JP3067851B2 - Reflective infrared sensor and sensor system using the same - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflection type infrared sensor and a sensor system using the same.

[0002]

2. Description of the Related Art Conventionally, there has been known a shutter sensor system for monitoring the open / closed state of a shutter using a reflection type infrared sensor (hereinafter simply referred to as a sensor). FIG. 5 shows an example of the configuration. In FIG. 5A, the shutter 3 can be housed in the shutter housing 4, and the sensor 1 is attached to a predetermined position of the shutter housing 4 or in the vicinity of the shutter housing 4 and faces the sensor 1 of the shutter 3. A reflection sheet 2 is attached to the position. The sensor 1 includes a light emitting unit that emits infrared rays toward the shutter 3 and a light receiving unit that receives the reflected light. And shutter 3
When the shutter is closed, the infrared light from the light projecting section is reflected by the reflection sheet 2 and enters the light receiving section, so that the signal level detected by the light receiving section becomes high.
Is open, the infrared light from the light projecting unit is irradiated on the shutter 3, so that the reflected light incident on the light receiving unit becomes very small, and the detected signal level also becomes low. Whether the shutter 3 is closed or opened can be detected based on the difference in signal level.

When the sensor 1 detects that the shutter 3 has been opened, it outputs an alarm signal to the sorting display. As shown in FIG. 5B, the sorting indicator 5 is provided with a sorting indicator light 6 corresponding to the sensor one-to-one, and upon receiving an alarm signal from the sensor, the sorting indicator light 6 corresponding to the sensor is reset. Lighting is maintained until 7 is pressed. The reset switch 7 is pressed when changing from the state in which the alert is released to the state in which the alert is performed.
That is, since the shutter is frequently opened and closed at the time of work, it is usual that the warning is released at the time of work and the warning is performed only at the time of non-work, so that the receiver connected to the sorting indicator 5 is used. 8 or the remote controller 9 is provided with appropriate means such as a switch for performing a warning / release operation. However, the sorting indicator lamp 6 of the sorting indicator 5 is always lit when the sensor 1 issues a warning. Therefore, even if the alert is issued by the sensor even in a state in which the alert is released, the sorting indicator corresponding to the sensor is turned on. Therefore, when shifting from the alert release state to the alert state, it is necessary to temporarily turn off all the indicator lights 6. This is performed by the reset switch 7. After the reset switch 7 is pressed to turn off all the sorting indicator lights 6, only the sorting indicator lights corresponding to the location where the intrusion has occurred are turned on.

[0004]

By the way, it is necessary to lay a power supply line and a signal line for transmitting an alarm signal between each sensor and the segmented display. When constructing a shutter sensor system for monitoring the condition, not only is the work of laying these power supply lines and signal lines extremely troublesome, but also the lengths of the power supply lines and signal lines to be used become very long. As a result, the cost was also high.

On the other hand, it is conceivable to connect a plurality of sensors 1 to one circuit system as shown in FIG. That is, in FIG. 6, the sensor 1 is provided in the first circuit system.
_{11, 1 12, ..., 1} 1 (n-1), 1 1n are n sensors of connection, also to the second circuit system sensors 1 _21, 1 _22, ..., 1
_M sensors of _{2 (m-1)} and _12m are connected. According to such a configuration, the length of the power supply line and the signal line can be minimized, and the work of laying the power supply line and the signal line can be reduced. Note that the receiver and the remote controller are omitted in FIG. However, in this case, since only one section indicator light 6 of the section indicator 5 is provided for one circuit system, the section indicator lamp 6 is in the alert state.
When is turned on, it is known that the shutter in the circuit system corresponding to the sorting indicator light 6 has been opened, but it cannot be specified which sensor has issued the alarm.

The present invention has been made to solve the above-mentioned problem, and can easily specify a sensor that has issued a warning even when a plurality of sensors are connected to one circuit system of a divided display. It is an object of the present invention to provide a reflective infrared sensor and a sensor system.

