JPH09284986A - Seismoscope and automatic reporting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a usable seismoscope for various applications, by providing an output relay for operating in it, based on the sensed output of a steel-ball type vibration sensor. SOLUTION: A vibration sensor 7 of an automatic horizontal steel-ball type vibration sensor senses a vibration having a seismic intensity not smaller than four to give its on-off sensing output by the rolling of a steel-ball in response to the vibration. When an earthquake is generated, a contact 71 of the vibration sensor 7 is turned on or off in response to the vibration of the earthquake. When the contact 71 is turned on first, a current is applied to a set coil 202 of a keep relay 20 to turn off a relay contact 201 . Thereby, breaking the current application to a coil 212 of a power relay 21, a relay contact 211 of the power relay 21 is turned off to break the electric path extending from the primary side plug socket of the power relay 21 to its secondary side one and keep the state thereof. Therefore, the current application to a load connected with a seismoscope 1 with the foregoing plug sockets is broken to keep the state thereof.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration-sensing device for detecting vibration such as an earthquake or shock and an automatic notification device using the vibration-sensing device.

[0002]

2. Description of the Related Art Recently, there have been frequent earthquakes in various places including the Great Hanshin-Awaji Earthquake, and disaster prevention measures such as prevention of secondary disasters at the time of earthquake occurrence are increasing.

In general households and various factories, electricity continues to be supplied even though the building is tilted or collapsed due to the occurrence of a large earthquake. For example, in an iron or an electric stove, heat is generated due to continuation of electricity. There is a risk that a fire will occur due to the accident, or the cord covering may be damaged by a collapsed building, causing a fire.
On the contrary, there is a risk that the lighting may be extinguished or important equipment may be stopped due to a power outage caused by an earthquake.

[0004]

Therefore, when a large earthquake or the like occurs, a seismic sensing device suitable for various purposes such as detecting the power and shutting off the power, or conversely turning on the illumination is desired. .

In addition, it is desired to be able to notify the other party of the occurrence of an earthquake or the like as needed.

The present invention has been made in view of the above points, and it is possible to detect a vibration such as an earthquake or shock and give a corresponding output, or to interrupt the energization of a load. It is an object of the present invention to provide a vibration-sensing device and an automatic notification device using the vibration-sensing device.

[0007]

In order to achieve the above-mentioned object, the present invention is configured as follows.

That is, the vibration-sensing device of the present invention according to claim 1 comprises a steel ball type vibration sensor for detecting a vibration of a predetermined level or more, and an output relay which operates based on the detection output of the vibration sensor. ing.

According to a second aspect of the present invention, there is provided a vibration-sensing device having an outlet and equipped with an outlet, which is a steel ball type vibration sensor for detecting a vibration of a predetermined level or higher, and a detection of the vibration sensor. And a disconnection relay that disconnects the electric path to the insertion port based on the output.

According to a third aspect of the present invention, there is provided a vibration-sensing device equipped with an outlet having an outlet, wherein the vibration-sensing device is a steel ball type vibration sensor for detecting a vibration of a predetermined level or higher, and the vibration sensor. A keep relay that operates based on the output and a power relay that shuts off the electric path to the insertion port by the output of the keep relay are provided, and the shut state is maintained by the keep relay.

According to a fourth aspect of the present invention, there is provided a vibration-sensing device equipped with an outlet having an outlet, which is a steel ball-type vibration sensor for detecting vibrations of a predetermined level or higher, and a detection of the vibration sensor. Discriminating means for discriminating whether or not there is an earthquake based on the output, and a breaking relay for breaking the electric circuit to the outlet when the earthquake is equal to or higher than the predetermined level based on the output of the discriminating means. It has and.

According to a fifth aspect of the present invention, there is provided the vibration sensing device according to the fourth aspect.
In the seismic sensing device, the battery is provided to supply power in the event of a power failure, and the determining means determines whether or not there is an earthquake by fuzzy reasoning.

According to a sixth aspect of the present invention, there is provided a vibration-sensing device according to the first aspect.
The seismic sensing device of Nos. 5 to 5 is provided with a plug-in type power input terminal.

According to a seventh aspect of the present invention, there is provided the vibration sensing device according to the first aspect.
The vibration-sensing device of Nos. 6 to 6 includes a reset operation unit that is operated to initialize the vibration-sensing device.

