabilization time has elapsed, the synchronization establishment unit 28c starts peak hold of the output of the amplification unit 23 by the peak hold unit 24 (step SF-3), and the output of the peak hold unit 24 is electrically And wait for the elapse of a predetermined time (hereinafter referred to as peak hold unit stabilization time) to stabilize (step SF-4). Specific values of the amplification unit stabilization time and the peak hold unit stabilization time may vary depending on the specifications of the amplification unit 23 and the peak hold unit 24, but are stored in the storage unit 26 in advance, and the synchronization establishment unit 28c Refer as necessary.

Then, after the stabilization time of the peak hold unit 24 has elapsed, the synchronization establishing unit 28c causes the A / D conversion unit 25 to A / D convert the output from the peak hold unit 24 (step SF-5). The A / D conversion, intends a predetermined number of times the line at a predetermined A / D conversion interval. The synchronization establishment unit 28c turns on the amplification unit 23 continuously for the light receiving time Ton ( step SF-1 to step SF-6, Yes), then turns off the amplification unit 23 (step SF-7), and the A / D Whether there is one or more A / D conversion values greater than or equal to a predetermined value among the A / D conversion values acquired by the A / D conversion of the conversion unit 25 (whether there is an A / D conversion value greater than or equal to a predetermined value) No) is determined (step SF-8). As this predetermined value, for example, a minimum value that can be determined to have received the detection light transmitted from the light transmitting unit 10 is set.

  If it is determined that there is no A / D conversion value greater than or equal to the predetermined value (step SF-8, No), the synchronization establishing unit 28c cannot receive the detection light from the light transmitting unit 10 and establishes synchronization. It is determined that there is a possibility that some abnormal state to be prevented has occurred, and the number of synchronization establishment abnormalities (initial value = 0) stored in the storage unit is incremented by one (step SF-9). Then, the synchronization establishing unit 28c determines whether or not the number of synchronization establishment abnormalities is equal to or greater than a predetermined number (for example, 10 to 20 times) that can be determined that abnormality has occurred in synchronization establishment (step SF-10). If the number has not yet reached the predetermined number (step SF-10, No), the process returns to step SF-1 to repeat the light receiving operation in order to continue the synchronization establishment process. Thereafter, when the number of synchronization establishment abnormalities exceeds a predetermined number (step SF-10, Yes), it is determined that an abnormality has occurred in synchronization establishment, and a synchronization establishment abnormality signal is output to the receiver 5 ( Step SF-11), the synchronization establishment process is terminated. The receiver 5 that has received the synchronization establishment abnormality signal notifies the worker of this abnormality state by, for example, performing a display or audio output indicating that the synchronization establishment abnormality has occurred.

  As described above, the synchronization establishing unit 28c performs steps SF-1 to SF until it is determined that the A / D conversion value equal to or greater than a predetermined value is 1 or more, or until the number of synchronization establishment abnormalities is equal to or greater than the predetermined number. Repeat the process of -10. Each timing of the light receiving operation in the processes of steps SF-1 to SF-10 can be determined as follows. First, as shown in FIG. 11, the sum of the amplifying unit stabilization time and the peak hold unit stabilization time is the overlap time Tov, the time for performing the peak hold by the peak hold unit 24 is the peak hold time Tpc, and the A / D conversion unit 25 The A / D conversion interval is expressed as A / D conversion interval TAD, and the light receiving interval (the time from when the amplifying unit 23 is turned on to when the amplifying unit 23 is turned on next) is expressed as the light receiving interval Tn.

