JP2660461B2 - Abnormal state detection device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an abnormal state detecting device for detecting an abnormal state when abnormal overheating occurs, for example, in a power receiving and distribution facility (cubicle).

[0002]

2. Description of the Related Art In a power receiving and distribution facility in a building or a factory, power is received at a high voltage, the voltage is reduced to a low voltage, and the power is distributed to various loads such as a motor and lighting equipment. For this reason, if the load becomes excessive, an overcurrent flows in the main circuit conductive portion, and abnormal heating may occur. Therefore, by detecting and reporting such abnormal overheating, an accident caused by overheating is prevented beforehand.

FIG. 1 is a schematic structural view of a closed switchboard provided with an abnormal state detecting device. An upper main circuit conductive part 3A, 3A, 3A is arranged above the inside of the closed switchboard CUB, an arrester LA is arranged on one side, and below the arrester LA,
High-voltage transformer PT is installed. Below the high-voltage transformer PT, lower main circuit conductive parts 3B, 3B, 3B are arranged at an appropriate distance therefrom, and at the lowest position below the high-voltage transformer CB
Is arranged.

The upper main circuit conductive parts 3A, 3A, 3A are connected to a lightning arrester LA and a high voltage transformer PT, and are connected to the lower main circuit conductive parts 3B, 3B via a high voltage current transformer CT and a high voltage circuit breaker CB. , 3B. An odor generator 31 that generates an odor when a predetermined temperature is reached is attached to each of the upper main circuit conductive parts 3A, 3A, 3A and the lower main circuit conductive parts 3B, 3B, 3B.

[0005] An odor detector 32 for detecting an abnormal odor generated by the odor generator 31 is mounted on the ceiling of the closed switchboard. The signal indicating that the odor detector 32 has detected an abnormal odor is provided to the abnormality determiner 2 which determines an abnormality in an overheated state based on the detected abnormal odor.

FIG. 2 is a sectional view showing an attached state of the odor generator 31, and FIG. 3 is a front view thereof. For example, upper main circuit conductive part
The odor generator 31 is mounted at a position where the plate conductors 30A and 30B constituting 3A are connected by connecting bolts B. The odor generator 31 has a square-shaped shallow container 31a,
A mounting plate 31b having one end connected to the upper end of one side of 31a and the other end extending in a direction away from the container 31a.
Is filled in the container 31a and emits an offensive odor when a predetermined temperature is reached, and a plurality of narrow holes 31d attached to the opening of the container 31a so as to cover the opening. And a front plate 31e opened in parallel.

The other end of the mounting plate 31b is joined to the plate conductor 30B by connecting bolts B. In this way, the odor generator 31 is disposed close to the connection between the plate-shaped conductors 30A and 30B where heat is easily generated.

FIG. 4 is a block diagram showing the configuration of the abnormality determiner 2. The signal when the odor detector 32 detects an unusual odor is amplified by an amplifier.
Entered into 35. The output of the amplifier 35 is input to the rectifier 36, and the DC voltage output from the rectifier 36 is input to the comparator 38. The comparator 38 has a reference voltage setting device 37 for setting a reference voltage corresponding to the lowest voltage of the off-odor detection signal generated by the odor generator 31 when the main circuit conductive portions 3A and 3B reach a predetermined temperature.
Is input.

The comparator 38 compares the input DC voltage with the reference voltage, and outputs a signal when the DC voltage is large. This signal is supplied to the timer 39. A signal generated when the timer 39 measures a predetermined time is given to the relay 40. When the signal is given to the relay 40, the relay 40 closes the normally open contact 40a.

Next, the operation of the abnormal state detecting device using the odor generator 31 and the abnormality determiner 2 will be described. Now, for example, when an abnormal current flows in the upper main circuit conductive portions 3A, 3A, 3A, and abnormal overheating occurs, the odor generators 31, 31, 31 attached to them are heated. When the odor generators 31, 31, 31 reach a predetermined temperature, an odor is generated from the odorant filled in the container 31a, and the odor passes through the long holes 31d, 31d of the front plate 31e. Spreads in closed switchboards. Odor detector 32
Is detected, the odor detector 32 outputs a detection signal, and the detection signal is input to the abnormality determiner 2. The DC voltage amplified by the amplifier 35 and rectified by the rectifier 36 is compared with a comparator 38.
Enter

Then, the comparator compares the input DC voltage with the reference voltage input from reference voltage setting device 37, and if the input DC voltage is large, provides an output signal of comparator 38 to timer 39. . When an output signal from the comparator 38 is given, the timer 39 starts counting time. When a predetermined time is counted, the timer 39 generates a signal and gives it to the relay 40.