[0007]

In order to achieve the above object, a reflection type infrared sensor according to the first aspect of the present invention comprises a light projecting section for projecting infrared rays, and a reflection section for projecting infrared rays projected from the light projecting section. A light receiving unit for receiving light, an alarm lamp, a memory lamp,
A level detection circuit that outputs a signal of a predetermined level when an output signal from the light receiving unit is at a predetermined level; and a warning signal and an alarm only when the output level of the level detection circuit is the predetermined level. An output circuit for turning on the lamp and a memory lamp when the output level of the level detection circuit is at the predetermined level, a clock is generated to start counting the clock, and then the power is turned off. A memory lamp driving circuit that turns off the memory lamp when the predetermined number of clocks are counted without powering off and when the power is turned off when the memory lamp is turned on. The reflection type infrared sensor according to claim 2 is the reflection type infrared sensor according to claim 1, wherein
A switch circuit for transmitting an output signal of the light receiving unit to the level detection circuit only during a period when the light emitting unit emits light is provided. A sensor system using the reflective infrared sensor according to claim 3 includes a light projecting unit that projects infrared light, and a light receiving unit that receives reflected light of infrared light projected from the light projecting unit, A reflective infrared sensor that outputs an alarm signal when the level is at a predetermined level; and a division indicator that supplies power to the reflective infrared sensor and receives an alarm signal from the reflective infrared sensor. In the sensor system, the reflection type infrared sensor turns on the memory lamp and the memory lamp for a predetermined period of time after the alarm is issued when the alarm is issued, and the sorting indicator is reset. In this case, a memory lamp driving circuit is provided which is reset when the power supply is momentarily interrupted.

[0008]

The reflection type infrared sensor includes a light emitting portion for emitting infrared light, a light receiving portion for receiving reflected light of infrared light emitted from the light emitting portion, an alarm lamp, a memory lamp, a level detection circuit, an output circuit, and A memory lamp drive circuit is provided. The level detection circuit outputs a signal of a predetermined level when an output signal from the light receiving section is at a predetermined level. The output circuit outputs the alarm signal and turns on the alarm lamp only when the output level of the level detection circuit is the predetermined level.
The memory lamp driving circuit turns on the memory lamp when the output level of the level detection circuit is the predetermined level, generates a clock, starts counting clocks, and then turns off the power. The memory lamp is turned off when a predetermined number of clocks are counted without the power being turned on and when the power is turned off when the memory lamp is turned on. Further, a reflection type infrared sensor according to the present invention includes a memory lamp and a memory lamp driving circuit. When the alarm signal is output, the memory lamp driving circuit turns on the memory lamp for a predetermined time set after the alarm. When the power is turned off, the memory lamp driving circuit is reset and the memory lamp is turned off.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment in which a shutter sensor system is constructed using a reflection type infrared sensor according to the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a schematic appearance of a sensor according to the present invention. An alarm light 11 and a memory light 12 are provided at predetermined positions of the sensor 10, that is, positions that can be visually recognized by a person with the sensor attached.
Is arranged. The alarm lamp 11 is lit only while the shutter is open, and the memory lamp 12
It is lit for a predetermined time T ₁ defined in advance from when a first calling report, in which the time T ₁ is is turned off is automatically reset when the elapsed. Therefore, when it is confirmed that the section indicator light of the section indicator is turned on and there is an alarm, the search is performed to search for the sensor 10 in which the memory lamp 12 is turned on, so that any shutter can be opened. Can be specified. Here, T ₁ is set to about 50 minutes. The alarm lamp 11 and the memory lamp 1
It is desirable that the two emission colors be different.

