KR20220158376A - method of measuring for insulation resistance of load and device of measuring for insulation resistance of load - Google Patents

Abstract

A method for measuring an insulation resistance of a load electrically connected to a power cable including a conductor layer for transmitting electricity and a shielding layer for shielding the conductor layer comprises the steps of: electrically connecting a cable probe receiving the cable leakage current to the shielding layer to prevent the cable leakage current, which is the leakage current caused by the power cable, from being transmitted through the load to a grounding member grounding the load; measuring a voltage applied to the power cable from a power source supplying power; measuring a load leakage current, which is a current leaked through the grounding member; and calculating the insulation resistance of the load based on the measured value of the measured voltage and the measured value of the measured load leakage current. The present invention can measure an insulation resistance of a load and an insulation resistance of a power cable, respectively.

Description

Load insulation resistance measuring method and load insulation resistance measuring device {method of measuring for insulation resistance of load and device of measuring for insulation resistance of load}

The present invention relates to a method for measuring the insulation resistance of a load and an apparatus for measuring the insulation resistance of a load.

In general, an insulator refers to a material that does not conduct electricity well due to its very low electrical conductivity. Further, insulation resistance refers to electrical resistance of an insulator that appears when a voltage is applied to such an insulator.

In general, a load refers to an element, device, electric facility, or the like that consumes power in a circuit. Such a load may include an insulating member for insulation in order to prevent the supplied current from leaking to the surface of the load or to the outside of the load.

When the insulation resistance of the insulating member included in the load is lowered due to deterioration, the electric power supplied to the load may be short-circuited and may cause an electric shock accident. Alternatively, when the insulation resistance is lowered, the performance of the load may deteriorate or it may lead to failure and/or damage of the load.

Therefore, it is necessary to periodically measure the insulation performance of the load and monitor the state of the insulation member. At this time, if the load to be measured is located in a remote location, a method of measuring insulation resistance by connecting a measuring device that measures resistance to a cable that electrically connects a switchboard or distribution board (hereinafter referred to as 'distribution panel') and the load can be used. could

However, in the case of measuring the insulation resistance in this way, the measured insulation resistance was measured as a composite resistance value of the insulation resistance of the cable and the insulation resistance of the load.

The problem to be solved by the present invention is to provide a method for measuring the insulation resistance of a load and an apparatus for measuring the insulation resistance of a load capable of obtaining an insulation resistance value for a load even when the insulation resistance is measured using a power cable connected to a switchboard, etc. will be.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In the method for measuring the insulation resistance of a load electrically connected to a power cable including a conductor layer for transmitting electricity and a shielding layer for shielding the conductor layer to solve the above problem, cable leakage, which is leakage current by the power cable, electrically connecting a cable probe receiving the cable leakage current to the shielding layer to prevent current from being transmitted through the load to a grounding member grounding the load; The step of measuring the applied voltage, the step of measuring the load leakage current, which is the current leaking through the grounding member, and the insulation resistance of the load based on the measured value of the measured voltage and the measured value of the measured load leakage current. Including the step in which this is computed.

The method may further include supplying power to the power cable and the load by electrically connecting a power supply probe electrically connected to the power source and the conductor layer.

The method may further include measuring the cable leakage current flowing through the cable probe.

The method may further include calculating an insulation resistance of the power cable based on the measured value of the voltage and the measured value of the cable leakage current.

In the step of calculating the insulation resistance of the load, the insulation resistance of the load is calculated as a ratio of the measured value of the load leakage current and the measured value of the voltage, and in the step of calculating the insulation resistance of the power cable, the cable leakage The insulation resistance of the power cable may be calculated as a ratio of the measured value of the current and the measured value of the voltage.

In the insulation resistance measuring device of a load electrically connected to a power cable including a conductor layer for transmitting electricity and a shielding layer for shielding the conductor layer to solve the above problem, a power source for supplying power, the power source and the electrical A power supply probe connected to and electrically connectable to the conductor layer, a load probe electrically connected to the power source and electrically connectable to a grounding member for grounding the load, and electrically connected to the power source. A cable probe electrically connected to the shielding layer and receiving the cable leakage current from the power source to prevent cable leakage current, which is leakage current by the power cable, from being transmitted to the grounding member through the load. A voltage measurement unit that measures the voltage applied to the power cable, a load current measurement unit that is connected to the load probe and measures a load leakage current, which is a current leaked from the load, and a measured value of the voltage measured from the voltage measurement unit. Obtain information on and obtain information on the measured value of the load leakage current measured from the load current measuring unit, and determine the insulation resistance of the load based on the measured value of the voltage and the measured value of the load leakage current. It includes a calculation unit that performs calculations.

