JP2013217809A - Handy type wiring checker and method for checking wiring conduction - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a handy type wiring checker capable of checking conduction of apparatus wiring without laying a long electric line for wiring conduction check and, even in a state where the wiring and a housing is in a conduction state, capable of performing detection, and a method for checking the wiring conduction.SOLUTION: Both ends (A and B) of wiring of a test object line 4 subject to a conduction check are connected to a housing 5 via resistors (2 and 3) respectively. A DC voltage is applied to the end of the test object line 4 by a battery 1. Potentials of the respective resistors (2 and 3) are measured to check the conduction of the test object line 4. The potentials of the resistors (2 and 3) are measured by classifying them into a plurality of levels such as an intermediate potential, a high potential and a low potential, or the intermediate potential and the low potential.

Description

  The present invention relates to a handheld wiring checker and a wiring continuity confirmation method used for a continuity test of equipment wiring between two points.

Conventionally, various devices have been developed as devices for checking the continuity of cables and wiring (see, for example, Patent Documents 1 to 4).
Conventionally, when a continuity check is performed in a device wiring continuity test, as shown in FIG. 8, a wiring checker 50 (battery 53 and buzzer 54 is connected to both ends (Ta, Tb) of the line under test 4 (wiring) for continuity check. If the two check rods (51, 52) are in contact and both ends (Ta, Tb) are conducting, the buzzer 54 (bell is also acceptable) will ring, It was confirmed that the wiring was connected.

  When confirming the continuity between both ends of a long test wire, as shown in FIG. 9, one end of the test wire 4 is connected to the ground by a fuse clip 55, and the other end is connected to a wiring checker 50 (battery 53 and buzzer 54). Connected to the ground via a built-in), and the continuity was confirmed by whether or not the buzzer 54 of the wiring checker 50 sounded. This is because when both ends of the tested wire 4 are correctly both ends of the same tested wire, a current flows through a closed circuit constituted by the tested wire 4 and the ground, and the buzzer 54 of the wiring checker 50 It used to ring.

Japanese Patent Laid-Open No. 05-322956 JP-A-11-006848 JP 2002-257890 A JP 2003-270282 A

  As described above, the conventional wiring check method is a method for confirming the presence or absence of continuity of the line under test by a very simple method of connecting the battery and buzzer. For this reason, it was necessary to feed an electric wire (return line) for the length of the line under test. For example, when performing a verification test on the train's outfitting wiring at the ends of the vehicle, it has been necessary to wire an electric wire that will be a return line of a length (about 20 m) for one vehicle. For this reason, the workability of the continuity check is poor, and there is a problem that the test line cannot be detected when the test line is in contact with the casing in the middle.

  In addition, in the confirmation method in which one end of the wire under test is connected to ground with a fuse clip and the other end is connected to ground via a wiring checker, the continuity check cannot be confirmed at the end where the fuse clip is connected. Similarly to the above, there is a problem that when the line under test is in contact with the casing on the way and is grounded (conducting with the casing), it cannot be detected.

  The present invention has been made in order to solve the above-described problem, and it is possible to check the continuity of the equipment wiring without having to squeeze a long electric wire for checking the continuity of the wiring. It is an object of the present invention to provide a handheld wiring checker and a wiring continuity confirmation method that can be detected even when they are in a conductive state.

In order to achieve the above object, a handy type wiring checker according to a first aspect of the present invention is a set of two wiring checkers (first wiring checker and second wiring checker provided at both ends of a line to be tested for continuity confirmation. Wiring checker), which is composed of the following elements.
(1) 1st wiring checker The 1st resistor, the 1st electric potential detection part, and DC power supply are provided.
A first resistor and a DC power source are connected in series between one end of the wire under test and the ground.
The first potential detector detects the potential of the first resistor.
(2) Second wiring checker A second resistor and a second potential detector are provided.
A second resistor is connected in series between the other end of the wire under test and the ground.
The second potential detection unit detects the potential of the second resistor.

  According to such a configuration, the plus (+) side check bar and the minus (−) side check bar included in the first wiring checker are respectively applied to one end of the line under test and the casing in the vicinity thereof, and the second wiring The continuity check of the line under test (wiring) can be performed by placing the plus (+) side check bar and the minus (-) side check bar of the checker against the other end of the line under test and the housing in the vicinity thereof. . By using the device to be tested or the housing of the device as a part of the test circuit, there is no need to wire the wires for continuity check. For example, work when the wiring length of the device is long, such as train wiring Efficiency can be improved.

