KR101056535B1 - Ground Simulation Circuit and Device of Low Voltage Wiring System - Google Patents

Abstract

A circuit and apparatus for simulating ground construction of a low voltage wiring system, the apparatus comprising: a power supply grounding unit for grounding a neutral wire (N) of a power supply to a ground grid; A first switch for switching the protective conductor PE connected to the load to the neutral wire N; A second switch for switching the protective conductor (PE) to a first device ground; A configuration including a third switch for switching the connection between the neutral wire (N) and the protective conductor (PE) is provided.

The grounding simulation circuit and device of the low voltage wiring system as described above can simulate the grounding work of the low voltage wiring system in advance, and the singularity of the loop impedance according to the grounding variables such as equipment grounding, load type, line length, etc. Can be detected and optimum grounding can be found.

Ground, power, grid ground, simulation, switch, TT ground, TN ground

Description

Ground simulation circuit and apparatus of low voltage wiring system {A simulation circuit and apparatus of a 3-phase low-voltage wiring system}

The present invention relates to a circuit and an apparatus for simulating the ground construction of a low voltage wiring system.

In particular, the present invention is a ground simulation circuit of a low-voltage wiring system that collects the loop impedance of the main line through the data acquisition device (DAQ) by simulating the grounding method, grounding equipment, load type, line length, etc. And to an apparatus.

In general, grounding is very important to maintain the safety of electrical installations, and its need has been emphasized for a long time. Accordingly, IEC (International Electrotechnical Commission) has established standards for grounding equipment for electrical equipment, and grounding of electrical equipment has been carried out in accordance with this standard.

Standards for grounding works for building electrical equipment are provided by IEC 60364. IEC 60364 (particularly part 3) defines the grounding method of low voltage wiring system, and the grounding method is classified into three types, TN method, TT method and IT method.

In the IT grounding method, the power supply side is ungrounded or high impedance grounded, and the exposed conductive part of the equipment is grounded to an electrically independent ground electrode. Consideration should be given to ground faults. Therefore, it is difficult to adopt in large power system. Most electrical equipment systems use TN-S, TN-C-S, or TT.

In the grounding method of TN system, the power supply side is directly grounded at one or more places, and the exposed conductive parts of the electrical equipment are connected to the grounding point of the power supply through protective conductors. Therefore, a metal path is formed through which the ground current can flow from the electric device side to the power supply ground point. The TN system is further divided into three types, TN-C, TN-S, and TN-C-S, depending on the relationship between the neutral wire (N) and the protective conductor (E).

As shown in Figure 1a, in the TN-C grounding method, the neutral wire (N) and the protective conductor (equipment ground) (PE) is connected by a single conductor throughout the system. Ground faults in TN systems are protected by overcurrent breakers. Therefore, in case of an accident, the characteristics of the breaker and the thickness of the conductor are determined so that the overcurrent breaker of the power supply operates within a certain time in consideration of the failure point impedance. In this case, the protective conductor is used as the grounding conductor.

As shown in Figure 1b, the TN-S grounding method is the neutral conductor (N) and the protective conductor (grounding wire) (PE) is separated throughout the system and shares the ground electrode on the power supply side. That is, the ground of the exposed conductive part of the equipment is connected to the grounding point of the power supply via the protective conductor in such a way that a PEN conductor that uses a neutral conductor and a protective conductor is connected.

As shown in Figure 1c, in the TN-C-S grounding method, the neutral wire (N) and the protective conductor (PE) is connected to a single conductor in a portion of the system. The power supply side is TN-C type and the electrical equipment side (or trunk line system) is TN-S type.

On the other hand, the grounding method of the TT system is a direct ground (system grounding) at one or more places of the power supply side, and the exposed conductive part of the equipment is grounded to a grounding electrode that is electrically independent of the system grounding. That is, the system ground and the device ground are completely separated. In this system, ground faults are protected by an overcurrent circuit breaker or an earth leakage circuit breaker, in which case the conditions for limiting the earth potential rise of the equipment frame should be considered.