As a result, the relay 40 closes its normally open contact 40a and gives an abnormal signal to an alarm section (not shown) to notify that the main circuit conductive sections 3A, 3A, 3A are in an abnormal state of being overheated abnormally. I do. That is, when the odor detector 32 continuously detects an abnormal odor for a predetermined period of time, the abnormal state in the closed switchboard is notified.

[0013]

However, when an odor generator filled with an odorant and an odor detector for detecting an odor generated by the odorant are used, the odorant is deteriorated by long-term use. Therefore, there is a possibility that the odor generating power is reduced. Further, the odor detector may have a reduced detection sensitivity due to, for example, the surface for detecting an unusual odor being soiled. For this reason, a state in which an unusual odor can be detected with high sensitivity cannot be maintained for a long period of time, and replacement of odorous substances and inspection of the odor detector are required, and complicated maintenance is required. Further, the odor detector has a problem in that, in order to quickly detect the generated off-flavor, its mounting position is limited, and the arrangement position of the devices in the closed switchboard is restricted.

The present invention has been made in view of the above problems, and provides an abnormal state detecting apparatus which can maintain the detection sensitivity of an abnormal state with high sensitivity for a long period of time and does not limit the position for detecting a sound related to the abnormal state. The purpose is to do.

[0015]

An abnormal state detecting apparatus according to a first aspect of the present invention includes an abnormal state detecting apparatus for detecting an abnormal state of an electric device.
In the delivery device, a spring or an abnormal
A member that releases the accumulating force of the spring in association with the occurrence of a normal state,
And releasing a plurality of predetermined frequencies by releasing the accumulating force of the spring.
An alarm sound generator comprising a bell that generates an alarm sound including
A sound electric conversion unit for converting into an electric signal by detecting a sound and a sound of a plurality of predetermined frequency warning sound generator emits a filter for extracting only a plurality of predetermined frequency components from the electrical signal, a plurality of predetermined frequency Each of the components exceeds the standard value
With a and a timer for measuring the duration, the timer is Tokoro
Signals an abnormal state when a fixed time is counted
Characterized that you have a configuration that.

The abnormality detecting apparatus according to the second invention, electric
In an abnormal state detection device that detects an abnormal state of a device,
An alarm that emits an alarm sound of a predetermined frequency repeatedly at a predetermined cycle
And a sound generator, a sound electric conversion unit for converting into an electric signal by detecting a sound comprising a sound warning sound generator, a filter for extracting a predetermined frequency component of said electrical signal, the duration of the predetermined frequency component It comprises a first timer for measuring, and a second timer for measuring the time from when the predetermined frequency component is cut off, the first
Abnormal when the timer and the second timer measure the specified time
It is characterized in that it is configured to emit a signal to determine the state
And

[0017]

According to the first aspect of the present invention, the energy stored in the spring is released.
To ring the bell, and the bell emits a plurality of predetermined frequency sounds.
Is converted into an electrical signal, and multiple predetermined frequencies are referenced.
If any of the values exceed the standard value,
The timer is activated and the timer counts for a specified period of time.
By doing so, it is possible to ensure that
An abnormal state can be detected.

[0018] In the second aspect the predetermined frequency at a predetermined cycle
Sound from an audible alarm generator that repeats a number of audible alarms
The duration time and the pause time are counted by the first and second timers, respectively.
Occasionally, it can be accurately distinguished from noise,
A malfunction due to noise can be more reliably prevented.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the drawings showing the embodiments. FIG. 5 is a schematic configuration diagram of a closed switchboard, which is a power receiving and distribution facility including the abnormal state detection device according to the present invention. In the upper part of the closed switchboard CUB, the upper main circuit conductive part 3
A, 3A, and 3A are arranged, and an arrester LA is arranged on one side, and a high-voltage transformer PT is arranged below the arrester LA. Below the high-voltage transformer PT, the lower main circuit conductive parts 3B, 3B, 3B are arranged at an appropriate distance from it, and at the lowest position below it, a high-voltage circuit breaker CB is installed. doing.