  Here, the case near the one end of the line under test and the case near the other end of the line under test need not be the same case. However, it is necessary that the casings are both connected to the ground or the casings are electrically connected.

Resistors are provided at both ends of the line under test, and a DC voltage is applied to only one end of the line under test, resulting in a series connection of DC voltage-resistor-line under test-resistor, and the line under test is in a conductive state In this case, both ends of the wire under test are divided by resistors. For this reason, when the size of the two resistors is the same and the wire under test is in a conductive state, the potential at both ends of the wire under test is ½ of the DC voltage.
In addition, when the wire under test is disconnected or not connected, the potential of the end of the wire under test where the DC voltage is applied is the DC voltage itself (however, the potential drops due to the voltage drop due to the resistor) The potential at the end of the line under test to which no DC voltage is applied is zero.
In addition, when the line under test is grounded (the wiring is in contact with the housing), the potential of the end of the line under test where the DC voltage is applied and the line under test where the DC voltage is not applied The potential at the end of is zero.
As described above, the above-described handheld wiring checker can detect a ground fault (conducting state between the casings) in the middle of the wiring.

In the handheld wiring checker, the first potential detection unit includes an intermediate potential detection unit, a high potential detection unit, and a low potential detection unit. The second potential detection unit includes an intermediate potential detection unit and a low potential detection unit.
The intermediate potential detector detects a state in which the potential at both ends of the line under test is ½ of the DC voltage. That is, the intermediate potential detection unit detects the conductive state of the wire under test.
The high potential detector detects a state in which the potential at the end of the line under test to which the DC voltage is applied becomes the DC voltage itself. That is, the high potential detection unit detects a state in which the test line is disconnected or not connected. However, since only the potential at the end of the line under test on the side to which the DC voltage is applied becomes a high potential, the wiring checker connected to the end of the line under test on the side to which the DC voltage is applied is in this state. Is detected.
The low potential detector detects a state in which the potential at the end of the line under test is zero. A wiring checker connected to the end of the line under test to which the DC voltage is applied detects a case where the line under test is grounded (the wiring is in contact with the housing).

In addition, the handy type wiring checker according to the second aspect of the present invention is a set of two wiring checkers (first wiring checker and second wiring checker) provided at both ends of the tested wire to be confirmed for continuity. It consists of the following elements.
The first wiring checker is the same as the handy wiring checker of the first aspect described above. That is, a first resistor, a first potential detection unit, and a DC power source are provided, a first resistor and a DC power source are connected in series between one end of the wire under test and the ground, and the first potential detection unit is The potential of the first resistor is detected.
On the other hand, the second wiring checker includes only the second resistor, unlike the handy wiring checker of the first aspect.

  According to such a configuration, since the circuit voltage can be detected by dividing the voltage with the resistors at both ends of the wire under test, it is possible to detect even when the wiring is in the middle of a ground fault (conducting state between the casings).

Further, in the above-described handheld wiring checker, more preferably, a notification means for notifying the detection result of the potential detection unit by sound and LED display is provided.
The sound is announced with a buzzer or bell. In LED display, for example, indicator lights such as “conduction”, “ground fault”, and “open” are lit with green and red LEDs.

Next, the wiring continuity confirmation method of the present invention will be described.
In the wiring continuity confirmation method of the present invention, both ends of the wiring of the wire under test for continuity confirmation are respectively connected to the ground via resistors, and a DC voltage is applied to one end of the wiring of the wire under test, The continuity of the line under test is checked by measuring the potential of the resistor or the potential of the resistor on the side to which the DC voltage is applied.
That is, in the wiring continuity confirmation method of the present invention, first, resistors are connected to both ends of the wiring to be subjected to the continuity test. A battery for applying a DC potential is connected to one of them. Connect the ground side of the battery to the ground. Connect the other side of the other resistor to ground. By connecting in this way, a closed loop circuit is configured. By measuring the potential at both ends of the wiring at this time, it is confirmed whether or not the wiring is conducting and whether or not the wiring is properly performed.
Instead of measuring the potential at both ends of the wiring, only the potential of the resistor on the side connected to the battery, that is, the side to which the DC voltage is applied may be measured. In this case, it is possible to easily measure with one wiring checker by incorporating two resistors connected to both ends of the wiring into one wiring checker.