Meanwhile, in the above-described grounding methods, the neutral wire N is connected to a ground grid and grounded. Grounding by the ground grid is the ground. In general, the grid-shaped grounding electrode is installed directly on the ground to ground. That is, the system ground is directly connected to the ground. On the other hand, the equipment ground is connected to a metal water pipe or gas pipe. In other words, the device ground is "bonding" and is intended for building space.

However, since the water pipe or gas pipe has its own resistance, the grounding resistance may increase depending on the type or length of the metal. In addition, grounding resistance may occur in the ground grid. If the grounding resistance increases, the risk of leakage may increase.

When the grounding system is installed by selecting the grounding method as described above, the grounding effect or the efficiency may vary depending on the selection of the water pipe or the gas pipe or the lengths of the tracks. In addition, when an electric shock or the like occurs, it is necessary to confirm that the installed grounding system is properly operated so that the entire electrical installation is safe from such an accident.

In other words, through the reliable design considering the characteristics of the electrical equipment, the geological characteristics of the construction site and the external environment, it is possible to select the optimum grounding system economically and safetyly, and also to select the reference grounding resistance, the grounding method and the selection of grounding materials. Grounding characteristics should be reflected. In order to maximize the effectiveness of a grounded system that is designed reliably, certain constructions must be performed in parallel, and accurate measurement and analysis of the grounds constructed prevents any possible accidents caused by grounding. In addition, stable grounding should prevent electric shock accidents caused by leakage current or high-low pressure contact, and prevent the damage or fire caused by lightning strike or brain surge, or safety of human life and stable operation of equipment.

However, changing the grounding system once installed is not easy, so it would be very effective to simulate the virtual grounding system in advance. Therefore, a simulator that can simulate grounding construction of low voltage wiring system is urgently needed.

An object of the present invention is to solve the problems described above, and to provide a circuit and apparatus for simulating the ground construction of the low-voltage wiring system.

In particular, an object of the present invention is to provide a low-voltage wiring system that collects the value of the loop impedance of the main line through a data acquisition device (DAQ) by simulating the grounding method, grounding equipment, load type, line length, etc. It is to provide a ground simulation circuit and apparatus.

In order to achieve the above object, the present invention relates to a ground simulation circuit of a low voltage wiring system, comprising: a power supply grounding unit for grounding a neutral line (N) of a power supply to a ground grid; A first switch for switching the protective conductor PE connected to the load to the neutral wire N; A second switch for switching the protective conductor (PE) to a first device ground; It characterized in that it comprises a third switch for switching the connection of the neutral wire (N) and the protective conductor (PE).

In addition, the present invention is characterized in that it further comprises a fourth switch for switching the protective conductor (PE) to the second device ground in the ground simulation circuit of the low voltage wiring system.

In addition, the present invention is characterized in that the ground simulation circuit of the low-voltage wiring system further comprises a fifth switch for switching the load to the ground for electric shock.

In addition, the present invention provides a grounding simulation circuit of a low voltage wiring system, comprising: a first cable conversion unit including a variable resistor on a line of three phases, a neutral line, and a protective conductor on a power supply side; It further comprises a second cable converter provided with a variable resistor on the three-phase, neutral wire, the protective conductor line of the load side.

In addition, in the ground simulation circuit of the low-voltage wiring system, the variable resistor provided in the three phase and the neutral wire of the second cable conversion unit is provided between the circuit breaker and the earth leakage breaker.

In addition, the present invention is characterized in that in the ground simulation circuit of the low-voltage wiring system, the ground grid or the device ground is composed of a variable resistor.

In addition, the present invention is characterized in that in the ground simulation circuit of the low-voltage wiring system, the device ground is connected to a water pipe or a gas pipe including a variable resistor.

In addition, the present invention is characterized in that in the ground simulation circuit of the low-voltage wiring system, the variable resistance of the device ground has a resistance range of 1 to 3 ohms (Ω).

In addition, the present invention is characterized in that in the ground simulation circuit of the low-voltage wiring system, the ground for electric shock comprises a grounding resistance of a variable resistor.