Next, the circuit configuration of the sensor 10 will be described with reference to FIG. The oscillation circuit 20 always generates a pulse 21 having a predetermined frequency, for example, about 800 Hz when the power is turned on. The pulse 21 is supplied to the light emission drive circuit 22 and the switch circuit 28. The light emission drive circuit 22 inputs a pulse 21 from the oscillation circuit 20 and drives the light emission element that emits infrared light to emit light. In FIG. 2, the two light emission elements 23 and 24 emit light simultaneously. . The reason why the two light emitting elements 23 and 24 are provided in this way is that even if one of the light emitting elements fails, the other light emitting element can continue to perform the shutter open / close detection operation. For the same reason, two light receiving elements 25 and 26 are provided. Outputs of these light receiving elements 25 and 26 are amplified by an amplifier 27 and input to one input terminal a of a switch circuit 28. The other input terminal b of the switch circuit 28 is set to high impedance. During the high-level period of the pulse 21, that is, during the period when the light-emitting elements 23 and 24 emit light, the output terminal c is connected to the input terminal a as shown by the solid line in FIG.
The output terminal c is connected to the input terminal b as shown by a broken line in the drawing during the low level period of the pulse 21, that is, during the period when the light emitting elements 23 and 24 do not emit light. As a result, only the signal based on the reflected light during the period in which the light emitting elements 23 and 24 emit light is transmitted to the circuit at the subsequent stage of the switch circuit 28, so that the influence of sunlight or other noise light can be eliminated. Can be.

The level detection circuit 29 performs envelope detection of the input pulse signal, compares the detected level with a predetermined threshold value, and outputs a predetermined signal according to the result of the comparison. Here, the level detection circuit 29 outputs a high level assuming that the shutter is closed when the detection level is equal to or higher than the threshold, and outputs a low level assuming that the shutter is open when the detection level is lower than the threshold. Shall be. The output circuit 30 does not operate when the output of the level detection circuit 29 is at a high level.
Is low level, an alarm signal is output to a not-shown section indicator and the alarm lamp 11 is turned on. Memory lamp drive circuit 31, the output of the level detection circuit 29 does not operate in the case of high level, if the output of the level detection circuit 29 becomes low level, the memory lamp 12 of T ₁ from the time Lights over a period.

FIG. 3 shows a configuration example of the memory lamp driving circuit 31. The output of the level detection circuit 29 is a flip-flop (F
F) Input to the set terminal S of 35. The FF 35 is set when the output of the level detection circuit 29 falls from the high level to the low level, and the Q output becomes the high level. When the Q output goes high, the memory lamp 12 is turned on, and the clock generation circuit 36 is triggered to start generating a clock signal. Counter 37 counts the clock signal from the clock generation circuit 36, when the counted number of clocks corresponding to T ₁ predetermined time, outputs a low level. This output is input to the reset terminal R of the FF 35, whereby the FF 35 is reset and the Q output becomes low level. When the Q output of the FF 35 becomes low level, the memory lamp 12 is turned off and the clock generation circuit 36 also stops operating.

[0013] By the above operation is performed, the memory lamp 12 is lit for T ₁ times since there is issued report.
In the circuit configuration of FIG. 3, the alarm generated while the memory lamp 12 is on is ignored, and the memory lamp 12 is turned off when the memory lamp 12 is turned on for the time T ₁ from the first alarm, but the memory lamp 12 is turned off. by the retrigger configurable respect alarm that occurred during the lighting, that the memory lamp 12 can be adapted to light up only T ₁ times from the last alarm that occurred during lit bright It is clear. Also, FF
35 of the reset terminal R is connected to a connection midpoint of the series circuit of a resistor R and a capacitor C provided between the ground and the power supply voltage V _B. The power supply voltage V _B are those which are supplied from the partitioned display device (not shown), is adapted to be instantaneous interruption by the reset switch of the segment indicator is pushed. Therefore, when the reset switch of the section indicator is pressed and the power supply is momentarily interrupted, the potential of the reset terminal R gradually increases from zero volts according to the time constant of the resistor R and the capacitor C. Since there is a period in which the FF 35 is at low level, the FF 35 is reset by this
Since the Q output goes low, the memory light 1
When 2 is on, the memory lamp 12 is turned off.

The reason why the memory lamp drive circuit 31 is reset when the alarm state is set is as follows.
Now, assuming that the above-described sensor 10 according to the present invention is constantly supplied with a power supply voltage from the divided display, the sensor 10 is constantly operating, and thus the shutter is opened as shown in FIG. 4A. In this case, an alarm signal is output to the sorting indicator, and the memory lamp 12 is turned on. In this case, as described above, when the alert is released, the sorting indicator of the sorting indicator is not turned on. But then, the shutter is the shutter tightened after being opened to ₁ hour in the T, when made in the alert state, the memory lamp 12 remains despite not receiving alarm is partitioned indicator lighting By continuing, the user feels discomfort and distrust. As described above, when the memory lamp driving circuit 31 is not reset when the alert state is set, the maximum T from the alert state is set.
_{Even if the} memory lamp 12 is turned on within _one hour, it is not necessarily based on the alert after the alert state is set.