The automatic notification device of the present invention according to claim 8 is an automatic notification device for automatically reporting to a predetermined contact point via a telephone line, and the seismic sensing device according to claim 1 is built in or connected to the automatic notification device. The automatic notification is made by the operation of the output relay.

According to the seismic sensing device of the present invention as claimed in claim 1, the output relay is connected to a device whose power is to be shut off in the event of an earthquake or a device such as a generator or an alarm device to be activated in the event of an earthquake. By doing so, when an earthquake of a predetermined level or higher occurs, the power of the required equipment is surely cut off, and the equipment that should be activated due to the occurrence of the earthquake is surely activated. Moreover, since the steel ball type vibration sensor is used, the cost can be reduced as compared with the capacitance type vibration sensor, and the vibration at any angle in the horizontal direction can be detected.

According to the vibration-sensing device of the present invention of claim 2, when an earthquake of a predetermined level or higher occurs, the electric path from the power supply side to the insertion port is shut off, so that the seismic-sensing device with the outlet is connected to the insertion port. Energization to the connected load will be reliably cut off.

According to the vibration-sensing device of the present invention as defined in claim 3, when the earthquake of a predetermined level or higher occurs, the shut-off state is maintained by the output of the keep relay, so that the energization can be restarted undesirably. Absent.

According to the vibration-sensing device of the present invention as defined in claim 4, it is determined whether or not there is an earthquake on the basis of the detection output of the vibration sensor, and when the earthquake occurs, the electric line is cut off. It is possible to prevent the malfunction due to the impact or the like.

According to the seismic sensing apparatus of the present invention as defined in claim 5, since each unit is provided with a battery for supplying electric power in case of power failure, the operation can be continued even in case of power failure.

According to the vibration-sensing device of the present invention of claim 6, since it has a plug-in type power input terminal, it can be operated only by inserting the power input terminal into an outlet embedded in a wall surface or the like. Become.

According to the seismic sensing apparatus of the present invention as set forth in claim 7, since the reset operation section is provided, the initial state can be obtained by operating the reset operation section.

According to the eighth aspect of the automatic notification device of the present invention, the vibration-sensing device of the present invention is built-in or connected, and when vibration of a predetermined level or more, for example, when an earthquake occurs,
An automatic notification is sent to a predetermined contact point via a telephone line.

[0024]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is an external perspective view of a seismic sensing device according to one embodiment of the present invention, FIG. 2 is an exploded perspective view thereof, and FIG. It is a figure.

The vibration-sensing device 1 of this embodiment is a vibration-sensing device with an outlet.
Four outlets 2 for inserting the plug on the load side are provided to form a two outlet, and on the back,
A pair of primary side outlet terminals 3 as plug-in type power source input terminals on the power source side are projected.

This vibration-sensing device 1 with an outlet has a predetermined level, in this embodiment, when a vibration with a seismic intensity of 4 or more occurs, the outlet terminal 3 on the primary side, which is the power supply side.
To cut off the electric path from the above to the insertion port 2.

As shown in FIG. 2, the seismic sensing device 1 with an outlet basically has a housing formed by a cover 4 and a case 5, and a circuit board 6 having components mounted therein. Also, the vibration sensor 7 and the like are built therein.

The cover 4 is formed with mounting holes 9 for mounting the cover 4 to the case 5 with screws 8 at four corners, and the four insertion ports 2 are formed as described above. Has been done.

On the back surface of the case 5, a pair of insertion holes 1 through which the plug-in L-shaped primary side outlet terminals 3 are inserted.
0 and the outlet hole 3 for attaching the outlet terminal 3 with the terminal screw 15 are formed, and the operation portion 12a of the reset switch 12 for initializing the seismic sensing device 1 is provided at the lower part of one side surface. An opening 13 that faces is formed.

Inside the case 5, terminal fixing bosses 17 for fixing a pair of secondary side outlet terminals 14 sandwiching a load-side plug (not shown) with terminal screws 16 are provided at two locations, and a circuit board is provided. Substrate fixing bosses 18 for fixing 6 with screws are provided at four locations. Further, a pair of holding portions 19 that holds the vibration sensor 7 is provided on the bottom surface of the case 5.