A high-voltage transformer CT is arranged beside the high-voltage circuit breaker CB. The upper main circuit conductive parts 3A, 3A, 3A are connected to the surge arrester LA and the high voltage transformer PT, and are connected to the lower main circuit conductive parts 3B, 3B, 3B via the high voltage current transformer CT and the high voltage circuit breaker CB. It is connected. Each of the upper main circuit conductive parts 3A, 3A, 3A and the lower main circuit conductive parts 3B, 3B, 3B has an alarm sound generator 1 that emits an alarm sound when a predetermined temperature is reached.

An abnormality determiner 2 is provided beside the lower main circuit conductive parts 3B, 3B, 3B, and the sound receiving side is above the lower main circuit conductive parts 3B, 3B, 3B. A microphone 20, which is a sound-electric conversion unit directed in the side-by-side direction, is provided. This microphone
Numeral 20 receives an alarm sound generated by the alarm sound generators 1, 1, 1,.... The microphone 20 converts the received sound into an electric signal, and inputs the converted electric signal to the abnormality determiner 2 via the lead L.

FIG. 6 is a sectional view showing an attached state of the alarm sound generator 1, and FIG. 7 is a front view thereof. For example, the alarm sound generator 1 is mounted at a position where the plate-shaped conductors 30A and 30B forming the upper main circuit conductive portion 3A are connected by connecting bolts B.

The alarm sound generator 1 is provided with a bell flange 14 having a flat bottomed cylindrical shape, a spiral spring 9 and the like.
They are mounted on a bell mounting plate 17a of a bell mounting 17 having a substantially rhombic shape in a front view. The portion of the bell mounting 17 extending in the direction away from the bell flange 14 is an alarm sound generator mounting plate 17b. Then, the alarm sound generator 1 has a flat surface of the bell flange 14 facing the plate-shaped conductor 30A, and a bolt insertion hole (not shown) formed in the alarm sound generator mounting plate portion 17b. A connection bolt is inserted through a bolt hole (not shown) provided at a connection position between the conductors 30A and 30B, and a nut N screwed into the connection bolt is attached.

FIG. 8 is an exploded view showing the structure of the alarm sound generator 1. The bell attachment 17 has one side half in the longitudinal direction,
It is bent in a U-shape in side view so as to protrude in one side direction leaving a part of the end side, forming a bell mounting plate part 17a, and the other half part is an alarm sound generator mounting plate part. 17b, and a step is formed between the bell mounting plate 17a and the alarm sound generator mounting plate 17b.

A circular hole 17d having a cutout 17c in a part of the circumference is opened at the center of the bell mounting plate portion 17a, and a screw hole is provided near one side in the width direction of the bell mounting plate portion 17a. 17e. On the other hand, a bolt insertion hole 17f is opened substantially at the center of the alarm sound generator mounting plate 17b. A screw hole 17g is opened at the tip end side of the bell mounting plate portion 17a of the bell mounting member 17.

A bearing 7 is fixed to the inner peripheral end of the spiral spring 9. Above the spiral spring 9, one end is fixedly mounted on the bearing 7, and a spring winding operation arm 10 of an appropriate length dimension extending in the radial direction of the spiral spring 9 is provided. The component mounting plate 4 has a substantially equilateral triangular shape, and its outer dimensions are formed to be approximately the same as the outer diameter of the bell mounting plate portion 17a, and screw holes 4a, 4b, 4c are provided in each corner. Has been established.

On one side of the component mounting plate 4 is formed a bulged portion 4d whose side edge is bulged, and a side of the corner facing the bulged portion 4d is only a suitable length from the corner. A cutout portion 4e cut out in parallel with the edge is formed. Screw holes 4a, 4b, 4c
Shaft holes 4f, 4g, and 4h are provided nearer the gear holes, and gear shaft holes 4i and 4j and a support shaft hole 4k are provided between the screw holes 4a and 4b.