A cable current measuring unit connected to the cable probe to measure the cable leakage current may be further included.

The calculation unit further obtains information about the measured value of the cable leakage current measured by the cable current measuring unit, and determines the insulation resistance of the power cable based on the measured value of the voltage and the measured value of the cable leakage current. can be computed further.

The calculator calculates the insulation resistance of the load as a ratio of the measured value of the load leakage current and the measured value of the voltage, and calculates the insulation resistance of the power cable as a ratio of the measured value of the cable leakage current and the measured value of the voltage. can be computed.

Other specific details of the invention are included in the detailed description and drawings.

According to embodiments of the present invention, at least the following effects are provided.

Even if insulation resistance is measured using a power cable connected to a switchboard or the like, an insulation resistance value for a load and an insulation resistance value of a power cable may be respectively measured.

Effects according to the present invention are not limited by the contents exemplified above, and more various effects are included in the present specification.

1 is a diagram illustrating that the insulation resistance of a load and a power cable, respectively, is calculated by an insulation resistance measuring device of a load according to an embodiment of the present invention.
2 is a block diagram of an apparatus for measuring insulation resistance of a load according to an embodiment of the present invention.
3 is a flowchart of a method for measuring the insulation resistance of a load according to an embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims.

In addition, the embodiments described in this specification will be described with reference to cross-sectional views and/or schematic views, which are ideal exemplary views of the present invention. Accordingly, the shape of the illustrative drawings may be modified due to manufacturing techniques and/or tolerances. In addition, in each drawing shown in the present invention, each component may be shown somewhat enlarged or reduced in consideration of convenience of description. Like reference numbers designate like elements throughout the specification.

A 'load' mentioned below may refer to an element, device, electrical equipment, etc. that consumes power in a circuit.

Hereinafter, the present invention will be described with reference to drawings for explaining an insulation resistance measuring device 1 of a load according to an embodiment of the present invention.

1 is a diagram illustrating that the insulation resistance of a load and a power cable, respectively, is calculated by an insulation resistance measuring device of a load according to an embodiment of the present invention. 2 is a block diagram of an apparatus for measuring insulation resistance of a load according to an embodiment of the present invention.

To aid understanding of FIG. 1 , dotted lines and solid lines in FIG. 1 represent an electrically connected state. For example, parts represented by dotted lines and/or solid lines may be electrically connected to each component by wires or the like.

1 and 2, the load insulation resistance measuring device 1 according to an embodiment of the present invention includes a power source 100, a power supply probe 210, a load probe 220, and a cable probe 230. ), a voltage measurement unit 300, a current measurement unit 400 and a calculation unit 500 may be included.

First, the power source 100 is a component that supplies power for measuring insulation resistance. For example, the power source 100 may be provided as AC power to supply AC power while being electrically connected to the power cable C.

The power supply probe 210 is a probe electrically connected to the power supply 100 . Specifically, the power supply probe 210 may be provided to be electrically connected to the power cable (C).

Specifically, the power supply probe 210 plays a role in transmitting power to the power cable (C) when receiving power from the power source 100 while being electrically connected to the power cable (C). Specifically, the power supply probe 210 may be electrically connected to the conductor layer C11 of the power cable C.

For better understanding, when describing the power cable (C) connected to the power supply probe 210, the power cable (C) is a cable electrically connected to the load (L) to be measured for insulation resistance. Specifically, the power cable (C) may be a cable electrically connecting the switchboard and the load (L) to supply power supplied from the switchboard to the load (L).

For example, the power cable (C) may be a cable for transmitting three-phase power to the load (L). Specifically, the power cable (C) is a first power cable (C1) for transmitting three-phase power to the load (L), a second power cable (C2) and three-phase power for transmitting three-phase power to the load (L) It may include a third power cable (C3) for transmitting to the load (L). For example, the power cable C may be a cable including a conductor layer C11, an insulator, a sheath, and a shielding layer C13. Here, the conductor layer C11 is a component that transmits electricity to a load. In addition, the shielding layer C13 is a layer that shields the conductor layer C11 and prevents current flowing through the conductor layer C11 from leaking to the outside.