In the first embodiment, since the A / D conversion is performed eight times during each light receiving operation during the synchronization timing determination process, the overlap time Tov can be expressed as follows.
Overlap time Tov = light reception time Ton− (A / D conversion interval TAD × 8)

In the first embodiment, the light receiving time Ton is included twice in one light transmission interval, and the amplifying unit is equivalent to the overlap time Tov that arrives at the second light receiving time Ton. By speeding up the ON time of 23, the outputs from the amplifying unit 23 and the peak hold unit 24 are already stable when receiving the detection light. For this reason, the light receiving interval Tn can be expressed as follows.
Light reception interval Tn = light transmission interval + overlap time Tov− (2 × light reception time Ton)

When the processes of steps SF-1 to SF-10 are repeated at such timing, and it is determined in step SF-8 that there is one or more A / D conversion values greater than or equal to a predetermined value (step SF-8, Yes). ), The detection light may have been received during the light receiving operation. Therefore, in this case, the timing at which the A / D change value is obtained may be used as a reference for the synchronization timing. However, since noise light other than the detection light may have been received, it is determined here whether or not the detection light is received at the same timing in the next light reception operation, and the detection light is detected at the same timing. The timing at which the A / D change value is obtained is used as the reference for the synchronization timing only when the signal is received. Specifically, the synchronization establishment unit 28c counts the number of times that an A / D conversion value equal to or greater than a predetermined value is obtained. This determination of the number of times can be performed, for example, by storing the number of times that an A / D conversion value equal to or greater than a predetermined value is obtained in the storage unit 26. Then, the synchronization establishing unit 28c determines whether or not the number of times is the first time (step SF-12), and when it is the first time (when an A / D conversion value equal to or greater than a predetermined value is obtained for the first time). In step SF-12, Yes), in order to confirm again that the detection light has been received during the light receiving operation, the light receiving interval Tn is reset as follows (step SF-13), and then step SF-1 Return to and confirm light reception again.
Light reception interval Tn = light transmission interval−light reception time Ton
Thus, A / D conversion can be performed at the same timing as the previous light receiving operation in which the detection light is received.

  On the other hand, when the number of times that an A / D conversion value greater than or equal to a predetermined value is obtained is not the first time (when an A / D conversion value greater than or equal to a predetermined value can be obtained twice or more; step SF-12, No). Counts the number of A / D conversion values greater than or equal to a predetermined value and stores it in the storage unit, and whether or not this count number is the same as the count number stored in the storage unit in the previous step SF-8. Is determined (step SF-14).

  If the count number of A / D conversion values equal to or greater than the predetermined value is not the same as the previous count number (step SF-14, No), the synchronization establishing unit 28c determines that the detection light reception timing during the light reception operation is the same. In other words, it is determined that the synchronization has been normally performed, and it is determined that the synchronization has not been performed, and the process returns to step SF-1 to reestablish synchronization from the beginning.

  On the other hand, when the count number of the A / D conversion value equal to or greater than the predetermined value is the same as the previous count number (step SF-14, Yes; hereinafter, this count number is referred to as the coincidence count number), the synchronization timing specifying process is performed. Then, the process proceeds to the next light receiving time adjustment process.

  Next, details of the light reception time adjustment processing will be described. FIG. 12 is a flowchart showing in detail the light reception time adjustment process, and FIG. 13 is a timing chart showing in detail the operation timing of each part of the light receiving unit 20 in the light reception time adjustment process. In this light reception time adjustment process, the light reception time is adjusted using the coincidence count number of the synchronization timing specifying process of FIG. That is, based on this coincidence count number, it is possible to specify at which point in time during the light receiving operation in the synchronization timing specifying process, the light reception time is determined based on this point in time from the synchronization timing specifying process. Is adjusted to a short second light receiving time.

Specifically, the synchronization establishing unit 28c resets the light receiving interval Tn ′, the light receiving time Ton ′, and the peak hold time Tpc ′ in the subsequent light receiving operations based on the coincidence count as follows. (Step SG-1).
Light reception interval Tn ′ = light transmission interval− (Tov + Tx) −TAD × (match count number−1)
Light reception time Ton ′ = Tov + Tx + TAD + Tx
Peak hold time Tpc ′ = Ton′−amplifying unit stabilization time Here, Tx is a synchronization shift (hereinafter referred to as “transmission”) that may occur between the light transmitting unit 10 and the light receiving unit 20 until a period correction process described later is performed. , Out of sync) (hereinafter, out of sync expected time). The expected synchronization deviation time is set to be larger as the accuracy of the timer for measuring a predetermined light transmission interval in the light transmitting unit 10 or the light receiving unit 20 is lower or as the time until the period correction processing is performed is longer. Become.