The outlet terminal 3 on the primary side is attached to the back side of the case 5, while the outlet terminal 14 on the secondary side is placed vertically so that the portion holding the plug faces the respective insertion ports 2 of the cover 4. Two terminal fixing bosses 17
It is fixed by the terminal screw 16. Also, the circuit board 6
Is fixed to the board fixing boss 18 by screws through the mounting holes at the four corners. The steel ball type vibration sensor 7 for detecting a vibration of a predetermined level or more is held by a pair of holding portions 19 on the bottom surface of the case 5 with the collar portion 7a press-fitted therein.

On the circuit board 6, the keep relay 20 which operates based on the detection output of the vibration sensor 7, and the output of the keep relay 20 from the outlet terminal 3 on the primary side to the outlet terminal on the secondary side which is the load side. A power relay 21 that shuts off the electric path to 14 is mounted, and further,
The respective outlet terminals 3, 14, the reset switch 12, and the vibration sensor 7 are connected via a lead wire 22.

The vibration sensor 7 of this embodiment is a so-called automatic horizontal steel ball type vibration sensor, which detects vibrations with a seismic intensity of 4 or more, and the on / off detection output is obtained by rolling the steel balls according to the vibration. To give.

The seismic sensing device 1 with an outlet having the above construction is assembled, for example, as follows.
That is, the plug-in type primary side outlet terminal 3 is attached to the case 5 with the terminal screw 15, the secondary side outlet terminal 14 is attached with the terminal screw 16, and further, the resetting is performed so as to face the opening 13 on the side surface of the case 5. Attach the switch 12. Next, the circuit board 6 on which the relays 20 and 21 are mounted is attached to a predetermined position in the case 5 with a screw, and then the cover 4 is attached to the case 5, whereby the seismic sensing device 1 shown in FIG. Is configured.

FIG. 4 is a circuit configuration diagram of the vibration-sensing device 1 of this embodiment, and the portions corresponding to the above respective drawings are designated by the same reference numerals.

The vibration sensor 7 of this embodiment, usually, the contact 7 ₁ are turned off, in which the contacts ₇₁ by the vibration of seismic intensity of 4 or more will give a detection output turned on and off. In the initial state, the relay contact 20 _{1 of the} keep relay 20 to which the output of the vibration sensor 7 is applied is turned on, and when the set coil 20 ₂ is energized, the relay contact 20 ₁ is turned off and the reset switch 12 is turned on. Is maintained until the reset coil 20 ₃ is energized.

In the vibration-sensing device 1 with an outlet of this embodiment, when the plug-in type primary outlet terminal 3 on the back side is inserted into a general outlet provided on a wall surface or the like, the keep relay 20 Relay contact 20 ₁
Is turned on, the coil 21 _{2 of the} power relay 21
Is energized to turn on the relay contact 21 ₁ , and the secondary side, that is, a load (not shown) having a plug inserted in the insertion port 2 is energized.

In this state, when a vibration having a seismic intensity of 4 or more, for example, an earthquake occurs, the vibration sensor 7 responds to the vibration.
Will be contact 7 ₁ is off, when the contact ₇₁ is initially turned on, the set coil 20 of the keep relay 20 ₂
By the relay contact 20 ₁ is off energized, thereby, is cut off energization of the coil 21 ₂ of the power relay 21 and the relay contact 21 ₁ is off power relay 21, electrical path from the primary side to the secondary side Is shut off and its state is maintained. Therefore, the load connected to the seismic sensing device 1 with the outlet is de-energized and the state is maintained.

[0040] After that, in terms of safety has been confirmed, when resuming energized, turn on the contact points ₇₁ of the vibration sensor 7 by applying an impact in a state of operating the reset switch 12.
Thereby, the reset coil 20 of the keep relay 20
₃ is energized to turn on the relay contact 20 ₁ , the coil 21 ₂ of the power relay 21 is energized to turn on the relay contact 21 ₁ , and the supply of power from the primary side to the secondary side is restarted. .

As described above, in the seismic sensing apparatus 1 of this embodiment, when an earthquake with a seismic intensity of 4 or more occurs, the electric path from the primary side to the secondary side is cut off, so that the load on the secondary side is Energization will not continue. In addition, the reset switch 7
Since the cutoff state is maintained until the is operated to give a shock, the power supply is not accidentally restarted before safety is confirmed.

