JP3337555B2 - Self-inspection device for safety disaster prevention system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a self-inspection system for a safety and disaster prevention system, and more particularly to a self-inspection system for a safety and disaster prevention system that automatically performs an alarm test of the safety and disaster prevention system.

[0002]

2. Description of the Related Art Conventionally, safety and disaster prevention systems such as fire alarms and intruder detectors have been required to have high reliability. Inspections are periodically performed to ensure that the sensor does not operate when it is normal but only when it is abnormal. In such an inspection, as shown in FIG.
1 directly to the room 50 where the
Inspection according to

[0003] However, in the case of a private house, there is a restriction in conducting an inspection such as an individual's privacy and an inspection time zone, so that the inspection method and visiting time of the sensor are limited. In the case of an apartment house, a large factory, or the like, the number of installed sensors is very large. Therefore, it takes a lot of labor and time for an inspector to directly inspect all sensors.

[0004]

SUMMARY OF THE INVENTION The present invention has been made to solve such a conventional problem. An inspection of a detection function of a sensor installed in a private house or the like is performed directly to a place where the sensor is installed. It is an object of the present invention to provide a self-inspection device for a safety and disaster prevention system that can be implemented without any means.

[0005]

A self-inspection apparatus for a safety and disaster prevention system according to the present invention which achieves the above object has a detection element for detecting an electromagnetic wave or an ultrasonic wave and a detection element for inspecting a detection function of the detection element. It comprises an inspection member and moving means for moving the detection inspection member in the direction in which the detection element is located.

In the self-inspection device for a safety and disaster prevention system according to the present invention, the detecting element is a photoelectric sensor, and the detecting and inspecting member is a light reflecting member for reflecting light from a light source installed at a predetermined position toward the photoelectric sensor. It is a board. Further, in the self-inspection device of the safety and disaster prevention system of the present invention, the detection element is a pyroelectric infrared sensor, and the detection and inspection member is a porous filter provided with a plurality of holes.

Further, in the self-inspection device of the safety and disaster prevention system according to the present invention, the detecting element is an ultrasonic sensor,
The detection inspection member is an ultrasonic reflector that reflects ultrasonic waves from an ultrasonic oscillator provided in the ultrasonic sensor. In the self-inspection device of the safety and disaster prevention system of the present invention, the driving means uses a motor for rotating the detection inspection member.

Further, in the self-inspection device of the safety and disaster prevention system according to the present invention, the driving means uses an electromagnetic valve for linearly moving the detection and inspection member back and forth.

[0009]

In the self-inspection device of the safety and disaster prevention system, the inspection function of the detection element can be inspected simply by moving the detection inspection member to a position facing the detection element. For example, when the detection element is a photoelectric sensor, the photoelectric sensor is driven only by moving a light reflecting plate, which reflects light from a light source installed at a predetermined position, to a position corresponding to the photoelectric sensor by a motor or an electromagnetic valve. Therefore, the detection function of the photoelectric sensor can be inspected.

When the detecting element is a pyroelectric infrared sensor, the porous filter having a plurality of holes is moved to a position corresponding to the pyroelectric infrared sensor by a motor or an electromagnetic valve, so that the pyroelectric infrared sensor can be used. The ambient temperature near the infrared sensor can be changed. Since the pyroelectric infrared sensor can be driven by this temperature change, the detection function of the pyroelectric infrared sensor can be inspected.

Further, when the detecting element is an ultrasonic sensor, an ultrasonic reflecting plate for reflecting ultrasonic waves from an ultrasonic oscillator provided in the ultrasonic sensor is provided at a position facing the ultrasonic sensor with a motor or an electromagnetic valve. Since the ultrasonic sensor can be driven only by moving the ultrasonic sensor, the detection function of the ultrasonic sensor can be inspected. Thus, the inspection of the sensor can be performed without the inspector directly going to the place where the sensor is installed.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a self-inspection device for a safety and disaster prevention system according to the present invention will be described below with reference to the drawings. The self-inspection device of the safety and disaster prevention system of the present invention is, for example, shown in FIG.
As shown in (a) and (b), it is provided in a smoke detector 2 installed on a ceiling or the like of each room of a private house. The smoke detector 2 includes a light source 4, a light receiving and emitting device 3 in which a photoelectric sensor 5 as a detecting element for detecting reflected light generated by light from the light source 4 being reflected by smoke, and a light source 4.
Light reflecting plate 6, which is a detection inspection member for artificially reflecting light from the photoelectric sensor 5, and the light reflecting plate 6 is supported by a support arm 17.
And a motor 7 serving as moving means for rotating the light reflecting plate 6, a substrate 8 for fixing the photoelectric sensor 5 and the motor 7, and a cover 9 for protecting these.

