JP6272135B2 - Power consumption system, leakage detection method, and program - Google Patents

Description

  The present invention relates to a power consumption system including a load device and a power supply device, a leakage detection method, and a program.

  2. Description of the Related Art Currently, a power consumption system is known that includes a load device that consumes supplied power, and a power supply device that is supplied with AC power from an AC power source and supplies power to the load device. As such a power consumption system, for example, a lighting device that consumes supplied DC power, a power conversion device that converts AC power supplied from an AC power source into DC power, and supplies DC power to the lighting device, There is a lighting system comprising: In addition, as such a power consumption system, for example, an outdoor unit that consumes supplied AC power and an AC power supplied from an AC power source are supplied to the outdoor unit. There is an air conditioning system including an indoor unit.

  In such a power consumption system, abnormalities such as electric leakage and poor contact may occur due to aging degradation and other factors. Currently, various techniques for detecting such an abnormality are known. For example, in Patent Document 1, an inrush current flowing in an LED (Light Emitting Diode) lighting terminal is detected immediately after the start of DC power supply, and the difference between the initial value of the inrush current and the current measured value is a predetermined reference value. A power distribution system that determines that an LED lighting terminal has deteriorated when it falls below is disclosed. The power distribution system disclosed in Patent Literature 1 is a system that detects an abnormality that occurs in an LED lighting terminal that is a load device.

JP 2012-008139 A

  However, the abnormality that occurs in the power consumption system is not limited to the abnormality that occurs in the load device. For example, leakage may occur on a path for supplying power from the power supply device to the load device. On the other hand, in the power distribution system disclosed in Patent Document 1, it is not possible to detect a leakage occurring on a path for supplying power from the power supply device to the load device. For this reason, there is a demand for a power consumption system that can detect a leakage occurring on a path for supplying power from the power supply device to the load device.

  The present invention has been made in view of the above problem, and includes a power consumption system, a leakage detection method, and a program capable of detecting a leakage occurring on a path for supplying power from a power supply device to a load device. The purpose is to provide.

In order to achieve the above object, a power consumption system according to the present invention includes:
The DC power is supplied to the load device via a load device that consumes the supplied DC power, and a first power supply line and a first reference line provided in parallel with the first power supply line, and a second power supply. A power supply device in which AC power is supplied from an AC power supply via a line and a second reference line provided in parallel with the second power supply line, wherein the AC power supplied from the AC power supply is converted to the DC power. A power consumption system comprising: a power conversion means for converting and supplying the DC power to the load device, and comprising a power conversion means that is a capacitor input type full-wave rectification power supply circuit comprising a capacitor. ,
First current value measuring means for measuring a current value of a current flowing through the first power supply line;
First leakage detection means for detecting a leakage generated between the first power line and the first reference line based on the current value measured by the first current value measurement means;
Second current value measuring means for measuring a current value of a current flowing through the second power supply line;
Based on the current value measured by the second current value measuring means, a current flowing through the second power line due to an abnormal current flowing through the capacitor and detected regardless of the period of the AC power supply is detected. And a second leakage detection means for detecting a leakage generated in the power conversion means.

In the present invention, based on the current value of the current flowing in the first power supply line, leakage occurring between the first power supply line and the first reference line is detected, based on a current value of current flowing in the second power supply line And generated by the power conversion means by detecting the current flowing through the second power supply line due to the abnormal current flowing through the capacitor provided in the power conversion means provided in the power supply device and flowing independently of the cycle of the AC power supply. leakage to the Ru is detected. Therefore, according to the present invention, it is possible to appropriately detect a leakage occurring on a path for supplying power from the power supply device to the load device.

It is a block diagram of the power consumption system which concerns on Embodiment 1 of this invention. It is a block diagram of an AC / DC converter. It is a block diagram of a control part. It is a figure for demonstrating the function of the power consumption system which concerns on Embodiment 1 of this invention. (A) is a figure which shows the voltage applied between L1-N1. (B) is a figure which shows the load current which flows into L1. (C) is a figure which shows the abnormal current which flows into L1. (D) is a figure which shows the electric current which flows into L1. (A) is a figure which shows the electric current which flows into L2 at the time of normal. (B) is a figure which shows the electric current which flows into L2 at the time of abnormality. It is a block diagram of the power consumption system which concerns on Embodiment 2 of this invention. It is a figure for demonstrating the function of the power consumption system which concerns on Embodiment 2 of this invention. It is a figure which shows the electric current which flows into L3 at the time of abnormality. (A) is a figure which shows the voltage applied between L3-N3 in the normal time. (B) is a figure which shows the voltage applied between L3-N3 at the time of abnormality.

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

(Embodiment 1)
First, the power consumption system 1000 according to Embodiment 1 of the present invention will be described. The power consumption system 1000 includes a load device that consumes the supplied power, and a power supply device that appropriately converts the AC power supplied from the AC power supply 300 and supplies the AC power to the load device. The load device and the power supply device are separated from each other and are connected to each other by a cable or the like. In the present embodiment, as illustrated in FIG. 1, the power consumption system 1000 is an illumination system including an illumination device 100 that is a load device and an illumination power source 200 that is a power supply device.

  Here, the power consumption system 1000 has a function of detecting abnormalities occurring in various places inside the system. Such an abnormality is, for example, an abnormality such as electric leakage or poor contact caused by various factors such as aging. Typically, such an abnormality occurs, for example, in a contact portion between an outlet and a plug to which a high AC voltage is applied or in a power supply apparatus to which a high DC voltage is applied. Such leakage includes leakage due to the tracking phenomenon. The tracking phenomenon is a phenomenon in which dust accumulated between power supply lines or the like becomes wet and becomes conductive, the dust is carbonized over time, and the carbonized portion is short-circuited to ignite. The power consumption system 1000 is a system suitable for detecting such an abnormality as early as possible and preventing an accident such as a fire. Note that the power consumption system 1000 can identify an approximate location where such an abnormality has occurred.

  The lighting device 100 is a device that consumes DC power supplied from the lighting power source 200 to illuminate. The lighting device 100 includes a terminal block 110 and an LED (Light Emitting Diode) 120.

  The terminal block 110 is a terminal block to which one end of a cable connecting the lighting device 100 and the lighting power source 200 is connected. This cable is a cable for supplying electric power from the illumination power supply 200 to the illumination device 100, and is configured by covering the power supply line L1 and the reference line N1 with an insulator. Therefore, the power supply line L1 and the reference line N1 are insulated in the cable. The power supply line L1 is an electric wire to which a power supply potential required by the lighting device 100 is applied. The reference line N1 is an electric wire to which a potential serving as a reference for the power supply potential is applied, and is typically an electric wire to which a ground potential is applied. The terminal block 110 includes a power supply terminal to which one end of the power supply line L1 is connected, and a reference terminal to which one end of the reference line N1 is connected.