In addition, in the ground simulation circuit of the low voltage wiring system, the variable resistance of the ground for electric shock is characterized in that it has a resistance range of 500 to 1,650 Ohm (Ω).

The present invention also provides a grounding simulation circuit for a low voltage wiring system, wherein the grounding simulation circuit for the low voltage wiring system includes first and second ground terminals, and the neutral wire (N) and the ground grid are connected to the first ground terminal. The protective conductor (PE) to the second ground terminal, the second switch connected to the first device ground to the first device ground, the third switch connected to the neutral wire (N) the first device It is characterized in that connected to the ground.

The present invention also provides a grounding simulation circuit for a low voltage wiring system, wherein the grounding simulation circuit for a low voltage wiring system includes first and second ground terminals, and the neutral wire (N) and the ground grid are connected to the first ground. The protective conductor (PE) to a second ground terminal, a second switch connected to the first device ground and a fourth switch connected to the second device ground to the first device ground, and a neutral wire ( And a third switch connected with N) to the first device ground.

The present invention also relates to a grounding simulation circuit device of a low voltage wiring system, comprising: a grounding simulation circuit of a low voltage wiring system (hereinafter, referred to as a grounding simulation circuit); In the ground simulation circuit, a probe is provided at any one or more of the front and rear ends of the circuit breaker, the load front end, the protective conductor (PE) connection, and the device ground connection part to measure voltage, current, or impedance, and measure the measured value. A data acquisition device (DAQ); And a display panel for displaying the measurement values collected by the data collection device, a control switch for controlling the variable resistance and a switch of the ground simulation circuit, and a simulator panel including a connection jack for connecting a load.

In addition, the present invention is characterized in that in the ground simulation circuit device of the low-voltage wiring system, the connection jack can selectively connect the electric load or the resistance load.

As described above, according to the grounding simulation circuit and apparatus of the low-voltage wiring system according to the present invention, it is possible to simulate the grounding work of the low-voltage wiring system in advance, and the parameters of the grounding work such as equipment grounding, load type, line length, etc. This results in the effect of detecting the singularity of loop impedance and finding the optimal grounding construction.

In addition, according to the grounding simulation circuit and apparatus of the low-voltage wiring system according to the present invention, by using a simulator for the construction, inspection, training, etc. of the grounding system by the TT grounding method or TN grounding method, more effective and efficient grounding construction The effect that can be obtained is obtained.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings.

In addition, in describing this invention, the same code | symbol is attached | subjected and the repeated description is abbreviate | omitted.

First, the configuration of the ground simulation circuit of the low voltage wiring system according to an embodiment of the present invention will be described with reference to FIG. 2.

As shown in FIG. 2, the ground simulation circuit of the low voltage wiring system according to the present invention is divided into a power supply side circuit 10 and a load side circuit 20.

The power supply side circuit 10 is a circuit for receiving AC power as a power source. The power supply side circuit 10 receives an external AC power as an internal power supply through a transformer. 2 shows a three-phase AC power supply as an example, and R, S, and T represent each phase of the three-phase AC power supply.

At this time, the size of the voltage is preferably set to about 380 ~ 440 V.

The load side circuit 20 is a circuit for connecting the load RR to an internal power supply. In the load side circuit 20, a circuit breaker 41 and an earth leakage breaker 42 for blocking the overcurrent are provided between the power supply section and the load section RR.

A neutral wire (N) and a protective conductor (PE) are provided between the power supply and the load for grounding. The neutral line N is a line connected to the center point N of the power source and grounded to the ground grid 60. Preferably, the ground of the neutral wire (N) is connected to the ground grid 60 through the first ground terminal (51). That is, the first ground terminal 51 is connected to the ground grid 60 and is connected to the ground terminal 51 by grounding the neutral wire N to the ground grid 60.

The ground grid 60 is directly targeted to the ground. Preferably, the ground grid 60 uses a grid-shaped ground network. In addition, the ground grid 60 may be used in a rod shape.