  Among the above numerical values, the light receiving interval Tn 'is basically calculated by subtracting the overlap time Tov from the light transmission interval. Here, by further subtracting the expected synchronization deviation time, the amplification unit 23 is turned on ahead of this synchronization deviation time, and the detection light can be received even when the synchronization deviation occurs, so that the reliability of smoke detection is improved. Is raised. Furthermore, as the number of A / D conversion values greater than or equal to a predetermined value increases, detection light is detected at an early stage during the light receiving operation, so that the light reception timing is advanced by this count number according to the count number. The A / D conversion interval is subtracted by a certain number. Note that 1 is subtracted from the count number. When the count number is 1, the detection light is received at the end of the light receiving time Ton ′, and the A / D conversion interval TAD is subtracted. This is because it is not necessary to advance the timing for turning on the amplifier 23. The light receiving time Ton ′ is basically calculated by adding the overlap time Tov and the minimum time during which the detection light can be received (here, one A / D conversion interval TAD). . Here, by adding the estimated synchronization deviation time Tx twice, either when the synchronization deviation occurs and the detection light is received earlier, or when the synchronization deviation occurs and the detection light is delayed. However, the detection light can be received and the smoke detection reliability is improved. The peak hold time Tpc ′ is calculated by subtracting the amplification unit stabilization time from the light receiving time Ton ′.

  Next, the synchronization establishing unit 28c confirms whether or not the light receiving operation after resetting functions effectively. Specifically, it is determined whether or not an A / D conversion value greater than or equal to a predetermined value is obtained in the light receiving operation after resetting (step SG-2). Here, when an A / D conversion value equal to or greater than a predetermined value is not obtained (step SG-2, No), the process returns to step SF-1 of the synchronization timing specifying process of FIG. 10, and the synchronization establishment process is started from the beginning. Try again. On the other hand, when an A / D conversion value equal to or greater than a predetermined value is obtained (step SG-2, Yes), the light receiving operation after the resetting functioned effectively (at this timing, the synchronization with the light transmitting unit 10 is synchronized). And the synchronization establishment flag is stored in the storage unit 26 (step SG-3).

Thereafter, the synchronization establishing unit 28c calculates the light receiving interval Tn ″ as follows (step SG-4).
Tn ″ = light transmission interval−light reception time Ton ′
Then, the synchronization establishment unit 28c sets the amplification factor of the amplification unit 23 to a predetermined amplification factor during normal monitoring that is smaller than the maximum amplification factor (step SG-5), and ends the light reception time adjustment process. Thereafter, each time the light receiving interval Tn ″ arrives, the light receiving operation synchronized with the light transmitting unit 10 can be performed by turning on the amplifying unit 23 only during the light receiving time Ton ′.

  Next, the synchronization correction process will be described. FIG. 14 is a flowchart of the synchronization correction process, and FIG. 15 is a timing chart showing in detail the operation timing of each part of the light receiving unit 20 in the synchronization correction process. In this synchronization correction process, the synchronization correction unit 28d monitors whether a predetermined synchronization correction interval stored in advance in the storage unit 26 has elapsed (step SH-1). This synchronization correction interval is set so that the synchronization correction processing can be performed before the amount of synchronization deviation becomes such that proper reception of the detection light is prevented even when synchronization deviation occurs. . During this specific period, the clocking accuracy of a clock circuit (not shown) that measures the light transmission interval in the light transmitting unit 10 or the clocking accuracy of the clock circuit (not shown) that measures the light reception interval in the light receiving unit 20 is low. As it is, it is determined to be shorter, for example, 5 to 10 minutes.

