JP2019028614A - Alarm system - Google Patents

Abstract

To generate an alarm of stable strength and cycle even in a case where a self-traveling cycle is made different from a synchronous signal cycle by a setting error in an alarm system capable of generating an alarm having a self-traveling cycle that is set from among multiple self-traveling cycles, and a strength that is set from among multiple strengths, and capable of generating an alarm that is forcibly set to a cycle of a synchronous signal from the outside.SOLUTION: In a case where setting of a light-emitting cycle is 1.0 Hz and setting of luminosity is Hi, an optical alarm control device supplies to an optical alarm device a synchronous pulse with setting information of Low time 30 msec. Upon detecting the synchronous pulse with setting information of Low time 30 msec, the optical alarm device forcibly emits light for a light-emitting time corresponding to luminosity that is set in the optical alarm device, and sets luminosity and a light-emitting cycle of the next light emission at values corresponding to the Low time 30 msec.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an alarm system.

  The alarm of the alarm system is generally performed by ringing a bell such as a buzzer. However, in recent years, there has also been proposed an optical alarm system for notifying the occurrence of a disaster such as a fire using a flashlight or the like having high visibility along with sound (for example, Patent Document 1). According to such a light warning system, since the occurrence of a disaster is notified not only by sound but also by strong light, for example, an effective warning can be given even to a hearing-impaired person. Hereinafter, such a light alarm is referred to as a light alarm in distinction from conventional display notifications such as LEDs and red lamps.

  The light alarm is performed by, for example, high-intensity white light (flash light) generated by pulse emission from a xenon lamp or the like. For this reason, compared with the conventional display notification, for example, a hearing-impaired person can recognize the occurrence of a disaster early and reliably.

  As such an optical alarm system, there is an optical alarm system provided with an optical alarm device 200 and an optical alarm control device 100 as shown in FIG. The light alarm control device 100 includes a light emission period setting unit 101. The light alarm device 200 includes a control unit 201, a charging unit 202, a light emitting unit 203, a light emission period setting unit 204, and a light intensity setting unit 205.

  The light emission cycle setting unit 101 of the light alarm control device 100 can set the cycle of the light emission synchronization signal to correspond to 1.0 Hz or 0.5 Hz. Here, 1.0 Hz correspondence and 0.5 Hz correspondence are 980 msec and 1975 msec, respectively. The light emission synchronization signal is a timing signal indicating a timing at which the light emitting unit 203 of the light alarm device 200 is forced to emit light (forced light emission).

  The light emission cycle setting unit 204 of the light alarm device 200 corresponds to the self-running light emission cycle of the light emission unit 203, that is, the light emission cycle when the light emission synchronization signal from the light alarm control device 100 is not detected, corresponding to 1.0 Hz or 0.5 Hz. Can be set. Here, the correspondences of 1.0 Hz and 0.5 Hz are 995 msec and 1990 msec, respectively.

  In this specification, for convenience, a cycle corresponding to 1.0 Hz and a cycle corresponding to 0.5 Hz are referred to as a cycle of 1.0 Hz and a cycle of 0.5 Hz, respectively. That is, 980 msec and 1975 msec are respectively referred to as 1.0 Hz and 0.5 Hz for the light alarm control device 100, and 995 msec and 1990 msec are respectively referred to as 1.0 Hz and 0.5 Hz for the light alarm device 200.

  The light intensity setting unit 205 of the light alarm device 200 can set the light intensity to Hi (high) or Low (low). Here, Hi and Low have a light emission time of 120 msec and 60 msec, respectively. That is, the luminous intensity is defined by the light emission time. Each of these setting sections is constituted by a dip switch, for example.

  When the light alarm control device 100 receives a fire detection signal from a fire detector (not shown), the light alarm control device 100 sets a predetermined cycle (1.0 Hz = 980 msec or 0.5 or 0.5 ms) set by the light emission cycle setting unit 101. (Hz = 1975 msec) is transmitted. Upon receiving the light emission synchronization signal, the light alarm device 200 discharges the charge accumulated in the charging unit 202 and causes the light emission unit 203 to emit light forcibly at the set cycle of the light emission synchronization signal.

  The light emission period and luminous intensity of the light alarm device 200 are as follows. That is, when a light emission synchronization signal is input from the light alarm control device 100, light is emitted at the light emission synchronization signal cycle and the light intensity set by the light intensity setting unit 205. When the light emission synchronization signal is temporarily interrupted, self-running light emission is performed with the light emission period set by the light emission period setting unit 204 and the light intensity set by the light intensity setting unit 205.

  FIG. 11 is a timing chart showing a first operation example of the conventional light alarm system. In this operation example, the setting cycle of the light alarm control device 100 is 0.5 Hz, the setting cycle of the light alarm device 200 is 0.5 Hz, the setting light intensity is Low (0.5 Hz / Low setting), and the light alarm device 200. This is for the case where the set period is 0.5z and the set luminous intensity is Hi (0.5Hz / Hi setting).

  In this case, in the light alarm device 200, the charging unit 202 starts charging based on the detection of the falling edge of the synchronization pulse having a low time of 30 msec (pulse width 30 msec) by the control unit 201, and the synchronization pulse of the next low time of 60 msec is detected. Based on the detection of the fall, the charging unit 202 is discharged, and the light emitting unit 203 is forced to emit light. At this time, when the set luminous intensity is low, the emission time is 60 msec, and when the set luminous intensity is Hi, the emission time is 120 msec.

  When the set emission time has elapsed, the charging unit 202 starts charging, and repeats the discharging operation based on the detection of the falling edge of the next synchronization pulse. That is, the light emitting unit 203 emits light intermittently for 60 msec or 120 msec corresponding to the set luminous intensity at a cycle of 1975 msec which is a set cycle of the light emission synchronization signal.

  Here, the sync pulse is detected by the following procedure. That is, as shown in the enlarged portion, after detecting the falling edge, sampling is performed five times at a 1 msec period, and when two or more low levels are detected, it is determined that the synchronization pulse is detected. Here, although the synchronization pulse of the first low time 30 msec is illustrated, the detection method of the subsequent synchronization pulse of the low time 60 msec is the same. Therefore, in actuality, the light emission start timing of the light emitting unit 203 of the light alarm device 200 is later than the timing of the fall of the synchronization pulse. However, for convenience, the light emission start timing is set to the fall of the synchronization pulse in FIG. The same applies to the other timing charts (FIGS. 3 to 9 and FIGS. 12 to 14).

  FIG. 12 is a timing chart showing a second operation example of the conventional light alarm system. In this operation example, the setting cycle of the light alarm control device 100 is 1.0 Hz (1.0 Hz setting), the setting cycle of the light alarm device 200 is 1.0 Hz, and the setting luminous intensity is Low (1.0 Hz / Low setting), and FIG. 6 is a timing chart when the light alarm device 200 has a set cycle of 1.0 Hz and a set light intensity of Hi (1.0 Hz · Hi setting). In these cases, the light emitting unit 203 emits light intermittently for 60 msec or 120 msec corresponding to the set luminous intensity at a cycle of 980 msec which is a setting cycle of the light emission synchronization signal.

JP 2011-198194 A

  However, in the conventional light alarm system, when the light emission cycle setting of the light alarm control device 100 is different from the light emission cycle setting of the light alarm device 200 (setting error), a stable light intensity or light emission cycle cannot be obtained. There is a problem.