A light emitting diode (LED) is used for the light source 4 of the light receiving / emitting device 3 in order to make the light emitting device as small as possible. preferable. The photoelectric sensor 5 has high sensitivity to scattered light and reflected light,
The light is converted into an electric signal.
An IN silicon photodiode or the like can be used.

The light reflecting plate 6 has a mirror-finished surface or a surface having a high reflectance such as a metal-deposited surface, and the reflecting surface reflects light from the light source 4 to the photoelectric sensor 5 efficiently. Shape. The light reflection plate 6 is for inspecting the detection function of the photoelectric sensor 5 and includes a motor 7.
Is driven to rotate the light source 4 and the photoelectric sensor 5 to a position corresponding to the light receiving and emitting device 3 incorporated therein during the inspection,
In a normal state (when smoke is detected), the rotation is made by a required rotation angle so as to deviate from a position facing the light emitting and receiving device 3.

The cover 9 is formed so as to completely block external light, and further has a plurality of holes 9a through which only smoke can enter. As shown in FIG. 2, the self-inspection device 1 thus configured
1 is driven and controlled by a self-inspection unit 11 having a control circuit 12 for controlling the motor 7 as a unit 1 and a drive circuit 13 for driving an alarm 14 based on an electric signal output from the photoelectric sensor 5 as a detection unit 10. You. The self-inspection unit 11 is provided in a control receiver (not shown) that controls the smoke detector 2 and the alarm 14 and the like.

In such a self-inspection device 1, the light reflecting plate 6 for inspecting the photoelectric sensor 5 is usually out of the position facing the light emitting / receiving device 3 in the normal state. Therefore, in order to inspect the detection function of the photoelectric sensor 5, the self-inspection unit 11
The motor 7 is driven by the control circuit 12 of FIG.
Is moved to a position facing the light emitting and receiving device 3. As a result, light from the light source 4 of the light emitting / receiving device 3 is reflected by the light reflecting plate 6,
The reflected light is received by the photoelectric sensor 5 of the light emitting / receiving device 3.

The light reflected by the light reflecting plate 6 is converted into an electric signal by the photoelectric sensor 5, and the electric signal from the photoelectric sensor 5 is guided to the drive circuit 13 of the self-inspection unit 11. The drive circuit 13 causes the alarm 14 to sound as an alarm test based on the electric signal from the photoelectric sensor 5. Accordingly, the inspection of the photoelectric sensor 5 can be performed without the inspector directly going to the place where the smoke detector 2 provided with the photoelectric sensor 5 is installed.

As shown in FIGS. 3 (a) and 3 (b), the smoke detector 2 is a moving means for linearly reciprocating a light reflecting plate 6 for reflecting light from the light source 4 to the photoelectric sensor 5 artificially. It may be fixed to a certain electromagnetic valve 15. In this case, the solenoid valve 1
When the inspection is performed, the light source 4 and the photoelectric sensor 5 are rotated to a position corresponding to the light emitting and receiving device 3 incorporated therein during inspection, and the light emitting device 3 is opposed to the light emitting and receiving device 3 during normal times (when smoke is detected). Move linearly until it deviates from the position. The self-inspection device 15 thus configured, like the self-inspection device 1, controls the electromagnetic circuit 16 as the self-inspection unit 11 and the electric signal output from the photoelectric sensor 5 as the detection unit 10. Is driven and controlled by a self-inspection unit 11 having a drive circuit 13 for driving an alarm 14 based on the alarm (FIG. 2).

In such a self-inspection device 15, the light reflecting plate 6 for inspecting the photoelectric sensor 5 is usually out of the position facing the light emitting / receiving device 3 in the normal state. Therefore,
To inspect the detection function of the photoelectric sensor 5, the self-inspection unit 1
The electromagnetic valve 16 is driven by the first control circuit 12 to move the light reflecting plate 6 to a position facing the light emitting and receiving device 3. As a result, light from the light source 4 of the light emitting / receiving device 3 is reflected by the light reflecting plate 6, and the reflected light is received by the photoelectric sensor 5 of the light emitting / receiving device 3.

The light reflected by the light reflecting plate 6 is converted into an electric signal by the photoelectric sensor 5, and the electric signal from the photoelectric sensor 5 is guided to the drive circuit 13 of the self-inspection unit 11. The drive circuit 13 causes the alarm 14 to sound as an alarm test based on the electric signal from the photoelectric sensor 5. Accordingly, the inspection of the photoelectric sensor 5 can be performed without the inspector directly going to the place where the smoke detector 2 provided with the photoelectric sensor 5 is installed.

In the above embodiment, the self-inspection device is applied to the smoke detector. However, the present invention is not limited to this, and may be applied to a human body detector for detecting the invasion of a human body. As shown in FIG. 4, such a human body sensor 20 changes a pyroelectric infrared sensor 22 which is a detecting element for detecting a temperature (infrared ray) emitted from a human body and an ambient temperature near the pyroelectric infrared sensor 22. A perforated filter 24 serving as a detection inspection member, the perforated filter 24 is fixed via a support arm 25, and a motor 26 for rotating the perforated filter 24, and the pyroelectric infrared sensor 22 and the motor 26 are fixed on a ceiling 28 or the like. And a cover 27 for protecting them.

The pyroelectric infrared sensor 22 is made of a pyroelectric material such as LiTaO ₃ . The pyroelectric material changes in spontaneous polarization due to irradiation, cutoff, or temperature change of infrared rays, and the electric charge on the crystal surface becomes non-equilibrium. By taking out this unbalanced charge as a voltage change, the pyroelectric infrared sensor 22
Can detect far infrared rays of about 3 to 9.5 μm emitted from the human body.

The porous filter 24 is a pyroelectric infrared sensor 2
2 for inspecting the detection function, and a plurality of holes are provided as shown in FIG. Perforated filter 24
Is rotated to a position corresponding to the pyroelectric infrared sensor 22 at the time of inspection by driving the motor 26, and deviates from a position corresponding to the pyroelectric infrared sensor 22 during normal times (when an intruder is detected). Rotate until When the porous filter 24 moves to a position opposite to the pyroelectric infrared sensor 22, a temperature difference occurs between a plurality of holes of the porous filter 24 and a portion where the plurality of holes are not formed. Since a temperature change occurs around 22, the pyroelectric infrared sensor 22 can be brought into the detection state.

The self-inspection device 21 having the above-described configuration, like the self-inspection device 1 described above, includes a control circuit 12 for controlling a motor 26 as a self-inspection unit 11 and a detection unit 10.
It is driven and controlled by a self-inspection unit 11 having a driving circuit 13 for driving an alarm 14 based on an electric signal output from a pyroelectric infrared sensor 22 (FIG. 2).

In such a self-inspection device 21, the porous filter 24 for inspecting the pyroelectric infrared sensor 22 is normally out of the position facing the pyroelectric infrared sensor 22. Therefore, the pyroelectric infrared sensor 22
In order to inspect the detection function, the control circuit 12 of the self-inspection unit 11 drives the motor 26 to move the porous filter 24 to a position facing the pyroelectric infrared sensor 22.
As a result, a temperature change occurs near the pyroelectric infrared sensor 22, and this temperature change is converted into an electric signal by the pyroelectric infrared sensor 22, and the pyroelectric infrared sensor 22
Is guided to the drive circuit 13 of the self-inspection unit 11. The drive circuit 13 causes the alarm 14 to sound as an alarm test based on the electric signal from the pyroelectric infrared sensor 22.

Thus, the inspector can read the pyroelectric infrared sensor 2
The inspection of the pyroelectric infrared sensor 22 can be carried out without directly going to the place where the human body sensor 20 provided with 2 is installed. Further, as shown in FIG. 5, the human body detector 20 may be fixed to the electromagnetic valve 15 for linearly reciprocating the porous filter 24 in order to make the pyroelectric infrared sensor 22 artificially detect. In this case, the solenoid valve 15
To drive the porous filter 24 so that the pyroelectric infrared sensor 2
2 can cause a temperature change in the vicinity of the pyroelectric infrared sensor 22 similarly to the motor 26, so that the detection function of the pyroelectric infrared sensor 22 is inspected by the human body sensor 20. Can be carried out without going directly to the place where is installed.

Further, the human body detector 20 is shown in FIG.
(C) In some cases, as shown in FIG. 5, an ultrasonic sensor 30 as a detection element is used. Piezoelectric ceramics are frequently used as a sound source of the ultrasonic sensor 30, and when used as an ultrasonic oscillator, a voltage is applied to the piezoelectric ceramics and applied, and mechanical vibrations are generated according to the voltage and frequency to vibrate. Conversely, when vibration is applied to the piezoelectric ceramic, an electric charge is generated, so that ultrasonic waves can be detected.

The ultrasonic sensor 30 having such characteristics
In the same manner as in the case of the pyroelectric infrared sensor 22, the ultrasonic sensor 30 and the ultrasonic reflecting plate 31 which is a detection inspection member for reflecting the ultrasonic wave oscillated from the ultrasonic oscillator of the ultrasonic sensor 30 are located at positions facing each other. Install it so that it can be moved. When the ultrasonic reflecting plate 31 is fixed to the motor 26, the ultrasonic reflecting plate 31 is rotated by the motor 26 to rotate to a position opposite to the ultrasonic sensor 30 at the time of inspection, and is normally operated (detecting an intruder). (In a state where the ultrasonic sensor 30 is in the state), it can be rotated by a required rotation angle so as to deviate from a position facing the ultrasonic sensor 30. Also, the ultrasonic reflecting plate 3
1 can be moved to a position facing the ultrasonic sensor 30 during inspection by linearly reciprocating with the electromagnetic valve 29, and can be moved a predetermined distance so as to deviate from the position facing the ultrasonic sensor 30 during normal operation. .

Thus, the inspection of the ultrasonic sensor 30 can be performed without the inspector directly going to the place where the human body sensor 20 provided with the ultrasonic sensor 30 is installed. In the above embodiment, the self-inspection device is applied to the smoke detector and the human body detector installed on the ceiling of each room of the private house. However, the present invention is not limited to this. The present invention may also be applied to smoke detectors, human body detectors, and the like installed in the like.

[0030]

As is apparent from the above embodiments, according to the self-inspection apparatus for the safety and disaster prevention system of the present invention, the detection element for detecting electromagnetic waves or ultrasonic waves and the detection function of the detection element are inspected. And a moving means for moving the detection / inspection member in the direction where the detection element is located. Therefore, the inspection of the detection function of a sensor installed in a private house or the like is performed by an inspector who has installed the sensor. It can be implemented without going directly to the place where you are. Therefore, in the case of a private house, the degree of freedom is increased during the inspection time without harming the privacy of the individual, and in the case of an apartment house or a large factory, it is necessary for the inspector to directly inspect the installed sensors. Therefore, labor for the inspection can be reduced, and the inspection time can be significantly reduced.

[Brief description of the drawings]

FIG. 1 is a view showing one embodiment of a self-inspection device for a safety and disaster prevention system according to the present invention, wherein FIG. 1 (a) is a top sectional view and FIG. 1 (b) is a side sectional view.

FIG. 2 is a block diagram of a control system used in a self-inspection device of the safety and disaster prevention system of the present invention.

3A and 3B are diagrams showing another embodiment of the self-inspection device of the safety and disaster prevention system of the present invention, wherein FIG. 3A is a top sectional view and FIG. 3B is a side sectional view.

FIG. 4 is a view showing another embodiment of the self-inspection device of the safety and disaster prevention system of the present invention, wherein (a) is a cross-sectional view and (b) is (a).
FIG.

FIG. 5 is a sectional view showing another embodiment of the self-inspection device of the safety and disaster prevention system of the present invention.

FIG. 6 is a diagram illustrating a self-inspection of a conventional safety and disaster prevention system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1, 21 ... Self-inspection apparatus 2 ... Smoke detector 3 ... Light emitting and receiving device 4 ... Light source 5 ... Photoelectric sensor (detection element) 6 ... Light reflection plate (detection inspection member) 7, 26 ... Motor (moving means) 16, 29 ... electromagnetic valves (moving means) 17, 25 ... support arm 20 ... human body detector 22 ... pyroelectric infrared sensor (detection element) 23 ... mounting arm 24 ... porous filter (detection inspection member) 30 ... ultrasonic sensor (detection element) 31: Ultrasonic reflector (detection inspection member)

Continuation of front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G08B 29/04 G08B 17/10

Claims (6)

(57) [Claims] 1. A detecting element for detecting an electromagnetic wave or an ultrasonic wave,
A self-inspection apparatus for a safety and disaster prevention system, comprising: a detection inspection member for inspecting a detection function of the detection element; and a moving unit for moving the detection inspection member in a direction in which the detection element is located. 2. The apparatus according to claim 1, wherein said detection element is a photoelectric sensor, and said detection and inspection member is a light reflecting plate for reflecting light from a light source installed at a predetermined position toward said photoelectric sensor. Item 1. A self-inspection device for the safety disaster prevention system according to Item 1. 3. The self-inspection system for a safety and disaster prevention system according to claim 1, wherein said detection element is a pyroelectric infrared sensor, and said detection and inspection member is a porous filter provided with a plurality of holes. apparatus. 4. The apparatus according to claim 1, wherein said detecting element is an ultrasonic sensor, and said detecting and inspecting member is an ultrasonic reflecting plate for reflecting ultrasonic waves from an ultrasonic oscillator provided in said ultrasonic sensor. The self-inspection device of the safety disaster prevention system according to claim 1. 5. The self-inspection system for a safety and disaster prevention system according to claim 1, wherein said moving means uses a motor for rotating said detection inspection member. 6. The self-inspection system for a safety and disaster prevention system according to claim 1, wherein said moving means uses an electromagnetic valve for linearly reciprocating said detection inspection member.