  When this synchronization correction interval has elapsed (step SH-1, Yes), the synchronization correction unit 28d determines whether or not the sensor 1 is at a predetermined synchronization correction permission level (A / D value above a certain level). (Step SH-2) Only when it is in the normal monitoring state, the process proceeds to the next step SH-3, and when it is not in the normal monitoring state, it waits for the return to the normal monitoring state before the next step SH-3. Migrate to

  Here, in the case of not being in the normal monitoring state, the state in which smoke (fire) is detected by the sensor 1 or the state in which a failure has occurred in the smoke sensor 1 (for example, the light of the detection light) For example, the amount of detection light received decreases due to dust accumulation on the shaft, and the amount of decrease decreases to a predetermined amount or more). The reason why the synchronization correction is not performed in the fire state or the failure state is that the received light amount is attenuated due to the presence of smoke or dust in these states, and the synchronization correction process cannot be performed appropriately. Although specific determination of the presence or absence of such a fire state or a failure state is arbitrary, for example, the control unit of the light receiving unit 20 sets a predetermined flag in the storage unit 26 in the case of the fire state or the failure state. The synchronization correction unit 28d determines the presence or absence of this flag and determines whether there is a fire state or a failure state. In the case where the sensor 1 is provided with an automatic compensation function that automatically increments the received light amount in order to compensate for the decrease in the received light amount of the detection light due to dust accumulation or the like, this automatic compensation function is Since this does not hinder the synchronization correction process, the synchronization correction process is executed during the automatic compensation in the same manner as in the normal monitoring state. However, when the fire state or the failure state does not become an obstacle to the synchronization correction, the synchronization correction may be executed even during the fire state or the failure state.

  Thereafter, the synchronization correction unit 28d determines whether or not there is one or more A / D conversion values greater than or equal to a predetermined value among the A / D conversion values output from the A / D conversion unit 25 (step). SH-3). As the predetermined value at this time, a threshold value for reducing the amount of light received for determining the presence or absence of smoke (fire alarm determination threshold value) is used. If there is no A / D conversion value equal to or greater than the predetermined value (step SH-3, No), the synchronization correction unit 28d determines that the amount of synchronization deviation exceeds the allowable limit of synchronization correction. Thus, the number of times exceeding the allowable limit is counted and stored in the storage unit 26 (step SH-4). Then, the synchronization correction unit 28d compares this number with the predetermined number (step SH-5), and when it is not equal to or larger than the predetermined number (step SH-5, No), only a temporary failure has occurred. This correction process is terminated without performing correction, and the next correction process is awaited. On the other hand, when the number of times is equal to or greater than the predetermined number (step SH-5, Yes), the synchronization correction unit 28d determines that there is a high possibility that a more serious failure has occurred, and indicates that the correction failure has occurred. (Step SH-6). The light reception control unit 28 performs a predetermined process for notifying the user that a correction failure has occurred. For example, the light reception control unit 28 outputs a correction failure signal to the receiver 5, and the receiver 5 blinks a failure indicator lamp (not shown). Also, the synchronization correction unit 28d activates the synchronization establishment process in the synchronization establishment unit 28c in order to automatically resolve the failure by reestablishing synchronization, thereby starting the synchronization timing specifying process in FIG. .

On the other hand, in step SH-3, when there is one or more A / D conversion values greater than or equal to a predetermined value (step SH-3, Yes), the light reception time Tn ′ ″ is calculated using this count number. The synchronization is corrected by resetting as follows (step SH-7). This completes the synchronization correction process.
Light reception time Tn ′ ″ = (light transmission interval light reception interval Ton ′) − (estimated synchronization time Tx × (count number−number of A / D conversion values greater than or equal to a predetermined value counted at normal time))

  That is, the larger the number of A / D conversion values that are actually counted than the predetermined value compared to the number of A / D conversion values that are equal to or higher than the predetermined value (hereinafter referred to as the reference count number) that is normally counted, Since the synchronization deviation between the light and the light reception has occurred, the synchronization timing is corrected by subtracting the expected synchronization deviation time Tx by the number corresponding to the excess. For example, when the reference count number is 2, 2 is subtracted from the actual count number, and the expected synchronization deviation time Tx is subtracted by the number corresponding to the subtraction result. The reference count number can be arbitrarily set according to the normal synchronization timing. However, it is preferable to set the reference count number so that it can be corrected even if the actual synchronization timing is shifted to either the front or back side. . For example, when the reference count number is 1, when the actual count number becomes less than 1, the deviation amount can no longer be corrected. Therefore, the reference count number is preferably about 2-3.