Meanwhile, the power supply probe 210 is provided to be electrically connectable to the conductor layer C11 of the power cable C. In a state electrically connected to the conductor layer (C11), the power supply probe 210 transfers the power supplied from the power source 100 to the conductor layer (C11) of the power cable (C).

The load probe 220 is a probe electrically connected to the power source 100 and electrically connectable to the ground members G1 and G2. Here, the grounding members G1 and G2 are components for grounding the load L. Specifically, the ground members G1 and G2 may be electrically connected to the load L so as to flow current leaking from the load L.

For better understanding, when the grounding members G1 and G2 are described, the grounding members G1 and G2 are electrically connected to the first grounding member G1 and the first grounding member G1 electrically connected to the load L. It may include a second grounding member (G2) connected to and installed in a switchboard or the like to ground all lines installed on the switchboard or the like.

For example, the first ground member G1 may be a ground line for grounding the load L. Also, for example, the second ground member G2 may be a ground rod, a ground plate, or the like connected to a ground line.

The cable probe 230 is a probe provided to be electrically connected to the power source 100 and electrically connected to the shielding layer C13 of the power cable C. Specifically, the cable probe 230 is electrically connected to the shielding layer C13 and receives cable leakage current, which is leakage current from the power cable C.

For example, as described above, when the power cable C includes the first to third power cables C, the cable probe 230 is included in the first to third power cables C, respectively. It may be provided to be electrically connected to all of the shielding layer (C13) of the.

For example, the cable probe 230 may be branched into three branches and electrically connected to each of the shielding layers C13 of the first to third power cables C.

As another example, a connection member (not shown) electrically connected to the shielding layer of the first to third power cables C may be provided, and the cable probe 230 may be provided to be electrically connected to the connection member.

On the other hand, in the load insulation resistance measuring device 1 according to an embodiment of the present invention, the power supply probe 210 is electrically connected to the conductor layer C11 of the power cable C, and the cable probe 230 is electrically connected to the shielding layer C13 of the power cable C, and the circuit including the power source 100 becomes a closed circuit in a state in which the load probe 220 is electrically connected to the second grounding member G2. .

When power is supplied to the conductor layer (C11) of the power cable (C) by the power source 100 in a state where the circuit including the power source 100 becomes a closed circuit, the current flows along the conductor layer (C11) to the load (L ) will flow.

At this time, the cable leakage current (IC) leaked through the shielding layer (C13) of the power cable (C) flows toward the cable probe (230), and the load leakage current (IR) leaked from the insulation member of the load (L) is controlled. It flows to the load probe 220 through the first grounding member G1 and the second grounding member G2.

The voltage measurement unit 300 is a module that is electrically connected to the power source 100 and measures the voltage applied to the power cable C. Specifically, the voltage measuring unit 300 may include a voltmeter 310 connected in parallel with the power source 100 to measure the voltage applied from the power source 100 .

In addition, the voltage measuring unit 300 transmits information about the measured value of the voltage measured by the voltmeter 310 to the calculating unit 500 .

The current measurement unit 400 is a module that measures cable leakage current (IC) and load leakage current (IR) and transmits information about the measured values to the calculation unit 500.

Specifically, the current measurement unit 400 may include a cable current measurement unit 420 that measures cable leakage current (IC) and a load current measurement unit 410 that measures load leakage current (IR).

The cable current measurement unit 420 is a component that measures the cable leakage current (IC) and transmits information about the measured value of the cable leakage current (IC) to the calculation unit 500 . Specifically, the cable current measuring unit 420 may include a cable current measuring ammeter 422 that is an ammeter connected in series with the cable probe 230 . The cable current measuring unit 420 transmits information about the measured value of the cable leakage current (IC) measured by the cable current measuring ammeter 422 to the calculating unit 500 .

The load current measuring unit 410 is a component that measures the load leakage current IR and transmits information about the measured value of the measured load leakage current IR to the calculating unit 500 . Specifically, the load current measuring unit 410 may include a load current measuring ammeter 412 that is an ammeter connected in series with the load probe 220 . The load current measuring unit 410 transmits information about the measured value of the load leakage current IR measured by the load current measuring ammeter 412 to the calculating unit 500 .