A variable resistor E1 is further included between the ground grid 60 and the neutral line N to serve as the ground resistance. When installing a grounding system in an actual building, the grounding grid 60 may be connected to a steel frame of a building, and the grounding resistance may vary depending on the characteristics of the ground and the grounding grid 60. Therefore, in order to simulate this, a separate variable resistor E1 is provided to adjust the variable resistor E1 to simulate the actual situation. In this case, the variable resistor E1 preferably has a resistance range of 1 to 3 ohms.

The line of each phase, the neutral wire N, and the protective conductor PE are comprised through the power supply side circuit 10 and the load side circuit 20. As shown in FIG.

Meanwhile, in the load side circuit 20, the neutral line N connected to the neutral point of the power supply unit is also connected to the load RR. In addition, a protective conductor PE for ground is connected to the load RR. The protective conductor PE on the opposite side of the protective conductor PE connected to the load RR, that is, the power supply side circuit 10, is connected to the neutral wire N.

The first switch SW1 is provided on the protective conductor PE side connected to the neutral wire N. That is, when the first switch SW1 is connected (or turned on), the protective conductor PE is connected to the neutral wire N, and when the first switch SW1 is off, the protective conductor PE is not connected to the neutral wire N.

Next, the load side circuit 20 is demonstrated.

The protective conductor PE in the load side circuit 20 is switched to the first device ground 61 or the second device ground 62. Preferably, the protective conductor PE is switched connected to the first device ground 61 or the second device ground 62 through the second ground terminal 52. That is, the second ground terminal 52 is connected to the first device ground 61 or the second device ground 62, and the protective conductor PE is connected to the second ground terminal 52 by connecting the protective conductor PE to the second ground terminal 52. ) And the first or second device ground (61, 62).

Preferably, the first or second device grounds 61 and 62 are implemented as water pipes or gas pipes. For example, the water supply pipe may be used as the first device ground 61 and the gas device may be installed as the second device ground 62.

The first or second device grounds 61 and 62 have variable resistors E2 and E3. Ground resistance may vary depending on the length of the water pipe or gas pipe. Therefore, water pipe or gas pipe is installed only a certain length, and the rest is simulated the ground resistance by using a variable resistor. In this case, the range of the variable resistors E2 and E3 preferably has a resistance range of 1 to 3 ohms.

In addition, the water pipe or the gas pipe simulates the internal resistance (or ground resistance) of the pipe by providing only about 10 cm in length and using the variable resistors E2 and E3. In the case of domestic technical standards, the ground resistance is treated as the same as the first class ground if it is within 3 ohms (Ω), but because IEC60364 applies different values, it is also used to verify the stability by changing the value of the variable resistor.

On the other hand, the first or second device ground (61, 62) is provided with a second or fourth switch (SW2, SW4) between the second ground terminal (52). When either one of the second or fourth switches SW2 and SW4 is connected, the ground is connected to the corresponding device grounds 61 and 62. For example, in order to connect to the water pipe which is the first device ground 61 in the above example, the second switch SW2 is connected (on) and the fourth switch SW4 is turned off.

In addition, a third switch SW3 is provided in order to switch connection between the neutral conductor N and the protective conductor PE located in the load side circuit 20. One conductor connected to the third switch SW3 is connected to the neutral wire N, and the other conductor is connected to the second ground terminal 52. Since the protective conductor PE is always connected to the second ground terminal 52, the neutral wire N is switched by the protective conductor PE and the third switch SW3 through the second ground terminal 52.

Accordingly, when the third switch SW3 is turned on, the neutral wire N and the protective conductor PE are connected, and when the third switch SE3 is turned off, the neutral wire N and the protective conductor PE are turned off. Will be disconnected.

On the other hand, in the load side circuit 20, the electric shock ground 63 is grounded to the load RR. The ground for electric shock 63 simulates the electric shock of a person. When a person is electrocuted by the current flowing in the load RR, it is as if the ground is generated through the person. Therefore, to simulate the electric shock may be further provided with a ground (63) for electric shock.