  As described above, according to the first embodiment, the detection light can be transmitted from the light transmitting unit 10 and received by the light receiving unit 20 to establish synchronization. Therefore, the light transmitting unit 10 and the light receiving unit 20 are connected to the control line. It is no longer necessary to connect at 4 and transmit a synchronization signal, and the installation of the control line 4 can be omitted, so that the installation work of the sensor 1 can be facilitated and the installation cost can be reduced.

  Further, since the detection light is used as the synchronization light, it is not necessary to provide a component for transmitting and receiving the light dedicated to the synchronization, and the configuration of the sensor 1 can be simplified and the manufacturing cost thereof can be reduced.

  In addition, since the light reception interval is shorter than the light transmission interval, the light transmission interval is set to a relatively long interval suitable for smoke detection, while the light reception time is shorter than the light transmission interval to speed up the establishment of synchronization. be able to.

  In addition, since the detection light reception time is changed to the second light reception time after the synchronization timing is specified, the relatively long light reception time is used until the synchronization is established, and the synchronization is quickly established and the synchronization is established. Thereafter, the received light power can be reduced by using a relatively short light receiving time.

  In addition, since the presence or absence of synchronization light reception is determined after the amplifying unit stabilization time has elapsed, the presence or absence of synchronization light reception is not determined when the amplification unit 23 is unstable. The reliability of the synchronization establishment process can be improved.

  In the synchronization establishment process, the amplification unit 23 is set to the maximum amplification factor, and after the synchronization is established, the amplification unit 23 is reset to a predetermined amplification factor smaller than the maximum amplification factor. The light reception performance can be maximized to improve the possibility of establishing synchronization.

  In addition, since the synchronization timing is corrected by the synchronization correction unit 28d, the synchronization deviation is automatically eliminated, and the detection light can be received by the light receiving unit 20 at an appropriate timing. Can be improved.

  Also, in the synchronization correction process, if no sync light with a light receiving amount equal to or greater than a predetermined value is not received, the synchronization establishment process by the synchronization establishment unit 28c is automatically started, so that the synchronization deviation exceeds the correction limit. If there is a possibility of synchronization, the synchronization establishment can be automatically restarted from the beginning, and the synchronization timing can be corrected to an appropriate state even when the synchronization deviation is large. Alternatively, by notifying the user that a correction failure has occurred, it is possible to prompt the user to respond early.

  Also, in the synchronization correction process, when sync light having a received light amount equal to or greater than a predetermined value is received, the timing at which the sync light is received at a predetermined light transmission interval is set as the sync timing. Thus, the synchronization deviation is automatically eliminated, and the detection light can be received by the light receiving unit 20 at an appropriate timing.

[Embodiment 2]
Next, specific contents of the second embodiment will be described in detail. The second embodiment relates to a mode in which synchronization establishment processing is intermittently performed at a predetermined light receiving interval longer than the light transmission interval. However, unless otherwise specified, the configuration is the same as that of the first embodiment, and the same reference numerals as those used in the first embodiment are attached to the same components as those of the first embodiment as necessary. .

  FIG. 16 is a block diagram conceptually showing main electrical configurations of the light transmitter and the light receiver of the sensor according to the second embodiment. The sensor 6 includes a light transmitting unit 10 and a light receiving unit 30. The light receiving unit 30 receives the detection light and corresponds to the light receiving means in the claims. The light receiving unit 30 houses a light receiving element 22, an amplifying unit 23, a peak hold unit 24, an A / D conversion unit 25, a storage unit 26, a synchronization instruction switch 27, and a light reception control unit 31 inside the housing 21. Configured. The light reception control unit 31 is functionally conceptually configured to include a light reduction amount calculation unit 31a, a smoke determination unit 31b, a synchronization establishment unit 31c, and a synchronization correction unit 31d. The light reduction calculation unit 31a, the smoke determination unit 31b, and the synchronization correction unit 31d are configured similarly to the light reduction calculation unit 28a, the smoke determination unit 28b, and the synchronization correction unit 28d of the first embodiment, respectively. The synchronization establishment unit 31c performs a predetermined process for establishing synchronization based on the detection light received by the light receiving element 22, and corresponds to the synchronization establishment processing means in the claims.