On the other hand, the calculation unit 500 is a calculation module or calculation device for calculating the insulation resistance of the load (L). A process in which the calculation unit 500 calculates the insulation resistance of the load L may be as follows.

First, the calculation unit 500 receives information on a voltage measurement value from the voltage measurement unit 300 and receives information on a load leakage current measurement value from the load current measurement unit 410 . After that, the calculation unit 500 calculates the insulation resistance of the load L based on the measured values of the voltage and the measured values of the load leakage current.

On the other hand, the calculation unit 500 may be provided to calculate the insulation resistance of the power cable (C). Specifically, the calculation unit 500 receives information about the measured value of the cable leakage current from the cable current measurement unit 420 . After that, the calculating unit 500 calculates the insulation resistance of the power cable C based on the measured values of the voltage and the measured values of the cable leakage current.

Specifically, the calculation unit 500 may calculate the insulation resistance of the load (L) as a ratio of the measured value of the load leakage current and the measured value of the voltage. For example, the insulation resistance of the load L may be calculated by dividing the measured value of the load leakage current by the measured value of the voltage.

In addition, the calculation unit 500 calculates the insulation resistance of the power cable C as a ratio of the measured value of the cable leakage current and the measured value of the voltage. For example, the insulation resistance of the power cable C may be calculated by dividing the measured value of the cable leakage current by the measured value of the voltage.

On the other hand, although not shown, the load insulation resistance measuring device 1 according to an embodiment of the present invention displays the calculated insulation resistance value of the load L and the insulation resistance value of the power cable C on the screen. A display unit (not shown) having a screen may be further included. For example, the display unit may be provided to receive information on the insulation resistance value of the load (L) and the insulation resistance value of the power cable (C) from the calculation unit and display it on the screen.

Hereinafter, a method for measuring the insulation resistance of a load according to an embodiment of the present invention will be described based on the description of the apparatus 1 for measuring the insulation resistance of a load according to an embodiment of the present invention.

3 is a flowchart of a method for measuring the insulation resistance of a load according to an embodiment of the present invention.

As shown in FIG. 3, in the method for measuring the insulation resistance of a load according to an embodiment of the present invention, the cable probe is electrically connected to the shielding layer (S10), and the power is supplied to the power cable and the load (step S10). S20), measuring the voltage applied to the power cable (S30), measuring the load leakage current (S42), calculating the insulation resistance of the load (S52), measuring the cable leakage current (S44) and calculating the insulation resistance of the power cable (S54).

First, in the step of electrically connecting the cable probe to the shielding layer (S10), the cable probe 230 is electrically connected to the shielding layer C13 of the power cable C. Also, in this step, the load probe 220 may be electrically connected to the second ground member G2.

In step S20 of supplying power to the power cable and the load, the power supply probe 210 electrically connected to the power source 100 is electrically connected to the conductor layer C11. After that, power is supplied to the power cable C and the load L by the power source 100 .

In step S30 of measuring the voltage applied to the power cable, the voltage measurement unit 300 measures the voltage applied to the power cable C by the power source 100 . Also, in this step, the voltage measuring unit 300 transmits information about the measured voltage to the calculating unit 500 .

In step S42 of measuring the load leakage current, the load current measuring unit 410 measures the load leakage current IR flowing through the load probe 220 . Also, in this step, the load current measuring unit 410 transmits information about the measured value of the load leakage current measured to the calculating unit 500 .

In step S52 of calculating the insulation resistance of the load, the insulation resistance of the load L is calculated based on the information about the measured value of the voltage and the information about the measured value of the load leakage current received by the calculation unit 500. . Since the method for calculating the insulation resistance of the load (L) by the calculation unit 500 has been described above, a detailed description thereof will be omitted.

In the step of measuring the cable leakage current (S44), the cable current measurement unit 420 measures the cable leakage current (IC) flowing through the cable probe 230. Also, in this step, the cable current measuring unit 420 transmits information about the measured value of the cable leakage current measured by the calculating unit 500.