The fifth switch SW5 is provided between the electric shock ground 63 and the load RR. When the fifth switch SW5 is turned on, an electric shock state is simulated. The variable resistor E4 may be added to the ground 63 for the electric shock. The ground resistance formed in the human body may vary according to the human condition and the electric shock condition. Therefore, to simulate this, the variable resistor 63 is placed. Preferably, the range of the variable resistor E4 is set to 500 to 1650 ohms.

Further, preferably, a ground terminal 53 is provided between the load RR and the ground for electric shock 63 so that the ground for the electric shock 63 and the load RR may be more easily connected.

Next, the line resistance of each phase (R, S, T), neutral wire (N), and protective conductor (PE) of the AC power source will be described.

The first cable converter 31 having a variable resistor on the lines of the phases R, S, and T, the neutral wire N, and the protective conductor PE exiting from the power supply side circuit 10 to the load side circuit 20. Configure In addition, the second cable converter (V) having a variable resistor on the lines of the phases (R, S, T), the neutral (N), and the protective conductor (PE) coming from the power supply circuit (10) from the power supply circuit (20) ( 32).

When power distribution is installed in a building, each line may be longer or shorter depending on the distance between the power supply and the load. Depending on the length of the line, the resistance (or impedance) generated in the line may vary. Therefore, the length of the line is simulated by changing the variable resistors provided in the first or second cable converters 31 and 32.

On the other hand, preferably, the second cable converter 32 is provided between the circuit breaker 41 and the ground fault breaker 42.

For line resistance, use the line constant table. The resistance value is adjusted using the calculated value. Allow the experimenter to find the line resistance by setting a high value resistor.

Next, examples in which the grounding system is configured by the switches SW1 to SW5 of the ground simulation circuit of the low voltage wiring system according to the present invention will be described with reference to FIGS. 3 and 4.

As shown in FIG. 3, TN-C, respectively according to ON and OFF of the first switch SW1, the second switch SW2 (or the fourth switch), and the third switch SW3. TN-S, TN-CS and TT grounding systems are simulated.

The second switch SW2 and the fourth switch SW4 are switches for selecting the type of equipment ground, for example, a water pipe or a gas pipe. Therefore, when connecting, it is enough to connect one of the two. Only the second switch SW2 will be described below. Since the fifth switch SW5 is a switch related to electric shock, a description thereof will be omitted.

First, in order to express the TN-S grounding scheme, the first switch SW1 is turned on, and both the second and third switches SW2 and SW3 are turned off. In FIG. 2, the circuit in this state is shown in FIG. 4A. That is, since the device grounds are not all connected in FIG. 2, only the first switch SW1 is connected to the same as FIG. Figure 4a can be seen that the circuit of the TN-S ground method of Figure 1b.

Next, to express the TN-C grounding system, all of the first, second, and third switches SW1, SW2, and SW3 are turned off. In FIG. 2, the circuit in this state is shown in FIG. 4B. That is, since both the device ground and the protective conductor in Figure 2 is not connected to the circuit as shown in Figure 4b. Figure 4b can be seen that the circuit of the TN-C ground method of Figure 1a.

 First, in order to express the TN-C-S grounding scheme, the first and second switches SW1 and SW2 are turned off and the third switch SW3 is turned on. In FIG. 2, the circuit in this state is shown in FIG. 4C. That is, in FIG. 2, there is no protective conductor PE in the power supply side circuit 10. In the load side circuit 10, the protective conductor PE and the neutral wire N are connected by the third switch SW3 (via the ground terminal). Therefore, since the power supply side circuit 10 is a TN-C method and the load side circuit 20 is a TN-S method, it can be seen that FIG. 4C is a circuit of the TN-C-S ground method of FIG. 1C.

First, in order to express the TT grounding method, the first switch SW1 is turned off and the second and third switches SW2 and SW3 are turned on. In FIG. 2, the circuit in this state is shown in FIG. 4D. That is, in FIG. 2, there is no protective conductor PE in the power supply side circuit 10. In addition, the protective conductor PE and the neutral conductor N are connected by the third switch SW3 in the load-side circuit 10 (via the ground terminal), and the protective conductor PE is connected to the device ground 61. Is grounded. Therefore, it can be seen that FIG. 4D is a circuit of the TT grounding method of FIG. 1D.