  The LED 120 is a diode that emits light having an intensity corresponding to a current value of a current flowing from the anode toward the cathode. The LED 120 emits light by electric power supplied via a cable connected to the terminal block 110. FIG. 1 shows an example in which the lighting device 100 includes only one LED 120 for easy understanding. The lighting device 100 can include a large number of LEDs 120 connected in series, in parallel, or in series-parallel between a power supply terminal included in the terminal block 110 and a reference terminal.

  The resistor 130 is a virtual resistor that exists between the power supply line L1 and the reference line N1. The resistance value of the resistor 130 is a value close to infinity in the initial state, but it drastically decreases as the insulation covering the power supply line L1 and the reference line N1 progresses. The current flowing through the resistor 130 is appropriately referred to as an abnormal current.

  The lighting power source 200 converts the AC power supplied from the AC power source 300 into DC power, and supplies the DC power to the lighting device 100. The illumination power source 200 includes a terminal block 210, a plug 220, an AC / DC (Alternate Current / Direct Current) converter 230, a control unit 240, current sensors 251, 252 and voltage sensors 253, 254, 255, 256. With.

  The terminal block 210 is a terminal block to which the other end of the cable connecting the lighting device 100 and the lighting power source 200 is connected. The terminal block 210 includes a power supply terminal to which the other end of the power supply line L1 is connected and a reference terminal to which the other end of the reference line N1 is connected. Therefore, the power supply terminal of the terminal block 210 is connected to the power supply terminal of the terminal block 110 via the power supply line L1. Further, the reference terminal of the terminal block 210 is connected to the reference terminal of the terminal block 110 via the reference line N1.

  The plug 220 is a plug that is inserted into an outlet 310 connected to the AC power supply 300 and receives AC power supplied from the AC power supply 300. The plug 220 includes a power supply terminal and a reference terminal. In a state where the plug 220 is plugged into the outlet 310, the L-phase potential is applied to the power supply terminal provided in the plug 220, and the N-phase potential is applied to the reference terminal provided in the plug 220.

  The AC / DC converter 230 converts AC power supplied from the AC power supply 300 via the plug 220 into DC power. The AC / DC converter 230 supplies the direct-current power obtained by the conversion to the lighting device 100 via the terminal block 210. Hereinafter, the configuration of the AC / DC converter 230 will be described with reference to FIG. As shown in FIG. 2, the AC / DC converter 230 includes a varistor 231, a capacitor 232, a diode bridge 233, a coil 234, a capacitor 235, a resistor 236, and a DC / DC (Direct Current / Direct Current) converter 237.

  The varistor 231 is an electronic component that has a high electrical resistance when the voltage between both terminals is low and a low electrical resistance when the voltage between both terminals is high. The varistor 231 has one end connected to the L phase of the AC power supply 300 and the other end connected to the N phase of the AC power supply 300.

  The capacitor 232 is an electronic component that charges or discharges electric charge according to a voltage applied between both terminals. Capacitor 232 has one end connected to the L phase of AC power supply 300 and the other end connected to the N phase of AC power supply 300. The varistor 231 and the capacitor 232 function as a protection circuit.

  The diode bridge 233 is an electronic circuit that converts an AC voltage applied between input terminals into a DC voltage and applies the output voltage between output terminals. The diode bridge 233 has one input terminal connected to the L phase of the AC power supply 300 and the other input terminal connected to the N phase of the AC power supply 300. The diode bridge 233 includes, for example, a diode connected in a bridge shape.

  The coil 234 is a passive element that can store energy in a magnetic field formed by a current flowing between both ends. One end of the coil 234 is connected to the + side output terminal of the diode bridge 233.

  The capacitor 235 is an electronic component that charges or discharges electric charge according to a voltage applied between both terminals. One end of the capacitor 235 is connected to the other end of the coil 234. The other end of the capacitor 235 is connected to the negative output terminal of the diode bridge 233. The capacitor 232 smoothes the voltage between the output terminals of the diode bridge 233.

  The resistor 236 is a passive element that limits a current flowing between both ends. One end of the resistor 236 is connected to the other end of the coil 234. The other end of the resistor 236 is connected to the negative output terminal of the diode bridge 233.

  The DC / DC converter 237 is a circuit that converts a DC voltage applied between input terminals and applies it between output terminals. One input terminal of the DC / DC converter 237 is connected to the other end of the coil 234. The other input terminal of the DC / DC converter 237 is connected to the negative output terminal of the diode bridge 233. One output terminal of the DC / DC converter 237 is connected to the power supply line L <b> 1 via a power supply terminal provided in the terminal block 210. The other output terminal of the DC / DC converter 237 is connected to the reference line N1 through a reference terminal provided in the terminal block 210. That is, the DC / DC converter 237 is a circuit that converts the voltage value of DC power. Note that when the input voltage is higher than the output voltage, the DC / DC converter 237 steps down the input voltage to generate the output voltage. On the other hand, when the input voltage is lower than the output voltage, the DC / DC converter 237 boosts the input voltage to generate an output voltage. In this case, the DC / DC converter 237 may include a boosting inverter and an AC / DC converter.

  The controller 240 controls the operation of the illumination power supply 200 as a whole. Typically, the control unit 240 detects the occurrence of an abnormality such as electric leakage or poor contact, and when the occurrence of the abnormality is detected, notifies the fact that the abnormality has occurred or stops the power supply. The control unit 240 detects the occurrence of an abnormality based on information supplied from the current sensors 251 and 252 and the voltage sensors 253, 254, 255, and 256.

  The current sensor 251 detects the current value of the current flowing through the power supply line L2, and outputs information indicating the detected current value to the control unit 240. The current sensor 252 detects the current value of the current flowing through the power supply line L1, and outputs information indicating the detected current value to the control unit 240. For example, the current sensors 251 and 252 may be current transformers or shunt resistors.

  The voltage sensor 253 detects the voltage value (potential) of the voltage of the power supply line L2, and outputs information indicating the detected voltage value to the control unit 240. The voltage sensor 254 detects the voltage value (potential) of the voltage of the reference line N2, and outputs information indicating the detected voltage value to the control unit 240. The voltage sensor 255 detects the voltage value (potential) of the voltage of the power supply line L1, and outputs information indicating the detected voltage value to the control unit 240. The voltage sensor 256 detects the voltage value (potential) of the voltage of the reference line N1, and outputs information indicating the detected voltage value to the control unit 240.

