JP3887929B2 - Seismic breaker - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a seismic breaker which is attached to a distribution board and prevents commercial fire by cutting off the supply of commercial power when a sign of building collapse or an earthquake is detected.
[0002]
[Prior art]
A conventional seismic breaker will be described with reference to FIG. FIG. 10 is a schematic graph for explaining the seismic sensor output of the seismic breaker. (A) is an example of the seismic sensor output waveform when the seismic sensor is mounted horizontally, (b) Shows an example of an output waveform of the seismic sensor in a state where the seismic sensor is not horizontal and is attached with some inclination.
[0003]
The seismic breaker is attached to the distribution board. When a power failure is detected after the earthquake is detected, the power line connected to the outlet of the house is automatically opened at the relay contact. That is, the seismic breaker prevents the occurrence of an electric fire by cutting off the power supply to the load by preventing the power from the power source from being transmitted to the power line on the load side such as an electric heater in the house.
[0004]
Such a seismic breaker includes a seismic sensor such as an acceleration sensor that outputs a voltage corresponding to the inclination or shaking acceleration from the horizontal plane in order to detect a vibration such as an earthquake. The seismic breaker is a predetermined upper limit threshold X for the voltage output value of the seismic sensor. ₁ And lower threshold X ₂ Is remembered. For example, the seismic breaker has an upper threshold X ₁ And lower threshold X ₂ Abnormal vibrations such as earthquakes are detected based on the number of times that
[0005]
When the seismic sensor is mounted horizontally, it outputs a voltage based on the zero level voltage as shown in the output waveform example (a) of Fig. 10, but it is not horizontal and has some inclination. In this case, as shown in the output waveform example (b) of FIG. 10, the voltage is output with reference to the voltage level corresponding to the inclination at the time of attachment.
[0006]
[Problems to be solved by the invention]
However, in the conventional seismic breaker as described above, even if the seismic breaker is mounted horizontally on the distribution board, if the seismic sensor is not horizontal and has some inclination, The seismic sensor output some voltage value regardless of the occurrence of the earthquake. For this reason, if the output voltage value of the seismic sensor is used as it is, the seismic breaker may lose the reliability of the judgment processing result in the judgment processing for detecting earthquakes or signs of building collapse.
[0007]
The present invention has been made in order to solve the above-described problems, and the object of the present invention is to eliminate the erroneous output caused by the inclination of the mounting state, and to detect the earthquake detection and the sign of building collapse. Is to provide a seismic breaker that can maintain the reliability of
[0008]
[Means for Solving the Problems]
In the invention according to claim 1, the seismic breaker includes a seismic sensor that generates an output in accordance with an inclination or an acceleration of shaking from a horizontal plane, a threshold relating to an output from the seismic sensor, and the seismic sensor. In the seismic breaker that stops the power supply to the load based on the output of the seismic sensor exceeding the threshold value, comprising an arithmetic processing unit that determines the presence or absence of abnormal vibration based on the output of An operation unit for determining a reference level related to the output from the seismic sensor is provided, and when the arithmetic processing unit receives a signal indicating that an operation input has been made to the operation unit, the seismic sensor at that time Is set as the reference level.
[0009]
According to a second aspect of the present invention, in the seismic breaker according to the first aspect, the seismic breaker indicates that the inclination with respect to the horizontal plane is an inclination within a predetermined range including the horizontal plane. It has the 1st alerting | reporting means to alert | report based on, It is characterized by the above-mentioned.
[0010]
According to a third aspect of the present invention, there is provided the seismic breaker according to the first aspect, wherein the seismic breaker performs notification according to an inclination with respect to a horizontal plane based on an output of the seismic sensor. It has a reporting means.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the seismic breaker according to the present invention will be described with reference to FIGS. 1 to 4, a second embodiment will be described with reference to FIGS. 5 and 6, and a third embodiment will be illustrated. Each will be described in detail with reference to FIGS.
[0012]
[First Embodiment]
FIG. 1 is a circuit diagram showing a seismic breaker, and FIG. 2 is a perspective view showing the seismic breaker. 3 and 4 are flowcharts showing a procedure for correcting the tilt of the seismic sensor.
[0013]
Seismic breaker BK is sensor block B ₁ And trip circuit block B ₂ And discrimination circuit block B _Three And horizontal decision block B _Four And power circuit block B _Five And is configured.