Moreover, since the steel ball type vibration sensor 7 is used, the cost can be reduced as compared with the structure using the capacitance type vibration sensor, and the vibration at any angle in the horizontal direction can be achieved. It can be detected.

As the vibration sensor 7, a vibration sensor whose contacts are normally on may be used, and a transistor circuit or the like may be provided in the preceding stage of the keep relay to invert it.

In this embodiment, the power relay 21 is used to open and close the electric path. However, as another embodiment of the present invention, the power relay 21 is omitted and the keep relay 20 opens and closes the electric path. Good.

Further, although the above-described embodiment is the seismic sensing device 1 with an outlet, as another embodiment of the present invention, the outlet is omitted and the electric path between the primary side and the secondary side is cut off. In place of this configuration, a steel ball type vibration sensor and an output relay that operates by the detection output of this vibration sensor constitute a seismic sensing device, and the output terminal of the output relay shuts off the power when an earthquake occurs. By connecting emergency equipment such as generators and alarms that should be started when an earthquake occurs or an earthquake occurs, the power of the required equipment can be ensured by the output of the output relay when an earthquake of a predetermined level or more occurs. It may be shut off, or the emergency equipment may be activated without fail.

Further, various contact configurations (1a, 1b, 1c ...) Can be adopted by selecting an output relay at that time.

FIG. 5 is a front view showing a part of a seismic sensing device 1 _{1 according to} another embodiment of the present invention by cutting away, and FIG.
It is the side sectional view, and the same reference numerals are given to the portions corresponding to the above-described embodiments.

[0048] In this embodiment, as a vibration sensor for detecting vibration more than a predetermined level, and using the vibration sensor ₇₁ of the steel ball type type attachment to the circuit board 6 _1, further, in this embodiment, based on the detection output of the vibration sensor ₇₁ includes a fuzzy chip 23 as a discrimination means for fuzzy inference whether the earthquake, the output of the fuzzy chip 23, and the outlet terminal 3 of the primary-side secondary The power relay 21 'that shuts off the electric path between the power relay 21' and the side outlet terminal 14 is controlled.

[0049] On the circuit board _61, along with a power supply circuit or the like (not shown) supplied to the fuzzy chip 23 or the like by rectifying and smoothing the power supply input is mounted below the battery 24
Is installed.

[0050] The vibration sensor _71, like the vibration sensor 7 described above, to detect the vibration of seismic intensity of 4 or more and gives an off output corresponding to the vibration in the fuzzy chip 23.

The fuzzy chip 23 analyzes the vibration pattern from the ON / OFF output from the vibration sensor 7 ₁ to determine whether it is an earthquake vibration pattern or a vibration pattern due to other impacts, and the vibration pattern of the earthquake. When it is, the power relay 21 'is controlled to cut off the electric path.

Further, in this embodiment, a battery 24 for supplying power to the fuzzy chip 23 or the like in the case of a power failure is provided so that the operation can be continued even during a power failure.

When the electric circuit is cut off due to the occurrence of an earthquake and then reset to the initial state, the reset switch 12 is operated to reset the fuzzy chip 23 to the initial state as in the above-described embodiment. Is set.

FIG. 7 shows the power relay 2 of this embodiment.
It is a figure for demonstrating the structure of interruption | blocking of the electric circuit by 1 '.

The AC input 36 from the outlet terminal 3 on the primary side is rectified and smoothed by the power supply circuit 25 and applied to the fuzzy chip 23. The fuzzy chip 23 causes the power relay 21 to operate when an earthquake of a predetermined level or higher occurs. By energizing the'coil 21 ₂ ', the power relay 2
The contact 21 ₁ ′ of ₁ ′ is switched from the outlet terminal 14 side on the secondary side to the empty contact side, thereby interrupting the electric path.

In this embodiment, the fuzzy chip 23
Since it is discriminated whether or not there is an earthquake, the electric circuit is not accidentally cut off in the event of an impact other than the earthquake, for example, when an object hits.

