JP2020171173A - Electrical apparatus - Google Patents

Abstract

To provide an electrical apparatus capable of detecting the presence or absence of ground faults in a path for supplying power from a battery to an electrical load.SOLUTION: A voltage is detected on a path for supplying power to an electric load from a battery power supply provided in a detachable state by a user. When a detected voltage drop amount dEV drops by a predetermined threshold value or more, it is determined that a ground fault has occurred. In a case of a voltage drop due to exhaustion of the battery power supply, the voltage drops only slowly, so if it is detected that the amount of voltage drop is equal to or more than the threshold value, an occurrence of a ground fault can be detected.SELECTED DRAWING: Figure 3

Description

The present invention relates to an electric device having a battery power source and an electric load driven by electric power from the battery power source, and more particularly to a technique for detecting the presence or absence of a ground fault in the electric device.

Various electric devices such as gas appliances are equipped with a power supply for displaying various information to the user of the device, in addition to the power supply for operating the device and controlling the operation. There are many things. Various information for the user is generally displayed using a display unit such as a liquid crystal screen or LED, and the display unit such as a liquid crystal screen or LED can be sufficiently driven by using a battery. Therefore, batteries are widely used as a power source for display. Further, not limited to the display unit, when the power consumption of the electric load is small, a battery is widely used as a power source for driving the electric load.

However, if a battery is used as a power source for a load that consumes less power, such as a display unit, it will not be possible to drive the load such as the display unit when the battery is exhausted, which will hinder the user's use of the device. Will be. Therefore, there has been proposed a technique of detecting the voltage supplied to such a load and notifying that the battery is exhausted when the voltage drops (Patent Document 1). If the user who receives the notification replaces the exhausted battery with a new battery, the device can be used normally again.

JP-A-2017-139845

However, in the above-mentioned conventional technology, even if a ground fault occurs somewhere in the power supply circuit that supplies power from the battery to the electric load, the voltage supplied to the electric load decreases, so that the battery is exhausted. There was a problem that it was misjudged. When a ground fault occurs, the battery is consumed rapidly, so even if the user replaces the battery, the battery will be consumed immediately, causing a great deal of inconvenience to the user.

The present invention has been made to solve the above-mentioned problems of the prior art, and can detect the presence or absence of a ground fault in a power supply circuit that supplies power from a battery to an electric load. The purpose is to provide electrical equipment.

In order to solve the above-mentioned problems, the electric device of the present invention adopts the following configuration. That is,
In an electric device having a battery power source provided in a detachable state by a user, an electric load driven by power from the battery power source, and a power supply circuit for supplying power from the battery power source to the electric load. ,
A voltage detecting means for detecting a voltage supplied to the electric load by the power supply circuit, and
It is characterized by including a ground fault detecting means for detecting the occurrence of a ground fault in the power supply circuit by detecting that the voltage detected by the voltage detecting means has dropped by a predetermined threshold value or more.

In the electric device of the present invention, when it is detected that the voltage supplied from the battery power source to the electric load drops by a predetermined threshold value or more, it is determined that a ground fault has occurred. For example, in the case of consumption of the battery power supply, the voltage drops only slowly, so if the voltage drops sharply, it is considered that the voltage drop is due to a ground fault rather than consumption of the battery power supply. Therefore, if it is detected that the voltage has dropped by the threshold value or more, the occurrence of a ground fault can be detected. It is not always necessary to detect the voltage value as long as it can be detected that the amount of decrease in voltage is equal to or greater than the threshold value.

Further, in the above-mentioned electric device of the present invention, the voltage value of the voltage supplied to the electric load is detected at a predetermined cycle, and the amount of decrease in the voltage value within the predetermined time is larger than the predetermined threshold value. If this happens, it may be possible to detect the occurrence of a ground fault.

In this way, since the voltage value is detected at a predetermined cycle, it is possible to quickly detect the occurrence of a ground fault, and it is possible to promptly take appropriate measures for the user of the electrical equipment. Become.