On the other hand, as described above, when the memory lamp driving circuit 31 is reset when the alert state is set, even if the memory lamp 12 is turned on before the alert state is set. Since the memory lamp 12 is turned off when the alert state is set as shown in FIG. 4B, when the memory lamp 12 is turned on after the alert state is set, the shutter is opened by the intruder. It will show that.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications are possible. In particular, it is known to those skilled in the art that the memory lamp driving circuit can be variously configured. It is clear. Further, although a circuit for instantaneously interrupting the power supply to the sensor 10 when the reset switch of the divided display is pressed has been omitted, it is apparent that the circuit can be variously configured. .

[0017]

As is apparent from the above description, the reflection type infrared sensor according to the present invention has an alarm memory function. Therefore, when a sensor system is constructed using this sensor, one circuit system of the segmented display is used. Not only can a plurality of sensors be connected to the same system, but also which sensor in one circuit system has issued an alarm can be easily specified. In addition, since a plurality of sensors can be connected in one circuit of the segmented display, the burden of laying power and signal lines can be reduced and costs can be reduced.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic appearance of a sensor according to the present invention.

FIG. 2 is a diagram showing a circuit configuration of the sensor shown in FIG.

FIG. 3 is a diagram illustrating a configuration example of a memory lamp driving circuit.

FIG. 4 is a diagram for explaining the necessity of resetting an alarm memory function.

FIG. 5 is a diagram showing a configuration example of a conventional shutter sensor system using a reflection type infrared sensor.

FIG. 6 is a diagram for explaining a problem of the present invention.

[Explanation of symbols]

10: reflective infrared sensor, 11: alarm light, 12:
Memory lamp, 20: oscillation circuit, 22: light emission drive circuit, 2
3, 24: light emitting element, 25, 26: light receiving element, 27: amplifier, 28: switch circuit, 29: level detection circuit, 3
0: output circuit, 31: memory lamp drive circuit, 35: flip-flop, 36: clock generation circuit, 37: counter.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-63-61153 (JP, A) JP-A-2-168399 (JP, A) JP-A-61-92889 (JP, U) 504440 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G01V 8/12 G08B 13/18

Claims (3)

(57) [Claims] A light emitting unit for emitting infrared light; a light receiving unit for receiving reflected light of the infrared light emitted from the light emitting unit; an alarm lamp; a memory lamp; and an output signal from the light receiving unit. A level detection circuit that outputs a signal of a predetermined level when the signal is at a level, and an output circuit that outputs an alarm signal and lights an alarm lamp only when the output level of the level detection circuit is the predetermined level, When the output level of the level detection circuit is at the predetermined level, the memory lamp is turned on, a clock is generated to start counting the clock, and thereafter, the predetermined number of clocks is counted without turning off the power. A memory lamp driving circuit for turning off the memory lamp when counting is performed and when the power is turned off when the memory lamp is lit. Infrared sensor. 2. A switch circuit for transmitting an output signal of the light receiving section to the level detecting circuit only during a period when the light emitting section emits light, between the light receiving section and the level detecting circuit. The reflective infrared sensor as described in the above. 3. A light-emitting unit for emitting infrared light, and a light-receiving unit for receiving reflected light of infrared light emitted from the light-emitting unit,
A reflective infrared sensor that outputs an alert signal when the level of the received light signal is at a predetermined level; and a divisional indicator that supplies power to the reflective infrared sensor and receives an alert signal from the reflective infrared sensor. In the sensor system comprising: the reflection-type infrared sensor, a memory lamp, and, if there is an alert, the memory lamp is turned on for a predetermined time set after the alert, the sorting indicator A sensor system using a reflection-type infrared sensor, comprising: a memory lamp driving circuit that is reset when power is momentarily interrupted when the device is reset.