  The synchronization establishment process by the synchronization establishment unit 31c is basically the same as the synchronization establishment process of the first embodiment, but the synchronization timing specifying process is intermittently performed at a predetermined light receiving interval longer than the light transmission interval. It is different. FIG. 17 is a timing chart showing the timing of the light transmitting operation of the light transmitting unit 10 and the light receiving operation of the light receiving unit 30 in the synchronization timing specifying process. The synchronization establishing unit 31c performs a light receiving operation for each predetermined light receiving interval Tn2 different from the light transmission interval Te. Here, the light reception interval Tn2 is longer than the light transmission interval Te (light reception interval Tn2> light transmission interval Te). For example, when the light transmission interval is 3 seconds, the light reception interval is 5 to 10 seconds. Perform the action. FIG. 17 shows three light receiving operations N1 to N3. Thus, even when the light reception interval is longer than the light transmission interval, the light transmission timing matches the light reception timing at the timing corresponding to the common multiple of the light transmission interval and the light reception interval. The detection light can be received by the light receiving unit 30 and the reference of the synchronization timing can be specified. That is, the light transmission time and the light reception time may be at least different from each other. Thereafter, the synchronization establishment can be established by performing the light receiving time adjustment process in the same manner as in the first embodiment using the synchronization timing specified in this way.

  As described above, according to the second embodiment, even when the light reception interval is longer than the light transmission interval, synchronization between the light transmitter 10 and the light receiver 30 can be established, and the same effect as in the first embodiment can be obtained. Can do.

  Although the embodiments of the present invention have been described above, the specific configuration and method of the present invention are arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. be able to. Hereinafter, such a modification will be described.

  In addition, the problems to be solved by the present invention and the effects of the invention are not limited to the above contents, and the present invention solves problems not described above or effects not described above. In some cases, only a part of the described problems can be solved, or only a part of the described effects can be achieved. For example, even if the laying of the control line for the light transmission unit cannot be completely omitted for some reason, it is possible to increase the possibility that the control line can be omitted by establishing wireless synchronization. The object of the present invention has been achieved.

  In addition, the present invention includes all sensors including components that perform wireless synchronization, and may include a sensor in which a light transmitting unit and a light receiving unit are connected to each other by wire. For example, a sensor having a wireless synchronization function using light as described above, and further, a light transmitting unit and a light receiving unit are connected to each other by a control line, and an electric signal is used via the control line. A sensor that establishes synchronization redundantly and a sensor that can omit the local power supply by supplying power to the light transmission unit via this control line also correspond to the sensor of the present invention. For example, when a redundant configuration of wireless synchronization and wired synchronization is employed, wireless synchronization may be performed only when wired synchronization cannot be established.

  The configurations shown in the embodiments can be combined with each other. For example, both the synchronization method of the first embodiment and the synchronization method of the second embodiment can be executed, and either method is used as a situation. You may make it selectable according to it.

  In each embodiment, the example in which the detection light is used as the synchronization light has been described. However, the light source or the light transmission control unit 14 that transmits the light dedicated to the synchronization, the light receiving element 22 that receives the dedicated light, or the light reception control unit. May be provided. In this case, the light source for synchronization and the light transmission control unit 14 may be provided in the light receiving unit, and the light receiving element 22 for receiving the dedicated light and the light reception control means may be provided in the light transmission unit. In this case, since the light transmission interval and the light reception interval can be set without being limited by the light transmission interval of the detection light, the degree of freedom of the light transmission interval and the light reception interval is improved.

  In each embodiment, the light reception time set before the establishment of synchronization is reset to the second light reception time after the establishment of synchronization. However, if the need for power saving is low, the establishment of synchronization is established. You may continue to use a relatively long light reception time later, or if there is little need for quick synchronization establishment, only a relatively short second light reception time may be used before synchronization establishment.