Further, in the above-mentioned electric device of the present invention, the voltage value of the voltage supplied to the electric load is detected every time a predetermined detection condition is satisfied, and the voltage value detected last time is compared with this time. The occurrence of a ground fault may be detected when the detected voltage value drops by a predetermined threshold value or more.

In this way, it is possible to detect the occurrence of a ground fault even when the voltage value is not constantly detected.

Further, in the above-mentioned electric device of the present invention, even if the occurrence of a ground fault is detected, it is not immediately notified, but the following may be performed. First, the voltage value when the occurrence of a ground fault is detected is stored. Then, after the switch of the electric device is switched to the disconnected state in which the electric device is not supplied with power, the battery is again waited for the switch to be switched again to be in the connected state in which the power is supplied. Detects the voltage value supplied from the power supply to the electrical load. Then, when there is no large difference between the detected voltage value and the stored voltage value (when the difference between the voltage values is less than or equal to the predetermined value), the occurrence of a ground fault is notified. Is also good.

In this way, it is possible to reliably detect the occurrence of a ground fault.

Further, in the above-mentioned electric device of the present invention, the occurrence of a ground fault may be detected as follows. First, the voltage value is detected at a position closer to the electric load than the battery power supply and a position closer to the battery power supply than the electric load. Then, the load-side voltage value detected at a position closer to the electric load than the battery power supply is lower than the power supply-side voltage value detected at a position closer to the battery power supply than the electric load by a predetermined allowable voltage value or more. If this is the case, the occurrence of a ground fault may be detected.

Even in this way, it is possible to detect the occurrence of a ground fault.

It is a block diagram which showed the rough structure of the electric device 1 of this Example. It is a flowchart of the ground fault detection process which is mounted on the electric apparatus 1 of this Example, and is carried out by a control device 30 for detecting the occurrence of a ground fault. It is explanatory drawing of the mechanism which generates the ground fault in the electric apparatus 1 by detecting the voltage value. It is a block diagram which showed the rough structure of the electric device 1 of the modification.

FIG. 1 is a block diagram showing a rough structure of the electric device 1 of the present embodiment. As shown in FIG. 1A, the electric device 1 of this embodiment has a structure in which various devices are mounted inside the main body case 2, and these devices are batteries that can be replaced by a user. It operates on the electric power from the power source 10 or the electric power from the separate power source 20 provided separately from the battery power source 10. A storage portion 2a for storing the battery power supply 10 is formed on the side surface of the main body case 2. When the battery power supply 10 is exhausted, the user removes the consumed battery power supply 10 from the storage portion 2a to obtain a new battery. It can be easily replaced with the power supply 10.

Further, in the electric device 1 of the present embodiment, a battery power source that can be easily replaced by the user is also adopted as the separate power source 20, and in response to this, the separate power source 20 is placed on the side surface of the main body case 2. A storage portion 2b for storing the above is formed. As the separate power supply 20, a power supply device or the like that converts a commercial AC power supply to generate the target power may be used. In this case, since it is less necessary for the user to replace the separate power supply 20, the separate power supply 20 is mounted inside the main body case 2.

As described above, the electric device 1 is provided with the battery power source 10 and the separate power source 20, and in response to this, various devices mounted on the electric device 1 operate with the electric power from the battery power source 10. It is roughly divided into a device and a device that operates with the power from the separate power source 20. Since the specific device differs depending on the assumed electric device 1, the electric device 1 will be described below assuming that the electric device 1 is a gas stove. As is well known, a gas stove is a device that heats and cooks cooked food in a cooking container such as a pot by burning a mixed gas of fuel gas and combustion intake with a stove burner, but the gas stove uses electric power. Various devices that operate are installed.

First, the fuel gas to be burned together with the combustion air by the stove burner is supplied from the gas pipe, but if the mixed gas of the fuel gas and the combustion air is not burned by the stove burner, it is necessary to supply the fuel gas. There is no. Therefore, the gas pipe is equipped with a solenoid valve 22 (so-called main valve) that is closed when the mixed gas is not burned by the stove burner and opened when the mixed gas is burned. Further, on the downstream side (stove burner side) of the solenoid valve 22, a flow rate control valve 23 that controls the flow rate of fuel gas according to the thermal power set by the user is mounted. Furthermore, the control device 30 that controls the operation of the solenoid valve 22 and the flow control valve 23, the notification LED 24 that lights up when an abnormality occurs in the gas stove and notifies the user of the occurrence of the abnormality, and the mixed gas are ignited. It is also equipped with a spark plug (not shown) for this purpose.

The solenoid valve 22, the flow rate control valve 23, the control device 30, the notification LED 24, and the like are operated by the electric power supplied from the separate power source 20. Hereinafter, to be described with reference to FIG. 1A, the electric power from the separate power source 20 is supplied to the voltage regulator 21 via the toggle type power supply switch 3. The voltage regulator 21 converts the voltage value of the electric power supplied from the separate power supply 20 into a standard voltage value used in the solenoid valve 22, the flow rate control valve 23, the notification LED 24, the control device 30, and the like, and then electromagnetically. It is supplied to the valve 22, the flow rate control valve 23, the notification LED 24, the control device 30, and the like. The power switch 3 of this embodiment corresponds to the "switch" in the present invention.

The control device 30 is a so-called microcomputer mainly composed of a CPU, a memory, a capacitor, and the like, and the solenoid valve 22 switches to a valve open state or a valve closed state according to an output signal from the control device 30. In FIG. 1A, the output signal from the control device 30 is represented by a broken line arrow. Further, the flow rate control valve 23 controls the flow rate of the combustion gas by adjusting the valve opening degree according to the output signal from the control device 30. Further, as will be described later, when the control device 30 detects an abnormality (for example, the occurrence of a ground fault), the notification LED 24 is turned on by outputting an output signal from the control device 30.

Further, in today's gas stoves, the convenience of users can be improved by displaying various information using a display unit 12 such as a liquid crystal display device. Here, the power source for operating the display unit 12 is a power source different from the power source for operating the control device 30, the solenoid valve 22, the flow rate control valve 23, and the like (separate power supply 20 in this embodiment) (this embodiment). Then, it is supplied from the battery power source 10). The reason why the power source for operating the control device 30, the solenoid valve 22, the flow rate control valve 23, and the like and the power source for operating the display unit 12 are different power sources is that the control device 30, the solenoid valve 22, and the like are used. The gas stove cannot be used if the flow rate control valve 23 or the like does not operate, whereas even if the display unit 12 does not operate (as long as the control device 30, the solenoid valve 22, the flow rate control valve 23, etc. operate). ) This is because the gas stove can be used. Therefore, for the purpose of avoiding a situation in which the power source for operating the control device 30, the solenoid valve 22, and the like is consumed due to the consumption of electric power in the display unit 12, and the gas stove cannot be used, the display unit 12 is used. Power is supplied from the battery power source 10 (not from the separate power source 20). In this embodiment, since the device that operates with the electric power of the battery power source 10 is the display unit 12, the display unit 12 of this embodiment corresponds to the “electrical load” in the present invention.

As shown in FIG. 1A, the electric power from the battery power source 10 is supplied to the voltage regulator 11 via the electric wiring 13a, and is adjusted by the voltage regulator 11 to the standard voltage value of the display unit 12. After that, it is supplied to the display unit 12 via the electrical wiring 13b. The information displayed on the display unit 12 is supplied from the control device 30. Further, a semiconductor type open / close switch 14 is connected in the middle of the electric wiring 13b for returning electric power from the display unit 12 to the battery power source 10. When the user of the electric device 1 turns on the power switch 3, the control device 30 starts and turns on the open / close switch 14. Then, electric power is supplied from the battery power source 10 to the display unit 12, and various information is displayed on the display unit 12. After that, when the user turns off the power switch 3, the control device 30 turns off the open / close switch 14. As described above, the display unit 12 is supplied with power when the power switch 3 is turned on, and is not supplied with power when the power switch 3 is turned off.