Further, a slightly larger diameter shaft hole is provided at the center of the component mounting plate 4.
A stopper 8 is provided between the shaft holes 4f and 4h on the upper surface of the component mounting plate 4 to protrude a stopper 8 for fixing the outer peripheral end of the spiral spring 9. The bimetals 15 and 16 that deform when reaching a predetermined temperature to be abnormal are formed in a strip shape, and the bimetal 15 is slightly longer than the bimetal 16, and each end is perpendicular to the longitudinal direction. And the tip is formed in a triangular shape.

The surface of the long portion of the bimetal 15 faces the component mounting plate 4, and the surface of the long portion of the bimetal 16 is orthogonal to the component mounting plate 4. And bimetal 16
Is provided near the outer edge of the bimetal 15, and the base ends of the bimetals 15, 16 are fixed to each other.

The gear mounting plate 18 is formed in a disk shape with a part of the outer peripheral edge being cut off, and the component mounting plate supporting shafts 18a, 18b, 18c are erected at positions on the upper surface of the gear mounting plate 18 arranged at equal intervals in the circumferential direction. Let me. At the center of the upper surface of the gear mounting plate 18, a first gear 5 having a gear shaft 6 mounted thereon is rotatably mounted, meshing with the first gear 5, and a second gear 11 having a gear shaft 11a mounted thereon. The third gear 12 meshed with the second gear 11 and having the gear shaft 12a mounted thereon.
And are rotatably mounted respectively.

The support shaft 13a is raised near the third gear 12, and
A hammer 13 whose tip swings with the support shaft 13a as a fulcrum is arranged. The hammer 13 can be swung with the rotation of the third gear 12. The bell flange 14 is formed in a flat cylindrical shape with a bottom, and a part of the peripheral side surface is formed with a protruding portion 14a slightly protruding inward.

[0032] Now, if these components assemble the warning sound generator, by inserting the screws b ₁ in screw holes which are opened to the proximal end of the screw hole 4c and the bimetal 15 and 16 of the component mounting plate 4 , it by screwing the nut n _1, and a state of protruding downward the tip of the bimetal 15 from the notch portion 4e, attached to the component mounting plate 4 in the state in which to position the bimetal 15 above the bimetal 16 .

Next, the gear shaft 6 is inserted into the shaft hole 41 and the gear mounting plate
The support shafts 18a, 18b, 18c and the gear shafts 11a,
12a and the support shaft 13a are inserted through the shaft holes 4f, 4g, 4h, the gear shaft holes 4i, 4j, and the support hole 4k of the component mounting plate 4, and are not shown on the inserted support shafts 18a, 18b, 18c. The nut is screwed in, and the gear mounting plate 18 is mounted on the component mounting plate 4. When assembled in this manner, the tip of the bimetal 15 is engaged with the tip of the hammer 13 to prevent the hammer 13 from swinging.

Next, the bearing 7 is attached to the gear shaft 6 through which the shaft hole 41 is inserted.
And a spiral spring 9 is disposed on the component mounting plate 4,
The outer peripheral end of the spiral spring 9 is fixed to the stopper 8. Since the sectional shapes of the gear shaft 6 and the bearing 7 are rectangular, the gear shaft 6 does not run idle with respect to the bearing 7.

Next, a bell is mounted on the screw hole 4a of the component mounting plate 4.
Face the screw holes 17g of the tool 17 and insert them into the screw holes 4a and 17g.
Screw b_TwoThrough. Screw holes in the bell mounting plate 17a
17e to screw b_ThreeAnd the screw b_ThreeSpace
After externally fitting the holding cylinder 19, screw b _ThreeWith the screws of the component mounting plate 4.
Insert through hole 4b. Then screw b_Two, B_ThreeTo nut
n_Two, N_ThreeAre screwed to the component mounting plate 4 to attach the bell
Assemble. Thereby, the component mounting plate 4 and the bell mounting plate portion
A space holding cylinder 19 is interposed between the space 17a and the space 17a.
To support the operation of the spiral spring 9 and the bimetals 15, 16.
A state in which no trouble occurs is obtained.

The spring winding operation arm 10 has a circular hole 17d.
Located within. Next, the tip of the hammer 13 and the bell flange 14
The gear mounting plate 18 is slightly dropped into the bell flange 14 and the bell flange 14 is mounted on the gear mounting plate 18 by an appropriate method to complete the assembly.