Next, a ground simulation circuit device of a low voltage wiring system according to an embodiment of the present invention will be described with reference to FIG. 5.

As shown in FIG. 5, the ground simulation circuit device 80 of the low voltage wiring system includes a ground simulation circuit 81, a data collection device (DAQ) 82, and a simulator panel 83. In addition, the data collecting device 82 may be configured to further include a memory for storing the data collected.

The ground simulation circuit 81 refers to the ground simulation circuit of the low voltage wiring system described above.

In the ground simulation circuit 81, the data collecting device 82 includes a probe at one or more of a circuit breaker, a front end and a rear end, a load front end, a protective conductor (PE) connection part, and a device ground connection part. Measure current or impedance and collect measurements.

That is, the data collecting device 82 is a device for measuring the voltage, current, impedance and the like of the portion to be measured by the ground simulation circuit 81 to collect measured values. It is preferable that the data collecting device 82 use general DAQ equipment.

For example, to measure current, voltage, etc., the probe of the DAQ device is measured through a CT or PT connection. It is desirable to install the measuring location in front of and behind the breaker, in front of the load connection, in the connection of the protective conductor (PE), in the connection of the ground, and in the system change section. It measures the operation characteristics of the breaker, the ground fault current and contact voltage of the protective conductor, the magnitude of the current and voltage applied to the load, and inversely calculates the magnitude of the loop impedance. The characteristic can be found by analyzing the value of the obtained loop impedance.

Preferably, the data acquisition characteristic of the DAQ device acquires data up to 0.1 (ms), the voltage can be up to 1,000 (V) in order to acquire a switching surge during a ground fault or breaker operation, and the current is an accident. Acquire up to a maximum of 10kA for current acquisition.

Meanwhile, the probe of the DAQ device may be installed in the simulation circuit 81 in advance or may be installed by an experimenter. In the latter case, a connecting jack is provided to allow the experimenter to install directly.

The simulator panel 83 includes a display unit for displaying measurement values collected by the data collecting device 82, a switch of the ground simulation circuit 81, a control switch for controlling a variable resistor, and a connection jack for connecting a load.

Elements that can be controlled by the ground simulation circuit 81 include ON / OFF of the switches SW1 to SW2, variable resistors E1 to E4 used as ground resistances, and a cable converter 31, 32 are resistance values of the variable resistor. Therefore, using the control switch of the simulator panel 83, the experimenter can set the values of the switch and the variable resistors to the value desired by the experimenter.

The connection jack connects the load. The load may be divided into an electric load or a resistance load. The experimenter can simulate different loads by connecting the connection jacks.

As mentioned above, although the invention made by this inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example, Of course, a various change is possible in the range which does not deviate from the summary.

The present invention is applicable to the development of a ground construction simulator that can be used when the construction, inspection, education, etc. of the grounding system by the TT grounding method or TN grounding method.

1 is a ground circuit showing the grounding method of the low voltage wiring system according to the IEC standard by type.

2 is a circuit diagram illustrating a configuration of a ground simulation circuit of a low voltage wiring system according to an embodiment of the present invention.

3 is a diagram showing a grounding scheme changed according to a switch of the grounding simulation circuit of the low voltage wiring system of the present invention.

FIG. 4 is a diagram illustrating a circuit determined according to on / off of a switch in the circuit of FIG. 2.