In the electric device 1 as described above, the power source for operating the electric device 1 (separate power source 20 in this embodiment) and the display battery for displaying various information (battery power source 10 in this embodiment). And are provided separately, so that the electric device 1 can be operated even if the display battery is exhausted. Of course, when the display battery is exhausted, various information cannot be displayed, but if the user replaces the battery, various information can be displayed again. However, a ground fault (a phenomenon of short-circuiting to the ground potential) occurs somewhere in the path (in this embodiment, the electric wiring 13a, the voltage regulator 11 and the electric wiring 13b) that supplies power to the battery power supplies 10 to 12. Then, the power cannot be supplied to the display unit 12, and the display unit 12 does not display various information. Seeing this situation, even if the user thinks that the battery power supply 10 is exhausted and replaces it with a new battery power supply 10, not only the information cannot be displayed, but also the new battery power supply 10 is exhausted immediately. , Will cause a great deal of trouble to the user. Therefore, in order to avoid the occurrence of such a situation, the control device 30 of the electric device 1 of the present embodiment can detect the occurrence of a ground fault by detecting the voltage supplied from the battery power source 10 to the display unit 12. It is said.

FIG. 1B shows a rough internal structure of the control device 30. As described above, the control device 30 is mainly formed by a microcomputer, but focusing on the function of the control device 30 to detect the occurrence of a ground fault, the inside of the control device 30 includes the CPU 31, the voltage detection unit 32, and the like. , Memory 33, and the like. Here, the CPU 31 controls the operation of the entire gas stove by executing a preset program, and the processing described later for detecting the occurrence of a ground fault is also mainly executed by the CPU 31. ..

The voltage detection unit 32 detects the voltage supplied from the battery power supply 10 to the display unit 12. In the example shown in FIG. 1A, the voltage in the electric wiring 13a connecting the battery power supply 10 and the voltage regulator 11 is detected, but somewhere from the battery power supply 10 to the display unit 12. As long as the voltage can be detected, therefore, the voltage may be detected inside the voltage regulator 11 or may be detected by the electrical wiring 13b connecting the voltage regulator 11 and the display unit 12. In this embodiment, the path for supplying power from the battery power source 10 to the display unit 12 (that is, the electric wiring 13a, the voltage regulator 11 and the electric wiring 13b) corresponds to the "power supply circuit" in the present invention. Further, although the voltage detection unit 32 of this embodiment will be described as detecting the voltage value, it suffices as long as it can detect that the voltage has dropped sharply (that is, the amount of the voltage drop), and the voltage value is not necessarily used. It does not have to be detected.

The memory 33 is a memory in which the CPU 31 can read and write data, but the data is retained even when power is not supplied. In the control device 30, in addition to the memory 33, a memory called a read-only ROM in which a predetermined program or data is stored (not shown) and a memory called a RAM in which the CPU 31 temporarily stores data (not shown). Is omitted) is also installed. Further, the CPU 31 reads data from the outside into the control device 30, and outputs an output signal or data to the outside (solenoid valve 22, flow rate control valve 23, notification LED 24, display unit 12) or the like. An interface section (not shown) is also installed. The memory 33 of this embodiment corresponds to the "storage means" in the present invention.

FIG. 2 is a flowchart of a ground fault detection process carried out by the control device 30 of this embodiment in order to detect the occurrence of a ground fault. As shown in the figure, in the ground fault detection process, it is first determined whether or not the power switch 3 is turned on (STEP 10). As a result, if the power switch 3 is not turned on (STEP 10: no), the same determination is repeated to enter the standby state until the power switch 3 is turned on.

Then, when the power switch 3 is turned on (STEP10: yes), it is determined whether or not the ground fault flag is set to ON (STEP11). Here, the ground fault flag is a flag set in the memory 33 (see FIG. 1B) when the control device 30 detects the occurrence of a ground fault. The method of detecting the occurrence of a ground fault will be described in detail later. Since no ground fault has occurred in the normal state, the ground fault flag is set to OFF, so that it is determined to be "no" in STEP 11.

Subsequently, it is determined whether or not the voltage value detection condition is satisfied (STEP 15). The voltage value detection condition may be that a predetermined time (for example, 1 second) has elapsed, or a user performs a predetermined operation (for example, ignition or extinguishing of a stove burner) on the electric device 1. Various conditions can be set, such as being damaged.

As a result, if the voltage value detection condition is not satisfied (STEP15: no), the process returns to the beginning, and after determining whether or not the power switch 3 is ON (STEP10), the above-mentioned description is performed. Carry out a series of procedures. On the other hand, when the detection condition is satisfied (STEP15: yes), the voltage value in the electrical wiring 13a (see FIG. 1A) is detected (STEP16). The voltage value may be detected between the battery power supply 10 and the display unit 12, and may not be the electrical wiring 13a.

Then, when the voltage value is detected (STEP 16), it is determined whether or not the amount of decrease in the detected voltage value is equal to or greater than a predetermined threshold value (STEP 17). That is, in the ground fault detection process of this embodiment, the voltage value is detected every time a predetermined detection condition is satisfied. Therefore, if the detected voltage value is significantly lowered by a predetermined threshold value or more, that fact is detected. It can be easily detected.

FIG. 3 is an explanatory diagram illustrating how the detected voltage value changes. When the voltage value is detected every time a certain period of time elapses, continuous time series data of the voltage value can be obtained as illustrated in FIG. 3A. When the battery power source 10 is consumed, the voltage value tends to decrease, but the decrease in the voltage value is gradual and does not decrease sharply. Therefore, as illustrated in FIG. 3A, when the voltage value drops sharply and the drop amount dEV is larger than a predetermined threshold value, it can be considered that a ground fault has occurred.

Further, if the voltage value is detected every time some event (for example, ignition by the user or extinguishing the fire) occurs, the data as shown in FIG. 3B can be obtained. The white circles shown in FIG. 3B represent the voltage values detected each time the detection condition is satisfied. Even when the voltage value is detected irregularly in this way, it is possible to detect that the voltage value has dropped sharply. That is, in the example shown in FIG. 3B, the voltage value did not decrease when the voltage value was detected the fourth time, but the voltage value detected the fifth time was the voltage value detected before that ( The voltage value detected from the 1st to the 4th time) is greatly reduced. Therefore, when the amount of decrease in the voltage value dEV is larger than the predetermined threshold value, it is considered that the ground fault has occurred at any timing between the fourth detection and the fifth detection. Be done.

In STEP 17 of FIG. 2, it is determined as described above whether or not the amount of decrease in the voltage value is equal to or greater than a predetermined threshold value. As a result, if the amount of decrease in the voltage value is small and does not exceed the threshold value (STEP17: no), it can be determined that no ground fault has occurred. Therefore, the process returns to the beginning and the above-mentioned series of procedures is performed. To do. On the other hand, when the amount of decrease in the voltage value is equal to or greater than the threshold value (STEP17: yes), it is highly probable that a ground fault has occurred. Therefore, in this case, the voltage value when "yes" is determined in STEP 17 is stored in the memory 33 (see FIG. 1 (b)) as the ground fault voltage value (STEP 18). As described above, the memory 33 can retain the stored contents even when the power is not supplied.

In STEP 17 of this embodiment, it was determined that a ground fault had occurred when the voltage value dropped significantly (that is, when the amount of drop in the voltage value was equal to or greater than a predetermined threshold value) (STEP 17: yes). .. However, when the battery power source 10 of the electric device 1 (the battery for displaying the gas stove in this embodiment) is normally used, it can be considered that the voltage value is within a certain voltage range, so that the voltage value is The fact that the voltage has dropped significantly also means that the voltage has dropped to a voltage value that is not normally used. Therefore, in STEP 17, when the voltage value falls below a predetermined reference value, it may be determined that a ground fault has occurred.

Subsequently, the ground fault flag indicating that a ground fault has been detected is set to ON (STEP 19). As described above, the ground fault flag is also set in the memory 33. After that, it is determined whether or not the power switch 3 is turned off (STEP 20). Then, if the power switch 3 is not turned off (STEP20: no), the same determination is repeated to wait until the power switch 3 is turned off. As a result, when the power switch 3 is turned off (STEP 20: yes), the process returns to the beginning of the process again, and it is determined whether or not the power switch 3 is set to ON (STEP 10). Then, when the power switch 3 is turned on (STEP10: yes), it is determined whether or not the ground fault flag is set to ON (STEP11). As described above, when the voltage value is significantly lower than the threshold value (STEP17: yes), the ground fault flag is set to ON (STEP19), so that it is judged as "yes" in STEP11. Become.

Then, when the ground fault flag is set to ON (STEP 11: yes), the voltage value supplied from the battery power supply 10 to the display unit 12 is detected (STEP 12), and the ground fault stored in the memory 33 is detected. Compare with the voltage value (STEP 13). As a result, if the deviation between the detected voltage value and the ground fault voltage value is small and is less than or equal to the predetermined value (STEP13: yes), it is certain that a ground fault has occurred, so the notification LED 24 is turned on. After notifying the user of the occurrence of the ground fault (STEP 21), the ground fault detection process of FIG. 2 is terminated.

On the other hand, when the deviation between the voltage value detected in STEP 12 and the ground fault voltage value read from the memory 33 is larger than the predetermined value (STEP 13: no), no ground fault has actually occurred. it is conceivable that. For example, when the battery power supply 10 is slightly consumed, the voltage value may drop sharply if the power consumption of the display unit 12 suddenly increases for some reason. In such a case, the voltage value is restored by turning the power switch 3 off and then on again. Further, if the state in which the battery power source 10 is not used continues for a while, the battery power source 10 is restored, so that the voltage value is also restored accordingly. Therefore, even if the voltage value drops significantly (STEP17: yes), instead of immediately turning on the notification LED 24 to notify the occurrence of a ground fault, wait for the power switch 3 to be turned off (STEP20: yes). ), When the voltage value detected after the power switch 3 is turned on again has not recovered (STEP13: yes), the occurrence of the ground fault is reliably detected by determining that the ground fault has occurred. It becomes possible.

On the other hand, if it is determined as "no" in STEP 13, that is, if the voltage value detected after the power switch 3 is turned on again is recovered, it is considered that the ground fault has not actually occurred. The ground fault flag setting is returned to OFF, and the stored ground fault voltage value is initialized (STEP 14). Then, it is determined whether or not the voltage value detection condition is satisfied (STEP15), and if the detection condition is not satisfied (STEP15: no), the process returns to the beginning and the above-mentioned series of procedures is performed. .. On the other hand, if the detection condition is satisfied (STEP15: yes), after the voltage value is detected (STEP16), the following procedures described above are carried out. In this way, it is possible to avoid erroneous detection that a ground fault has occurred even though the ground fault has not occurred.

In the above-described embodiment, after the ground fault flag is set to ON (STEP 19), the user waits for the power switch 3 to be turned off (STEP 20), and after the power switch 3 is turned OFF. (STEP20: yes), and further, it has been described as waiting for the power switch 3 to be turned on by the user (STEP10). However, after setting the ground fault flag to ON (STEP19), the user is urged to turn the power switch 3 on again by outputting audio, turning on the lamp, and displaying an image. You may do so.