  Next, the physical configuration of the control unit 240 will be described with reference to FIG. As shown in FIG. 3, the control unit 240 includes a CPU (Central Processing Unit) 11, a ROM (Read Only Memory) 12, a RAM (Random Access Memory) 13, a flash memory 14, an RTC (Real Time Clock) 15, and a touch screen. 16, a sensor interface 17, an external device interface 18, and a home telecommunications network interface 19. The components included in the control unit 240 are connected to each other via a bus.

  The CPU 11 controls the overall operation of the control unit 240. The CPU 11 operates according to a program stored in the ROM 12 and uses the RAM 13 as a work area. The ROM 12 stores programs and data for controlling the overall operation of the control unit 240. The RAM 13 functions as a work area for the CPU 11. That is, the CPU 11 temporarily writes programs and data in the RAM 13 and refers to these programs and data as appropriate.

  The flash memory 14 is a nonvolatile memory that stores various types of information. For example, the flash memory 14 stores information supplied from the current sensors 251 and 252 and the voltage sensors 253, 254, 255, and 256.

  The RTC 15 is a time measuring device. The RTC 15 incorporates a battery, for example, and continues timing while the power of the control unit 240 is off. The RTC 15 includes an oscillation circuit including a crystal oscillator, for example.

  The touch screen 16 detects a touch operation performed by the user and supplies a signal indicating the detection result to the CPU 11. The touch screen 16 displays an image based on the image signal supplied from the CPU 11 or the like. As described above, the touch screen 16 functions as a user interface of the control unit 240.

  The sensor interface 17 is an interface for receiving information supplied from the current sensors 251 and 252 and the voltage sensors 253, 254, 255 and 256. The sensor interface 17 includes a buffer memory that stores information (current value or voltage value) acquired every predetermined period (sampling period) for a predetermined period. This buffer memory is a loop buffer and stores information for the most recent predetermined period. The sensor interface 17 can supply information stored in the buffer memory to the CPU 11, RAM 13, flash memory 14, etc. automatically or in accordance with an instruction from the CPU 11. Note that the sampling period (for example, 50 μSec) is sufficiently shorter than the period of the AC power supply 300 (for example, 20 mSec).

  The external device interface 18 is an interface for connecting the control unit 240 to an external device such as an alarm device or a breaker (not shown). The external device interface 18 can control the external device according to the control by the CPU 11. The external device interface 18 is, for example, a LAN interface for connecting to a wireless LAN such as a wired LAN (Local Area Network), Wi-Fi (Wireless Fidelity), specific low power radio, or RS (Recommended-Standards)- 232C, RS-485, USB (Universal Serial Bus), IEEE (Institute of Electrical and Electronic Engineers) 1394 and other interfaces for serial communication. The external device interface 18 may have a function of communicating with the lighting device 100.

  The home telecommunication network interface 19 is an interface for connecting the control unit 240 to a home telecommunication network (not shown). The home telecommunications network interface 19 includes a LAN interface such as a NIC (Network Interface Card).

  The AC power supply 300 is an AC power supply that supplies AC power to the power consumption system 1000. The AC power supply 300 is, for example, a voltage having an effective value of 100 V and a frequency of 50 Hz (or 60 Hz).

  The outlet 310 is an outlet for supplying AC power from the AC power source 300 to the power consumption system 1000. The outlet 310 includes a power supply terminal and a reference terminal. The power supply terminal provided in the outlet 310 is connected to the L phase of the AC power supply 300 through the power supply line L2. Further, the reference terminal provided in the outlet 310 is connected to the N phase of the AC power supply 300 via the reference line N2. When the plug 220 is inserted into the outlet 310, the power terminal provided in the outlet 310 is connected to the power terminal provided in the plug 220, and the reference terminal provided in the outlet 310 is connected to the reference terminal provided in the plug 220. .

  Next, basic functions of the power consumption system 1000 will be described with reference to FIG. Functionally, the power consumption system 1000 includes a load device 400 and a power supply device 500. Here, the load device 400 consumes the supplied power. On the other hand, the power supply device 500 supplies power to the load device 400 via the first power supply line and the first reference line, and AC power is supplied from the AC power supply 300 via the second power supply line and the second reference line. Is done. The load device 400 is, for example, the lighting device 100. The power supply device 500 is, for example, an illumination power supply 200. The first power supply line, the first reference line, the second power supply line, and the second reference line are, for example, the power supply line L1, the reference line N1, the power supply line L2, and the reference line N2, respectively. Here, the power consumption system 1000 functionally includes a first current value measurement unit 101 and a first leakage detection unit 102.

  The first current value measuring unit 101 measures the current value of the current flowing through the first power supply line. The first current value measuring unit 101 includes, for example, a current sensor 252.

  The first leakage detection unit 102 detects a leakage generated between the first power supply line and the first reference line based on the current value measured by the first current value measurement unit 101. The first leakage detection unit 102 includes, for example, a CPU 11.

  Here, the load device 400 may be a device that consumes DC power. In this case, the power supply device 500 may include the power conversion unit 103. The power conversion unit 103 converts AC power supplied from the AC power supply 300 via the second power supply line and the second reference line into DC power, and loads the load device via the first power supply line and the first reference line. DC power is supplied to 400. The power conversion unit 103 includes, for example, an AC / DC converter 230.

  The power consumption system 1000 may further include a second current value measurement unit 104 and a second leakage detection unit 105. The second current value measuring unit 104 measures the current value of the current flowing through the second power supply line. The second current value measuring unit 104 includes, for example, a current sensor 251. The second leakage detection unit 105 detects a leakage generated in the power conversion unit 103 based on the current value measured by the second current value measurement unit 104. The second leakage detection unit 105 includes, for example, a CPU 11.

  Here, the second leakage detection unit 105 determines whether or not the degree of coincidence of the current value waveforms for each cycle of the AC power supply 300 based on the current value measured by the second current value measuring unit 104 is equal to or less than a threshold value. be able to. For example, if the second leakage detection unit 105 determines that the degree of coincidence is equal to or less than a threshold value, it determines that a leakage has occurred.

  Further, the second leakage detection unit 105 can determine whether or not the high-frequency component of the current value measured by the second current value measurement unit 104 is equal to or greater than a threshold value. For example, when the second leakage detection unit 105 determines that the high-frequency component is equal to or greater than the threshold value, the second leakage detection unit 105 determines that a leakage has occurred.

  Further, the first leakage detection unit 102 can detect that the high-frequency component of the current value measured by the first current value measurement unit 101 is equal to or greater than a threshold value. For example, if the first leakage detection unit 102 determines that the high-frequency component is greater than or equal to a threshold value, the first leakage detection unit 102 determines that a leakage has occurred.

  Next, the operation of the power consumption system 1000 will be described.