Here, in the wiring continuity confirmation method of the present invention, specifically, a return line constituting the test circuit for the line under test is an equipment case.
In the wiring continuity confirmation method of the present invention, by using the casing of the device or apparatus to be tested as a part of the test circuit (return line), there is no need to wire the wires for continuity check. As described above, it is possible to improve the work efficiency when the wiring length of the device is long and to detect the ground fault (the wiring contacts the casing). In addition, when the line under test is long, for example, in the case of a long wiring such as a train, it can be confirmed at two places on both sides of the wiring, so double checking at two places is possible.

According to the handy type wiring checker and the wiring continuity check method of the present invention, resistors are connected to both ends of the wiring to be subjected to the continuity test, and the device casing is used for a part (return line) of the closed circuit of the continuity test. By doing so, there is an effect that the test can be performed without breaking the test electric wire at the time of the confirmation test of the long outfitting wiring like a train.
In addition, by displaying the check result on both of the wirings for which the continuity test is performed, it is possible to check each of the both ends of the wiring, and there is an effect that two people at both ends of the wiring can double check.

Illustration of the measurement principle of the hand-held wiring checker Explanatory diagram of voltage level status of handheld wiring checker (I side and II side) Configuration diagram of handy type wiring checker (I side and II side) of Example 1 External view of handheld wiring checker Configuration diagram of handy type wiring checker (I side and II side) of Example 2 Configuration diagram of handy type wiring checker (I side) of embodiment 3 External appearance image diagram of the handheld wiring checker according to the third embodiment Conventional wiring checker usage example (1) Usage example of conventional wiring checker (2)

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The scope of the present invention is not limited to the following examples and illustrated examples, and various changes and modifications can be made.

FIG. 1 is an explanatory diagram of the measurement principle of the handheld wiring checker of the present invention. A resistor 2 (R1) and the positive side of the battery 1 having a generated voltage of V (volts) are connected to one end (I side) of the wire under test 4. The negative (−) side of the battery 1 is electrically connected to a casing 5 (such as a vehicle body) of the device.
On the other hand, a resistor 3 (R2) having the same resistance value as that of the resistor 2 is connected to the other end (II side) of the wire under test 4, and one of the resistors 3 is connected to the housing 5. It is connected. Therefore, a closed loop of the test circuit is configured by the battery 1 -resistor 2 -tested wire 4 -resistor 3 -housing 5.

Next, the operation of the handheld wiring checker will be described. FIG. 2 is an explanatory diagram of the voltage level state of the handheld wiring checker (I side and II side).
When the above closed-loop circuit is configured, that is, when there is continuity between both ends (between A and B) of the line under test 4 in FIG. 1, the indication value of the voltmeter (11, 12) is the same as that of the resistor 2 Since the voltage is divided by the resistor 3, it is exactly half the voltage V volts of the battery 1. That is, the indicated value of the voltmeter (11, 12) indicates a voltage value of 1/2 × V (volt).

However, when the line under test 4 is not connected or when there is no continuity between A and B due to poor contact, the voltmeter 11 on the I side (the A end of the line 4 under test) is the battery voltage V volts. Instruct. At this time, the voltmeter 12 on the II side (the B end of the wire 4 to be tested) is 0 volts because A-B is open.
On the other hand, when the wire under test 4 is in contact with the housing in the middle of A-B, that is, when there is a ground fault, the potential on the I side (the A end of the wire under test 4) is negative (−) of the battery 1. It becomes the same as the electric potential, and the voltmeter on the I side becomes 0 volts.

Next, FIG. 3 shows a configuration diagram of the handheld wiring checker of the present invention. The concept of the closed-loop test circuit configuration is the same as in FIG.
First, a hand-held type wiring checker on the I side (A end of the line under test 4) will be described with reference to FIG. Instead of the voltmeter of FIG. 1, as shown in FIG. 3, a high level detection circuit 9 that detects a voltage at the time of opening, an intermediate potential detection circuit 8 that detects a voltage at normal time (conduction state between A and B), The low level detection circuit 10 that detects the voltage at the time of ground fault (contact state with the casing), the detection circuit that detects each voltage value, the operation indicator lamps (17 to 19) of each detection circuit, the buzzer 16, It consists of a battery 1, a switch 13 and a resistor 2.
On the other hand, the handy type wiring checker on the II side (the B end of the wire 4 to be tested) is composed of only the resistor 3 as the simplest one. However, when only the resistor 3 is used, the conduction state cannot be confirmed on the II side. Therefore, it is better to provide an indicator lamp and a buzzer as in Example 2 described later.