[0014]
Sensor block B ₁ Is configured to include a seismic sensor 1, an amplifier 2, and a filter 3. The seismic sensor 1 is, for example, a semiconductor acceleration sensor, and outputs an analog voltage corresponding to the acceleration from tilt or shake from a horizontal plane. That is, the seismic sensor 1 outputs a larger voltage value as the acceleration from the horizontal plane or the acceleration of the shake increases. The amplifier 2 amplifies and outputs the voltage output of the seismic sensor 1. The filter 3 is a circuit unit that cuts a predetermined frequency or higher from the output value of the amplifier 2.
[0015]
Trip circuit block B ₂ Is configured to include a tripping circuit 4 and a release relay 5. The trip circuit 4 includes, for example, a semiconductor switching element, and is a circuit unit that performs drive control of the release relay 5, that is, control for opening the relay contact 5a. The release relay 5 has a single-phase three-wire power line L through its own relay contacts 5a, 5a and 5a. ₁ , L ₂ , L _Three It is a relay circuit that opens. The relay contacts 5a, 5a, and 5a are controlled to be closed when an operation handle SW described later is turned on. Also, single-phase three-wire power line L ₁ , L _Three Are provided with bimetallic overcurrent detection elements M and M attached thereto, and when an overcurrent flows, the bimetal overcurrent detection elements M are bent to forcibly open the relay contacts 5a.
[0016]
Discrimination circuit block B _Three Is configured to include an A / D conversion unit 6, a voltage detection unit 7, and an arithmetic processing unit 8. The A / D conversion unit 6 is a circuit unit that performs A / D conversion on the output value of the filter 3 and outputs the result. The voltage detection unit 7 is represented by, for example, a symbol L as illustrated in the single-phase three-wire power line. ₂ And L _Three A voltage detection circuit unit that detects a voltage value by connecting to a load side (secondary side) circuit as viewed from each relay contact 5a of the power line shown in FIG.
[0017]
The arithmetic processing unit 8 is an MPU, for example, and is connected to the A / D conversion unit 6, the voltage detection unit 7, and the trip circuit 4. The arithmetic processing unit 8 receives the output of the A / D conversion unit 6 and the detection voltage value of the voltage detection unit 7. The arithmetic processing unit 8 determines the upper limit threshold value X for the input value from the A / D conversion unit 6. ₁ And lower threshold X ₂ For example, the input value from the A / D converter 6 is the upper limit threshold value X. ₁ Or lower threshold X ₂ Based on the number of times and the period of exceeding, the occurrence of earthquakes and excessive inclination of buildings are determined using means such as fuzzy reasoning. If the arithmetic processing unit 8 determines that an earthquake has occurred or determines that the inclination of the building is excessive, the arithmetic processing unit 8 detects the occurrence of a power failure via the voltage detection unit 7. Only when the occurrence of a power failure is detected and then recovery from the power failure is detected, the arithmetic processing unit 8 controls the trip circuit 4 to open the relay contact 5a. In this way, when the arithmetic processing unit 8 detects the recovery from the power failure, the single-phase three-wire power line L ₁ , L ₂ , L _Three By preventing the power from being transmitted to the load-side circuit as viewed from each of the relay contacts 5a, the power supply to the load is cut off to prevent the occurrence of an electric fire.
[0018]
Horizontal fixed block B _Four Is configured to include an operation unit 9, a memory 10, and a confirmation display unit 11. The operation unit 9 is, for example, an operation button and is connected to the arithmetic processing unit 8 and is provided in an easy-to-handle part on the outer surface of the seismic breaker BK as shown in FIG. For example, if the operation unit 9 is kept pressed for a predetermined time of 3 seconds, the arithmetic processing unit 8 outputs the input value from the A / D conversion unit 6, that is, the A / D conversion voltage output of the seismic sensor 1. It is stored in the memory 10 as a reference level. Hereinafter, this reference level, that is, the A / D conversion voltage output of the A / D conversion unit 6 at this time is referred to as a correction value. That is, even if the analog voltage output of the seismic sensor 1 is not zero level, the arithmetic processing unit 8 sets the analog voltage output of the seismic sensor 1 at that time as a reference level for determining the occurrence of an earthquake or excessive building inclination. To do.
[0019]
The memory 10 is, for example, an EEPROM, and is connected to the arithmetic processing unit 8. In addition to the correction value, the memory 10 stores information indicating whether or not an earthquake occurrence has been detected within the past predetermined time. The confirmation display means 11 is, for example, an LED display circuit, which is connected to the arithmetic processing unit 8 and is an easy-to-handle part on the outer surface of the seismic breaker BK, as shown in FIG. A part is provided. When the correction value is confirmed by pressing the operation unit 9, the confirmation display unit 11 is controlled to be lit for several seconds by the arithmetic processing unit 8. That is, the confirmation display means 11 notifies the worker who pressed the operation unit 9 that the correction value has been confirmed by a lighting display.
[0020]
Power circuit block B _Five Is configured to include a DC power supply unit 12 and a backup circuit unit 13. The DC power supply unit 12 takes in AC power via the fuse FU from the power supply side (primary side) circuit instead of the load side as viewed from each relay contact 5a, converts it into DC, and converts the sensor block B ₁ And trip circuit block B ₂ And discrimination circuit block B _Three And horizontal decision block B _Four And supply DC power. The backup circuit unit 13 is connected to the DC power supply unit 12 so that the sensor block B is connected during a power failure. ₁ And trip circuit block B ₂ And discrimination circuit block B _Three And horizontal decision block B _Four And an auxiliary power circuit for supplying DC power.
[0021]
A procedure for correcting the tilt of the seismic sensor 1 in the seismic breaker BK configured as described above will be described below with reference to FIGS. 3 and 4.
[0022]
The seismic circuit breaker BK is attached to the distribution board to connect the DC power supply 12 to the power line L. ₂ , L _Three Are connected to the primary side of the power source, and power is supplied from the primary side (step 110). The voltage detector 7 starts secondary side voltage detection. When the operation handle SW is turned on, each relay contact 5a is closed and the power line L ₂ , L _Three The power source power is transmitted to the secondary side electric circuit (step 120).
[0023]
In this state, the seismic breaker BK is not necessarily mounted horizontally on the distribution board. In most cases, the seismic sensor 1 is not subjected to zero level output, but is subject to inclination or shaking acceleration from the horizontal plane. The corresponding analog voltage is output. Therefore, the worker corrects the inclination of the seismic sensor 1 as follows in order to correct the analog voltage output of the seismic sensor 1.
[0024]
When the operation unit 9 is kept pressed for a predetermined time, for example, 3 seconds (step 130), the arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 (step 140), and the correction value is The upper threshold value X until then ₁ Or lower threshold X ₂ It is determined whether or not this has been exceeded (step 150). That is, the arithmetic processing unit 8 determines whether or not the seismic sensor 1 outputs an output exceeding the threshold value of the tilt adjustment limit, that is, the seismic sensor 1 is slanted too horizontally. It is determined whether or not it is a case where it is attached. In step 150 above, the correction value is the upper threshold X ₁ Or lower threshold X ₂ If it has exceeded, the arithmetic processing unit 8 controls the trip circuit 4 to open the relay contact 5a and switch the operation handle SW off (step 160). That is, the seismic breaker BK switches its operation handle SW off to notify the worker that the mounting angle at which the seismic breaker BK is attached to the distribution board is off the horizontal. Show it. Here, the worker reattaches the tripped seismic breaker BK to the distribution board so as to be as horizontal as possible, and returns to step 120 to turn on the operation handle SW again.
[0025]
In step 150 above, the correction value is the upper threshold X ₁ And lower threshold X ₂ The calculation processing unit 8 determines the A / D conversion voltage output value of the A / D conversion unit 6 read in step 140 as a correction value, and displays the confirmation display unit 11. By lighting and displaying only for a predetermined time, the operator who pressed the operation unit 9 is notified that the correction value has been determined (step 170). At this time, the arithmetic processing unit 8 uses the upper threshold X ₁ And lower threshold X ₂ The level is also shifted according to the correction value. The arithmetic processing unit 8 records the correction value in the memory 10 (step 180).
[0026]
Thus, the inclination of the seismic sensor 1 has been corrected. In this seismic breaker BK, the arithmetic processing unit 8 receives the output of the A / D conversion unit 6 and the detection voltage value of the voltage detection unit 7, and means such as fuzzy inference for the occurrence of an earthquake and the excessive inclination of the building. (Step 190). If the arithmetic processing unit 8 determines that an earthquake has occurred, the arithmetic processing unit 8 stores information indicating that the occurrence of the earthquake has been detected in the memory 10 and detects the occurrence of a power outage via the voltage detection unit 7.
[0027]
If the arithmetic processing unit 8 determines that the inclination of the building is not excessive and an earthquake has occurred, the arithmetic processing unit 8 detects the occurrence of a power outage via the voltage detection unit 7. Only when the occurrence of a power failure is detected (step 200) and the recovery from a power failure is detected (step 210), the arithmetic processing unit 8 reads the memory 10 and detects whether an earthquake has occurred within the past predetermined time. Confirm. If the occurrence of the earthquake has been detected within the past predetermined time, the arithmetic processing unit 8 determines that the power failure has been restored after the occurrence of the earthquake, and controls the trip circuit 4 to open the relay contact 5a (step S1). 220). In addition, when the arithmetic processing unit 8 detects that the inclination of the building is excessive, it determines that there is a sign of the building collapse and controls the tripping circuit 4 to open the relay contact 5a (step 220). . In this way, the arithmetic processing unit 8 determines that the inclination of the building is excessive or detects a power failure recovery after the earthquake is detected, so that the single-phase three-wire power line L ₁ , L ₂ , L _Three By preventing the power source power from being transmitted to the load-side circuit as viewed from each relay contact 5a, the power supply to the load is cut off to prevent the occurrence of an electric fire.
[0028]
Accordingly, since the seismic breaker BK generates an output corresponding to the inclination or shaking acceleration from the horizontal plane, the operation unit 9 for determining the zero level with respect to the tilting or shaking acceleration from the horizontal plane is provided. The breaker BK can correct the inclination that occurs when it is attached to the attachment part, eliminates erroneous output that occurs due to the inclination of the attachment state, and can maintain the reliability of the judgment processing results for signs of earthquake detection and building collapse. .
[0029]
[Second Embodiment]
FIG. 5 is a perspective view showing the seismic breaker. FIG. 6 is a flowchart showing a procedure for correcting the tilt of the seismic sensor. In addition, the same code | symbol is attached | subjected to the location same as the above-mentioned 1st Embodiment, and detailed description of the same location is abbreviate | omitted.
[0030]
The seismic breaker of the second embodiment differs from the seismic breaker of the first embodiment described above in that the seismic sensor 1 is horizontal or substantially before the correction value is determined. It is the structure which provided the 1st alerting | reporting means 14 which lights only in the state where it is horizontal.
[0031]
The first notification means 14 is, for example, an LED display circuit similar to the confirmation display means 11, and is connected to the arithmetic processing unit 8 and is an easy-to-handle part on the outer surface of the seismic breaker BK as shown in FIG. Thus, a display part is provided near the display part of the confirmation display means 11 and the operation part 9.
[0032]
The arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 when the operation unit 9 is continuously pressed for a predetermined time of, for example, 3 seconds, and whether or not it is within a predetermined range near zero voltage. Determine whether. If the A / D conversion voltage output value of the A / D conversion unit 6 is within a predetermined range near the zero voltage, the arithmetic processing unit 8 controls the lighting of the first notification unit 14, and the A / D conversion unit 6. If the A / D conversion voltage output value does not fall within a predetermined range near zero voltage, the first notification means 14 is controlled to be turned off.
[0033]
In other words, the first notification means 14 notifies the operator who has pressed the operation unit 9 whether or not the seismic sensor 1 is leveled by the success or failure of the lighting display.
[0034]
A procedure for correcting the tilt of the seismic sensor 1 in the seismic breaker BK configured as described above will be described below with reference to FIG.
[0035]
The seismic circuit breaker BK is attached to the distribution board to connect the DC power supply 12 to the power line L. ₂ , L _Three Are connected to the primary side of the power source, and power is supplied from the primary side (step 110). The voltage detector 7 starts secondary side voltage detection. When the operation handle SW is turned on, each relay contact 5a is closed and the power line L ₂ , L _Three The power source power is transmitted to the secondary side electric circuit (step 120).
[0036]
In this state, the seismic breaker BK is not necessarily mounted horizontally on the distribution board, and the seismic sensor 1 is not a zero-level voltage output in most cases, but an inclination or shaking acceleration from a horizontal plane. The analog voltage output according to is performed. Therefore, the worker corrects the inclination of the seismic sensor 1 as follows in order to correct the analog voltage output of the seismic sensor 1.
[0037]
The arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 (step 140) when the operation unit 9 is kept pressed for a predetermined time, for example, 3 seconds (step 130), and the seismic sensor It is determined whether or not the inclination of 1 with respect to the horizontal plane falls within an inclination within a predetermined range including the horizontal plane (step 230).
[0038]
If the arithmetic processing unit 8 determines that the seismic sensor 1 is horizontal, the arithmetic processing unit 8 controls the lighting of the first notification unit 14 (step 240). Thus, the 1st alerting | reporting means 14 becomes a standard for attaching the seismic sensor 1 so that it may become nearly horizontal. When the operation unit 9 is pressed for a predetermined time after the above step 240, the arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 at that time, determines it as a correction value, and determines the memory 10 And the upper threshold X ₁ And lower threshold X ₂ The level is also shifted in accordance with the correction value (step 250). The arithmetic processing unit 8 controls the first notification unit 14 to turn off and displays the confirmation display unit 11 for a predetermined time (step 260), so that a correction value is given to the worker who pressed the operation unit 9. Notify that it has been confirmed.
[0039]
If it is determined in step 230 that the inclination of the seismic sensor 1 with respect to the horizontal plane does not fall within a predetermined range including the horizontal plane, the arithmetic processing unit 8 continues to turn off the first notification means 14. (Step 270). With this extinguished state, the worker can know that the mounting angle of the seismic breaker BK is not horizontal or substantially horizontal, and again while checking whether the first notification means 14 is lit, What is necessary is just to adjust the attachment angle of seismic breaker BK so that it may become horizontal. If the mounting angle of the seismic breaker BK is horizontal or very close to the horizontal, the first notification means 14 is turned on in steps after step 140.
[0040]
Therefore, since the seismic breaker BK has the first notification means 14 for notifying based on the output of the seismic sensor 1 that the tilt with respect to the horizontal plane is within a predetermined range including the horizontal plane, Since the inclination generated when the seismic breaker BK is attached to the attachment portion may be corrected while looking at the first notification means 14, the correction work can be facilitated as compared with the first embodiment. Moreover, since the seismic breaker BK can eliminate the erroneous output generated due to the inclination of the mounting state, it is possible to maintain the reliability of the determination processing result of the earthquake detection or the sign of the building collapse.
[0041]
In the above embodiment, the first notification unit 14 is exemplified as a display unit such as an LED. However, the present invention is not limited to this, and the first notification unit performs notification using a buzzer sound. It may be a thing, and the notification by a synthetic voice may be performed.
[0042]
[Third Embodiment]
FIG. 7 is a perspective view showing the seismic breaker. 8 and 9 are flowcharts showing a procedure for correcting the tilt of the seismic sensor. In addition, the same code | symbol is attached | subjected to the location same as the above-mentioned 2nd Embodiment, and detailed description of the same location is abbreviate | omitted.
[0043]
The seismic breaker of the third embodiment differs from the seismic breaker of the second embodiment described above in that the tilt of the seismic breaker BK from the horizontal plane is used instead of the first notification means. Or it is the structure which provided the 2nd alerting | reporting means 15 which expresses the acceleration of a shake with blinking speed in the seismic breaker.
[0044]
The second notification means 15 is, for example, an LED display circuit similar to the confirmation display means 11 and is connected to the arithmetic processing unit 8 and is an easy-to-handle part on the outer surface of the seismic breaker BK as shown in FIG. Thus, a display part is provided near the display part of the confirmation display means 11 and the operation part 9.
[0045]
The arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 and continues the A / D conversion of the A / D conversion unit 6 when the operation unit 9 is continuously pressed for a predetermined time of 3 seconds, for example. The second notification means 15 is mainly controlled to blink according to the magnitude of the voltage output value.
[0046]
That is, the second informing means 15 increases the blinking speed as the seismic sensor 1 approaches horizontal, and the seismic sensor 1 becomes horizontal, that is, the output voltage of the seismic sensor 1 is at a zero level. Then, it will be in a lighting state. In this way, the second notification means 15 notifies the worker who has pressed the operation unit 9 of the display of the inclination or the acceleration of the shaking from the horizontal plane by the blinking speed.
[0047]
A procedure for correcting the tilt of the seismic sensor 1 in the seismic breaker BK configured as described above will be described below with reference to FIGS.
[0048]
The seismic circuit breaker BK is attached to the distribution board to connect the DC power supply 12 to the power line L. ₂ , L _Three Are connected to the primary side of the power source, and power is supplied from the primary side (step 110). The voltage detector 7 starts secondary side voltage detection. When the operation handle SW is turned on, each relay contact 5a is closed and the power line L ₂ , L _Three The power source power is transmitted to the secondary side electric circuit (step 120).
[0049]
In this state, the seismic breaker BK is not necessarily mounted horizontally on the distribution board, and the seismic sensor 1 is not a zero-level voltage output in most cases, but an inclination or shaking acceleration from a horizontal plane. The analog voltage output according to is performed. Therefore, the worker corrects the inclination of the seismic sensor 1 as follows in order to correct the analog voltage output of the seismic sensor 1.
[0050]
The arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 (step 140) when the operation unit 9 is kept pressed for a predetermined time, for example, 3 seconds (step 130), and the seismic sensor It is determined whether or not the inclination of 1 with respect to the horizontal plane falls within an inclination within a predetermined range including the horizontal plane (step 230).
[0051]
If the arithmetic processing unit 8 determines that the seismic sensor 1 is horizontal or substantially horizontal, the arithmetic processing unit 8 controls the lighting of the second notification means 15 (step 240). Next, when the arithmetic processing unit 8 determines in step 230 that it is not horizontal or substantially horizontal, is the seismic sensor 1 tilted within a predetermined one-level tilt range that is greater than the tilt defined in step 230? It is determined whether or not (step 231). If the arithmetic processing unit 8 determines in step 231 that the seismic sensor 1 is tilted within a predetermined 1 level tilt range, the arithmetic processing unit 8 blinks the second notification means 15 (step 241). . If the arithmetic processing unit 8 determines in step 231 that the seismic sensor 1 is tilted beyond a predetermined 1 level inclination range, the arithmetic processing unit 8 further determines that the seismic sensor 1 is at the predetermined 1 level. It is discriminated whether or not it is tilted within a predetermined two-level tilt range that is greater than (step 232). In Step 232, when the arithmetic processing unit 8 determines that the seismic sensor 1 is tilted within the predetermined two-level tilt range, the arithmetic processing unit 8 causes the second notifying unit 15 to switch the second notifying unit 15 in Step 241. Blinks slower than the blinking speed (step 242). If it is determined in step 232 that the seismic sensor 1 is tilted beyond the predetermined two-level tilt range, the arithmetic processing unit 8 controls the second notification means 15 to turn off (step 270). With this light-off state, the operator can know that the mounting angle of the seismic breaker BK is far from the horizontal plane, and again feel whether the second notification means 15 is lit or not. What is necessary is just to adjust the attachment angle of breaker BK so that it may become horizontal. As the mounting angle of the seismic breaker BK becomes closer to the horizontal, the lighting speed of the second notifying unit 15 becomes faster in the steps after step 140, and when the seismic sensor 1 is just level, the second notifying unit 15 Light.
[0052]
Thus, the 2nd alerting | reporting means 15 becomes a standard for attaching so that the seismic sensor 1 may become near horizontal. When the operation unit 9 is pressed for a predetermined time after the above step 240, the arithmetic processing unit 8 reads the A / D conversion voltage output value of the A / D conversion unit 6 at that time, determines it as a correction value, and determines the memory 10 And the upper threshold X ₁ And lower threshold X ₂ The level is also shifted in accordance with the correction value (step 250). The arithmetic processing unit 8 controls the second notification unit 15 to be turned off, and displays the confirmation display unit 11 to be turned on for a predetermined time (step 260), so that the correction value is given to the worker who pressed the operation unit 9. Notify that it has been confirmed.
[0053]
Therefore, since the seismic breaker BK has the second notifying means 15 that performs notification according to the inclination with respect to the horizontal plane based on the output of the seismic sensor 1, the worker attaches the seismic breaker BK. The degree of correction of the inclination that occurs during attachment to the unit may be adjusted so that the second notification means 15 is finally turned on while the blinking speed of the second notification means 15 is increased. The correction work can be made easier than in the example.
[0054]
Moreover, since the seismic breaker BK can eliminate the erroneous output generated due to the inclination of the mounting state, it is possible to maintain the reliability of the determination processing result of the earthquake detection or the sign of the building collapse.
[0055]
In the above embodiment, the acceleration of the tilt or the swing from the horizontal plane is exemplified by the change of the blinking speed of the second notification means 15, but the present invention is not limited to this, and the acceleration from the horizontal plane is illustrated. The acceleration of inclination or shaking may be expressed as a change in brightness of the second notification means, or the second notification means may be composed of a plurality of primary color LEDs and expressed as a change in hue of the plurality of primary color LEDs. Good.
[0056]
In the above embodiment, the second notification means 15 is exemplified as a display means using an LED or the like. However, the present invention is not limited to this, and the second notification means is a buzzer. As a notification based on the timbre speed of the intermittent sound emitted from the sound, or as a change in the timbre emitted from this buzzer sound, it is also possible to notify the inclination or shaking acceleration from the horizontal plane. The generating means may be a means for notifying the inclination or shaking acceleration from the horizontal plane by the synthesized voice generated from the synthesized voice generating means.
[0057]
【The invention's effect】
In the invention according to claim 1, the seismic breaker is provided with an operation unit for determining a reference level related to the output from the seismic sensor, and the arithmetic processing unit has an operation input to the operation unit. Because the output of the seismic sensor at that time is set as a reference level when the signal is received, the seismic breaker can correct the tilt that occurs when it is attached to the mounting part and It is possible to eliminate the erroneous output caused by the inclination of the object and maintain the reliability of the judgment processing result of the detection of the earthquake or the sign of the collapse of the building.
[0058]
In the invention according to claim 2, in addition to the effect of the invention according to claim 1, the seismic breaker indicates that the inclination with respect to the horizontal plane is an inclination within a predetermined range including the horizontal plane. Therefore, the operator should correct the inclination generated when the seismic breaker is attached to the attachment portion with reference to the first notification means. This makes it easy to make corrections.
[0059]
In the invention according to claim 3, in addition to the effect of the invention according to claim 1, the seismic breaker performs second notification based on the inclination with respect to the horizontal plane based on the output of the seismic sensor. Since it has the notification means, the worker can know the degree of correction of the inclination that occurs when the seismic breaker is attached to the mounting portion, and if the correction is made with reference to the second notification means, Since it is good, the correction work can be made easier.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a seismic breaker according to a first embodiment of the present invention.
FIG. 2 is a perspective view showing the seismic breaker.
FIG. 3 is a flowchart showing a procedure for correcting the tilt of the seismic sensor.
FIG. 4 is a part of the flowchart of the above.
FIG. 5 is a perspective view showing a seismic breaker according to a second embodiment of the present invention.
FIG. 6 is a flowchart showing a procedure for correcting the tilt of the seismic sensor.
FIG. 7 is a perspective view showing a seismic breaker according to a third embodiment of the present invention.
FIG. 8 is a flowchart showing a procedure for correcting the tilt of the seismic sensor.
FIG. 9 is a part of the flowchart of the above.
FIG. 10 is a schematic graph for explaining the seismic sensor output of the above.
[Explanation of symbols]
1 Seismic sensor
8 Arithmetic processing part
9 Operation part
14 1st alerting | reporting means
15 Second notification means
BK seismic breaker
X ₁ , X ₂ Threshold

Claims (3)

A seismic sensor that generates an output according to the inclination or acceleration of shaking from a horizontal plane, and an arithmetic processing unit that determines the presence or absence of abnormal vibration based on the threshold value related to the output from the seismic sensor and the output of the seismic sensor An operation for determining a reference level related to the output from the seismic sensor in a seismic breaker that stops supplying power to the load based on the output of the seismic sensor exceeding the threshold value When the operation processing unit receives a signal indicating that there has been an operation input to the operation unit, the operation processing unit sets the output of the seismic sensor at that time as the reference level. A seismic breaker. The seismic breaker includes first informing means for informing, based on the output of the seismic sensor, that the inclination with respect to the horizontal plane is an inclination within a predetermined range including the horizontal plane. The seismic breaker according to claim 1. The seismic breaker according to claim 1, wherein the seismic breaker has second notifying means for notifying according to an inclination with respect to a horizontal plane based on an output of the seismic sensor.

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