Next, the operation of the alarm sound generator 1 thus assembled will be described. Now, the spiral spring 9 can be charged by rotating the spring winding operation arm 10. If the bimetals 15 and 16 do not reach the abnormal temperature in the energy storage state, the bimetals 15 and 16 are not deformed.
The movement of the bimetal 16 is prevented by the bimetal 15, the swinging motion of the hammer 13 is prevented by the bimetal 16, and the spiral spring 9 maintains a state of accumulation.

By the way, the bimetals 15 and 16 are deformed when they reach an abnormal temperature.
When deformed away from the side edge of 15, the bimetal 15
Is released from the locked state, and the tip of the bimetal 15 curves upward. Thereby, the hammer 13 is released from the locked state by the bimetal 15.

Then, the swinging motion of the hammer 13 becomes possible, and the first force is stored by the stored power of the spiral spring 9.
The gear 5 is rotated, followed by a second gear 11 and a third gear
When the third gear 12 is rotated, the hammer 13 is driven to swing the head. Thereby hammer
13 strikes the projection 14a of the bell flange 14 to generate an alarm sound. The alarm sound continues until the stored force of the spiral spring 9 disappears and the rotation of each of the gears 5, 11, 12 stops. Then, when the energy stored in the spiral spring 9 has disappeared, the spiral spring 9 can be stored again by rotating the spring winding operation arm 10 again.

FIG. 9 shows the frequency characteristics of the alarm sound generated by the alarm sound generator. In FIG. 9, the horizontal axis represents frequency, and the vertical axis represents sound pressure. As is apparent from FIG. 9, the alarm sound has a remarkably high sound pressure at 3.6 kHz, 8.1 kHz and 12.5 kHz.

FIG. 10 is a block diagram showing the configuration of the abnormality determiner 2. The electric signal output from the microphone 20 (see FIG. 5) is input to the amplifier 21. amplifier
The output voltage of 21 is input to a band-pass filter 22a that passes a frequency component of 3.6 kHz, a band-pass filter 22b that passes a frequency component of 8.1 kHz, and a band-pass filter 22c that passes a frequency component of 12.5 kHz.

The output voltages of the band-pass filters 22a, 22b, 22c are individually input to rectifiers 23a, 23b, 23c. The DC voltage rectified by the rectifiers 23a, 23b, and 23c is output by a comparator.
24a, 24b, 24c are individually input. Comparators 24a, 24b, 24c
From the reference voltage setting unit 25 that sets the reference voltage corresponding to the lowest sound pressure level of each of the 3.6 kHz, 8.1 kHz, and 12.5 kHz alarm sounds, the frequency is changed to 3.6 kHz, 8.1 kHz, and 12.5 kHz. The corresponding reference voltages are individually input to the comparators 24a, 24b, 24c.

The signals output from the comparators 24a, 24b, 24c are AND
The signal is input to the circuit 26a, and the output signal is supplied to the timer 27a. A signal generated when the timer 27a measures a predetermined time is given to the relay 29. The relay 29 closes its normally open contact 29a when a signal is applied.

Next, an abnormal state detecting device including the microphone 20, the alarm sound generator 1 and the abnormality judging device 2 is closed.
The following describes the abnormal state detection operation when a CUB is installed. Thus, the alarm sound generator 1 is connected to the main circuit conductive part 3A or 3B.
, The spiral spring 9 is charged.
Now, if the load is appropriate and proper current flows through the upper main circuit conductive parts 3A, 3A, 3A and the lower main circuit conductive parts 3B, 3B, 3B, the respective main circuit conductive parts 3A, 3A , 3A, 3B, 3B, 3B are not overheated, whereby the bimetals 15, 16 in any of the alarm sound generators 1 are not deformed, the hammer 13 is held in a locked state, and the spiral spring 9 is charged. Hold state.

By the way, when the load increases and the overload occurs, an overcurrent flows through the main circuit conductive portions 3A, 3A, 3A, 3B, 3B, 3B. Then, for example, when the connection between the plate-shaped conductors 30A and 30B in the upper main circuit conductive portion 3A overheats and reaches an abnormal temperature, the abnormal temperature causes the bimetal 15, 15 16 are deformed together. Thereby, the bimetal 16 first separates from the bimetal 15 to release the bimetal 15 from the locked state.