Further, in the above-described embodiment, the control device 30 has been described as detecting the voltage value at one location from the battery power supply 10 to the display unit 12. However, the voltage value may be detected at a plurality of points. FIG. 4 is a block diagram showing a rough internal structure of an electric device 1 of a modified example in which the control device 30 detects a voltage value at a plurality of locations. The electric device 1 of the modified example shown in FIG. 4 has a plurality of positions where the control device 30 detects the voltage value with respect to the electric device 1 of the present embodiment described with reference to FIG. 1 (two in the illustrated example). It differs in that it is increased in places), but the same is true for other points.

In the example shown in FIG. 4, the voltage value is detected at two points A and B on the electric wiring 13a. At any of the points A and B, the detected voltage value is the voltage value generated by the battery power supply 10, and no voltage difference occurs. However, when a ground fault occurs, a large current flows through the electrical wiring 13a, so the voltage value (voltage value on the power supply side) detected at point A on the side closer to the battery power supply 10 is B on the side closer to the display unit 12. It becomes higher than the voltage value detected at the point (load side voltage value). Therefore, a ground fault occurs when the voltage value detected at point A (power supply side voltage value) becomes larger than the predetermined allowable voltage value than the voltage value detected at point B (load side voltage value). You may judge that it was done.

Although the electrical equipment 1 of the present embodiment and the modified example has been described above, the present invention is not limited to the above-mentioned embodiment and the modified example, and can be implemented in various embodiments without departing from the gist thereof. Is.

1 ... Electrical equipment, 2 ... Main body case, 2a ... Storage section, 2b ... Storage section,
3 ... Power switch, 10 ... Battery power, 11 ... Voltage regulator,
12 ... Display, 13a ... Electrical wiring, 13b ... Electrical wiring,
14 ... Open / close switch, 20 ... Separate power supply, 21 ... Voltage regulator,
22 ... Solenoid valve, 23 ... Flow control valve, 24 ... Notification LED,
30 ... Control device, 31 ... CPU, 32 ... Voltage detector, 33 ... Memory.

Claims (5)

In an electric device having a battery power source provided in a detachable state by a user, an electric load driven by power from the battery power source, and a power supply circuit for supplying power from the battery power source to the electric load. ,
A voltage detecting means for detecting a voltage supplied to the electric load by the power supply circuit, and
An electric device including a ground fault detecting means for detecting the occurrence of a ground fault in the power supply circuit by detecting that the voltage detected by the voltage detecting means has dropped by a predetermined threshold value or more. In the electrical device according to claim 1,
The voltage detecting means detects the voltage value of the voltage supplied to the electric load at a predetermined cycle.
The ground fault detecting means is an electric device that detects the occurrence of the ground fault when the amount of decrease in the voltage value within a predetermined time becomes larger than the threshold value. In the electrical device according to claim 1,
The voltage detecting means detects the voltage value of the voltage supplied to the electric load every time a predetermined detection condition is satisfied.
The ground fault detecting means is characterized in that it detects the occurrence of the ground fault when the voltage value detected this time is lower than the threshold value with respect to the voltage value detected last time. machine. In the electric device according to claim 2 or 3.
A switch that switches between a connection state in which power is supplied to the electrical device and a disconnection state in which power is not supplied.
A storage means for storing the voltage value detected by the voltage detecting means when the occurrence of the ground fault is detected, and a storage means for storing the voltage value.
When the switch is switched from the disconnected state to the connected state after the occurrence of the ground fault is detected, the voltage value is detected by using the voltage detecting means, and the detected voltage value and the storage means are used. An electric device provided with a notification means for notifying the occurrence of an abnormality when the difference from the voltage value stored in is less than or equal to a predetermined value. In the electric device according to any one of claims 2 to 4.
The voltage detecting means can be used as the voltage value.
The load-side voltage value detected at a position closer to the electric load than the battery power supply on the power supply circuit,
On the power supply circuit, the voltage value on the power supply side detected at a position closer to the battery power supply than the electric load is detected.
The ground fault detecting means is characterized in that it detects the occurrence of the ground fault even when the load side voltage value is lower than the power supply side voltage value by a predetermined allowable voltage value or more. machine.

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