  The illumination power supply 200 converts AC power supplied from the AC power supply 300 via the power supply line L2 and the reference line N2 into DC power having a voltage value suitable for the illumination device 100 to use. Specifically, first, the illumination power source 200 rectifies the supplied AC power to generate DC power having a voltage value of about several tens of volts. The lighting power supply 200 boosts this DC power by an inverter or the like to generate AC power having a voltage value of about several hundred volts. Furthermore, the illumination power source 200 rectifies the acquired AC power to generate DC power having a voltage value of about several hundred volts (for example, 300 V). Here, the illumination power supply 200 supplies the generated DC power to the illumination device 100 via the power supply line L1 and the reference line N1. On the other hand, the lighting device 100 consumes the supplied DC power and illuminates it.

  Here, while the power consumption system 1000 is operating, there is a possibility that deterioration occurs in various parts. For example, a cable covering the power supply line L1 and the reference line N1 may be significantly deteriorated before the end of its useful life depending on the surrounding environment. For example, when the temperature and humidity change abruptly, when the temperature and humidity are extremely high (or low), or when moisture, oil, or chemical substances are present, insulation that covers the power line L1 or the reference line N1 There is a high possibility of deterioration. When a high DC voltage is applied between the power supply line L1 and the reference line N1 in such a state where deterioration is severe, a leakage current may flow from the power supply line L1 to the reference line N1 and the like. If such a leakage current continues to flow, the temperature of the insulator rises, the carbonization of the insulator proceeds, and the power supply line L1 and the reference line N1 may be short-circuited to generate a spark.

  Moreover, the contact part in the terminal block 110 or the terminal block 210 also deteriorates with the passage of time depending on the surrounding environment. Therefore, a contact failure or a short circuit may occur at a contact portion in the terminal block 110 or the terminal block 210. Note that when contact failure occurs, the supply of power may be stopped. In addition, there is a possibility of ignition due to a short circuit or tracking phenomenon.

  Hereinafter, a method for detecting leakage occurring in the power supply line L1 and the reference line N1 will be described.

  FIG. 5A shows a state in which the voltage applied between the power supply line L1 and the reference line N1 changes gently with time. Since this voltage is a direct current voltage generated by the AC / DC converter 230, basically, the alternating current component is hardly included.

  FIG. 5B shows a state in which the load current flowing through the power supply line L1 changes gently with time as the voltage applied between the power supply line L1 and the reference line N1 changes. ing. Note that the load current is a current that flows from the illumination power supply 200 to the illumination device 100 via the power supply line L1. Here, the lighting device 100 has a characteristic that the impedance hardly changes. Therefore, basically, the load current contains almost no AC component, like the voltage applied between the power supply line L1 and the reference line N1. Note that an AC component may be included in the load current due to external noise or residual noise included in the DC voltage generated by the AC / DC converter 230.

  FIG. 5C shows a state in which deterioration between the power supply line L1 and the reference line N1 has progressed, and an abnormal current flowing through the power supply line L1 has occurred after the time indicated by t1. The abnormal current is not a normal current (load current) that flows from the power supply line L1 to the lighting device 100, but is an abnormal current that flows from the power supply line L1 to the reference line N1 due to deterioration of the covering. The abnormal current is intermittently generated after the stage where the deterioration of the coating has progressed to some extent. The abnormal current is a pulsed current having a level close to a short-circuit current. Insulation deterioration proceeds by short-circuiting between the wires, generating sparks, forming a carbonization path, and further carbonization by ignition and incineration.

  FIG. 5D shows a state where an abnormal current is included in the current (detected current) flowing through the power supply line L1. The detected current is a current detected when a current flowing through the power supply line L1 is detected by the current sensor 252. As shown in FIG. 5 (D), the load current shown in FIG. 5 (B) superimposed with the abnormal current shown in FIG. 5 (C) is detected as the detected current. Here, the load current is a current containing almost no AC component, but the abnormal current is a current containing an AC component. Therefore, the detected current contains almost no AC component until an abnormal current occurs, and contains an AC component after the abnormal current occurs. For this reason, it is possible to determine whether or not there is a leakage between the power supply line L1 and the reference line N1 based on the detected current.

  For example, the CPU 11 samples the current value of the current flowing through the power supply line L1 at a frequency sufficiently higher than the frequency of the AC power supply 300 (for example, about several kHz to several tens kHz), and detects the current value of the detected current for several cycles. Are stored in the flash memory 14 or the like (hereinafter referred to as “current value waveform” as appropriate). Then, the CPU 11 can analyze the current value waveform stored in the flash memory 14 or the like to determine whether or not the AC component included in the detected current is equal to or greater than a threshold value. For example, the CPU 11 can perform a discrete fast Fourier transform process on the current value waveform, and can determine that a leakage has occurred when a frequency component equal to or higher than a predetermined frequency is a ratio equal to or higher than a threshold value. . Or CPU11 can discriminate | determine that the electrical leakage has generate | occur | produced, when a low frequency cutoff filter process is performed with respect to an electric current value waveform and the component after a process is more than a threshold value.

  In addition, CPU11 can stop supply of electric power, when it determines with the electric leakage having generate | occur | produced. Thereby, it can be expected to suppress a dangerous situation such as ignition due to leakage current. Moreover, CPU11 can alert | report that it has leaked from the power supply line L1 with the stop of supply of electric power. For example, the CPU 11 can display a message on the touch screen 16 that there is a leakage from the power line L1. In addition, the CPU 11 outputs a sound indicating that there is a leakage from the power supply line L1 to a speaker (not shown) or leaks from the power supply line L1 via the external device interface 18 or the home telecommunications network interface 19. The message may be displayed on a display device (not shown).

  Here, also in the AC / DC converter 230, a leakage current may flow due to deterioration. Hereinafter, a method for detecting a leakage occurring inside the AC / DC converter 230 will be described.

  First, it is assumed that the AC / DC converter 230 is a capacitor input type full-wave rectification power supply circuit. In this case, when there is no deterioration in the power supply circuit, as shown in FIG. 6A, the diode bridge 233 is near the peak of the AC voltage (voltage applied between the power supply line L2 and the reference line N2) as shown in FIG. Only during the period when the internal diode is conductive, current flows through the power supply line L2. In FIGS. 6A and 6B, the current value of the current flowing through the power supply line L2 is indicated by a solid line, and the voltage value of the AC voltage is indicated by a broken line. The conduction angle depends on the magnitude of the load current.

  Here, it is assumed that an electrolyte leak or the like occurs due to deterioration of the capacitor 235, and an abnormal current flows through the capacitor 235. In this case, as shown in FIG. 6B, a current flows irregularly through the power supply line L2 regardless of the period of the AC voltage. The reason is that the capacitor 235 is disposed at the subsequent stage of the rectifier circuit, and a DC voltage that is smoothed to some extent is applied to both ends. That is, abnormal current tends to flow when a high voltage is applied to the abnormal location, but when the voltage applied to the abnormal location is a DC voltage, the time when the abnormal current tends to flow is not determined.

  Note that the method of determining whether or not an abnormal current is flowing through the capacitor 235 can be adjusted as appropriate. For example, the CPU 11 can analyze the current value waveform and determine whether or not the degree of coincidence of the current value waveform for each period of the AC power supply 300 is equal to or less than a threshold value. For example, the CPU 11 takes a difference in the order of sampling between the current value constituting the current value waveform in a certain period and the current value constituting the current value waveform in another period, and the reciprocal number of the average value of the difference is the degree of coincidence described above. Can be obtained as And CPU11 can discriminate | determine that the abnormal electric current is flowing into the capacitor | condenser 235, when this coincidence is below a threshold value.

  Alternatively, the CPU 11 performs discrete fast Fourier transform processing on the current value waveform, and when the frequency component equal to or higher than the threshold frequency (frequency exceeding the commercial frequency) is equal to or higher than the threshold, an abnormal current is generated in the capacitor 235. It can be determined that it is flowing. Alternatively, the CPU 11 performs low-frequency cutoff filter processing on the current value waveform using the threshold frequency as a cutoff frequency, and when the processed component is equal to or higher than the threshold, an abnormal current flows through the capacitor 235. Can be determined.

  If the CPU 11 determines that an abnormal current is flowing through the capacitor 235, the CPU 11 can stop supplying power. Thereby, it can be expected to suppress a dangerous situation such as ignition due to leakage current. Further, the CPU 11 can notify that there is a possibility that an abnormal current is flowing in the capacitor 235 when the supply of power is stopped. For example, the CPU 11 can display a message on the touch screen 16 that an abnormal current is flowing through the capacitor 235. Further, the CPU 11 outputs a sound indicating that an abnormal current is flowing through the capacitor 235 to a speaker (not shown) via the external device interface 18 or the home telecommunications network interface 19, or the abnormal current is flowing through the capacitor 235. A message to this effect may be displayed on a display device (not shown).

  In the present embodiment, the leakage occurring from the power supply line L1 is detected based on the current value of the current flowing through the power supply line L1 that supplies power from the illumination power supply 200 to the illumination device 100. Therefore, according to the present embodiment, it is possible to appropriately detect a leakage generated from the power line L1. In addition, when the illumination power source 200 includes the current sensor 251 and the current sensor 252 in advance for controlling the current value, the illumination power source 200 only needs to have a function of executing a leakage detection program.

  Further, in the present embodiment, the electric leakage generated in the AC / DC converter 230 is detected based on the current value of the current flowing through the power supply line L2 that supplies power from the AC power supply 300 to the AC / DC converter 230. Therefore, according to the present embodiment, it is possible to appropriately detect a leakage occurring in the AC / DC converter 230.

  Further, in the present embodiment, it is determined whether or not the degree of coincidence of current value waveforms for each cycle of the AC power supply 300 based on the current value of the current flowing through the power supply line L2 is equal to or less than a threshold value. Therefore, according to the present embodiment, it is possible to efficiently detect a leakage occurring in the AC / DC converter 230.

  In the present embodiment, it is determined whether or not the high-frequency component of the current value of the current flowing through the power supply line L2 is greater than or equal to the threshold value. Therefore, according to the present embodiment, it is possible to efficiently detect a leakage occurring in the AC / DC converter 230.

  In the present embodiment, it is determined whether or not the high-frequency component of the current value of the current flowing through the power supply line L1 is greater than or equal to the threshold value. Therefore, according to the present embodiment, it is possible to efficiently detect a leakage generated from the power supply line L1.

(Embodiment 2)
Next, a power consumption system 1001 according to Embodiment 2 of the present invention will be described. As illustrated in FIG. 7, the power consumption system 1001 is an air conditioning system including an outdoor unit 150 that is a load device and an indoor unit 250 that also functions as a power supply device. Hereinafter, a description will be given focusing on the difference between the power consumption system 1001 and the power consumption system 1000.

  The outdoor unit 150 consumes AC power supplied from the indoor unit 250 and executes a part of the air conditioning process. Typically, outdoor unit 150 performs cooling processing, such as a refrigerant. The outdoor unit 150 and the indoor unit 250 are connected to each other by a control line for communication, a flow path of a medium for heat exchange, and the like. The outdoor unit 150 includes a terminal block 110 and an air conditioning load 121.

  The terminal block 110 is a connector to which one end of a cable connecting the outdoor unit 150 and the indoor unit 250 is connected. This cable is a cable for supplying electric power from the indoor unit 250 to the outdoor unit 150, and is configured by covering the power supply line L1 and the reference line N1 with an insulator.

  The air conditioning load 121 is a load that consumes AC power supplied from the indoor unit 250. The air conditioning load 121 executes, for example, a cooling process for the refrigerant.

  The indoor unit 250 supplies AC power supplied from the AC power source 300 to the outdoor unit 150. In addition, the indoor unit 250 consumes AC power supplied from the AC power source 300 and executes a part of the air conditioning processing. For example, the indoor unit 250 performs an indoor air conditioning process using thermal energy obtained from a medium supplied from the outdoor unit 150. The indoor unit 250 includes a terminal block 210, a plug 220, a control unit 240, a current sensor 251, and voltage sensors 253 and 254.

  The terminal block 210 is a connector to which the other end of the cable connecting the outdoor unit 150 and the indoor unit 250 is connected.

  The plug 220 is a plug that is inserted into an outlet 310 connected to the AC power supply 300 and receives AC power supplied from the AC power supply 300.

  The resistor 261 is a virtual resistor present at the contact portion between the power terminal of the plug 220 and the power terminal of the outlet 310. The resistance value of the resistor 261 increases due to deterioration of the contact portion. The resistor 262 is a virtual resistor present at the contact portion between the reference terminal of the plug 220 and the reference terminal of the outlet 310. The resistance value of the resistor 262 increases due to deterioration of the contact portion.

  The control unit 240 controls the overall operation of the indoor unit 250. Typically, the control unit 240 detects the occurrence of an abnormality such as electric leakage or poor contact, and when the occurrence of the abnormality is detected, notifies the fact that the abnormality has occurred or stops the power supply. The control unit 240 detects the occurrence of an abnormality based on information supplied from the current sensor 251 and the voltage sensors 253 and 254. In addition, the control unit 240 communicates with the outdoor unit 150 and executes processing for controlling air conditioning.