Further, the bimetal 15 separates from the hammer 13 and releases the hammer 13 from the locked state. Then, the first gear 5 is driven by the energy stored in the spiral spring 9, and the second and third gears are driven.
The gears 11 and 12 are rotated, and the hammer 13 is driven.
Then, the hammer 13 swings and strikes the bell flange 14 to emit an alarm sound. Microphone 20
Receives sound and converts it into an electric signal. Then, the converted electric signal is input to the abnormality determiner 2 via the lead wire L.

The abnormality determiner 2 amplifies the input electric signal by the amplifier 21 and sets the amplified output voltage of the amplifier 21 at 3.6 kHz.
Rectifiers 23a, 23b, 23c for z, 8.1kHz, 12.5kHz frequency components
And rectify them separately. Then, the rectified DC voltage of each frequency component is input to each of the comparators 24a, 24b, 24c. The comparators 24a, 24b, and 24c individually compare the reference voltage provided from the reference voltage setting device 25 with the DC voltage of each frequency component, and output a signal when the input DC voltage is higher than the reference voltage. Output and input to AND circuit 26a.

That is, a frequency component at which the sound pressure of the alarm sound generated by the alarm sound generator 1 is extremely high is detected. When the frequency components of 3.6 kHz, 8.1 kHz, and 12.5 kHz are detected together, a signal is supplied from the AND circuit 26a to the timer 27a. This signal causes the timer 27a to start timing. That is, it measures the time during which the alarm sound with a high sound pressure continues.
Then, when a predetermined time is counted, a signal is issued assuming that the main circuit conductive portion is in an abnormal state, and the signal is given to the relay 29. Then, the normally open contact 29a of the relay 29 is closed to output a signal determined as an abnormal state.

A signal indicating that the normally open contact 29a is closed is given to a not-shown notifying unit or a cut-off control unit of the high-voltage circuit breaker CB so that an abnormal condition can be notified to draw attention or a current to the load can be obtained. This will prevent the accident from spreading due to overcurrent. Then, when the normal state is restored after the abnormal state has been detected, the spring winding operation arm 10 of the activated alarm sound generator 1 is operated to accumulate the spiral spring 9 again, and the next alarm is generated. Be prepared for sound. Further, the timer 27a of the abnormality determiner 2 is reset,
Be prepared for the next timing operation.

FIG. 11 is a block diagram showing the configuration of another embodiment of the abnormality determiner 2. Each output voltage of the comparators 24a, 24b, 24c is input to an AND circuit 26b. The output signal of the AND circuit 26b is supplied to a timer 27b as a second timer. Timer
The signal generated when 27b times the specified time is an AND circuit
Input to one input terminal of 28. To the other input terminal of the AND circuit 28, a signal from the timer 27a, which is the first timer, is input.

The other components are the same as those of the abnormality determiner 2 shown in FIG. 10, and the same components are denoted by the same reference numerals. This abnormality determiner 2 is suitable when the alarm sound generator 1 repeatedly emits an alarm sound at a predetermined cycle. Now, when the alarm sound generator 1 periodically emits an alarm sound, the microphone 20 receives the alarm sound, inputs the converted electric signal to the abnormality determiner 2, and the timer 27a issues an alarm in the same manner as described above. When the sound continues, a signal is issued when a predetermined time, that is, one cycle of the alarm sound, is counted.

On the other hand, when the alarm sound is generated periodically, when the alarm sound is interrupted, the output voltages of the comparators 24a, 24b, 24c disappear, and the AND circuit 26b outputs a signal, whereby the timer 27b is activated. Start timing. That is, the timer 27b measures the time of one cycle in which the alarm sound is not emitted, and when the counting is completed, generates a signal and inputs it to the AND circuit 28. As a result, the time of one cycle during which the alarm sound is generated is timed. On the other hand, when the time of one cycle of the alarm sound pause time is ended from the time when the alarm sound is interrupted, the output signal of the AND circuit 28 is relayed.
The signal is supplied to the power supply 29 and the normally open contact 29a is closed to detect an abnormal state.

Therefore, if the output of the AND circuit 26b is extinguished if the time corresponding to one pause period of the alarm sound has not been reached, the timer 27b is reset, and no signal is issued from the timer 27b. Can be clearly distinguished from other confusing sounds in which the alarm sound pauses at the same cycle as the alarm sound, preventing false alarm sound detection and detecting abnormal conditions with high accuracy be able to.