Next, the operation of the handheld wiring checker of the present invention will be described. When there is continuity between lines A and B of the line under test 4, that is, when the connection is made normally, the intermediate potential detection circuit 8 operates and the buzzer sounds at the same time as the “continuity” indicator lights. As a result, the tester can be informed that the line under test is in a conductive state.
Further, when the line under test is not in a conductive state, that is, when it is disconnected or not connected, or when the contact is poor, the high level detection circuit 9 operates and the “open” indicator lamp lights up. In addition, when the case is grounded between A and B of the line under test, the Low level detection circuit 10 operates and the “ground fault” indicator lamp is lit.

FIG. 4A shows an outline image diagram of the handheld wiring checker 30 on the I side (the A end of the line under test 4). 31 is a plus (+) side check bar, and 32 is a minus (−) side check bar. Reference numerals 33 to 35 are indicator lights, and 36 is a buzzer. Reference numeral 37 denotes a switch for turning on / off the power. Reference numerals 38 and 39 denote a plus (+) side terminal and a minus (−) side terminal, respectively.
For example, if the wiring is regularized and there is continuity, a green indicator light and buzzer are sounded to inform the tester with eyes and ears. In the non-conducting state (open state), the red indicator lamp is turned on, and in the ground fault state (contacting the casing), the yellow indicator lamp is turned on.

As described above, the handheld wiring checker according to the present invention uses a housing for a part of a loop of a test circuit, and detects a circuit voltage by dividing the resistance with resistors at both ends of the line under test. It is also possible to detect when the wiring is in the middle of ground fault (conducting state between the casings).
In addition, there is an advantage in simplifying the work that the test can be performed without breaking the test electric wire, especially in the confirmation test of the outfitting wiring having a long test line length like a train.

In Example 1 described above, only the resistor 3 is the handy type wiring checker on the II side (the B end of the wire under test 4). However, it is possible to confirm the conduction state on the II side. As a result, double check can be performed by two persons at both ends of the line under test 4, and the reliability of the inspection can be improved.
In the second embodiment, a handheld wiring checker capable of confirming the conduction state on the II side will be described.
As shown in FIG. 2 (2), on the II side, the voltage level is 0 volts regardless of whether the wire under test 4 is in the open state or in contact with the housing (ground fault). For this reason, as shown in FIG. 5, the handheld wiring checker 7 on the II side includes two detection circuits, that is, an intermediate potential detection circuit 14 and a low level detection circuit 15, and operation indicator lamps (21, 22) of the respective detection circuits. ), Buzzer 20, battery 1, switch 13 and resistor 3.

  FIG. 4B shows an outline image of the handheld wiring checker 40 on the II side. 41 is a plus (+) side check bar, and 42 is a minus (−) side check bar. 44 to 44 are indicator lights, and 46 is a buzzer. Reference numeral 47 denotes a switch for turning on / off the power. Reference numerals 48 and 49 denote a plus (+) side terminal and a minus (−) side terminal, respectively. If there is continuity as with the I side, the tester is informed with the eyes and ears by sounding the green “continuity” indicator and buzzer. In the non-conducting state (open state) or the ground fault state (contacting the casing), the red “abnormal” indicator lamp is lit as an abnormal state without conduction.

  In the above description, the case where the case is used for the closed loop of the test circuit has been described as an example. However, each of the handheld wiring checker 6 on the I side and the handy wiring checker 7 on the II side directly without using the case. It is also possible to connect the minus (−) terminals to each other.

In the third embodiment, an apparatus that can be tested by the handheld wiring checker 6 on the I side alone will be described.
When the distance of the line under test is short, it is more efficient to perform the test with one checker. By incorporating the resistor 3 on the II side in the handheld wiring checker on the I side, it is possible to test even with the handheld wiring checker on the I side alone.