  The current sensor 251 detects the current value of the current flowing through the power supply line L3 and outputs information indicating the detected current value to the control unit 240. The power line L3 is an electric wire that connects the power terminal of the terminal block 210 and the power terminal of the plug 220. Accordingly, the power supply potential of the AC power supply 300 is applied to the power supply line L3.

  The voltage sensor 253 detects the voltage value (potential) of the voltage of the power supply line L3, and outputs information indicating the detected voltage value to the control unit 240. The voltage sensor 254 detects the voltage value (potential) of the voltage of the reference line N3, and outputs information indicating the detected voltage value to the control unit 240. The reference line N3 is an electric wire that connects the reference terminal of the terminal block 210 and the reference terminal of the plug 220. Therefore, the reference potential of the AC power supply 300 is applied to the reference line N3.

  Next, basic functions of the power consumption system 1001 will be described with reference to FIG. Functionally, the power consumption system 1001 includes a load device 401 and a power supply device 501. Here, the load device 401 consumes the supplied power. On the other hand, the power supply device 501 supplies power to the load device 401 via the first power supply line and the first reference line, and AC power is supplied from the AC power supply 300 via the second power supply line and the second reference line. Is done. The load device 401 is, for example, the outdoor unit 150. The power supply device 501 is an indoor unit 250, for example. The first power supply line, the first reference line, the second power supply line, and the second reference line are, for example, the power supply line L1, the reference line N1, the power supply line L2, and the reference line N2, respectively. Here, the power consumption system 1001 functionally includes a first current value measurement unit 101 and a first leakage detection unit 102.

  The first current value measuring unit 101 measures the current value of the current flowing through the first power supply line. The first current value measuring unit 101 includes, for example, a current sensor 251.

  The first leakage detection unit 102 detects a leakage generated between the first power supply line and the first reference line based on the current value measured by the first current value measurement unit 101. The first leakage detection unit 102 includes, for example, a CPU 11.

  Here, the load device 401 may be a device that consumes AC power. In this case, the power supply device 501 includes a third power supply line that connects the first power supply line and the second power supply line, and a third reference line that connects the first reference line and the second reference line.

  The power consumption system 1001 may further include a voltage value measurement unit 106 and a contact failure detection unit 107. The voltage value measuring unit 106 measures the voltage value of the voltage between the third power supply line and the third reference line. The voltage value measurement unit 106 includes voltage sensors 253 and 254, for example. Based on the voltage value measured by the voltage value measurement unit 106, the contact failure detection unit 107 detects a contact failure at the contact portion between the second power supply line and the third power supply line, or the second reference line and the third reference line. Detects poor contact at the contact area. The contact failure detection unit 107 includes, for example, a CPU 11.

  Here, the contact failure detection unit 107 determines whether the correlation coefficient between the current value measured by the first current value measurement unit 101 and the voltage value measured by the voltage value measurement unit 106 is equal to or greater than a threshold value. can do.

  Further, the first leakage detection unit 102 determines whether or not the degree of coincidence of the current value waveforms for each cycle of the AC power supply 300 based on the current value measured by the first current value measuring unit 101 is equal to or less than a threshold value. Can do.

  Next, the operation of the power consumption system 1001 will be described.

  When the plug 220 is connected to the outlet 310, AC power is supplied to the indoor unit 250 from the AC power source 300. The indoor unit 250 supplies the supplied AC power to the outdoor unit 150 via the power line L1 and the reference line N1. On the other hand, the outdoor unit 150 consumes the supplied AC power and executes a part of the air conditioning process.

  Here, while the power consumption system 1001 is operating, there is a possibility that deterioration occurs at various parts. For example, as in the first embodiment, when the insulator covering the power supply line L1 and the reference line N1 deteriorates, the power supply line L1 and the reference line N1 may be short-circuited to generate a spark.

  Hereinafter, a method for detecting electric leakage occurring in the electric wire portion (power supply line L1 and reference line N1) will be described.

  First, if the power supply circuit configuration of the outdoor unit 150 is a capacitor input type, before the leakage between the power supply line L1 and the reference line N1 occurs, a current as shown in FIG. (Referred to as “load current” as appropriate) flows through the power supply line L3 (the same applies to the power supply lines L1 and L2).

  On the other hand, when an electric leakage occurs between the power supply line L1 and the reference line N1, the resistance value of the resistor 130 is drastically reduced, a spark or the like is generated between the power supply line L1 and the reference line N1, and an abnormal current is generated in the resistor 130. Flowing. This abnormal current is a current whose amplitude is extremely large and whose amplitude varies irregularly every period of the AC power supply 300. Note that the amplitude of the abnormal current is extremely larger than the amplitude of the load current. Therefore, the current (detected current detected by the current sensor 251) that flows through the power supply line L3 after the occurrence of electric leakage is almost an abnormal current. In FIG. 9, the current value of the current flowing through the power supply line L3 after the insulation deterioration occurs is indicated by a solid line. In FIG. 9, the voltage value of the AC voltage of the AC power supply 300 is indicated by a broken line.

  Based on the current flowing through the power supply line L3, the method of detecting a leakage between the power supply line L1 and the reference line N1 can be adjusted as appropriate. For example, the CPU 11 samples the current value of the current flowing through the power supply line L3, and stores a current value waveform for several cycles in the flash memory 14 or the like. And CPU11 compares the current value waveform for every period mutually, and discriminate | determines the reproducibility of a current value waveform. For example, when the CPU 11 determines that the difference in amplitude of the current value waveform for each period is equal to or greater than the threshold value, the CPU 11 can determine that the current value waveform is not reproducible. When determining that the current value waveform has reproducibility, the CPU 11 determines that there is no leakage between the power supply line L1 and the reference line N1. On the other hand, if the CPU 11 determines that there is no reproducibility of the current value waveform, it determines that there is a leakage between the power supply line L1 and the reference line N1.

  When the CPU 11 determines that there is a leakage between the power supply line L1 and the reference line N1, the CPU 11 can stop supplying power. Thereby, it can be expected to suppress a dangerous situation such as ignition due to leakage current. In addition, the CPU 11 can notify that there is a leakage between the power supply line L1 and the reference line N1 when the supply of power is stopped. For example, the CPU 11 can display a message on the touch screen 16 that there is a leakage between the power supply line L1 and the reference line N1. Further, the CPU 11 outputs a sound indicating that there is a leakage between the power supply line L1 and the reference line N1 to a speaker (not shown) via the external device interface 18 or the home telecommunications network interface 19, or the power supply line L1. A message indicating that there is a leakage between the reference line N1 may be displayed on a display device (not shown).

  Next, a method for detecting a contact failure occurring at the contact portion between the plug 220 and the outlet 310 will be described.