  In each embodiment, it has been described that the synchronization correction process is performed when a predetermined synchronization correction interval elapses. However, another timing may be adopted as the timing for starting the synchronization correction process. For example, when the amount of received detection light is reduced, the cause may be the generation of smoke, accumulation of dust on the optical axis of the detection light, or contamination of optical elements such as lenses. However, in addition to this, there is a possibility that the entire amount of detection light cannot be received by the light receiving unit due to a slight synchronization shift. Therefore, when the amount of detection light received decreases by a predetermined amount or more, synchronization correction processing is performed first, and then only when the amount of detection light received is still reduced, it is determined that smoke is generated and the alarm signal May be output or compensation processing may be performed. Alternatively, the synchronization correction process may be activated based on a predetermined control signal from the receiver.

  In addition, the circuit examples, structure examples, parameters, various numerical values, and the like shown in the above document and drawings are merely examples, and can be arbitrarily changed unless otherwise specified. For example, a part of the circuit configuration may be replaced by a program, or all or part of the processing contents of the functions of the light transmission control unit 14 and the light reception control unit 28 may be achieved by hardware.

  As described above, the separation type sensor according to the present invention can be applied to synchronize the light transmitting unit and the light receiving unit which are separated from each other, and quickly establish this synchronization with power saving. Useful for.

(Appendix 1)
The separation type sensor according to appendix 1 receives a detection light transmitted by the light transmission means and a light transmission means for transmitting the detection light to the monitoring region, and receives the received detection light. And a light receiving means for determining the presence or absence of a predetermined monitoring target in the monitoring area based on a quantity, and a separate type sensor, wherein the light transmitting means and the light receiving means Either one of the light transmitting means and the light receiving means is provided with a synchronized light transmitting means for wirelessly transmitting a synchronizing light for mutual synchronization, and either the light transmitting means or the light receiving means is provided. On the other hand, a synchronizing light receiving means for receiving the synchronizing light transmitted from the synchronizing light transmitting means, and for establishing the synchronization based on the synchronizing light received by the synchronizing light receiving means A synchronization establishment processing means for performing a predetermined process is provided.

(Appendix 2)
The separation-type sensor according to attachment 2 is the separation-type sensor according to attachment 1, wherein the synchronization light transmission means is provided in the light transmission means, and the synchronization light reception means and the synchronization establishment processing means are provided in the separation detection sensor. Provided in a light receiving means, the synchronized light transmitting means transmits the detection light as the synchronized light, the synchronized light receiving means receives the detected light as the synchronized light, and the synchronization establishment processing means includes: A predetermined process for establishing synchronization is performed based on the detection light received by the synchronization light receiving means.

(Appendix 3)
The separation type sensor according to attachment 3 is the separation type sensor according to attachment 2, wherein the synchronous light transmission means intermittently transmits the detection light for a predetermined light transmission time every predetermined light transmission interval. The synchronization establishment processing means intermittently receives the detection light for a predetermined light reception time at a predetermined light reception interval different from the light transmission interval, and transmits the detection light during the light reception operation. Determining whether or not light is received and determining that the detection light has been received, specifying the timing at which the detection light is received at the predetermined light transmission interval with reference to the timing at which the detection light is received as a synchronization timing; Features.

(Appendix 4)
The separation type sensor according to attachment 4 is characterized in that, in the separation type sensor according to attachment 3, the light receiving interval is shorter than the light transmission interval.

(Appendix 5)
The separation type sensor according to attachment 5 is characterized in that, in the separation type sensor according to attachment 3, the light receiving interval is longer than the light transmission interval.

(Appendix 6)
The separation type sensor according to appendix 6, in the separation type sensor according to any one of appendices 3 to 5, wherein the synchronization establishment processing means specifies the synchronization timing and then receives the detection light. Is changed to a predetermined second light receiving time shorter than the light receiving time.

(Appendix 7)
The separate type sensor according to appendix 7, in the separate type sensor according to any one of appendices 1 to 6, wherein the other of the light transmitting means and the light receiving means has a received light amount of the synchronous light. And amplifying means for amplifying the output from the synchronizing light receiving means according to the condition, and the synchronization establishment processing means starts up the amplifying means and then elapses after a predetermined stabilization time for the output from the amplifying means to stabilize. The presence or absence of reception of the synchronization light is determined based on the output from the amplification means.

(Appendix 8)
The separate type sensor according to appendix 8, in the separate type sensor according to any one of appendices 1 to 7, wherein the other of the light transmitting means and the light receiving means has a received light amount of the synchronous light. Amplifying means for amplifying the output from the synchronizing light receiving means according to the above; the synchronization establishing processing means sets the amplifying means to a maximum amplification factor to determine whether or not the synchronizing light is received; and Then, the amplification means is reset to a predetermined amplification factor smaller than the maximum amplification factor.

(Appendix 9)
The separation type sensor according to attachment 9, wherein the separation type sensor according to any one of attachments 1 to 8, wherein the synchronization light receiving means receives the synchronization light after the synchronization establishment by the synchronization establishment processing means. A synchronization correction processing means for performing a predetermined process for correcting the synchronization timing based on the synchronization light is provided.

(Appendix 10)
The separation type sensor according to attachment 10 is the separation type sensor according to attachment 9, wherein the synchronization correction processing unit compares the received light amount of the synchronization light received by the synchronization light reception unit with a predetermined value. By determining whether or not the amount of received sync light of a predetermined value or more is received, if the number of times that the amount of received sync light of the predetermined value or more is not received is a predetermined number of times, The synchronization establishment processing by the synchronization establishment processing means is started, or predetermined processing for notifying that a correction failure has occurred is performed.

(Appendix 11)
The separation type sensor according to attachment 11 is the separation type sensor according to attachment 9 or 10, wherein the synchronization correction processing means determines a light reception amount of the synchronization light received by the synchronization light reception means to a predetermined value. In contrast, when a sync light having a received light amount equal to or greater than a predetermined value is received, the timing at which the sync light is received with reference to the timing at which the sync light is received is set as the sync timing, It is characterized by.

  According to the present invention, synchronization light can be transmitted from either one of the light transmitting means and the light receiving means, and this can be received by either one of the light transmission means and the light receiving means. Thus, it is not necessary to connect and transmit a synchronization signal, and the installation of the control line can be omitted, so that the installation work of the separation type sensor becomes easy and the installation cost can be reduced.

DESCRIPTION OF SYMBOLS 1, 6, 100 Sensor 2 Power supply line 3 Local power supply 4, 103, 105 Control line 5, 104 Receiver 10, 10A-10C, 101A-101C Light transmission part 11 Case 12 Light source 13 Storage part 14 Light transmission control part 20, 20A to 20C, 30, 102A to 102C Light receiving unit 21 Housing 22 Light receiving element 23 Amplifying unit 24 A / D conversion unit 25 Peak hold unit 26 Storage unit 27 Synchronization instruction switch 28 Light receiving control unit 28a, 31a Light reduction calculation unit 28b, 31b Smoke determination unit 28c, 31c Synchronization establishment unit 28d, 31d Synchronization correction unit

Claims (1)

Light transmitting means for transmitting detection light to the monitoring area, and detection light transmitted by the light transmitting means, and a predetermined monitoring in the monitoring area based on the amount of received light of the detected light A light-receiving means for determining the presence or absence of an object is a separate type sensor configured to be arranged separately from each other,
One of the light transmitting means or the light receiving means is provided with a synchronized light transmitting means for wirelessly transmitting synchronous light for synchronizing the light transmitting means and the light receiving means,
The other of the light transmitting unit or the light receiving unit is instructed to start the synchronization establishing operation by being automatically pressed when a case cover provided on the light transmitting unit or the light receiving unit is closed. Receiving means, storage means for storing a synchronization establishment flag for specifying whether or not the synchronization is established, and synchronization light reception for receiving the synchronization light transmitted from the synchronization light transmission means And synchronization establishment processing means for performing processing for establishing the synchronization based on the synchronization light received by the synchronization light receiving means,
Since the casing cover is closed, the synchronization establishment processing means receives an instruction to start the synchronization establishment operation by the instruction means, and the synchronization establishment flag is stored in the storage means If not, perform processing to establish the synchronization;
Separate sensor.

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