In the step of calculating the insulation resistance of the power cable (S54), the insulation resistance of the power cable C is determined based on the information about the measured value of the voltage and the information about the measured value of the cable leakage current received by the calculation unit 500. calculate Since the calculation unit 500 calculates the insulation resistance of the power cable C has been described above, a detailed description thereof will be omitted.

Meanwhile, the step of measuring the load leakage current (S42) and the step of measuring the cable leakage current (S44) may be performed simultaneously or with a time difference set by the user. Likewise or similarly, the step of calculating the insulation resistance of the load (S52) and the step of calculating the insulation resistance of the power cable (S54) may be performed simultaneously or with a time difference set by the user.

Therefore, according to the method for measuring the insulation resistance of a load according to an embodiment of the present invention, the insulation resistance of the load (L) and the power cable (C) can be obtained with one measurement.

Those skilled in the art to which the present invention pertains will understand that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the following claims rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be construed as being included in the scope of the present invention. do.

1: load insulation resistance measuring device 100: power
210: power supply probe 220: load probe
230: cable probe 300: voltage measuring unit
310: voltmeter 400: current measuring unit
410: load current measuring unit 412: load current measuring ammeter
420: cable current measuring unit 422: cable current measuring ammeter
500: calculation unit C: power cable
C1: first power cable C11: conductor layer
C13: shielding layer C2: second power cable
C3: 3rd power cable G1: 1st grounding member
G2: 2nd grounding member IC: cable leakage current
IR: load leakage current L: load

Claims (6)

In the method for measuring the insulation resistance of a load electrically connected to a power cable including a conductor layer for transmitting electricity and a shielding layer for shielding the conductor layer,
electrically connecting a cable probe that receives the cable leakage current to the shielding layer to prevent transmission of cable leakage current, which is leakage current by the power cable, to a grounding member grounding the load through the load;
measuring a voltage applied to the power cable from a power supply;
measuring a load leakage current, which is a current leaking through the grounding member; and
Calculating the insulation resistance of the load based on the measured value of the voltage and the measured value of the load leakage current; According to claim 1,
Further comprising the step of supplying power to the power cable and the load by electrically connecting a power supply probe electrically connected to the power source and the conductor layer, the method of measuring the insulation resistance of the load. According to claim 1,
measuring the cable leakage current flowing through the cable probe; and
Further comprising calculating the insulation resistance of the power cable based on the measured value of the voltage and the measured value of the cable leakage current,
In the step of calculating the insulation resistance of the load,
The insulation resistance of the load is calculated as a ratio of the measured value of the load leakage current and the measured value of the voltage,
In the step of calculating the insulation resistance of the power cable,
The method of measuring the insulation resistance of the load, wherein the insulation resistance of the power cable is calculated as a ratio of the measured value of the cable leakage current and the measured value of the voltage. In the insulation resistance measuring device of a load electrically connected to a power cable including a conductor layer for transmitting electricity and a shielding layer for shielding the conductor layer,
a power source that supplies power;
a power supply probe electrically connected to the power source and electrically connectable to the conductor layer;
a load probe electrically connected to the power source and electrically connectable to a grounding member for grounding the load;
A cable electrically connected to the power source and electrically connected to the shielding layer to receive the cable leakage current to prevent cable leakage current, which is leakage current by the power cable, from being transmitted to the grounding member through the load. probe;
a voltage measuring unit measuring a voltage applied from the power source to the power cable;
a load current measuring unit connected to the load probe and measuring a load leakage current, which is a current leaked from the load; and
Information on the measured value of the voltage measured by the voltage measuring unit is obtained and information on the measured value of the load leakage current measured by the load current measuring unit is obtained, and the measured value of the voltage and the load leakage current are obtained. Based on the measured value of the calculation unit for calculating the insulation resistance of the load; including, the insulation resistance measuring device of the load. According to claim 4,
A cable current measuring unit connected to the cable probe to measure the cable leakage current; further comprising an insulation resistance measuring device of a load. According to claim 5,
The calculation unit,
Further obtaining information on the measured value of the cable leakage current measured by the cable current measurement unit,
calculating the insulation resistance of the load as a ratio of the measured value of the load leakage current and the measured value of the voltage;
An insulation resistance measuring device of a load that calculates the insulation resistance of the power cable as a ratio of the measured value of the cable leakage current and the measured value of the voltage.

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