  First, when there is no poor contact between the plug 220 and the outlet 310, the resistance value of the resistor 261 and the resistance value of the resistor 262 are extremely small, and the voltage drop and power loss at the contact portion are negligibly small. Therefore, when there is no poor contact between the plug 220 and the outlet 310, the voltage applied between the power supply line L3 and the reference line N3 is a voltage as shown by a solid line in FIG. In FIGS. 10A and 10B, the current flowing through the power supply line L3 is indicated by a broken line. When there is no poor contact between the plug 220 and the outlet 310, since the series impedance on the power supply side is low, as shown in FIG. 10A, the fluctuation of the voltage applied between the power supply line L3 and the reference line N3 is There is no correlation with the fluctuation of the current flowing through the power line L3.

  Here, when the quick connection terminal or the screw type terminal which is the electric wire connection terminal in the outlet 310 is loose, etc., minute discharge is repeated, and as a result, the oxidation of the contact surface proceeds and the contact failure occurs. Become.

  When a poor contact between the plug 220 and the outlet 310 occurs, the resistance value of the resistor 261 and the resistance value of the resistor 262 increase, and the voltage drop and power loss at the contact portion become so large that they cannot be ignored. Therefore, when a poor contact between the plug 220 and the outlet 310 occurs, the voltage applied between the power supply line L3 and the reference line N3 is a voltage as shown by a solid line in FIG. When the contact failure between the plug 220 and the outlet 310 occurs, the series impedance on the power supply side cannot be ignored. Therefore, as shown in FIG. 10B, the voltage applied between the power supply line L3 and the reference line N3. Is correlated with the fluctuation of the current flowing through the power supply line L3.

  The method for detecting a contact failure between the plug 220 and the outlet 310 can be adjusted as appropriate. For example, the CPU 11 determines whether or not there is a correlation between fluctuations in the current flowing through the power supply line L3 (current consumed by the outdoor unit 150) and fluctuations in the voltage applied between the power supply line L3 and the reference line N3. As a result, a contact failure between the plug 220 and the outlet 310 can be detected.

The presence or absence of correlation is normalized by the equation (1), where I is the current value of the current flowing through the power line L3 and V is the voltage value of the voltage applied between the power line L3 and the reference line N3. It is possible to determine whether or not the cross correlation coefficient R _NCC exceeds a threshold value. Note that M is the number of samplings per cycle, and N is the number of sampled cycles. CPU11, when it is determined that R _NCC does not exceed the threshold value, it is determined that there is no correlation (i.e., there is no defective contact with the contact portion). On the other hand, if the CPU 11 determines that _RNCC exceeds the threshold value, the CPU 11 determines that there is a correlation (that is, there is a contact failure in the contact portion).

  If the CPU 11 determines that there is a poor contact between the plug 220 and the outlet 310, the CPU 11 can notify that there is a poor contact between the plug 220 and the outlet 310. For example, the CPU 11 can display a message indicating that there is a poor contact between the plug 220 and the outlet 310 on the touch screen 16. Further, the CPU 11 outputs a sound indicating that there is a poor contact between the plug 220 and the outlet 310 via the external device interface 18 or the home telecommunications network interface 19, or outputs a sound that is not shown between the plug 220 and the outlet 310. A message indicating that there is a contact failure may be displayed on a display device (not shown).

  In the present embodiment, the leakage occurring from the power line L1 is detected based on the current value of the current flowing through the power line L1 that supplies power from the indoor unit 250 to the outdoor unit 150. Therefore, according to the present embodiment, it is possible to appropriately detect a leakage generated from the power line L1. Note that when the indoor unit 250 includes the current sensor 251 in advance for controlling the current value, the indoor unit 250 only needs to have a function of executing a program for detecting leakage.

  In the present embodiment, the power supply line L2 is connected to the power supply line L2 based on the voltage value between the power supply line L3 connecting the power supply line L1 and the power supply line L2 and the reference line N3 connecting the reference line N1 and the reference line N2. A contact failure at the contact portion with the power supply line L3 or a contact failure at the contact portion between the reference line N2 and the reference line N3 is detected. Therefore, according to the present embodiment, it is possible to appropriately detect a contact failure that has occurred on the path for supplying AC power from the AC power supply 300 to the indoor unit 250.

  In the present embodiment, it is determined whether or not the correlation between the current value of the current flowing through the power supply line L3 and the voltage value between the power supply line L3 and the reference line N3 is equal to or greater than a threshold value. Therefore, according to the present embodiment, it is possible to appropriately detect a contact failure that has occurred on the path for supplying AC power from the AC power supply 300 to the indoor unit 250.

  Further, in the present embodiment, it is detected whether or not the degree of coincidence of current value waveforms for each cycle of the AC power supply 300 based on the current value of the current flowing through the power supply line L3 is equal to or less than a threshold value. Therefore, according to the present embodiment, it is possible to efficiently detect a leakage occurring on the path for supplying AC power from the indoor unit 250 to the outdoor unit 150.

(Modification)
As mentioned above, although embodiment of this invention was described, when implementing this invention, a deformation | transformation and application with a various form are possible.

  In the present invention, which part of the configuration, function, and operation described in the above embodiment is adopted is arbitrary. Further, in the present invention, in addition to the configuration, function, and operation described above, further configuration, function, and operation may be employed.

  In the first embodiment, an example in which the power consumption system 1000 is a lighting system has been described, and in the second embodiment, an example in which the power consumption system 1001 is an air conditioning system has been described. The power consumption system to which the present invention is applied is not limited to this example. For example, the present invention provides a heat pump hot water supply system (heat pump water heater) having a hot water supply device and a power supply device, and an electric cleaning system (electric vacuum cleaner) having a head portion having a brush motor and a cleaner body having a power supply device. Can be applied.

  In the first embodiment, an example in which the lighting device 100 includes the terminal block 110 and the illumination power source 200 includes the terminal block 210 has been described. In the present invention, the lighting device 100 may include a connector instead of the terminal block 110, and the lighting power source 200 may include a connector instead of the terminal block 210.

  In the first embodiment, the example has been described in which the illumination power source 200 detects deterioration such as a short circuit or poor contact without communicating with the illumination device 100. In the present invention, the lighting power source 200 may communicate with the lighting device 100 via the external device interface 18 or the like, and acquire information useful for detecting deterioration from the lighting device 100. Information useful for detection of deterioration is, for example, information indicating the driving capability of the lighting device 100, the operation mode of the lighting device 100, the operating environment of the lighting device 100 (ambient temperature, ambient humidity, ambient pressure, etc.), and the like. Similarly, in the second embodiment, the indoor unit 250 can communicate with the outdoor unit 150 via the external device interface 18 or the like, and can acquire information useful for detecting deterioration from the outdoor unit 150.