In this embodiment, the abnormal state due to overheating is
The case where the alarm sound generated by the alarm sound generator is detected to detect the abnormal state has been described. However, even when the alarm sound is not detected, that is, a sound such as a partial discharge generated from the electric device may be detected. A similar effect can be obtained. Further, the use of the abnormal state detecting device is not limited to the closed type switchboard. Further, the filter frequency of each bandpass filter is not limited to 3.6 kHz, 8.1 kHz, and 12.5 kHz.

[0055]

According to the first aspect of the invention, the accumulating force of the spring is used.
Because the alarm sound generator used is used, special control
No need for power supply, simple configuration, reliable operation,
In addition, a plurality of predetermined frequencies are detected, and the level thereof is set to a reference value.
If it exceeds, the timer operates, and the timer counts the predetermined time.
In some cases, it is determined that the state is abnormal.
It does not malfunction even with various types of noise and can increase reliability
You. According to the second invention, an alarm sound which operates periodically is provided.
Using a living creature, the ringing time and the pause time
Accurate discrimination with noise by measuring with timer 2
The present invention has an excellent effect that it can be performed and the reliability can be further improved .

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a closed switchboard provided with a conventional abnormal state detection device.

FIG. 2 is a sectional view of an attached state of an odor generator.

FIG. 3 is a front view of an attached state of the odor generator.

FIG. 4 is a block diagram showing a configuration of a conventional abnormality determiner.

FIG. 5 is a schematic configuration diagram of a closed switchboard provided with the abnormal state detection device according to the present invention.

FIG. 6 is a cross-sectional view of the alarm sound generator in an attached state.

FIG. 7 is a front view of an attached state of the alarm sound generator.

FIG. 8 is an exploded view of the alarm sound generator.

FIG. 9 is a characteristic diagram illustrating a frequency characteristic of an alarm sound generated by the alarm sound generator.

FIG. 10 is a block diagram showing a configuration of an abnormality determiner used in the abnormal state detection device according to the present invention.

FIG. 11 is a block diagram showing a configuration of another embodiment of the abnormality determiner used in the abnormal state detection device according to the present invention.

[Explanation of symbols]

 1 Alarm sound generator 2 Abnormality judging device 3A, 3B Main circuit conductive part 9 Spiral spring 10 Spring operation arm 13 Hammer 14 Bell flange 15,16 Bimetal 22a, 22b, 22c Band pass filter 23a, 23b, 23c Rectifier 24a, 24b , 24c Comparator 26a AND circuit 27a, 27b Timer 28 AND circuit 29 Relay

Continuation of the front page (56) References JP-A-1-320478 (JP, A) JP-A-4-91618 (JP, A) JP-A-61-56537 (JP, U) JP-A-62-29725 (JP) , U)

Claims (2)

(57) [Claims] 1. An abnormal state detecting device for detecting an abnormal state of an electric device, wherein a spring which is normally kept in a charged state,
A part that releases the accumulating force of the spring in connection with the occurrence of an abnormal condition
Material and a plurality of predetermined frequencies due to release of the accumulating force of the spring.
Alarm sound generator with a bell that generates an alarm sound including a number
And a plurality of predetermined frequency sounds generated by the alarm sound generator.
A sound electric conversion unit for converting into an electric signal by detecting a silence, a filter for extracting only a plurality of predetermined frequency components from the <br/> electrical signals, any of a plurality of predetermined frequency components of the reference value Yue
Obtain the a timer for measuring the duration, the timer abnormality detecting device, characterized in that it is constituted to emit determining signal an abnormal state when measuring a predetermined time. 2. An abnormal state detecting device for detecting an abnormal state of an electric device, wherein an alarm sound of a predetermined frequency is repeated at a predetermined cycle.
The alarm sound generator that returns and emits the sound
A sound electric conversion unit for converting into an electric signal by detecting a silence, a filter for extracting a predetermined frequency component of the <br/> electrical signal, a first timer for measuring the duration of the predetermined frequency component, a predetermined A second timer for measuring the time from when the frequency component is interrupted, wherein a signal for determining an abnormal state is issued when the first timer and the second timer have measured a predetermined time. Abnormal state detection device.