  FIG. 13 is a timing chart when the setting cycle of the light alarm control device 100 is 1.0 Hz (1.0 Hz setting), the setting cycle of the light alarm device 200 is 0.5 Hz, and the setting light intensity is Hi (0.5 Hz / Hi setting). . In this case, the charging time of the charging unit 202 is insufficient. That is, when the setting cycle of the light alarm device 200 is 0.5 Hz and the setting luminous intensity is Hi, as shown in FIG. 11, the charging time corresponding to the setting cycle of 0.5 Hz is required, but about half that time. Therefore, the charge that can supply the required discharge current to the light emitting unit 203 is not charged to the charging unit 202 for 120 msec, which is the light emission time of the set luminous intensity Hi. For this reason, the light intensity is not stabilized within the light emission time of 120 msec and decreases.

  FIG. 14 is a timing chart when the setting cycle of the light alarm control device 100 is 0.5 Hz (0.5 Hz setting), the setting cycle of the light alarm device 200 is 1.0 Hz, and the setting light intensity is Low (1.0 Hz / Low setting). It is. In this case, the light emitting unit 203 performs self-running light emission at 980 msec which is the set cycle of the light emission cycle setting unit 204 between adjacent synchronization pulses having a cycle of 1975 msec. As a result, the light emission time intervals of the light emitting unit 203 are alternately 995 msec and 980 msec, and the light emission period is not stable.

  The present invention has been made to solve such a problem, and an object thereof is to have an alarm control device and an alarm device, and the alarm control device is alternatively selected from a plurality of cycles. A synchronization signal having a set cycle can be output, and the alarm device is set alternatively from a plurality of self-running cycles and a plurality of strengths. In an alarm system capable of generating an alarm forcibly set to the period of the synchronization signal based on the generation of an alarm having a strength and the detection of the synchronization signal, the period of the synchronization signal and the period set independently Is to generate a stable intensity and periodic alarm even when the difference between the two is caused by a setting error.

  The present invention includes an alarm control device and an alarm device, and the alarm control device can output a synchronization signal having a cycle set alternatively from a plurality of cycles, and the alarm device includes a plurality of alarm devices. Based on the occurrence of an alarm having a self-running cycle set alternatively from among the cycles and an intensity set alternatively from a plurality of intensities, and detection of the sync signal, An alarm system that can forcibly set an alarm, wherein the synchronization signal has a cycle and a plurality of intensities set alternatively from a plurality of cycles on the alarm control device side. The alarm device forcibly sets the alarm period and intensity to the period and intensity corresponding to the pulse width based on the detection of the pulse width. An alarm system having means for automatically setting.

  According to the present invention, it has an alarm control device and an alarm device, and the alarm control device can output a synchronization signal having a cycle set alternatively from a plurality of cycles, , Based on the occurrence of an alarm having a self-running cycle set alternatively from a plurality of free-running cycles and a strength set alternatively from a plurality of intensities, and detection of the synchronization signal, In an alarm system capable of generating an alarm compulsorily set to the period of the synchronization signal, even if the period of the synchronization signal and the period set uniquely differ due to a setting error, a stable intensity and period alarm Can be generated.

It is a block diagram which shows the structure of the light alarm system which concerns on embodiment of this invention. It is a flowchart which shows the light emission synchronous signal setting process of the light alarm control apparatus which concerns on embodiment of this invention. It is a timing chart which shows the light emission synchronizing signal output from the light alarm control apparatus which concerns on embodiment of this invention. It is a timing chart which shows the 1st operation example of the optical alarm system which concerns on embodiment of this invention. It is a timing chart which shows the 2nd operation example of the optical alarm system which concerns on embodiment of this invention. It is a timing chart which shows the 3rd operation example of the light alarm system concerning the embodiment of the present invention. It is a timing chart which shows the 4th example of operation of the light alarm system concerning the embodiment of the present invention. It is a timing chart which shows the 5th operation example of the optical alarm system which concerns on embodiment of this invention. It is a timing chart which shows the 6th operation example of the optical alarm system which concerns on embodiment of this invention. It is a block diagram of the structure of the conventional light alarm system. It is a timing chart which shows the 1st operation example of the conventional optical alarm system. It is a timing chart which shows the 2nd operation example of the conventional optical warning system. It is a timing chart which shows the 1st problem of the conventional optical warning system. It is a timing chart which shows the 2nd problem of the conventional light alarm system.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
<Configuration of light alarm system>
FIG. 1 is a block diagram showing a configuration of a light alarm system according to an embodiment of the present invention. This light warning system includes a light warning control device 10 and a light warning device 20.

  The light alarm control device 10 includes a control unit 11, a fire detection signal receiving unit 12, a light emission synchronization signal output unit 13, a light emission period setting unit 14, and a light intensity setting unit 15.

  The control part 11 consists of microcontrollers provided with CPU, memory, various input / output ports etc., for example, and controls this light alarm control apparatus 10 whole. The fire detection signal receiving unit 12 receives a fire detection signal from a fire detector (not shown) and notifies the control unit 11 of the fire detection signal. The light emission synchronization signal output unit 13 generates a light emission synchronization signal based on the control of the control unit 11 and supplies it to the light alarm device 20.

  The light emission cycle setting unit 14 can set the cycle of the light emission synchronization signal to 1.0 Hz or 0.5 Hz. Here, 1.0 Hz and 0.5 Hz are 980 msec and 1975 msec, respectively. The luminous intensity setting unit 15 can set the luminous intensity to Hi or Low. Here, Hi and Low have a light emission time of 120 msec and 60 msec, respectively. Each of these setting sections is constituted by a dip switch, for example. That is, two types of light emission periods can be set by the light emission period setting unit 14, and two types of light intensity can be set by the light intensity setting unit 15, and a total of 4 (2 × 2) types of combinations thereof can be set. It is.

  The light emission synchronization signal output unit 13 generates and outputs a light emission synchronization signal having a cycle and a low time (pulse width) of the synchronization pulse as shown in Table 1 below for these four types of settings. Here, the synchronization pulse is a synchronization pulse with setting information described later with reference to FIG.

  The light alarm device 20 includes a control unit 21, first to fourth current control units 22 to 25, a changeover switch 26, a charging unit 27, a light emitting unit 28 as an alarm generating unit, a light emission cycle setting unit 29, and a first luminous intensity. A setting unit 30, a second luminous intensity setting unit 31, a changeover switch 32, a light emission current adjustment unit (Hi) 33, and a light emission current adjustment unit (Low) 34 are provided.

  The control unit 21 includes a microcontroller including a CPU, a memory, various input / output ports, and the like, and controls the entire light alarm device 20. The first current control unit 22, the second current control unit 23, the third current control unit 24, and the fourth current control unit 25 receive the emission synchronization signal, and the detection result of the low time of the synchronization pulse is displayed. Based on this, it is configured such that currents corresponding to the four settings shown in Table 1 can be supplied to the charging unit 27 via the changeover switch 26. That is, for example, the first current control unit 22 has a capability of supplying the charging unit 27 with charges necessary for stable light emission of Hi setting within a setting period (980 msec) of 1.0 Hz (for details, see FIG. 4-9, described below with reference to Tables 2 and 3).

  The changeover switch 26 is switched by the control unit 21 based on the detection result of the synchronization pulse low time by the control unit 21, and the first to fourth current control units corresponding to the synchronization pulse low time shown in Table 1 are displayed. Select 22 to 25 outputs.

  The charging unit 27 charges the built-in capacitor with the current from the first to fourth current control units 22 to 25 supplied through the changeover switch 26. The light emitting unit 28 incorporates an LED as a light emitting element and a switching regulator, and the control unit 21 controls the switching regulator based on the detection result of the low time of the synchronization pulse, so that the capacitor of the charging unit 27 Current flows through the light emitting element, so that light is emitted at the light intensity (Hi or Low) in the setting content corresponding to the low time of the synchronization pulse shown in Table 1 (for details, see FIGS. 4 to 9, Tables 2 and 3). To be described later).

  The light emission cycle setting unit 29 can set the light emission cycle of the self-running light emission of the light emitting unit 28 to 1.0 Hz or 0.5 Hz. Here, 1.0 Hz and 0.5 Hz are 995 msec and 1990 msec, respectively. The first luminous intensity setting unit 30 can set the light emission time of the light emitting unit 28 to Hi or Low. Here, Hi and Low are, for example, 120 msec and 60 msec, respectively. Further, the second luminous intensity setting unit 31 can set the light emission current, that is, the current flowing through the LED that is the light emitting element of the light emitting unit 28 to Hi or Low. Here, Hi and Low are, for example, 50 mA and 30 mA, respectively. That is, in the light alarm device 20, the light intensity of the light emitting unit 28 is defined by the light emission time of the light emitting unit 28 (light emitting element driving time) or the light emitting current (light emitting element driving current). Each of these setting sections is constituted by a dip switch, for example.

  Here, the reason why 1.0 Hz and 0.5 Hz of the light emission synchronization signal in the light alarm control device 10 are set to 980 msec and 1975 msec, respectively, and 1.0 Hz and 0.5 Hz of the self-running light emission period in the light alarm device 20 is set to 995 msec and 1990 msec, respectively. To do.

  First, the reason for the self-running light emission is that the flashing cycle must be 0.5Hz or more and 2Hz or less in the “Quality Evaluation Regulations for Light Alarm Devices and Light Alarm Control Devices” of the Fire Fighting Certification Association. This is because it is necessary to emit light within 0.5 Hz to 2 Hz even when there is no input to the synchronization signal.

The reason why the self-running light emission period is made slightly longer than the light emission synchronization signal period is that if they are the same, the operation becomes unstable due to variations in products. That is, for example, when the self-running light emission period and the light emission synchronization signal period of 1.0 Hz are designed at 980 msec ± 2 msec, the following operations I) to III) occur.
I) When the light emission synchronization signal cycle is 978 msec and the free-running light emission cycle is 982 msec, the operation is the same as in this embodiment.
II) When the light emission synchronization signal period is 982 msec and the self-running light emission period is 978 msec, the light emission synchronization signal arrives so that the light alarm device further emits light during the self-running light emission, so the light emission time is extended by 4 msec.
III) When the light emission synchronization signal period is 980 msec and the self-running light emission period is 980 msec, it is unclear whether the control unit (CPU) selects self-running light emission or light emission based on the light emission synchronization signal.

  The changeover switch 32 alternatively connects the light emission current adjustment unit (Hi) 33 and the light emission current adjustment unit (Low) 34 to the output side of the light emission unit 28 based on the control of the control unit 21. The light emission current adjusting unit (Hi) 33 is a member for adjusting the light emission current to, for example, 50 mA, and is configured by, for example, a 5Ω resistance element. The light emission current adjustment unit (Low) is a member for adjusting the light emission current to, for example, 30 mA, and is configured by a 10Ω resistance element, for example.

<Flash sync signal setting processing>
FIG. 2 is a flowchart showing the light emission synchronization signal setting process of the light alarm control device 10. This process is executed by the control unit 11.

  First, the control unit 11 reads the setting of the light emission period and the setting of the luminous intensity (step S1). These settings are set in advance by the light emission period setting unit 14 and the luminous intensity setting unit 15 and stored in the memory in the control unit 11.

  Next, the control part 11 determines the setting of the light emission period and the setting of the luminous intensity (step S2). Then, depending on the determination result, the following steps S3 to S6 are executed alternatively. In other words, in the case of 1.0 Hz / Hi setting, the cycle is set to 980 msec and the low time is set to 30 msec (step S3), and in the case of 1.0 Hz / low setting, the cycle is set to 980 msec and the low time is set to 40 msec (step S4). In the case of setting, the cycle is set to 1975 msec and the low time is set to 50 msec (step S5), and in the case of 0.5 Hz / Low setting, the cycle is set to 1975 msec and the low time is set to 60 msec (step S6). These settings are executed with reference to the table in Table 1 stored in the memory in the control unit 11.

<Timing chart of emission sync signal>
FIG. 3 is a timing chart showing a light emission synchronization signal output from the light alarm control device 10. Here, FIGS. 3A, 3B, 3C, and 3D respectively show the emission synchronization signals generated by the settings of steps S3, S4, S5, and S6 in FIG.

  3A, 3B, 3D, and 3D, the first pulse having a Hi time of 150 msec is referred to as a start pulse, and the subsequent pulse having a low time of 30 msec is referred to as a start synchronization pulse. In addition, after the start synchronization pulse, a pulse output in the period and low time set in steps S3, S4, S5, and S6 is called a synchronization pulse with setting information.

  The synchronization pulse with setting information is based on the low time (pulse width), the selection of the first to fourth current control units 22 to 25 in the light alarm device 20, the light emission period, the light emission time, and the light emission current of the light emitting unit 28. Used for setting. As the setting operation, an operation mode in which the light emission time is variably set and the light emission current is fixed (hereinafter referred to as a light emission time control mode), and an operation mode in which the light emission current is variably set and the light emission time is fixed ( Hereinafter, the light emission time control mode and the light emission current control mode are selected by operating the first light intensity setting unit 30 and the second light intensity setting unit 31, for example.

  Table 2 below shows the relationship between the low time of the sync pulse with setting information in the light emission time control mode, the current control unit selected by the changeover switch 26, the light emission period of the light emission unit 28, the light emission time, and the light emission current. Show.

  That is, when the light emission time control mode is selected, the control unit 21 sets the light emission current of the light emitting unit 28 to 30 mA, and thereafter fixes it to 30 mA until the mode is canceled. For this reason, the light emission current of the light emitting unit 28 is fixed to 30 mA regardless of the low time of the synchronization pulse with setting information. And the control part 21 performs the selection of a current control part, the setting of the light emission period of the light emission part 28, and light emission time as follows (i) thru | or (iv).

(i) When a synchronization pulse with setting information at a low time of 30 msec is detected, the first current control unit 22 is selected, the light emission period of the light emitting unit 28 is set to 980 msec, and the light emission time is set to 120 msec.
(ii) When a synchronization pulse with setting information with a low time of 40 msec is detected, the second current control unit 23 is selected, and the light emission periphery of the light emitting unit 28 is set to 980 msec and the light emission time is set to 60 msec.
(iii) When a synchronization pulse with setting information at a low time of 50 msec is detected, the third current control unit 24 is selected, the light emission period of the light emitting unit 28 is set to 1975 msec, and the light emission time is set to 120 msec.
(iv) When a synchronization pulse with setting information with a low time of 60 msec is detected, the fourth current control unit 25 is selected, the light emission period of the light emitting unit 28 is set to 1975 msec, and the light emission time is set to 60 msec.
These settings are used at the next light emission. Details will be described later with reference to timing charts (FIGS. 4 to 7).

  Table 3 below shows the relationship between the low time of the synchronization pulse with setting information in the light emission current control mode, the current control unit selected by the changeover switch 26, the light emission period of the light emission unit 28, the light emission current, and the light emission time. Show.

  That is, when the light emission current control mode is selected, the control unit 21 sets the light emission time of the light emitting unit 28 to 60 msec, and thereafter fixes it to 60 msec until the mode is canceled. For this reason, the light emission time of the light emitting unit 28 is fixed to 60 msec regardless of the low time of the synchronization pulse with setting information. And the control part 21 performs the selection of the current control part, the setting of the light emission period of the light emission part 28, and light emission time as follows (v) thru | or (viii).

(v) When a synchronization pulse with setting information for a low time of 30 msec is detected, the first current control unit 22 is selected, the light emission period of the light emitting unit 28 is set to 980 msec, and the light emission current is set to 50 mA.
(vi) When a synchronization pulse with setting information at a low time of 40 msec is detected, the second current control unit 23 is selected, the light emitting portion 28 emits light around 980 msec, and the light emission current is set to 30 mA.
(vii) When a synchronization pulse with setting information at a low time of 50 msec is detected, the third current control unit 24 is selected, the light emission period of the light emitting unit 28 is set to 1975 msec, and the light emission current is set to 50 mA.
(viii) When a synchronization pulse with setting information with a low time of 60 msec is detected, the fourth current control unit 25 is selected, the light emission period of the light emitting unit 28 is 1975 msec, and the light emission current is 30 mA.
These settings are used at the next light emission. Details will be described later with reference to timing charts (FIGS. 8 and 9).

Next, spontaneous light emission that is light emission when the synchronization pulse with setting information is not input to the control unit 21 will be described in the order of the light emission time control mode and the light emission current control mode.
Table 4 below shows the setting contents of the light emission cycle setting unit 29 and the light intensity setting unit 30 in the light emission time control mode, the current control unit selected by the changeover switch 26, the light emission cycle of the light emission unit 28, the light emission time, and the light emission. The relationship with current is shown.

  When the light emission time control mode is selected, the control unit 21 sets the light emission current of the light emitting unit 28 to 30 mA, and thereafter fixes it to 30 mA until the mode is canceled. For this reason, the light emission current of the light emitting unit 28 is fixed to 30 mA regardless of the setting content of the second light intensity setting unit 31. And the control part 21 reads the setting of a light emission period and the setting of a luminous intensity, when the synchronous pulse with setting information is not input into the control part 21. FIG. These settings are set in advance by the light emission period setting unit 29 and the first luminous intensity setting unit 30 and stored in the memory in the control unit 21.

Next, the control unit 21 determines the setting of the light emission period and the setting of the luminous intensity. Then, the following (a) to (d) are executed according to the determination result.
(a) In the case of 1.0 Hz · Hi setting, the first current control unit 22 is selected, and the light emission period and light emission time of the light emitting unit 28 are set to 995 msec and 120 msec, respectively.
(b) In the case of 1.0 Hz · Low setting, the second current control unit 23 is selected, and the light emission period and light emission time of the light emitting unit 28 are set to 995 msec and 60 msec, respectively.
(c) In the case of 0.5 Hz · Hi setting, the third current control unit 24 is selected, and the light emission period and light emission time of the light emitting unit 28 are set to 1990 msec and 120 msec, respectively.
(d) In the case of 0.5 Hz · Low setting, the fourth current control unit 25 is selected, and the light emission period and light emission time of the light emitting unit 28 are set to 1990 msec and 60 msec, respectively.

  Table 5 below shows the setting contents of the light emission cycle setting unit 29 and the light intensity setting unit 30 in the light emission current control mode, the current control unit selected by the changeover switch 26, the light emission cycle of the light emission unit 28, the light emission current, and the light emission. Shows the relationship with time.

  When the light emission current control mode is selected, the control unit 21 sets the light emission time of the light emission unit 28 to 60 msec, and thereafter fixes it to 60 msec until the mode is canceled. For this reason, the light emission time of the light emitting unit 28 is fixed to 60 msec regardless of the setting contents of the first light intensity setting unit 30. And the control part 21 reads the setting of a light emission period and the setting of a luminous intensity, when the synchronous pulse with setting information is not input into the control part 21. FIG. These settings are set in advance by the light emission period setting unit 29 and the second luminous intensity setting unit 31 and stored in the memory in the control unit 21.

Next, the control unit 21 determines the setting of the light emission period and the setting of the luminous intensity. Then, the following (e) to (h) are executed according to the determination result.
(e) In the case of 1.0 Hz · Hi setting, the first current control unit 22 is selected, and the light emission period and light emission current of the light emitting unit 28 are set to 995 msec and 50 mA, respectively.
(f) In the case of 1.0 Hz · Low setting, the second current control unit 23 is selected, and the light emission period and light emission current of the light emitting unit 28 are set to 995 msec and 30 mA, respectively.
(g) In the case of 0.5 Hz · Hi setting, the third current control unit 24 is selected, and the light emission period and light emission current of the light emitting unit 28 are set to 1990 msec and 50 mA, respectively.
(h) In the case of 0.5 Hz · Low setting, the fourth current control unit 25 is selected, and the light emission period and light emission current of the light emitting unit 28 are set to 1990 msec and 30 mA, respectively.

  Hereinafter, first to sixth operation examples of the light alarm system will be described in order. Here, the first to fourth operation examples relate to the light emission time control mode, and the fifth and sixth operation examples relate to the light emission current control mode. Therefore, in the first to fourth operation examples, the light emission current is fixed at 30 mA, and in the fifth and sixth operation examples, the light emission time is fixed at 60 msec. Therefore, the description about the light emission current is omitted for the first to fourth operation examples. However, since the fifth and sixth operation examples are timing charts, the light emission time is described.

<First operation example of light alarm system>
FIG. 4 is a timing chart showing a first operation example of the light alarm system according to the embodiment of the present invention. In this operation example, when the set cycle of the light alarm control device 10 is 1.0 Hz and the set light intensity is Hi (1.0 Hz / Hi setting), the four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz · Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3A.

<When the light alarm device 20 is set to 1.0 Hz / Low>
First, when the control unit 21 detects a start synchronization pulse that falls at time t0, the control unit 21 sets the changeover switch 26 to select the second current control unit 23 based on the setting (1.0 Hz · Low) of the light alarm device 20. Control. Thereby, the second current control unit 23 supplies the charging current to the charging unit 27.

  Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 30 msec that falls at the time t1, the control unit 21 forcibly emits the light emission unit 28 for 60 msec from the falling (low setting time of the light alarm device 20). At the same time, the detection of a synchronization pulse with setting information for a low time of 30 msec determines the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. As described with reference to Table 2, here, the selection of the first current control unit 22 and the light emission time of 120 msec and the light emission period of 980 msec are determined. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission time of 60 msec, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, the current control unit is switched (second current control unit 23 → first current control unit 22), the light emission time is changed (60 msec → 120 msec), and the light emission cycle is changed. (995msec → 980msec).

  Next, when the control unit 21 detects the synchronization pulse with setting information at the low time 30 msec that falls at time t2, the control unit 21 causes the light emitting unit 28 to emit light synchronously with the synchronization pulse with setting information for 120 msec from the fall and at the low time By detecting the synchronization pulse with setting information of 30 msec, as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28, the selection of the first current control unit 22, the light emission time of 120 msec and 980 msec. Determine the light emission cycle. Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, and the current control unit is changed, the light emission time is changed, and the light emission cycle. No change is necessary and will not be done. Thereafter, the same operation is repeated each time the control unit 21 detects a synchronization pulse with setting information having a low time of 30 msec with a period of 980 msec.

  Here, the difference between synchronous light emission and forced light emission will be described. The synchronized light emission and the forced light emission are the same in that light is forcibly emitted in response to the detection of the falling edge of the synchronization pulse with setting information. The difference between the two is the light emission when the falling edge of the sync pulse with setting information is detected in a state where the light emission cycle and the light emission time are determined based on the low time of the sync pulse with setting information one cycle before. The latter is light emission when the falling edge of the synchronization pulse with setting information is detected in a state where the synchronization pulse with setting information is not input in advance and the self-running light emission is set.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
First, when the control unit 21 detects a start synchronization pulse that falls at time t0, the control unit 21 sets the changeover switch 26 so as to select the first current control unit 22 based on the setting (1.0 Hz · Hi) of the light alarm device 20. And charge current is supplied to the charging unit 27.

  Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 30 msec that falls at the time t1, the control unit 21 forcibly emits the light emitting unit 28 for 120 msec (Hi setting time of the light alarm device 20) from the fall. In addition, the detection of the synchronization pulse with the setting information of the low time 30 msec, the selection of the first current control unit 22 and 120 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. Determine the light emission time and the light emission period of 980 msec. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission time of 120 msec, and the light emission period of 995 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission time, and only change the light emission cycle (995 msec → 980 msec) at the timing when the light emission time of 120 msec ends. Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
First, when the control unit 21 detects a start synchronization pulse that falls at time t0, the control unit 21 sets the changeover switch 26 to select the fourth current control unit 25 based on the setting of the light alarm device 20 (0.5 Hz · Low). And charge current is supplied to the charging unit 27.

  Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 30 msec that falls at the time t1, the control unit 21 forcibly emits the light emission unit 28 for 60 msec from the falling (low setting time of the light alarm device 20). In addition, the detection of the synchronization pulse with the setting information of the low time 30 msec, the selection of the first current control unit 22 and 120 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. Determine the light emission time and the light emission period of 980 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission time of 60 msec, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, the current control unit is switched (fourth current control unit 25 → first current control unit 22), the light emission time is changed (60 msec → 120 msec), and the light emission cycle is changed. (1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
First, when the control unit 21 detects a start synchronization pulse that falls at time t0, the control unit 21 sets the changeover switch 26 so as to select the third current control unit 24 based on the setting (0.5 Hz · Hi) of the light alarm device 20. And charge current is supplied to the charging unit 27.

  Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 30 msec that falls at the time t1, the control unit 21 forcibly emits the light emitting unit 28 for 120 msec (Hi setting time of the light alarm device 20) from the fall. (This light emission is unstable due to lack of charging time), and the sync pulse with setting information of Low time 30 msec is detected, so that the current control unit to be selected next and the light emission time and light emission of the light emitting unit 28 As the period, the selection of the first current control unit 22 and the light emission time of 120 msec and the light emission period of 980 msec are determined. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission time of 120 msec, and the light emission period of 1990 msec are set. Therefore, it is not necessary to change the light emission time. At the timing when the light emission time of 120 msec ends, switching of the current control unit (third current control unit 24 → first current control unit 22) and change of the light emission cycle ( 1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<Second operation example of light alarm system>
FIG. 5 is a timing chart showing a second operation example of the light alarm system according to the embodiment of the present invention. In this operation example, four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz / 1.0 Hz) when the setting cycle of the light alarm control device 10 is 1.0 Hz and the light intensity setting is Low (1.0 Hz / Low setting). Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3B.

<When the light alarm device 20 is set to 1.0 Hz / Low>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 40 msec that falls at the time t1, the control unit 21 forcibly emits the light emitting unit 28 for 60 msec (the low setting time of the light alarm device 20) from the fall. In addition, the detection of the synchronization pulse with setting information at the low time of 40 msec, the second current control unit 23 is selected as the current control unit to be selected next and the light emission time and the light emission period of the light emission unit 28, and 60 msec. Determine the light emission time and the light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission time of 60 msec, and the light emission period of 995 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission time, and only change the light emission cycle (995 msec → 980 msec) at the timing when the light emission time of 60 msec ends.

  Next, when the control unit 21 detects the synchronization pulse with the setting information at the low time 40 msec that falls at the time t2, the control unit 21 causes the light emitting unit 28 to emit light synchronously for 60 msec from the falling and the synchronization with the setting information at the low time 40 msec. By detecting the pulse, the second current control unit 23 is selected, and the 60 msec light emission time and the 980 msec light emission cycle are determined as the light emission time and light emission cycle of the current control unit to be selected next and the light emission unit 28. . Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, switching the current control unit, changing the light emission time, and the light emission cycle. No change is necessary and will not be done. Thereafter, the same operation is repeated each time the control unit 21 detects a synchronization pulse with setting information having a low time of 40 msec with a period of 980 msec.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 40 msec that falls at the time t1, the control unit 21 forcibly emits the light emitting unit 28 for 120 msec (Hi setting time of the light alarm device 20) from the fall. In addition, the detection of the synchronization pulse with setting information at the low time of 40 msec, the second current control unit 23 is selected as the current control unit to be selected next and the light emission time and the light emission period of the light emission unit 28, and 60 msec. Determine the light emission time and the light emission period of 980 msec. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission time of 120 msec, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 120 msec ends, switching of the current control unit (first current control unit 22 → second current control unit 23), change of the light emission time (120msec → 60msec), and change of the light emission cycle (995msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 40 msec that falls at the time t1, the control unit 21 forcibly emits the light emitting unit 28 for 60 msec (the low setting time of the light alarm device 20) from the fall. In addition, the detection of the synchronization pulse with setting information at the low time of 40 msec, the second current control unit 23 is selected as the current control unit to be selected next and the light emission time and the light emission period of the light emission unit 28, and 60 msec. Determine the light emission time and the light emission period of 980 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission time of 60 msec, and the light emission period of 1990 msec are set. Therefore, it is not necessary to change the light emission time. At the timing when the light emission time of 60 msec ends, the current control unit is switched (fourth current control unit 25 → second current control unit 23) and the light emission cycle is changed ( 1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects the synchronization pulse with setting information for the low time 40 msec that falls at the time t1, the control unit 21 causes the light emitting unit 28 to emit light for 120 msec (Hi setting time of the light alarm device 20) from the fall. (This light emission is unstable due to lack of charging time), and at the same time, by detecting a synchronization pulse with setting information of Low time 40 msec, the current control unit to be selected next, and the light emission time and light emission period of the light emission unit 28 As a result, the selection of the second current control unit 23 and the light emission time of 60 msec and the light emission period of 980 msec are determined. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission time of 120 msec, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 120 msec ends, the current control unit is switched (third current control unit 24 → second current control unit 23), the light emission time is changed (120msec → 60msec), and the light emission cycle is changed. (1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<Third operation example of light alarm system>
FIG. 6 is a timing chart showing a third operation example of the light alarm system according to the embodiment of the present invention. In this operation example, the four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz / 1.0 Hz) when the setting cycle of the light alarm control device 10 is 0.5 Hz and the light intensity setting is Hi (0.5 Hz / Hi setting). Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3C.