  In addition, it is possible to detect deterioration such as a short circuit or poor contact in the wiring between the units in the integrated device or in the connection portion in the same manner as in the first and second embodiments.

  Embodiment 1 and Embodiment 2 demonstrated the example which applies this invention to the system which consumes alternating current power. The present invention may be applied to a system that consumes DC power. In this case, it is preferable to apply the technique for detecting a short circuit generated in the direct current section shown in the first embodiment and the technique for detecting a contact failure generated in the outlet 310 section shown in the second embodiment.

  In the first embodiment, the example in which the illumination power source 200 has a built-in function for detecting deterioration such as a short circuit or poor contact has been described. In the present invention, the function of detecting deterioration may not be provided in the power supply device (lighting power supply 200). In this case, the power supply device or the like only needs to include a sensor for detecting a current value and a voltage value and an actuator for driving a protection circuit when detecting deterioration. A function for determining deterioration based on the detected current value and voltage value and a function for outputting a protection instruction when the deterioration is detected can be provided as a program in a processing apparatus on the cloud.

  By applying an operation program that defines the operation of the control unit 240 according to the present invention to an existing personal computer or information terminal device, the personal computer or the like can also function as the control unit 240 according to the present invention.

  Further, such a program distribution method is arbitrary. For example, a computer-readable medium such as a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), an MO (Magneto Optical Disk), or a memory card is readable. It may be distributed by storing in a recording medium, or distributed via a communication network such as the Internet.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. Further, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

  The present invention is applicable to a power consumption system including a load device and a power supply device.

L1, L2, L3 Power line, N1, N2, N3 Reference line, 11 CPU, 12 ROM, 13 RAM, 14 Flash memory, 15 RTC, 16 Touch screen, 17 Sensor interface, 18 External device interface, 19 Home telecommunications network Interface, 100 Lighting device, 101 First current value measurement unit, 102 First leakage detection unit, 103 Power conversion unit, 104 Second current value measurement unit, 105 Second leakage detection unit, 106 Voltage value measurement unit, 107 Contact failure Sensing unit, 110, 210 terminal block, 120 LED, 130, 236, 261, 262 resistance, 150 outdoor unit, 200 lighting power supply, 220 plug, 230 AC / DC converter, 240 control unit, 250 indoor unit, 251, 252 Current sensor, 253, 254, 255, 2 56 Voltage Sensor, 300 AC Power Supply, 310 Outlet, 231 Varistor, 232, 235 Capacitor, 233 Diode Bridge, 234 Coil, 237 DC / DC Converter, 400, 401 Load Device, 500, 501 Power Supply Device, 1000, 1001 Power Consumption System

Claims (6)

The DC power is supplied to the load device via a load device that consumes the supplied DC power, and a first power supply line and a first reference line provided in parallel with the first power supply line, and a second power supply. A power supply device in which AC power is supplied from an AC power supply via a line and a second reference line provided in parallel with the second power supply line, wherein the AC power supplied from the AC power supply is converted to the DC power. A power consumption system comprising: a power conversion means for converting and supplying the DC power to the load device, and comprising a power conversion means that is a capacitor input type full-wave rectification power supply circuit comprising a capacitor. ,
First current value measuring means for measuring a current value of a current flowing through the first power supply line;
First leakage detection means for detecting a leakage generated between the first power line and the first reference line based on the current value measured by the first current value measurement means;
Second current value measuring means for measuring a current value of a current flowing through the second power supply line;
Based on the current value measured by the second current value measuring means, a current flowing through the second power line due to an abnormal current flowing through the capacitor and detected regardless of the period of the AC power supply is detected. And a second leakage detection means for detecting a leakage generated in the power conversion means,
Power consumption system. The second leakage detection means generates a current value waveform for each cycle of the AC power supply from the current value measured by the second current value measurement means, and the first current value waveform is generated among the generated current value waveforms. The difference between the current value constituting and the current value constituting the second current value waveform among the generated current value waveforms is obtained in the sampling order, and it is determined whether or not the reciprocal of the average value of the obtained differences is equal to or less than the threshold value. ,
The power consumption system according to claim 1. The second leakage detection means has a frequency equal to or higher than a predetermined frequency when a discrete fast Fourier transform process is performed on a current value waveform generated from the current value measured by the second current value measurement means. Determine whether the component is a ratio equal to or greater than a threshold value ,
The power consumption system according to claim 1 or 2. The first leakage detection means has a frequency equal to or higher than a predetermined frequency when a discrete fast Fourier transform process is performed on a current value waveform generated from the current value measured by the first current value measurement means. Determine whether the component is a ratio equal to or greater than a threshold value ,
The power consumption system according to any one of claims 1 to 3. The DC power is supplied to the load device via a load device that consumes the supplied DC power, and a first power supply line and a first reference line provided in parallel with the first power supply line, and a second power supply. A power supply device in which AC power is supplied from an AC power supply via a line and a second reference line provided in parallel with the second power supply line, wherein the AC power supplied from the AC power supply is converted to the DC power. A power consumption system comprising: a power conversion unit that converts and supplies the DC power to the load device, the power conversion unit including a power conversion unit that is a capacitor input type full-wave rectification power supply circuit including a capacitor. A leakage detection method,
A first current value measuring step of measuring a current value of a current flowing through the first power line;
A first leakage detection step of detecting a leakage occurring between the first power line and the first reference line based on the current value measured in the first current value measurement step;
A second current value measuring step for measuring a current value of a current flowing through the second power supply line;
Based on the current value measured in the second current value measuring step, a current that flows through the second power supply line due to an abnormal current flowing through the capacitor and that flows regardless of the cycle of the AC power supply is detected. And a second leakage detection step of detecting a leakage occurring in the power conversion means.
Electric leakage detection method. The DC power is supplied to the load device via a load device that consumes the supplied DC power, and a first power supply line and a first reference line provided in parallel with the first power supply line, and a second power supply. A power supply device in which AC power is supplied from an AC power supply via a line and a second reference line provided in parallel with the second power supply line, wherein the AC power supplied from the AC power supply is converted to the DC power. A power conversion device for converting and supplying the DC power to the load device, and comprising a power conversion device that is a capacitor input type full-wave rectification power supply circuit including a capacitor; and a current flowing through the first power supply line A computer provided in a power consumption system, comprising: a first current value measuring means for measuring a current value of the second current value measuring means for measuring a current value of a current flowing through the second power line;
First leakage detecting means for detecting a leakage generated between the first power line and the first reference line based on the current value measured by the first current value measuring means;
Based on the current value measured by the second current value measuring means, a current flowing through the second power line due to an abnormal current flowing through the capacitor and detected regardless of the period of the AC power supply is detected. By making it function as a second leakage detection means for detecting leakage occurring in the power conversion means,
program.

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