[0057] Figure 8 is a front view of yet cut away a portion of the seismic device 1 ₂ of another embodiment of the present invention, FIG. 9 is its side cross-sectional view, the embodiment described above The same reference numerals are attached to the portions corresponding to the forms.

In this embodiment, the steel ball 27 placed on the steel ball receiver 26 has a predetermined level. In this embodiment, the steel ball receiver 26 is vibrated by a vibration having a seismic intensity of 4 or more, as shown by an imaginary line. From the operating lever 28, and the lever 28 rotates, thereby rotating the cam 29 provided on the proximal end side of the operating lever 28 to rotate the micro switch 30.
Is operated to cut off the electric path from the primary side outlet terminal 3 to the secondary side outlet terminal 14.

When the electric circuit is restored, the return spring 31
By operating the reset lever 32 upward against the urging force of the reset lever 32, the tip of the reset lever 32 comes into contact with the lower portion of the free end of the operating lever 28 to rotate the operating lever 28, and the cam 29 rotates. The movement causes the micro switch 30 to return, and the steel ball 27 is placed on the steel ball receiver 26 to return to the initial state.

In this embodiment, unless the reset lever 32 as the reset operation portion is manually operated, the initial state cannot be restored and the energization is not restarted by mistake.

As another embodiment of the present invention, the seismic sensing device with an outlet may be an embedded type.

As another embodiment of the present invention, the seismic sensing device has an emergency illumination lamp and a battery for supplying power to the illumination lamp incorporated therein so that an emergency emergency lamp is generated when an earthquake of a predetermined level occurs. By turning on the illumination lamp, it may be possible to calm down and evacuate or take a required action in the event of a power failure at night.

In each of the above-described embodiments, the power supply is cut off when an earthquake of a predetermined seismic intensity level or higher occurs in both of the two power outlets, but only one of them is cut off and the other is continuously supplied with power. Alternatively, the other battery may continue to be energized by the built-in battery even when a power failure occurs. Thereby, the power supply may be cut off or continued depending on the type of load connected to the seismic sensing device with an outlet. Of course, the number of outlets is not limited to two.

FIG. 10 is an explanatory diagram of a system using the automatic notification device according to one embodiment of the present invention.

Like the conventional fire alarm device, the automatic alarm device 33 of this embodiment automatically dials the 119 address via the telephone line 34 when the 119 alarm button 40 is operated during a fire. It conveys the name accurately.

Furthermore, the automatic notification device 3 of this embodiment
3, a vibration-sensing device 35 of the present invention is connectable, and this vibration-sensing device 35 is basically the same as the above-described vibration-sensing device and detects vibrations of a predetermined level or higher. A built-in steel ball type vibration sensor and an output relay that operates based on the detection output of the vibration sensor are provided. By the operation of the output relay, the automatic notification device 33 causes the pre-registered emergency. It automatically dials the contact information, etc., and accurately conveys the address and name.
The basic operation of 3 is the same as that of the conventional fire alarm device.

According to the automatic notification device 33 of this embodiment, when an earthquake having a predetermined level, for example, a seismic intensity of 4 or more occurs, the registered contact information such as relatives or acquaintances is automatically dialed. The address, address and name will be transmitted accurately.

By installing the automatic notification device 33 of this embodiment on an important object such as a safe, vibrations of a predetermined level or higher other than an earthquake, for example, vibrations that try to destroy a safe with a hammer or the like are detected. However, the address and name can be accurately transmitted by automatically dialing the contact information registered in advance, for example, the security company, so that the security company can take appropriate measures.

As described above, in the event of an earthquake or theft, since the contact information registered in advance is automatically notified, it is possible to take immediate action and minimize damage. It is effective for elderly people living alone.

From the viewpoint of crime prevention, it is conceivable that the automatic notification device is installed at a front door, a door, a window, etc. to detect an abnormal vibration or impact and automatically notify.

In the above embodiment, the automatic notification device 33 is used.
Although the seismic sensing device 35 of the present invention is connected to the above, as another embodiment of the present invention, the automatic notification device may include a vibration sensor and an output relay.

