JP7282224B1 - Wiring search system and control method - Google Patents

Abstract

A wiring exploration system and control method capable of safely inspecting wiring are provided.
A wiring inspection system comprising a wiring identification transmitter and a wiring identification load device, wherein the wiring identification load device includes a first terminal connected to one of a pair of power lines and a first terminal connected to the other. A series circuit including two terminals, a load and a switch, and a series circuit that generates an inrush current in response to a remote control signal from the wiring identification transmitter and transmits a response signal in response to the generation of the inrush current. The wiring identification transmitter includes a second control unit for transmitting a remote control signal in accordance with an operation, and the first control unit controls the inrush current by turning on or off the switch to the first terminal and the first terminal. 2 terminals, monitors the operation of the switch, transmits a response signal as a signal indicating the monitoring result, and when the response signal is received, the second control unit outputs the monitoring result in a predetermined output mode. Output.
[Selection drawing] Fig. 4

Description

The present invention relates to a wiring survey system and control method.

Patent Literature 1 describes a method for identifying a distribution line as follows. That is, in the method described in Patent Document 1, a test high-frequency signal is continuously or intermittently injected between one wire of the power supply line to be removed and the ground, and the same test signal is applied to the wiring on the power supply side. A wiring search is performed depending on whether or not a high-frequency signal is observed. In this method, for example, a high-frequency test signal is continuously injected into the power supply line, and in some cases, there is a risk of malfunction or failure of other load devices during operation, and there is a safety issue. .

JP-A-9-329636

SUMMARY OF THE INVENTION It is an object of the present invention to provide a wiring inspection system and a control method that can safely inspect wiring.

(1) In order to solve the above problems, one aspect of the present invention provides a wiring identification transmitter that transmits a remote control signal for remote control, and a wiring identification that receives the remote control signal from the wiring identification transmitter. a load device, wherein the wire identification load device includes a first terminal connected to one of a first power line and a second power line forming a pair of power lines, and a first terminal connected to the other. a second terminal, a series circuit including a load and a switch, and a first communication processing section formed to communicate with the wiring identification transmitter and receiving the remote control signal from the wiring identification transmitter. , a first control unit that causes the series circuit to generate an inrush current in response to the reception of the remote control signal, and causes the first communication processing unit to transmit a response signal corresponding to the generation of the inrush current; The wiring identification transmitter includes a second communication processing section configured to be communicable with the wiring identification load device, and a second control section for transmitting the remote control signal from the second communication processing section according to an operation. , wherein the first control unit causes the inrush current to flow between the first terminal and the second terminal by turning on or off the switch, and monitors the operation of the switch to monitor The response signal is generated as a signal indicating the result of the communication, the response signal is transmitted from the first communication processing unit, and the second control unit controls, when the second communication processing unit receives the response signal, the It is a wiring investigation system that outputs monitoring results in a predetermined output mode.

(2) One aspect of the present invention is the wiring survey system of (1), wherein the wiring identification load device includes a first alarm unit that issues an alarm, and the wiring identification transmitter includes a second alarm unit that issues an alarm. An alarm unit is provided, and when an operation for transmitting the remote control signal is performed, at least one of the first alarm unit and the second alarm unit issues an alarm for a predetermined period of time.

(3) One aspect of the present invention is the wiring investigation system of (2), wherein the wiring identification load device is driven by a battery, and the first control unit, when the voltage of the battery is equal to or less than a predetermined value, The first communication processing unit transmits a battery voltage drop signal indicating that the voltage of the battery is equal to or lower than the predetermined value, and the second control unit causes the second communication processing unit to transmit the battery voltage drop signal. If received, an alarm is issued from the second alarm unit.

(4) An aspect of the present invention is the wiring survey system of (2), wherein the load includes a capacitor, and the first control unit controls the first When the communication processing unit transmits a capacitor high voltage signal indicating that the voltage of the capacitor is equal to or higher than the predetermined value, and the second control unit receives the capacitor high voltage signal, , an alarm is issued from the second alarm unit.

(5) One aspect of the present invention is the wiring survey system of (1), wherein the switch is a contact of a relay (hereinafter referred to as a relay contact), and the first control unit operates the relay contact is monitored based on the operation of other relay contacts to generate said response signal.

(6) One aspect of the present invention is the wiring exploration system of (1) to (5), wherein the load selectively operates a plurality of resistors having at least some different resistance values and the resistors the second control unit causes the second communication processing unit to transmit a setting signal corresponding to a setting state of a predetermined setting unit; and the first control unit causes the first The selection relay is controlled to be on or off based on the setting signal received by the communication processing unit.

(7) One aspect of the present invention is a wiring including a wiring identification transmitter that transmits a remote control signal for remote control, and a wiring identification load device that receives the remote control signal from the wiring identification transmitter. In the control method of an inspection system, the wiring identification load device has a first terminal connected to one of a first power line and a second power line forming a pair of power lines and a second terminal connected to the other. a series circuit including a load and a switch; a first communication processing unit formed to communicate with the wiring identification transmitter and receiving the remote control signal from the wiring identification transmitter; a first control unit that causes the series circuit to generate an inrush current in response to reception of a signal, and causes the first communication processing unit to transmit a response signal corresponding to the generation of the inrush current; The machine comprises: a second communication processing unit configured to be able to communicate with the wiring identification load device; and a second control unit that transmits the remote control signal from the second communication processing unit according to an operation, By turning on or off the switch by the first control unit, the inrush current is caused to flow between the first terminal and the second terminal, the operation of the switch is monitored, and the result of monitoring is displayed. a step of generating the response signal as a signal and transmitting the response signal from the first communication processing unit; is output in a predetermined output mode.

According to each aspect of the present invention, wiring can be probed safely.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the structural example of the wiring investigation system which concerns on embodiment of this invention. 1 is a configuration diagram showing a configuration example of a wiring identification load device according to an embodiment of the present invention; FIG. 1 is a configuration diagram showing a configuration example of a wiring identification transmitter according to an embodiment of the present invention; FIG. 4 is a flow chart showing an operation example of the wiring identification transmitter according to the embodiment of the present invention; It is a flowchart which shows the operation example of the wiring identification load apparatus which concerns on embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings. In each figure, the same reference numerals are used for the same or corresponding configurations, and the description thereof will be omitted as appropriate.

(First embodiment)
FIG. 1 is a configuration diagram showing a configuration example of a wiring survey system according to a first embodiment of the present invention. A wiring survey system 100 shown in FIG. 1 includes a wiring identification load device 1 and a wiring identification transmitter 2 . FIG. 1 shows an example of searching for a pair of power lines 303 and 304 that supply AC power to a removal device 7 to be removed in a power supply wiring system 10 using a wiring search system 100 .

The power supply wiring system 10 shown in FIG. 1 is an AC power supply system, and AC power is supplied to the removal device 7 and the current device 8 from terminals L1 and L2 of the power supply device 4 . Note that the wiring survey system 100 according to the present embodiment, for example, in addition to the two-wire single-phase AC power supply wiring system 10 such as AC 100V and AC 200V, is also applied to a power supply wiring system such as DC 48V. be able to.

The removal device 7 and the working device 8 are communication devices, for example, and are devices that the removal device 7 intends to remove in the electrical installation work. From the power supply device 4 to the removal device 7, there are a pair of power wires 301 and 302, a pair of power wires 303 and 304, a breaker 51 in the distribution board 5, and a pair of power wires. AC power is supplied via certain power lines 305 and 306 . From the power supply device 4 to the active device 8, power lines 301 and 302 as a pair of power lines, branch points B1 and B2, power lines 307 and 308 as a pair of power lines, a breaker 61 in the distribution board 6, and , AC power is supplied via power lines 309 and 310, which are a pair of power lines.

The wiring identification load device 1 includes a first terminal 11 , a second terminal 12 , and a series circuit 15 of a load 13 and a switch 14 . Series circuit 15 includes load 13 and switch 14 . The first terminal 11 is connected by the power line 41 to the power line 305 which is one of the pair of power lines connected to the removing device 7 on the secondary side of the breaker 51 . The second terminal 12 is connected by the power line 42 to the power line 306 which is the other of the pair of power lines connected to the removing device 7 on the secondary side of the breaker 51 . A load 13 is a load element such as a resistor or a capacitor. The switch 14 is a contact such as an electromagnetic relay, a semiconductor switch such as a MOS-FET (Metal-Oxide-Semiconductor Field Effect Transistor), a solid state relay, or the like. It is controlled to be on or off by a microcomputer (microcomputer) or the like, which will be described later. In the example shown in FIG. 1, one terminal of the load 13 is connected to the first terminal 11 directly or through another circuit. The other terminal of load 13 is connected to one terminal of switch 14 either directly or through another circuit. Also, the other terminal of the switch 14 is connected to the second terminal 12 directly or through another circuit.

The wiring identification load device 1 energizes a predetermined pattern of current (load current Ia) between the first terminal 11 and the second terminal 12 by turning on or off the switch 14 . The predetermined pattern can be, for example, a waveform of inrush current (inrush current pattern) when charging a capacitor included in the load 13, or a pattern consisting of a combination of a plurality of inrush currents. The current Ia that flows between the first terminal 11 and the second terminal 12 is generated in the wiring identification load device 1 by AC power supplied from the power supply device 4 that supplies AC power to the removal device 7 .

It should be noted that the load 13 in this embodiment is one structural example of the load of the present invention. Also, in this embodiment, the switch 14 is one configuration example of the switch of the present invention. Also, in this embodiment, the series circuit 15 is one structural example of the series circuit of the present invention.

On the other hand, the wiring identification transmitter 2 is used, for example, in combination with a clamp-type current sensor 2s to detect a change in current in a predetermined pattern flowing through the power supply line 303 or 304 . An operator remotely controls the wiring identification load device 1 by operating the wiring identification transmitter 2, causes the wiring identification load device 1 to generate a current change in a predetermined pattern, and uses, for example, a clamp-type current sensor 2s to control the power line. A change in a predetermined pattern of current flowing through 303 or 304 is confirmed. The wiring identification transmitter 2 transmits a remote control signal to the wiring identification load device 1 by wireless communication according to the operator's operation. The wiring identification load device 1 that has received the remote control signal turns on or off the switch 14 to pass the inrush current between the first terminal 11 and the second terminal 12, and monitors the operation of the switch 14, A response signal is transmitted to the wiring identification transmitter 2 as a signal indicating the monitoring result. When receiving the response signal, the wiring identification transmitter 2 outputs the monitoring result in a predetermined output mode (for example, outputs as an image, an optical signal, an acoustic signal, a synthesized voice signal, etc.).

The clamp-type current sensor 2s is, for example, a sensor that detects AC and DC currents in a non-contact manner by using a Hall element to detect a magnetic field generated by a current that flows through a measurement conductor penetrating the measurement section 2h. The clamp-type current sensor 2s may have, for example, only a function of displaying the detected current value, or may have a microcomputer or the like inside to detect whether or not a change in the measured current in a predetermined pattern is detected. It may have a function of judging and displaying the judged result. Alternatively, the clamp-type current sensor 2s may have a function of displaying the detected current waveform (current change over time). The clamp-type current sensor 2s detects, for example, a change in a predetermined pattern of current flowing through the power supply line 303 or 304 as the current to be measured. In this embodiment, the clamp-type current sensor 2s outputs an analog signal indicating the detected current waveform. The clamp-type current sensor 2s and the wiring identification transmitter 2 may be configured integrally.

According to the wiring inspection system 100, the wiring identification load device 1 automatically generates the load current Ia in a predetermined turn, and the current flowing through the wiring on the power supply side is confirmed using the clamp-type current sensor 2s, and the current is the same as the load current. A system in which a pattern of measured current is observed can be identified as a power line scheduled to be removed. According to this embodiment, there is no need to inject a high-frequency voltage into the power line, so the power line can be searched safely without causing malfunction or failure in other devices.

Next, a configuration example of the wiring identification load device 1 will be described with reference to FIG. FIG. 2 is a configuration diagram showing a configuration example of the wiring identification load device according to the embodiment of the present invention. The wiring identification load device 1 shown in FIG. 2 includes a first terminal 11, a second terminal 12, a diode bridge DB, a battery BT1, a microcomputer 101, a battery voltage detection section 102, a capacitor voltage detection section 103, an alarm section 104, and a load application section. 105, a load selection unit 106, a wireless communication unit 107, a capacitor C1, a resistor R3, an ammeter AS, and a voltmeter VS. The wiring identification load device 1 is driven by a battery BT1 as a power source. In the following description, as the wiring identification load device 1, a configuration applied to wiring for single-phase alternating current will be exemplified.

A power line 41 shown in FIG. 1 is connected to the first terminal 11 . A power line 42 shown in FIG. 1 is connected to the second terminal 12 . The diode bridge DB is, for example, a full-wave rectifier for single-phase alternating current. The diode bridge DB connects the AC input side to the first terminal 11 and the second terminal 12 . The diode bridge DB also connects the positive terminal on the DC output side to the positive terminals of the capacitor C1, the ammeter AS and the voltmeter VS. Also, the diode bridge DB connects the negative terminal on the DC output side to the ground (GND). The battery BT1 has a positive terminal connected to the power supply Vc and a negative terminal connected to the ground. Note that the voltage of the power supply Vc is hereinafter also referred to as the power supply voltage Vc. Even if the wiring identification load device 1 is applied to the wiring for direct current, by providing the diode bridge DB, it is possible to protect the case where the first terminal 11 and the second terminal 12 are connected with opposite polarities. .

A capacitor C1 is an element for generating an inrush current pattern, and is an electrolytic capacitor, for example. Both terminals of the capacitor C1 are connected to the positive terminal of the DC output side of the diode bridge DB and the negative terminal of the voltmeter VS. A resistor R3 is a discharge resistor, and discharges the charge charged in the capacitor C1. Both terminals of the resistor R3 are connected to the negative terminal of the ammeter AS and the negative terminal of the voltmeter VS. Ammeter AS measures the current flowing through resistor R3. A voltmeter VS measures the terminal voltage of the capacitor C1.

The microcomputer 101 internally includes a processor, memory, timer, analog/digital converter, serial communication circuit, wireless module control circuit, etc., and each part in the wiring identification load device 1 is controlled by executing a program stored in the memory. to control. The microcomputer 101 has power supply terminals Vc and GND, an analog input terminal AI1, digital input terminals DI1 and DI2, digital output terminals DO1 to DO8, and wireless module control terminals TX and RX. A microcomputer is also called a CPU (Central Processing Unit) or the like. In this embodiment, the microcomputer 101 is one configuration example of the first control unit of the present invention. It is assumed that the digital output terminals DO1 to DO8 have the ability to directly drive transistors.

Battery voltage detection unit 102 includes a resistor R1 and a resistor R2. One terminal of the resistor R1 is connected to the power supply Vc, and the other terminal is connected to one terminal of the resistor R2 and the analog input terminal AI1 of the microcomputer 101. FIG. Resistor 2 connects the other terminal to ground. Battery voltage detection unit 102 divides power supply voltage Vc, which is the terminal voltage of battery BT1, with resistors R1 and R2 and outputs the divided voltage to analog input terminal AI1 of microcomputer 101 .

The capacitor voltage detection unit 103 includes a comparator CMP, a resistor R4, a resistor R5, and a variable resistor R6. The resistor R4 has one terminal connected to the positive terminal of the capacitor C1 and the other terminal connected to one terminal of the resistor R5 and the non-inverting input terminal of the comparator CMP. Resistor 5 connects the other terminal to ground. The variable resistor R6 has one terminal connected to the power supply Vc, the other terminal connected to the ground, and the terminal connected to the movable contact connected to the inverting input terminal of the comparator CMP. The comparator CMP compares the voltage obtained by dividing the terminal voltage of the capacitor C1 by the resistors R4 and R5 with the voltage obtained by adjusting the voltage Vc by the variable resistor R6. The capacitor voltage detection unit 103 outputs an H level (power supply Vc) signal when the voltage of the capacitor C1 is equal to or higher than a predetermined value, and outputs an L level (ground level) signal when the voltage of the capacitor C1 is less than the predetermined value. Output.

The alarm unit 104 has a buzzer BZ1 and a transistor TR8. One terminal of the buzzer BZ1 is connected to the power supply Vc, and the other terminal is connected to the collector of the transistor TR8. The emitter of the transistor TR8 is connected to the ground, and the base is connected to the digital output terminal DO1 of the microcomputer 101. FIG. Buzzer BZ1 sounds when transistor TR8 is turned on. The alarm unit 104 outputs an alarm sound when the digital output terminal DO1 is at H level. The alarm unit 104 is one configuration example of the first alarm unit of the present invention.

The load application unit 105 includes a relay RY1, a resistor R7, and a transistor TR1. The load application unit 105 constitutes a switch 14 that allows a rush current to flow between the first terminal 11 and the second terminal 12 . Relay RY1 is an electromagnetic relay and includes terminals 1a, 1c, 2a and 2c and coil L1. The coil L1 has one terminal connected to the power supply Vc and the other terminal connected to the collector of the transistor TR1. The emitter of the transistor TR1 is connected to the ground, and the base is connected to the digital output terminal DO2 of the microcomputer 101. FIG. When the digital output terminal DO2 is at H level, the transistor TR1 is turned on and current flows through the coil L1. Terminal 1a is a normally open terminal, and is connected to terminal 1c, which is a common terminal, when current flows through coil L1 of relay RY1. A normally open contact is provided between terminals 1a and 1c. Terminal 2a is a normally open terminal, and is connected to terminal 2c, which is a common terminal, when current flows through coil L1 of relay RY1. A normally open contact is provided between terminals 2a and 2c. Terminal 1a is connected to power supply Vc. The terminal 1c is connected to one terminal of the resistor R7 and the digital input terminal DI2 of the microcomputer 101. FIG. The other terminal of resistor R7 is connected to ground. Terminal 2a is connected to the ground. Terminal 2c is connected to one terminal of load selector 106 . The load application unit 105 outputs a signal of H level to the digital input terminal DI2 when the contact between the terminal 1a and the terminal 1c is turned on, and outputs the digital input terminal DI2 when the contact between the terminal 1a and the terminal 1c is turned off. An L level signal is output to DI2.

In the load application unit 105, the contact between the terminals 1a and 1c and the contact between the terminals 2a and 2c operate in conjunction with each other. A contact between the terminals 2a and 2c corresponds to the switch 14 shown in FIG. In this case, the operation of the switch 14, that is, the contact between the terminal 2a and the terminal 2c, is monitored by the microcomputer 101 based on the operation of another contact between the terminal 1a and the terminal 1c (hereinafter also referred to as a monitoring contact). become.

The load selector 106 includes relays RY2-RY7, resistors R11-R19, and transistors TR2-TR7. The relays RY2 to RY7 are electromagnetic relays, each having terminals a and c and one each of coils L2 to L7. Relays RY2 to RY7 are one configuration example of a selection relay in the present invention. The relays RY2 to RY7 are hereinafter also referred to as selection relays. Note that the transistors TR3 to TR6 and the coils L3 to L6 are omitted from the drawing. Terminal a is a normally open terminal, and terminal c is a common terminal. One terminal of each of the coils L2 to L7 is connected to the power supply Vc. The other terminals of the coils L2-L7 are connected to the collectors of the transistors TR2-TR7. Each emitter of the transistors TR2-TR7 is connected to the ground, and each base is connected to the digital output terminals DO3-DO8 of the microcomputer 101. FIG. When the digital output terminals DO3-DO8 are at H level, the transistors TR2-TR7 are turned on, and currents flow through the coils L2-L7. When current flows through the coils L2-7 of the relays RY2-RY7, the terminals a and c are connected.

Each terminal c of the relays RY5 to RY7 is connected to the negative terminal of the capacitor C1. A terminal a of the relay RY5 is connected to one terminal of each of the resistors R11 to R13. A terminal a of the relay RY6 is connected to one terminal of each of the resistors R14 to R16. A terminal a of the relay RY7 is connected to one terminal of each of the resistors R17 to R19.

Terminal a of relay RY2 is connected to the other terminals of resistors R11, R14 and R17. Terminal a of relay RY3 is connected to the other terminals of resistors R12, R15 and R18. Terminal a of relay RY4 is connected to the other terminals of resistors R13, R16 and R19. Each terminal c of relays RY2 to RY4 is connected to terminal 2c of relay RY1.

Any one of the resistors R11-R19 is selected by turning on any one of the relays RY2-RY4 and any one of the relays RY5-RY7. A series circuit of any one of the resistors R11 to R19 and the capacitor C1 corresponds to the load 13. FIG. The resistance values of resistors R11 to R19 are different from each other. However, a plurality of resistors having the same resistance value may be included. By selecting one of the relays RY5 to RY7 according to, for example, three types of power supply voltages of the power supply wiring system 10, and selecting one of the relays RY2 to RY4 according to, for example, three types of current values of the inrush current, Any one of the resistors R11 to R19 can be selected according to the power supply voltage and current value. For example, at three power supply voltages of DC 48V, AC 100V, and AC 200V, by setting each resistance value of resistors R11 to R19 to set values that set the inrush current to, for example, 5A, 10A, and 30A. , power supply voltage and inrush current can be selected.

The wireless communication unit 107 has a communication module RM1. The communication module RM1 is formed to communicate with a communication module RM2 of the wiring identification transmitter 2, which will be described later. The wireless communication unit 107 receives predetermined signals such as a remote control signal, a battery voltage drop signal, and a setting signal from the wiring identification transmitter 2 . The wireless communication unit 107 transmits predetermined signals such as a battery voltage drop signal, a capacitor high voltage signal, and a response signal to the wiring identification transmitter 2 . The communication module RM1 wirelessly communicates with the communication module RM2 either directly or via an access point or the like (not shown). The wireless communication unit 107 (or a functional configuration obtained by combining the functions of the wireless communication unit 107 and a part of the microcomputer 101) is one configuration example of the first communication processing unit of the present invention.

In this embodiment, the remote control signal from the wiring identification transmitter 2 is a signal that instructs the generation of rush current. The battery voltage drop signal from the wiring identification transmitter 2 is a signal that notifies that the voltage of the battery BT2 (FIG. 3) included in the wiring identification transmitter 2 is below a predetermined value. The setting signal from the wiring identification transmitter 2 is a signal that instructs the selection operation of the resistors R11 to R19 of the load selection unit 106 (on or off operation state of the relays RY2 to RY7). The battery voltage drop signal to the wiring identification transmitter 2 is a signal notifying that the voltage of the battery BT1 is below a predetermined value. The capacitor high voltage signal to the wiring identification transmitter 2 is a signal notifying that the terminal voltage of the capacitor C1 is equal to or higher than a predetermined value. The response signal to the wiring identification transmitter 2 is a signal that notifies the monitoring result of the operating state of the load application unit 105 when the load application unit 105 generates a rush current.

Next, a configuration example of the wiring identification transmitter 2 will be described with reference to FIG. FIG. 3 is a configuration diagram showing a configuration example of the wiring identification transmitter according to the embodiment of the present invention. The wiring identification transmitter 2 shown in FIG. A communication unit 208 is provided. The wiring identification transmitter 2 is driven using the battery BT2 as a power source.

The battery BT2 has a positive terminal connected to the power supply Vc and a negative terminal connected to the ground. Note that the voltage of the power supply Vc is hereinafter also referred to as the power supply voltage Vc.

The microcomputer 201 internally includes a processor, memory, timer, analog/digital converter, serial communication circuit, wireless module control circuit, etc., and each part in the wiring identification transmitter 2 is controlled by executing a program stored in the memory. to control. The microcomputer 201 has power supply terminals Vc and GND, analog input terminals AI1 to AI4, a digital input terminal DI1, digital output terminals DO1 to DO3, wireless module control terminals TX and RX, a serial data terminal SDA, and a serial clock. terminal SCL. In this embodiment, the microcomputer 201 is one configuration example of the second control unit of the present invention. It is assumed that the digital output terminals DO1 to DO8 have the ability to directly drive transistors and LEDs (light emitting diodes).

The battery voltage detection unit 202 has a resistor R1 and a resistor R2. The resistor R1 has one terminal connected to the power supply Vc and the other terminal connected to one terminal of the resistor R2 and the analog input terminal AI1 of the microcomputer 201 . Resistor 2 connects the other terminal to ground. Battery voltage detection unit 202 divides power supply voltage Vc, which is the terminal voltage of battery BT2, with resistors R1 and R2, and outputs the divided voltage to analog input terminal AI1 of microcomputer 201. FIG.

The alarm unit 203 has a buzzer BZ1 and a transistor TR8. One terminal of the buzzer BZ1 is connected to the power supply Vc, and the other terminal is connected to the collector of the transistor TR8. The emitter of the transistor TR8 is connected to the ground, and the base is connected to the digital output terminal DO1 of the microcomputer 201. FIG. Buzzer BZ1 sounds when transistor TR8 is turned on. The alarm unit 203 outputs an alarm sound when the digital output terminal DO1 is at H level. The alarm unit 203 is one configuration example of the second alarm unit of the present invention.

The inrush current output switch section 204 includes a switch SW1 and a resistor R23. The switch SW1 is, for example, a normally open (A contact) push button switch of momentary operation. One terminal of the switch SW1 is connected to the power supply Vc, and the other terminal is connected to the digital input terminal DI1 and one terminal of the resistor R23. The other terminal of resistor R23 is connected to the ground. The inrush current output switch unit 204 outputs an H level signal to the digital input terminal DI1 when the operator presses the switch SW1. The switch SW1 is an operator for instructing generation of a remote control signal and transmission to the wiring identification load device 1. FIG.

The LED display unit 205 includes a light emitting diode LED1, a light emitting diode LED2, a resistor R24, and a resistor R25. One end of the resistor R24 is connected to the digital output terminal DO2, and the other end is connected to the anode of the light emitting diode LED1. The cathode of the light emitting diode LED1 is connected to ground. One end of the resistor R25 is connected to the digital output terminal DO3, and the other end is connected to the anode of the light emitting diode LED2. The cathode of the light emitting diode LED2 is connected to the ground. When the digital output terminal DO2 is at H level, the light emitting diode LED1 lights up. When the digital output terminal DO2 is at L level, the light emitting diode LED1 is extinguished. When the digital output terminal DO3 is at H level, the light emitting diode LED2 lights up. When the digital output terminal DO3 is at L level, the light emitting diode LED2 is extinguished. The LED display section 205 is one configuration example of the second alarm section of the present invention. In addition, the LED display unit 205 is one configuration of an output destination when outputting the monitoring result in a predetermined output mode in the present invention.

The setting unit 206 includes a variable resistor R26 and a variable resistor R27. The variable resistor R26 has one terminal connected to the power source Vc, the other terminal connected to the ground, and the terminal connected to the movable contact connected to the analog input terminal AI2. The variable resistor R27 has one terminal connected to the power source Vc, the other terminal connected to the ground, and the terminal connected to the movable contact connected to the analog input terminal AI3. The variable resistor R26 is used, for example, to set the power supply voltage of the power supply wiring system 10 to be searched to, for example, DC 48V, AC 100V, or AC 200V. A variable resistor R27 is used, for example, to set the value of the inrush current. The setting unit 206 outputs a voltage corresponding to the position of the movable contact of the variable resistor R26 to the analog input terminal AI2. The setting unit 206 also outputs a voltage corresponding to the position of the movable contact of the variable resistor R27 to the analog input terminal AI3. The setting unit 206 is a configuration example of the setting unit of the present invention.

The liquid crystal display unit 207 includes a liquid crystal display panel LCD. The liquid crystal display panel LCD is connected to a power source Vc, a ground, a real data terminal SDA, and a serial clock terminal SCL, and displays characters and images based on control signals output from the real data terminal SDA and the serial clock terminal SCL. . The liquid crystal display section 207 is one configuration example of the second alarm section of the present invention. Further, in the present invention, the liquid crystal display unit 207 is one configuration of an output destination when outputting the monitoring result in a predetermined output mode.

The wireless communication unit 208 has a communication module RM2. The communication module RM1 is formed to communicate with the communication module RM1 of the wiring identification load device 1. FIG. The wireless communication unit 208 transmits predetermined signals such as a remote control signal, a battery voltage drop signal, and a setting signal to the wiring load device 1 . The wireless communication unit 208 receives predetermined signals such as a battery voltage drop signal, a capacitor high voltage signal, and a response signal from the wiring identification load device 1 . The communication module RM2 performs wireless communication with the communication module RM1 either directly or via an access point or the like (not shown). The wireless communication unit 208 (or a functional configuration obtained by combining the functions of the wireless communication unit 208 and a part of the microcomputer 201) is one configuration example of the second communication processing unit of the present invention.

Further, in this embodiment, an analog signal indicating the current value measured by the clamp-type current sensor 2s is input to the analog input terminal AI4. The microcomputer 201, for example, outputs the current waveform measured by the clamp-type current sensor 2s from the liquid crystal display unit 207, and outputs information indicating the comparison result between the predicted current waveform and the measured current waveform from the liquid crystal display unit 207. or

Next, an operation example of the wiring identification transmitter 2 will be described with reference to FIG. FIG. 4 is a flow chart showing an operation example of the wiring identification transmitter 2 according to the embodiment of the present invention. The process shown in FIG. 4 is repeatedly executed at a predetermined cycle after the wiring identification transmitter 2 is activated and after a predetermined initialization process is performed. Note that wireless communication section 107 and wireless communication section 208 perform wireless communication in parallel with the processing of FIG. 4 and FIG. It is assumed that the storage unit has a function of storing data.

In the process shown in FIG. 4, first, the microcomputer 201 acquires a voltage value corresponding to the battery voltage detected by the battery voltage detector 202 input to the analog input terminal AI1 (step S101). Next, the microcomputer 201 determines whether or not the battery voltage is equal to or less than a predetermined value (step S102). If the battery voltage is not equal to or lower than the predetermined value (step S102: NO), the microcomputer 201 determines whether the wireless communication unit 208 has received a low battery signal (step S103). If the low battery signal has not been received (step S103: NO), the microcomputer 201 determines whether the wireless communication unit 208 has received the capacitor high voltage signal (step S104). If the capacitor high voltage signal has not been received (step S104: NO), the microcomputer 201 stops outputting an alarm from the alarm unit 203 (step S105). In step S105, if the output of the alarm has been stopped, the microcomputer 201 may execute a process of outputting a signal to stop again, or may execute nothing.

After the process of step S105, the microcomputer 201 acquires the voltage values (hereinafter also referred to as setting states) output by the setting unit 206 to the analog input terminals AI2 and AI3 (step S106). Next, the microcomputer 201 generates a setting signal based on the setting state, and transmits the generated setting signal from the wireless communication section 208 to the wiring identification load device 1 (step S107).

Next, the microcomputer 201 determines whether or not the switch SW1 of the rush current output switch section 204 has been operated (step S108). If the switch SW1 of the inrush current output switch unit 204 has been operated (depressed) (step S108: YES), the microcomputer 201 transmits a remote control signal from the wireless communication unit 208 to the wiring identification load device 1 (step S109). . Next, the microcomputer 201 sounds the buzzer BZ1 of the alarm unit 203 for a predetermined time to output an alarm (step S110).

The output of the alarm in step S110 was made when another worker mistakenly connected the wiring identification load device 1 and the power supply lines 41 and 41 of the distribution board 51 during remote control of the inrush current. This is to prevent the operator from receiving an electric shock, impact, etc. When the inrush current output switch SW1 provided in the wiring identification transmitter 2 is pressed, the buzzer BZ1 of both the wiring identification transmitter 2 and the wiring identification load device 1 or either of the alarm units 203 or 104 is activated for a certain period of time. , for example, to alert workers around both devices. As a result, the risk of electric shock, shock, etc. to the operator is reduced. Note that the output of the alarm may be performed using the liquid crystal display section 207, the LED display section 205, or the like.

Next, the microcomputer 201 determines whether or not the wireless communication section 208 has received a response signal from the wiring identification load device 1 (step S111). If no response signal has been received (step S111: NO), the microcomputer 201 determines whether or not a predetermined time has passed since the remote control signal was transmitted (step S112). If the predetermined time has not passed (step S112: NO), the microcomputer 201 again determines whether or not the wireless communication section 208 has received a response signal from the wiring identification load device 1 (step S111).

When the response signal has been received (step S111: YES), the microcomputer 201 outputs information indicating the monitoring result of the operating state of the load application unit 105 indicated by the response signal from the liquid crystal display unit 207 or the like (step S113). 4 ends. If the response signal has not been received after the predetermined time has passed (step S112: YES), the microcomputer 201 outputs information indicating that the response signal could not be received from the liquid crystal display unit 207 or the like (step S113). , ends the processing shown in FIG.

On the other hand, if the battery voltage is equal to or less than the predetermined value (step S102: YES), the microcomputer 201 transmits a battery voltage drop signal from the wireless communication section 208 to the wiring identification load device 1 (step S114). Next, the microcomputer 201 outputs an alarm to the effect that the battery voltage has dropped from the alarm unit 203, the liquid crystal display unit 207, etc. (step S115), and ends the processing shown in FIG.

When the wireless communication unit 208 receives the low battery signal (step S103: YES), the microcomputer 201 issues an alarm to the effect that the battery voltage of the wiring identification load device 1 has decreased from the alarm unit 203, the liquid crystal display unit 207, and the like. output (step S115), and the process shown in FIG. 4 ends.

When the wireless communication unit 208 receives the capacitor high voltage signal (step S104: YES), the microcomputer 201 detects from the alarm unit 203, the liquid crystal display unit 207, etc. that the voltage of the capacitor C1 of the wiring identification load device 1 is high. An alarm to that effect is output (step S115), and the process shown in FIG. 4 is terminated.

Next, an operation example of the wiring identification load device 1 will be described with reference to FIG. FIG. 5 is a flow chart showing an operation example of the wiring identification load device 1 according to the embodiment of the present invention. The process shown in FIG. 5 is repeatedly executed at a predetermined cycle after the wiring identification load device 1 is activated and after a predetermined initial setting process is performed.

In the process shown in FIG. 5, first, the microcomputer 101 acquires a voltage value corresponding to the battery voltage detected by the battery voltage detection unit 102 input to the analog input terminal AI1 (step S201). Next, the microcomputer 101 determines whether or not the battery voltage is below a predetermined value (step S202). If the battery voltage is not equal to or lower than the predetermined value (step S202: NO), the microcomputer 101 acquires the comparison result between the voltage of the capacitor C1 output by the capacitor voltage detection unit 103 input to the digital input terminal DI1 and the predetermined value. (Step S203). Next, the microcomputer 101 determines whether the voltage of the capacitor C1 is equal to or higher than a predetermined value based on the value of the digital input terminal DI1 (step S204). If the voltage of the capacitor C1 is not equal to or higher than the predetermined value (step S204: NO), the microcomputer 101 determines whether the wireless communication section 107 has received the low battery signal (step S205).

If the low battery signal has not been received (step S205: NO), the microcomputer 101 stops outputting an alarm from the alarm unit 104 (step S206). In step S206, if the output of the alarm has been stopped, the microcomputer 101 may execute a process of outputting a signal to stop again, or may execute nothing.

After the process of step S206, the microcomputer 101 turns on or off the selection relays RY2 to RY7 based on the setting signal received by the wireless communication unit 107 from the wiring identification transmitter 2 (step S207). Next, the microcomputer 101 determines whether or not the wireless communication section 107 has received the remote control signal (step S208). When the remote control signal is received (step S208: YES), the microcomputer 101 sounds the buzzer BZ1 of the alarm unit 104 for a predetermined time to output an alarm (step S209).

Next, the microcomputer 101 outputs a predetermined signal from the digital output terminal DO2 to control the contact corresponding to the switch 14 of the load applying section 105, and changes the state of the monitoring contact based on the input signal of the digital input terminal DI2. Acquire (step S210). Next, the microcomputer 101 generates a response signal based on the acquired state of the monitoring contact, transmits it from the wireless communication section 107 to the wiring identification transmitter 2 (step S211), and ends the processing shown in FIG.

On the other hand, if the battery voltage is equal to or less than the predetermined value (step S202: YES), the microcomputer 101 transmits a battery voltage drop signal from the wireless communication section 107 to the wiring identification transmitter 2 (step S212). Next, the microcomputer 101 outputs an alarm indicating that the battery voltage has decreased from the alarm unit 104 or the like (step S214), and terminates the processing shown in FIG.

On the other hand, when the voltage of the capacitor C1 is equal to or higher than the predetermined value (step S204: YES), the microcomputer 101 transmits a capacitor high voltage signal from the wireless communication section 107 to the wiring identification transmitter 2 (step S213). Next, the microcomputer 101 outputs an alarm to the effect that the voltage of the capacitor C1 is high from the alarm unit 104 or the like (step S214), and ends the processing shown in FIG.

Further, when the wireless communication unit 107 receives the low battery signal (step S205: YES), the microcomputer 101 outputs an alarm to the effect that the battery voltage of the wiring identification transmitter 2 has decreased from the alarm unit 104 or the like (step S214 ), the process shown in FIG. 5 ends.

As described above, according to this embodiment, the power supply line can be identified by passing a predetermined rush current through the load 13 in the wiring identification load device 2 by remote control, and the wiring can be safely searched. can.

In addition, according to this embodiment, it is possible to detect cables for a plurality of power supply types with one type of wiring identification load device, and it is possible to reduce product costs (development and manufacturing) by unifying the lineup.

In addition, the safety of wiring inspection and the reliability of work have been improved by the detection function of capacitor voltage, battery voltage, alarm function, etc.

In addition, inrush current can be easily controlled remotely, improving work efficiency. In addition, the setting status of the wiring identification load device can be confirmed with the wiring identification transmitter at hand, reducing the risk of misoperation of the device. can be reduced.

Further, in the operation example described above, when the voltage of the capacitor C1 is equal to or higher than the predetermined value, both the wiring identification load device 1 and the wiring identification transmitter 2 output an alarm. Therefore, it is possible to alert workers around both the wiring identification load device 1 and the wiring identification transmitter 2 that the voltage of the capacitor C1 is equal to or higher than the predetermined value.

(Modification of the first embodiment)
In the above embodiment, an example of application to wiring for two-wire single-phase alternating current has been described, but instead of this, it may be applied to wiring for three-wire single-phase alternating current. Wiring for three-wire single-phase alternating current includes first-phase and second-phase wiring as well as a medium wire. In this case, the power supply wiring system 10 having the first terminal 11 and the second terminal 12 may be used by connecting to the above two wires. Note that the AC voltage applied to the first terminal 11 and the second terminal 12 varies depending on the combination of connection destinations.

(Second embodiment)
In the first embodiment, an example of application to wiring for single-phase AC or wiring for DC has been described, but instead of this, application may be made to wiring for three-phase AC. In this case, change the configuration as follows.

For example, the diode bridge DB (FIG. 2) may be a full-wave rectifier for three-phase alternating current. The AC input side of the diode bridge DB in this case is connected from the first terminal for external connection to the third terminal (not shown). The first to third terminals are used instead of the first terminal 11 and the second terminal 12 described above, and are connected to the distribution board.

The current changes according to the pulse current generated by the power supply wiring system 10 regardless of the phase of the fundamental wave of the three-phase alternating current. However, the magnitude of the pulse current flowing in each phase of the three-phase alternating current changes depending on the phase of the fundamental wave of the three-phase alternating current and the timing of the pulse current generated by the power wiring system 10 . Therefore, when applying to three-phase AC wiring, it is preferable to generate pulse currents a plurality of times while maintaining the same connection configuration, and to determine the appropriateness of cable selection based on the results.

Although the embodiments of the present invention have been described above with reference to the drawings, the specific configuration is not limited to the above embodiments, and design changes and the like are also included within the scope of the present invention.

For example, in the above embodiment, the result of comparison by the comparator CMP between the voltage of the capacitor C1 and a predetermined voltage is input to the microcomputer 101. For example, a voltage obtained by dividing the voltage of the capacitor C1 is input to the analog input terminal. You may make it

Also, part or all of the programs executed by the computer in the above embodiments can be distributed via computer-readable recording media or communication lines.

DESCRIPTION OF SYMBOLS 100... Wiring investigation system, 10... Power supply wiring system, 1... Wiring identification load apparatus, 2... Wiring identification transmitter, 2s... Clamp-type current sensor, 11... First terminal, 12... Second terminal, 15... Series circuit, RY1 to RY7...relays, 13...loads, R11 to R19...resistors (loads), C1...capacitors (loads), R3...resistors (discharge resistors), 301, 302, 303, 304, 305, 306, 41, 42... Power supply line BT1, BT2 Battery 101 Microcomputer (first control unit) 201 Microcomputer (second control unit) 102, 202 Battery voltage detection unit 103 Capacitor voltage detection unit 104 Alarm unit ( 1st alarm unit), 203 alarm unit (second alarm unit), 105 load application unit, 106 load selection unit, 107 wireless communication unit (first communication processing unit), 208 wireless communication unit (second communication processing section), 204... inrush current output switch section, 205... LED display section, 206... setting section, 207... liquid crystal display section

Claims (7)

a wire identification transmitter for transmitting remote control signals for remote control;
a wire identification load device for receiving the remote control signal from the wire identification transmitter;
A wiring probe system comprising:
The wiring identification load device is
a first terminal connected to one of a first power line and a second power line forming a pair of power lines;
a second terminal connected to the other;
a series circuit including a load and a switch;
a first communication processing unit configured to communicate with the wiring identification transmitter and receive the remote control signal from the wiring identification transmitter;
a first control unit that causes the series circuit to generate an inrush current in response to reception of the remote control signal, and causes the first communication processing unit to transmit a response signal corresponding to the generation of the inrush current;
with
The wiring identification transmitter includes:
a second communication processing unit configured to communicate with the wiring identification load device;
a second control unit that transmits the remote control signal from the second communication processing unit in response to an operation;
with
The first control unit causes the inrush current to flow between the first terminal and the second terminal by turning on or off the switch, monitors the operation of the switch, and indicates the result of monitoring. generating the response signal as a signal, transmitting the response signal from the first communication processing unit;
The wiring survey system, wherein the second control unit outputs the monitoring result in a predetermined output mode when the second communication processing unit receives the response signal. The wiring identification load device includes a first alarm unit that issues an alarm,
The wiring identification transmitter includes a second alarm unit that issues an alarm,
2. The wiring survey system according to claim 1, wherein at least one of said first alarm unit and said second alarm unit issues an alarm for a predetermined time when an operation to transmit said remote control signal is performed. the wire identification load device is powered by a battery;
When the voltage of the battery is equal to or less than a predetermined value, the first control unit causes the first communication processing unit to transmit a battery voltage drop signal indicating that the voltage of the battery is equal to or less than the predetermined value,
The wiring survey system according to claim 2, wherein the second control unit issues an alarm from the second alarm unit when the second communication processing unit receives the battery voltage drop signal. the load includes a capacitor;
When the voltage of the capacitor is equal to or higher than a predetermined value, the first control unit causes the first communication processing unit to transmit a capacitor high voltage signal indicating that the voltage of the capacitor is equal to or higher than the predetermined value,
The wiring survey system according to claim 2, wherein the second control unit issues an alarm from the second alarm unit when the second communication processing unit receives the capacitor high voltage signal. The switch is a contact of a relay (hereinafter referred to as a relay contact),
The wiring survey system according to claim 1, wherein the first control unit monitors the operation of the relay contact based on the operation of another relay contact and generates the response signal. The load includes a plurality of resistors, at least some of which have different resistance values, and a plurality of selection relays that selectively operate the resistors,
The second control unit causes the second communication processing unit to transmit a setting signal corresponding to a setting state of a predetermined setting unit,
The wiring survey system according to any one of claims 1 to 5, wherein the first control section controls the selection relay to turn on or off based on the setting signal received by the first communication processing section. a wire identification transmitter for transmitting remote control signals for remote control;
a wire identification load device for receiving the remote control signal from the wire identification transmitter;
A control method for a wiring survey system comprising
The wiring identification load device is
a first terminal connected to one of a first power line and a second power line forming a pair of power lines;
a second terminal connected to the other;
a series circuit including a load and a switch;
a first communication processing unit configured to communicate with the wiring identification transmitter and receive the remote control signal from the wiring identification transmitter;
a first control unit that causes the series circuit to generate an inrush current in response to reception of the remote control signal, and causes the first communication processing unit to transmit a response signal corresponding to the generation of the inrush current;
with
The wiring identification transmitter includes:
a second communication processing unit configured to communicate with the wiring identification load device;
a second control unit that transmits the remote control signal from the second communication processing unit in response to an operation;
with
By turning on or off the switch by the first control unit, the inrush current is caused to flow between the first terminal and the second terminal, the operation of the switch is monitored, and the result of monitoring is displayed. generating the response signal as a signal and transmitting the response signal from the first communication processing unit;
and a step of causing the second control unit to output the monitoring result in a predetermined output mode when the second communication processing unit receives the response signal.

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