FIG. 6 is a configuration diagram of the handheld wiring checker (I side) according to the third embodiment. As shown in FIG. 6, a high level detection circuit 9 for detecting a voltage at the time of opening, an intermediate potential detection circuit 8 for detecting a voltage at normal time (conducting state between the A end and the B end of the line 4 to be tested), The low level detection circuit 10 that detects the voltage at the time of contact (contact state with the housing), the detection circuit that detects each voltage value, the operation indicator lamps (17 to 19) of each detection circuit, the buzzer 16, and the battery 1 and the switch 13 and the resistor 2 are the same as the handheld wiring checker (I side) of the first and second embodiments.
In FIG. 6, unlike the handheld wiring checker (I side) of the first and second embodiments, a plus (+) side terminal and a minus (−) side terminal connected to the B end of the wire 4 to be tested A resistor 3 is provided between the two.

FIG. 7 shows an outline image diagram of the handheld wiring checker (I side) 60 of the third embodiment. 31 is a plus (+) side check bar, and 32 is a minus (−) side check bar. Reference numerals 33 to 35 are indicator lights, and 36 is a buzzer. Reference numeral 37 denotes a switch for turning on / off the power. Further, 38 and 61 are plus (+) side terminals, and 39 is a minus (−) side terminal. The two plus (+) terminals (38, 61) are connected to the A terminal Ta and the B terminal Tb of the wire under test 4, respectively. This may be reversed. Further, the minus (−) side terminal 39 is connected to the housing 5 (earth).
By using one such hand-held type wiring checker (I side) alone, both ends of the wiring of the wire under test for continuity confirmation are respectively connected to the ground via resistors, and the wiring of the wire under test is connected. The continuity of the line under test can be confirmed by applying a DC voltage to one end and measuring the potential of the resistor to which the DC voltage is applied.

  INDUSTRIAL APPLICABILITY The present invention is useful as a continuity confirmation test device for wiring between devices (devices) or in a device.

1,52 Battery 2,3 Resistor 4 Wire under test 5 Case 6, 30, 60 Hand-held wiring checker (I side)
7, 40 Handy type wiring checker (II side)
8, 14 Intermediate potential detection circuit 9 High level detection circuit 10, 15 Low level detection circuit 11, 12 Voltmeter 13, 37, 47 Switch 16, 20, 36, 46, 54 Buzzer 17, 18, 19, 21, 22 LED
31, 32, 41, 42 Check rod 33-35, 43, 44 Indicator 38, 39, 48, 49, 61 Terminal 50 Conventional wiring checker 55 Fuse clip Ta, Tb terminal R1, R2 Resistor

Claims (7)

A set of two wiring checkers provided at both ends of the line under test for continuity confirmation,
The first wiring checker includes
A first resistor, a first potential detector and a DC power supply;
A first resistor and a DC power source are connected in series between one end of the wire under test and the ground,
The first potential detector detects the potential of the first resistor,
The second wiring checker
A second resistor and a second potential detector are provided;
A second resistor is connected in series between the other end of the wire under test and the ground,
The second potential detector detects the potential of the second resistor;
Handy type wiring checker characterized by that. A set of two wiring checkers provided at both ends of the line under test for continuity confirmation,
The first wiring checker includes
A first resistor, a first potential detector and a DC power supply;
A first resistor and a DC power source are connected in series between one end of the wire under test and the ground,
The first potential detector detects the potential of the first resistor,
The second wiring checker
A second resistor was provided,
Handy type wiring checker characterized by that.   The first potential detector includes an intermediate potential detector, a high potential detector, and a low potential detector. The second potential detector includes an intermediate potential detector and a low potential detector. The handy type wiring checker according to claim 1, which is provided.   The handheld wiring checker according to claim 2, wherein the first potential detector includes an intermediate potential detector, a high potential detector, and a low potential detector.   5. The handheld wiring checker according to claim 1, further comprising notification means for notifying the detection result of the potential detection unit by sound and LED display.   Connect both ends of the wire under test for continuity to the ground via resistors, apply a DC voltage to one end of the wire under test, and apply the potential or DC voltage of each resistor. A method for confirming the continuity of wiring, wherein the continuity of the line under test is confirmed by measuring the potential of the resistor on the finished side. 7. The wiring continuity confirmation method according to claim 6, wherein a return line constituting a test circuit for the line under test is an equipment casing.