<When the light alarm device 20 is set to 1.0 Hz / Low>
First, when the control unit 21 detects a start synchronization pulse that falls at time t10, the control unit 21 sets the changeover switch 26 to select the second current control unit 23 based on the setting (1.0 Hz · Low) of the light alarm device 20. And charge current is supplied to the charging unit 27.

  Next, the control unit 21 causes the light emitting unit 28 to self-run for 60 msec (low setting time of the light alarm device 20) after 995 msec (cycle of setting the 1.0 Hz of the light alarm device 20) from time t10. Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 50 msec that falls at time t11, the control unit 21 forcibly causes the light emitting unit 28 to emit light for 60 msec (low setting time of the light alarm device 20) from the fall. At the same time, the detection of the synchronization pulse with setting information for the low time 50 msec, the selection of the third current control unit 24 and 120 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. Determine the light emission time and the light emission period of 1975 msec. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission time of 60 msec, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, the current control unit is switched (second current control unit 23 → third current control unit 24), the light emission time is changed (60msec → 120msec), and the light emission cycle is changed. (995msec → 1975msec).

  Next, when the control unit 21 detects the synchronization pulse with setting information at the low time 50 msec that falls at time t12, the control unit 21 causes the light emitting unit 28 to emit light for 120 msec from the falling and also the synchronization pulse with setting information at the low time 50 msec. Is detected, the current controller to be selected next and the light emission time and light emission period of the light emission part 28 are selected as the third current control part 24 and the light emission time of 120 msec and the light emission period of 1975 msec are determined. Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, switching the current control unit, changing the light emission time, and the light emission cycle. No change is necessary and will not be done. Thereafter, the same operation is repeated every time a synchronization pulse with setting information with a low time of 50 msec in a 1975 msec cycle is detected.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
First, when the control unit 21 detects a start synchronization pulse that falls at time t10, the control unit 21 sets the changeover switch 26 to select the first current control unit 22 based on the setting (1.0 Hz · Hi) of the light alarm device 20. And charge current is supplied to the charging unit 27.

  Next, the control unit 21 causes the light emitting unit 28 to self-run for 120 msec (Hi setting time of the light alarm device 20) after 995 msec (period of setting the 1.0 Hz of the light alarm device 20) from time t10. Next, when the control unit 21 detects the synchronization pulse with setting information for the low time 50 msec that falls at time t11, the control unit 21 forcibly causes the light emitting unit 28 to emit light for 120 msec (Hi setting time of the light alarm device 20) from the fall. At the same time, the detection of the synchronization pulse with setting information for the low time 50 msec, the selection of the third current control unit 24 and 120 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. Determine the light emission time and the light emission period of 1975 msec. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission time of 120 msec, and the light emission period of 995 msec are set. Therefore, it is not necessary to change the light emission time, and at the timing when the light emission time of 120 msec ends, the current control unit is switched (first current control unit 22 → third current control unit 24) and the light emission cycle is changed ( 995msec → 1975msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
First, when the control unit 21 detects a start synchronization pulse that falls at time t10, the control unit 21 sets the changeover switch 26 to select the fourth current control unit 25 based on the setting of the light alarm device 20 (0.5 Hz · Low). And charge current is supplied to the charging unit 27.

  Next, when the control unit 21 detects a synchronization pulse with setting information for the low time 50 msec that falls at time t11, the control unit 21 forcibly emits the light emitting unit 28 for 60 msec from the falling (low setting time of the light alarm device 20). In addition, the detection of the synchronization pulse with setting information for the low time of 50 msec, the selection of the third current control unit 24 and 120 msec as the light emission time and light emission cycle of the current control unit to be selected next and the light emission unit 28 The light emission time and the light emission period of 1975 msec are determined. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission time of 60 msec, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, switching of the current control unit (fourth current control unit 25 → third current control unit 24), change of the light emission time (60msec → 120msec), and change of the light emission cycle ( 1990msec → 1975msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
First, when the control unit 21 detects a start synchronization pulse that falls at time t10, the control unit 21 sets the changeover switch 26 to select the third current control unit 24 based on the setting (0.5 Hz · Hi) of the light alarm device 20. And charge current is supplied to the charging unit 27.

  Next, when the control unit 21 detects the synchronization pulse with setting information for the low time 50 msec that falls at time t11, the control unit 21 causes the light emitting unit 28 to emit light for 120 msec (Hi time of the light alarm device 20) from the fall. The detection of the synchronization pulse with setting information for the low time 50 msec, the selection of the third current control unit 24 and the light emission of 120 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28. Determine the time and emission cycle of 1975 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission time of 120 msec, and the light emission period of 1990 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission time, and only change the light emission cycle (1990 msec → 1975 msec) at the timing when the light emission time of 120 msec ends. Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<Fourth operation example of light alarm system>
FIG. 7 is a timing chart showing a fourth operation example of the light alarm system according to the embodiment of the present invention. In this operation example, the four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz / 1.0 Hz) when the setting cycle of the light alarm control device 10 is 0.5 Hz and the setting light intensity is Low (0.5 Hz / Low setting). Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3D.

<When the light alarm device 20 is set to 1.0 Hz / Low>
The operation from time t10 to immediately before t11 is the same as the third operation example (FIG. 6).
Next, when the control unit 21 detects a synchronization pulse with setting information for the low time 60 msec that falls at time t11, the control unit 21 forcibly emits the light emitting unit 28 for 60 msec from the falling (low setting time of the light alarm device 20). In addition, the detection of the synchronization pulse with the setting information for the low time of 60 msec, the selection of the fourth current control unit 25 and 60 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28, and 60 msec. The light emission time and the light emission period of 1975 msec are determined. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission time of 60 msec, and the light emission period of 995 msec are set. Therefore, it is not necessary to change the light emission time, and at the timing when the light emission time of 60 msec ends, switching of the current amplification unit (second current control unit 23 → fourth current control unit 25) and change of the light emission cycle ( 995msec → 1975msec).

  Next, when the control unit 21 detects the synchronization pulse with the setting information for the low time 60 msec that falls at time t12, the control unit 21 causes the light emitting unit 28 to emit light for 60 msec from the falling and the synchronization pulse with the setting information for the low time 60 msec. As a result, the fourth current control unit 25 is selected, and the 60 msec light emission time and the 1975 msec light emission cycle are determined as the light emission time and light emission cycle of the current control unit to be selected next and the light emission unit 28. Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, switching the current control unit, changing the light emission time, and the light emission cycle. No change is necessary and will not be done. Thereafter, the same operation is repeated every time a synchronization pulse with setting information with a low time of 60 msec in a 1975 msec cycle is detected.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
The operation from time t10 to immediately before t11 is the same as the third operation example (FIG. 6).
Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 60 msec that falls at time t11, the control unit 21 forcibly emits the light emitting unit 28 for 120 msec (Hi setting time of the light alarm device 20) from the fall. In addition, the detection of the synchronization pulse with the setting information for the low time of 60 msec, the selection of the fourth current control unit 25 and 60 msec as the light emission time and light emission period of the current control unit to be selected next and the light emission unit 28, and 60 msec. The light emission time and the light emission period of 1975 msec are determined. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission time of 120 msec, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 120 msec ends, switching of the current control unit (first current control unit 22 → fourth current control unit 25), change of the light emission time (120msec → 60msec), and change of the light emission cycle ( 995msec → 1975msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
The operation from time t10 to immediately before t11 is the same as the third operation example (FIG. 6).
Next, when the control unit 21 detects a synchronization pulse with setting information for the low time 60 msec that falls at time t11, the control unit 21 forcibly emits the light emitting unit 28 for 60 msec from the falling (low setting time of the light alarm device 20). In addition, the detection of the synchronization pulse with setting information for the low time of 60 msec, the selection of the fourth current control unit 25 as the current control unit to be selected next and the 0 light emission time and the light emission period of the light emitting unit 28, and Determine the light emission time of 60 msec and the light emission period of 1975 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission time of 60 msec, and the light emission period of 1990 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission time, and only change the light emission cycle (1990 msec → 1975 msec) at the timing when the light emission time of 60 msec ends. Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
The operation from time t10 to immediately before t11 is the same as the third operation example (FIG. 6).
Next, when the control unit 21 detects the synchronization pulse with setting information for the low time 60 msec that falls at time t11, the control unit 21 causes the light emitting unit 28 to emit light for 120 msec (Hi setting time of the light alarm device 20) from the fall. At the same time, the detection of the synchronization pulse with setting information for the low time of 60 msec, the selection of the fourth current control unit 25 and the 60 msec of the current control unit to be selected next and the light emission time and light emission period of the light emission unit 28 are selected. Determine the light emission time and the light emission period of 1975 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission time of 120 msec, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 120 msec ends, switching of the current control unit (third current control unit 24 → fourth current control unit 25), change of the light emission time (120msec → 60msec), and change of the light emission cycle ( 1990msec → 1975msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<Fifth operation example of light alarm system>
FIG. 8 is a timing chart showing a fifth operation example of the light alarm system according to the embodiment of the present invention. In this operation example, when the set cycle of the light alarm control device 10 is 1.0 Hz and the set light intensity is Hi (1.0 Hz / Hi setting), the four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz · Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3A.

<When the light alarm device 20 is set to 1.0 Hz / Low>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects the synchronization pulse with the setting information of the low time 30 msec that falls at time t1, the control unit 21 causes the light emitting unit 28 to emit the light current 30 mA (light) for 60 msec (fixed time in the current control mode) from the fall. The forced light emission is performed at the low setting of the alarm device 20 and the sync pulse with setting information for the low time of 30 msec is detected, so that the light emission current of the current control unit to be selected next and the light emission unit 28 is determined. As described with reference to Table 3, the selection of the first current control unit 22 and the light emission current of 50 mA and the light emission period of 980 msec are determined here. Before these are determined, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission current of 30 mA, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, switching of the current control unit (second current control unit 23 → first current control unit 22), change of the light emission current (30 mA → 50 mA), and change of the light emission cycle (995msec → 980msec).

  Next, when the control unit 21 detects the synchronization pulse with the setting information at the low time 30 msec that falls at the time t2, the control unit 21 causes the light emitting unit 28 to emit light synchronously with the synchronization pulse with the setting information for 60 msec from the fall and at the low time By detecting a synchronization pulse with setting information of 30 msec, the current controller to be selected next, and the light emission current and light emission period of the light emission unit 28, the selection of the first current control unit 22, the light emission current of 50 mA and 980 msec Determine the light emission cycle. Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, and the current control unit, the light emission current, and the light emission cycle may be retained. No change is necessary and will not be done. Thereafter, the same operation is repeated each time the control unit 21 detects a synchronization pulse with setting information having a low time of 30 msec with a period of 980 msec.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects a synchronization pulse with setting information at a low time of 30 msec that falls at time t1, the control unit 21 causes the light emitting unit 28 to emit light with a light emission current of 50 mA (Hi setting of the light alarm device 20) for 60 msec. The forced light emission and the detection of the synchronization pulse with setting information for the low time 30 msec, the selection of the first current control unit 22 as the current control unit to be selected next, and the light emission current and light emission cycle of the light emission unit 28, And a light emission current of 50 mA and a light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission current of 50 mA, and the light emission period of 995 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission current, and only change the light emission cycle (995 msec → 980 msec) at the timing when the light emission time of 60 msec ends. Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects a synchronization pulse with setting information for a low time of 30 msec that falls at time t1, the control unit 21 causes the light emission unit 28 to emit light at a current of 30 mA (low setting of the light alarm device 20) for 60 msec from the fall. The forced light emission and the detection of the synchronization pulse with setting information for the low time 30 msec, the selection of the first current control unit 22 as the current control unit to be selected next, and the light emission current and light emission cycle of the light emission unit 28, And a light emission current of 50 mA and a light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission current of 30 mA, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, switching of the current control unit (fourth current control unit 25 → first current control unit 22), change of the light emission current (30mA → 50mA), and change of the light emission cycle (1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as the first operation example (FIG. 4).
Next, when the control unit 21 detects a synchronization pulse with setting information at a low time of 30 msec that falls at time t1, the control unit 21 causes the light emitting unit 28 to emit light with a light emission current of 50 mA (Hi setting of the light alarm device 20) for 60 msec. The forced light emission and the detection of the synchronization pulse with setting information for the low time 30 msec, the selection of the first current control unit 22 as the current control unit to be selected next, and the light emission current and light emission cycle of the light emission unit 28, And a light emission current of 50 mA and a light emission period of 980 msec. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission current of 50 mA, and the light emission period of 1990 msec are set. Therefore, it is not necessary to change the light emission current, and at the timing when the light emission time of 60 msec ends, the current control unit is switched (third current control unit 24 → first current control unit 22) and the light emission cycle is changed ( 1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<Sixth operation example of light alarm system>
FIG. 9 is a timing chart showing a sixth operation example of the light alarm system according to the embodiment of the present invention. In this operation example, four types of settings of the light alarm device 20 (1.0 Hz / Low setting, 1.0 Hz / 1.0 Hz) when the setting cycle of the light alarm control device 10 is 1.0 Hz and the light intensity setting is Low (1.0 Hz / Low setting). Hi setting, 0.5Hz / Low setting, 0.5Hz / Hi setting). Hereinafter, the operation in the case of the four types of settings of the light emission synchronization signal output from the light alarm control device 10 and the light alarm device 20 will be described in order.

<< Light emission synchronization signal output from the light alarm control device 10 >>
The light alarm control device 10 sends a light emission synchronization signal shown in FIG. 3B.

<When the light alarm device 20 is set to 1.0 Hz / Low>
The operation from time t0 to immediately before t1 is the same as in the second operation example (FIG. 5).
Next, when the control unit 21 detects a synchronization pulse with setting information for a low time of 40 msec that falls at time t1, the control unit 21 causes the light emission unit 28 to emit light at a current of 30 mA (low setting of the light alarm device 20) for 60 msec. The forced light emission and the detection of the synchronization pulse with setting information for the low time 40 msec, the second current control unit 23 is selected as the current control unit to be selected next, and the light emission current and the light emission period of the light emission unit 28. And a light emission current of 30 mA and a light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Low, so the selection of the second current control unit 23, the light emission current of 30 mA, and the light emission period of 995 msec are set. Therefore, it is not necessary to switch the current control unit and change the light emission current, and only change the light emission cycle (995 msec → 980 msec) at the timing when the light emission time of 60 msec ends.

  Next, when the control unit 21 detects the synchronization pulse with the setting information for the low time 40 msec that falls at time t2, the control unit 21 causes the light emitting unit 28 to emit light synchronously with a light emission current of 30 mA for 60 msec from the fall and the low time 40 msec. By detecting the synchronization pulse with setting information, the current controller to be selected next and the light emission current and light emission cycle of the light emission unit 28 are selected as the second current control unit 23, the light emission current of 30 mA and the light emission of 980 msec. Confirm the period. Since each of these determined information is the same as the previously determined information, the control unit 21 only needs to hold these information, switching the current control unit, changing the light emission current, and the light emission cycle. No change is necessary and will not be done. Thereafter, the same operation is repeated each time the control unit 21 detects a synchronization pulse with setting information having a low time of 40 msec with a period of 980 msec.

<When the light alarm device 20 is set to 1.0 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as in the second operation example (FIG. 5).
Next, when the control unit 21 detects a synchronization pulse with setting information at a low time of 40 msec that falls at time t1, the control unit 21 causes the light emitting unit 28 to emit light with a light emission current of 50 mA (Hi setting of the light alarm device 20) for 60 msec. The forced light emission and the detection of the synchronization pulse with setting information for the low time 40 msec, the second current control unit 23 is selected as the current control unit to be selected next, and the light emission current and the light emission period of the light emission unit 28. And a light emission current of 30 mA and a light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 1.0 Hz / Hi, so the selection of the first current control unit 22, the light emission current of 50 mA, and the light emission period of 995 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, switching of the current control unit (first current control unit 22 → second current control unit 23), change of the light emission current (50 mA → 30 mA), and change of the light emission cycle (995msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Low>
The operation from time t0 to immediately before t1 is the same as in the second operation example (FIG. 5).
Next, when the control unit 21 detects a synchronization pulse with setting information for a low time of 40 msec that falls at time t1, the control unit 21 causes the light emission unit 28 to emit light at a current of 30 mA (low setting of the light alarm device 20) for 60 msec. The forced light emission and the detection of the synchronization pulse with setting information for the low time 40 msec, the second current control unit 23 is selected as the current control unit to be selected next, and the light emission current and the light emission period of the light emission unit 28. And a light emission current of 30 mA and a light emission period of 980 msec. Before these are confirmed, the light alarm device 20 is set to 0.5 Hz / Low, so the selection of the fourth current control unit 25, the light emission current of 30 mA, and the light emission period of 1990 msec are set. Therefore, it is not necessary to change the light emission current. At the timing when the light emission time of 60 msec ends, the current control unit is switched (fourth current control unit 25 → second current control unit 23) and the light emission cycle is changed ( 1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

<When the light alarm device 20 is set to 0.5 Hz / Hi>
The operation from time t0 to immediately before t1 is the same as the second operation example (FIG. 5).
Next, when the control unit 21 detects a synchronization pulse with setting information at a low time of 40 msec that falls at time t1, the control unit 21 causes the light emitting unit 28 to emit light with a light emission current of 50 mA (Hi setting of the light alarm device 20) for 60 msec. Forced light emission (the light intensity of this light emission is not stable due to lack of charging time), and the detection of a synchronization pulse with setting information for a low time of 40 msec allows the current control unit to be selected next and the light emission current of the light emission unit 28 As the light emission period, the selection of the second current control unit 23 and the light emission current of 30 mA and the light emission period of 980 msec are determined. Before these are determined, the light alarm device 20 is set to 0.5 Hz / Hi, so the selection of the third current control unit 24, the light emission current of 50 mA, and the light emission period of 1990 msec are set. Therefore, at the timing when the light emission time of 60 msec ends, switching of the current control unit (third current control unit 24 → second current control unit 23), change of the light emission current (50 mA → 30 mA), and change of the light emission cycle (1990msec → 980msec). Subsequent operations are the same as in the case of 1.0 Hz / Low setting.

  In addition, although embodiment described above has both the 1st luminous intensity setting part 30 and the 2nd luminous intensity setting part 31 as a luminous intensity setting part, the structure which has any one is also possible. Further, although the embodiment of the present invention has been described by exemplifying the light alarm device in which the light emitting unit generates a light alarm, the present invention is similarly applied to the sound alarm device in which the sound generating unit generates a sound alarm. Can be applied.

DESCRIPTION OF SYMBOLS 10 ... Light alarm control apparatus, 20 ... Light alarm apparatus, 21 ... Control part, 22 ... 1st current control part, 23 ... 2nd current control part, 24 ... 3rd current control part, 25 ... 4th Current control unit 26, 32 ... changeover switch, 27 ... charging unit, 28 ... light emitting unit, 29 ... light emission cycle setting unit, 30 ... first light intensity setting unit, 31 ... second light intensity setting unit, 33 ... light emission current Adjustment unit (Hi), 34... Light emission current adjustment unit (Low).

Claims (4)

An alarm control device and an alarm device, wherein the alarm control device can output a synchronization signal having a cycle set alternatively from a plurality of cycles, and the alarm device is capable of outputting a plurality of cycles. Based on the generation of an alarm having a self-running cycle set alternatively from the above and a strength set alternatively from a plurality of intensities, and detection of the sync signal, and forcing the cycle of the sync signal An alarm system capable of generating a set alarm,
The synchronization signal has a pulse width corresponding to a cycle set alternatively from a plurality of cycles and a strength set alternatively from a plurality of strengths on the alarm control device side,
The alarm device has means for forcibly setting the alarm period and intensity to a period and intensity corresponding to the pulse width based on the detection of the pulse width. The alarm system according to claim 1,
The alarm system wherein the alarm is a light alarm and the intensity is a light intensity. The alarm system according to claim 1,
The setting means is an alarm system in which the intensity is set by setting a driving time or a driving current of an alarm generating unit. The alarm system according to claim 3,
The alarm device can output a current of a level corresponding to a combination of a charging unit, the alarm generating unit driven by a discharging current of the charging unit, and a plurality of cycles and a plurality of levels. A plurality of (multiple × multiple) current control units, a means for supplying the output of the current control unit corresponding to the period and intensity corresponding to the pulse width to the charging unit based on the detection of the pulse width, and the pulse And a means for driving the alarm generation unit with a driving time or a driving current having an intensity corresponding to the pulse width based on the detection of the width.

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