5 is a block diagram of a configuration of a ground simulation circuit device of a low voltage wiring system according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

R, S, T: Each phase of 3-phase AC power supply N: Neutral wire, neutral point

SW1, SW2, SW3, SW4, SW5: first, second, third, fourth, fifth switch

E1, E2, E3, E4: Ground potentiometer RR, 70: Load

10: power supply ground circuit 20: load side ground circuit

31, 32: 1st, 2nd cable conversion part

33: line resistance

41: wiring breaker 42: earth leakage breaker

51, 52, 53: 1st, 2nd, 3rd ground terminal

55: ground terminal groove 60: ground grid

80: ground simulation circuit device 81: ground simulation circuit

82: Data Acquisition Device (DAQ) 83: Simulator Panel

Claims (14)

A ground grid connected to a neutral wire N of a power source to ground the neutral wire N; A first switch connected in parallel with the ground grid and for switching a protective conductor (PE) connected to a load to a neutral wire (N); A second switch for switching the protective conductor (PE) to a first device ground; It is connected in parallel with the first switch, and comprises a third switch for switching the connection of the neutral wire (N) and the protective conductor (PE), The second switch is a ground simulation circuit of the low-voltage wiring system, characterized in that the first and the third switch is connected in series with a circuit configured in parallel. The method of claim 1, The first and the third switch is connected in series with a circuit configured in parallel, further comprising a fourth switch configured in parallel with the second switch, for switching the protective conductor (PE) to a second device ground Ground simulation circuit for low voltage wiring system. The method of claim 1, And a fifth switch configured in parallel with a circuit including the first to third switches, the fifth switch configured to switch the load to the ground for electric shock. The method of claim 1, A first cable conversion unit provided with a variable resistor on a three-phase, neutral, and protective conductor line on the power supply side; The ground simulation circuit of the low-voltage wiring system, further comprising a second cable conversion unit provided with a variable resistor on the three-phase, neutral, and protective conductor lines on the load side. 5. The method of claim 4, The variable resistance provided in the three phase and the neutral line of the second cable conversion unit is a ground simulation circuit of the low voltage wiring system, characterized in that provided between the circuit breaker and the circuit breaker. 6. The method according to any one of claims 1 to 5, The ground grid or the grounding circuit of the low-voltage wiring system, characterized in that the grounding resistance consisting of a variable resistor. The method of claim 6, wherein the device ground A grounding simulation circuit for a low voltage wiring system, characterized in that connected to a water pipe or a gas pipe including a variable resistor. The method of claim 6, The variable resistance of the device ground is a ground simulation circuit of a low voltage wiring system, characterized in that it has a resistance range of 1 to 3 ohms (Ω). The method of claim 3, wherein The grounding circuit of the low voltage wiring system, characterized in that the grounding of the electric shock is configured by a variable resistor. 10. The method of claim 9, The variable resistance of the ground for electric shock is ground simulation circuit of the low-voltage wiring system, characterized in that having a resistance range of 500 to 1,650 Ohm (Ω). 6. The method according to any one of claims 1 to 5, The ground simulation circuit of the low voltage wiring system includes a first and a second ground terminal, The neutral wire (N) and the ground grid is connected to the first ground terminal, Connecting the protective conductor PE to a second ground terminal, connecting a second switch connected to the first device ground to the first device ground, and connecting a third switch connected to the neutral wire N to the first device ground. Grounding simulation circuit of the low-voltage wiring system, characterized in that. The method of claim 2, The ground simulation circuit of the low voltage wiring system includes a first and a second ground terminal, The neutral wire (N) and the ground grid is connected to the first ground terminal, The protective conductor PE is connected to the second ground terminal, the second switch connected to the first device ground and the fourth switch connected to the second device ground are connected to the first device ground, and are connected to the neutral wire N. A grounding simulation circuit for a low voltage wiring system, comprising connecting a switch to a ground of a first device. A ground simulation circuit (hereinafter referred to as a ground simulation circuit) of the low voltage wiring system according to any one of claims 1 to 5; In the ground simulation circuit, a probe is provided at any one or more of the front and rear ends of the circuit breaker, the load front end, the protective conductor (PE) connection, and the device ground connection part to measure voltage, current, or impedance, and measure the measured value. A data acquisition device (DAQ); Grounding simulation device of a low voltage wiring system including a display unit for displaying the measurements collected by the data collection device, a switch of the ground simulation circuit and a control switch for controlling a variable resistor, and a simulator panel including a connection jack for connecting a load . The method of claim 13, The connection jack is a grounding simulation device of a low voltage wiring system, characterized in that can selectively connect the electric load or the resistance load.

Images