[0072]

As described above, according to the seismic sensing device of the present invention, the output relay is a device whose power supply should be shut off in the event of an earthquake, or a device such as a generator or alarm that should be started in the event of an earthquake. By connecting the above, when the earthquake of a predetermined level or more occurs, the power of the required equipment is surely cut off, and the equipment which should be activated due to the occurrence of the earthquake is surely activated. Moreover, since the steel ball type vibration sensor is used, the cost can be reduced as compared with the capacitance type vibration sensor, and the vibration at any angle in the horizontal direction can be detected.

Further, according to the seismic-sensing device with an outlet of the present invention, when an earthquake of a predetermined level or more occurs, the electric path from the power supply side to the insertion port is shut off, so that the seismic-sensing device with the outlet has an insertion port. Energization to the load connected to is reliably cut off, and the cut-off state is maintained by the keep relay, so that undesired re-energization does not occur.

Further, according to the seismic sensing device with an outlet of the present invention, whether or not there is an earthquake is discriminated based on the detection output of the vibration sensor, and when there is an earthquake, the electric line is cut off. It is possible to prevent malfunction due to impacts other than the above.

Further, according to the automatic notification device of the present invention, when a vibration of a predetermined level or higher is generated, for example, when an earthquake or an abnormal vibration is generated, a predetermined contact is automatically notified via a telephone line. , You can take immediate action,
This can reduce damage such as an earthquake and theft.

[Brief description of drawings]

FIG. 1 is a perspective view of a seismic sensing device according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the seismic sensor of FIG.

FIG. 3 is a front view showing a part of the seismic sensing device of FIG. 1 in a cutaway manner.

FIG. 4 is a circuit configuration diagram of the seismic sensing device of FIG. 1.

FIG. 5 is a front view showing a part of a seismic sensing device according to another embodiment of the present invention by cutting away.

FIG. 6 is a side view of FIG. 5;

FIG. 7 is a circuit configuration diagram for explaining the operation of the seismic sensing device of FIG.

FIG. 8 is a front view showing a notch of a part of a seismic sensing device according to still another embodiment of the present invention.

9 is a side view of FIG.

FIG. 10 is an explanatory diagram of a system using the automatic notification device according to one embodiment of the present invention.

[Explanation of symbols]

1, 1 ₁ , 1 ₂ , 35 Seismic device 3 Primary side outlet terminal 7, 7 ₁ Vibration sensor 12 Reset switch 14 Secondary side outlet terminal 20 Keep relay 21, 21 'Power relay 23 Fuzzy chip 33 Automatic notification device

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Office reference number FI technical display location H01H 35/14 H01H 35/14 A

Claims (8)

[Claims] 1. A vibration-sensing device comprising a steel ball type vibration sensor for detecting a vibration of a predetermined level or higher, and an output relay which operates based on a detection output of the vibration sensor. 2. A vibration-sensing device with an outlet having an outlet, which is a steel ball type vibration sensor for detecting a vibration of a predetermined level or higher, and an electric circuit to the inlet based on a detection output of the vibration sensor. A seismic sensing device comprising: a shutoff relay for shutting off an electric shock. 3. A vibration-sensing device having an outlet having an outlet, a steel ball type vibration sensor for detecting vibration of a predetermined level or higher, and a keep relay operated based on a detection output of the vibration sensor. 3. A power relay that shuts off an electric path to the insertion port by the output of the keep relay, and holds the shut off state by the keep relay.
The described seismic device. 4. A vibration-sensing device with an outlet having an insertion port, wherein a steel ball type vibration sensor for detecting vibration of a predetermined level or higher, and whether or not there is an earthquake based on the detection output of the vibration sensor. A seismic vibration characterized by comprising a discrimination means for discriminating whether or not there is a discriminator, and a breaking relay for breaking the electric path to the outlet when the earthquake is equal to or higher than the predetermined level based on the output of the discrimination means. apparatus. 5. The seismic sensing apparatus according to claim 4, further comprising a battery that supplies power in the event of a power failure, and the determining means determines whether or not there is an earthquake by fuzzy reasoning. 6. The seismic sensing device according to claim 1, further comprising a plug-in type power input terminal. 7. The seismic sensing device according to claim 1, further comprising a reset operation unit that is operated to initialize the seismic sensing device. 8. An automatic notification device for automatically making a notification to a predetermined contact point via a telephone line, wherein the vibration-sensing device according to claim 1 is built in or connected to, and automatically notified by the operation of the output relay. An automatic notification device characterized by: