KR102265843B1 - System for preventing over current flow - Google Patents

Abstract

The present invention relates to an overcurrent inflow prevention system, and more specifically, to an overcurrent inflow prevention system that prevents overcurrent from flowing in when reversed by connecting an overcurrent inflow prevention circuit including a separate switch to the gate terminal and the source terminal of a discharge switch. it's about

Description

SYSTEM FOR PREVENTING OVER CURRENT FLOW

The present invention relates to an overcurrent inflow prevention system, and more specifically, to an overcurrent inflow prevention system that prevents overcurrent from flowing in when reversed by connecting an overcurrent inflow prevention circuit including a separate switch to the gate terminal and the source terminal of a discharge switch. it's about

With the development of industry, the demand for electricity is increasing, and the gap in electricity consumption between day and night, season, and day is gradually deepening. Recently, for this reason, many technologies for reducing the peak load by utilizing the surplus power of the system have been rapidly developed.

A representative of these technologies is an Energy Storage System (ESS) that stores surplus power of the system in a battery or supplies insufficient power of the system from the battery.

The ESS includes an energy generator, an inverter, a battery and a load.

During normal energy supply, the electric energy generated by the energy generator is supplied to the load. At the same time, the surplus power of the energy generator is converted through an inverter, which is a power conversion device, and charged in the battery.

Thereafter, during peak power or power failure, the power charged in the battery is converted through an inverter and supplied to the load.

On the other hand, when the inverter and the battery are connected in such an ESS configuration, a dangerous situation may occur where a large current instantaneously flows by connecting the (+) and (-) terminals incorrectly.

In general, in order to prevent the inflow of overcurrent, a protection circuit and a protection fuse are configured in the battery to turn on/off the current of the battery to protect it. When overcurrent flows in, the protection fuse is melted or the switch in the protection circuit is turned off to protect the battery. protect

However, since the configuration of the protection circuit is controlled through the BMS, the response speed is slower than that of the protection fuse, and the protection fuse needs to be replaced once it is melted.

Therefore, in the reverse connection as described above, the simplest method is to simply form the shapes of the (+) and (-) terminals different from the current O-ring type, but since the connection terminal changes according to the user, the connection terminal If you change the product, the production cost increases and the produced product cannot be used universally.

Therefore, it is required to develop a technology that improves the versatility of the product by forming a different terminal shape or forming a separate configuration on the system instead of using BMS, and rapidly preventing the inflow of overcurrent generated during reverse connection.

US 2012-0096217 A

The present invention provides an overcurrent inflow prevention system that prevents the inflow of an overcurrent generated when a terminal is connected in reverse.

The overcurrent inflow prevention system according to an embodiment of the present invention is an overcurrent inflow prevention system for preventing an inflow of overcurrent when power is reversed. The discharge switch unit and the first side are connected to a gate terminal in the discharge switch unit, and the second side discharges It is connected to the source terminal in the switch part, the third side is connected to the ground (GND) where the overcurrent inflow path is formed when the power is reversely connected, and the fourth side is configured to include an overcurrent inflow prevention circuit part connected to the battery (+) side, When an overcurrent flows in through the third side of the overcurrent inflow prevention circuit part, the first side and the second side of the overcurrent inflow prevention circuit part conduct and the discharge switch part is short-circuited.

A diode forwardly connected in a direction from the third side to the fourth side of the overcurrent inflow prevention circuit part is disposed on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit part.

The overcurrent inflow prevention circuit unit includes a first resistor connected to the overcurrent inflow path, a Zener diode connected to the first resistor, a second resistor connected to the first resistor, and an overcurrent inflow prevention connected to the first resistor. It consists of a switch part.

The overcurrent inflow prevention switch unit is turned on when a current equal to or greater than a predetermined voltage value is applied to the gate terminal of the reverse connection prevention switch unit from the first resistor unit to electrically connect the source terminal and the drain terminal of the reverse connection prevention switch unit.

The Zener diode and the second resistor unit are connected to a gate terminal in the discharge switch unit to form a first current path, and are connected to a source terminal in the discharge switch unit to form a second current path.

The overcurrent inflow prevention circuit unit is configured to further include a notification unit for transmitting a reverse connection signal to the BMS that controls the on/off of the discharge switch unit when the overcurrent inflow prevention switch unit is turned on.

Upon receiving the reverse connection signal from the notification unit, the BMS transmits the reverse connection signal to a separate display device mounted outside the battery.

The overcurrent inflow prevention system according to an embodiment of the present invention is a method of configuring a reverse connection prevention circuit unit for preventing an overcurrent inflow when the power is reversed, and the current and voltage for measuring the current and voltage values of the flowing in when the power is reversed A first measurement step, a diode reference value setting step of setting a selection reference value of a diode based on the current and voltage measured in the current and voltage measurement step, a first based on the voltage value measured in the current and voltage measurement step Based on the voltage decreased through the first resistance reference value set in the first resistance reference value setting step of setting the selection reference value of the resistor unit and the first resistance reference value setting step, the selection reference value of the Zener diode and the second resistance unit It is configured to include a Zener diode and a second resistance reference value setting step for setting the .

The current and voltage measuring step is repeated a predetermined number of times.

After repeating a predetermined number of times in the current and voltage measuring step, the highest value among the measured voltage values is used.

The first resistance reference value in the first resistance reference value setting step, the Zener diode and the second resistance reference value in the Zener diode and second resistance reference value setting step are set according to the withstand voltage of the overcurrent inflow switching unit.

The overcurrent inflow prevention system according to an embodiment of the present invention adds an overcurrent inflow prevention circuit unit comprising a separate switch to the existing discharge switch, and when an overcurrent flows in during reverse connection, the discharge switch is physically connected using the overcurrent inflow prevention circuit unit. By shorting the battery, it is possible to quickly and safely protect the battery from overcurrent.

1 is a structural diagram of an overcurrent inflow prevention system according to an embodiment of the present invention;
2 is a flowchart of a method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the contents described in the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Only the embodiments are provided to complete the disclosure of the present invention, and to fully inform those of ordinary skill in the art of the scope of the present invention.

Also, terms including an ordinal number, such as first, second, etc., may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of identifying one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

<Example 1>

Next, an overcurrent inflow prevention system according to an embodiment of the present invention will be described.

The overcurrent inflow prevention system of the present invention connects the overcurrent inflow prevention circuit part that is turned on/off when the overcurrent flows in to the gate terminal and the source terminal of the discharge switch, and prevents overcurrent from flowing into the battery through the overcurrent inflow prevention circuit part when the power is reversed.

1 is a structural diagram of an overcurrent inflow prevention system according to an embodiment of the present invention.

Referring to FIG. 1 , in the overcurrent inflow prevention system 100 according to an embodiment of the present invention, a discharge switch unit 110 and a first side are connected to a gate terminal in the discharge switch unit, and a second side is a source in the discharge switch unit terminal, the third side is connected to the ground (GND) where the overcurrent inflow path is formed when the power is reversely connected, and the fourth side is configured to include an overcurrent inflow prevention circuit unit 120 connected to the battery (+) side.

Therefore, when the power is reversed and an overcurrent flows through the third side of the overcurrent inflow prevention circuit unit 120 , the first side and the second side of the overcurrent inflow prevention circuit unit 120 conduct and the discharge switch unit 110 ) to prevent overcurrent from flowing into the battery as a result of a short circuit.

This configuration is formed to prevent a dangerous situation where large currents and voltages instantaneously flow by erroneously connecting the (+) and (-) terminals in the process of assembling the inverter and the battery when configuring the ESS.

In addition, in the overcurrent inflow prevention system 100 of the present invention, since the overcurrent prevention control does not go through the BMS, a faster immediate response is possible.

Each configuration of the overcurrent inflow prevention system 100 will be described in more detail below.

The discharge switch unit 110 is configured as an FET to turn on/off the discharge current flowing when the load is supplied from the battery.

In addition, the drain terminal of the discharging switch unit 110 is connected to the charging switch unit for turning on/off the charging current, and the gate terminal responsible for on/off of the discharging switch unit 110 is the BMS of the battery and the overcurrent It is connected to the first side of the inflow prevention circuit part 120, and the source terminal is connected to the second side of the overcurrent inflow prevention circuit part 120 so that when overcurrent flows due to the reverse power connection, the first side and the second The side is conductive and physically shorted.

As such, when the discharging switch unit 110 is short-circuited, the state of the discharging switch unit 110 continues to be in an off state and ON control is impossible.

Therefore, the overcurrent generated by the reverse connection to the battery does not flow into the battery until the inverter connected to the battery in reverse is removed.

On the other hand, when the power supply is reversely connected, the (+) voltage of the battery is converted to (-), and the ground (GND) voltage is converted to a (+) voltage, which is converted into a structure as if discharging.

Therefore, the overcurrent inflow path is connected to the discharging switch unit 110 instead of the charging switch unit, so that the discharging switch unit 110 can be used similarly to the discharge.

In addition, the first side of the overcurrent inflow prevention circuit unit 120 is connected to the gate terminal in the discharge switch unit 110 , the second side is connected to the source terminal in the discharge switch unit 110 , and the third side is connected to the reverse power supply. It is connected to the ground (GND) where the overcurrent inflow path is formed, and the fourth side is connected to the battery (+) side.

In addition, the overcurrent inflow prevention circuit unit 120 includes a first resistance unit 122 connected to the overcurrent inflow path, a Zener diode 123 connected to the first resistance unit 122 , and a second resistance unit connected to the first resistance unit 122 . It is configured to include a resistance unit 124 and an overcurrent inflow prevention switch unit 125 connected to the first resistance unit 122 . Here, a diode 121 connected in a forward direction from the third side to the fourth side of the overcurrent inflow prevention circuit unit 120 is disposed on the overcurrent inflow path.

Accordingly, the Zener diode 123 , the second resistor unit 124 , and the overcurrent inflow prevention switch unit 125 are connected in parallel, and the overcurrent with reduced voltage is divided and introduced through the first resistance unit 122 .

In addition, the configuration of the overcurrent inflow prevention circuit unit 120 will be described in more detail below.

The diode 121 is forwardly connected in a direction from the third side to the fourth side of the overcurrent inflow prevention circuit unit 120 so that only the overcurrent coming from the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit unit 120 can flow. let it be

Therefore, when current flows from the fourth side to the third side of the overcurrent inflow prevention circuit unit 120 due to the diode in the photo relay 121 , the overcurrent inflow prevention system 100 is not driven, and the overcurrent inflow prevention circuit unit The overcurrent inflow prevention system 100 is driven only when a current flows from the third side to the fourth side of 120 .

In addition, the first resistor unit 122 is connected to the overcurrent inflow path, to be more precise, is connected to the diode 121 in the overcurrent inflow path so that the overcurrent flows in through the diode 121 .

In addition, since the overcurrent passing through the first resistor unit 122 flows in divided into the overcurrent inflow prevention switch unit 125 connected in parallel with the Zener diode 123 and the second resistor unit 124, the first resistance unit ( In 122), an overcurrent protection resistance value that allows the voltage of the overcurrent flowing into the overcurrent inflow prevention switch unit 125 to have a value less than the withstand voltage that the overcurrent inflow prevention switch unit 125 can withstand is set.

In addition, the first resistor unit 122 may include one or more resistors so that excessive heat is not generated in one large resistor.

In addition, the Zener diode 123 and the second resistor unit 124 are connected to the first resistor unit 122 so that the overcurrent divided by the first resistance unit 122 is reduced and flows.

In addition, the Zener diode 123 and the second resistor unit 124 are connected to a gate terminal in the discharge switch unit 110 to form a first current path, and are connected to a source terminal in the discharge switch unit 110 to form a second By forming a current path, the reduced overcurrent is supplied to each current path through the Zener diode 123 and the second resistor unit 124 .

In addition, the overcurrent inflow prevention switch unit 125 is composed of an FET, and a gate terminal in the overcurrent inflow prevention switch unit 125 is connected to the first resistor unit 122 , and a source terminal is the Zener diode 123 . and a second current path connected to the second resistor unit 124 , and a drain terminal is connected to a gate terminal of the discharge switch unit 110 .

Accordingly, when an overcurrent having a reduced voltage in the first resistor unit 122 flows into the gate terminal of the overcurrent inflow prevention switch unit 125 , the overcurrent inflow prevention switch unit 125 is turned on to turn on the overcurrent inflow prevention switch The source and drain terminals of the unit 125 are electrically connected, and the current of the second current path connected to the Zener diode 123 and the second resistor unit 124 flows in the overcurrent inflow prevention switch unit 125 . do.

In addition, when the source terminal and the drain terminal of the overcurrent inflow prevention switch unit 125 are electrically connected, the discharge switch unit 110 is automatically short-circuited because the gate terminal and the source terminal in the discharge switch unit 110 are electrically connected.

In addition, the voltage of the overcurrent having the reduced voltage in the first resistor unit 122 is greater than or equal to a predetermined voltage value.

Here, the predetermined voltage value means the minimum voltage value for driving the overcurrent inflow prevention switch unit 125, and it is preferable to select a value within 1.5 to 2.5 times the voltage value flowing inside the battery when the battery is discharged.

If the value of the voltage reduced through the first resistor unit 122 is less than a predetermined voltage value, it is determined that the overcurrent does not flow and the overcurrent inflow prevention circuit unit 120 is not driven.

In addition, in the overcurrent inflow prevention circuit unit 120, when the overcurrent inflow prevention switch unit 125 is turned on, a notification unit for transmitting a reverse connection signal to the BMS that controls the on/off of the discharge switch unit 110 is additionally added. consists of including

The notification unit is connected to the first side of the overcurrent inflow prevention circuit unit 120 to notify the BMS immediately when the overcurrent inflow prevention switch unit 125 is turned on.

In addition, the BMS receiving the reverse connection signal from the notification unit transmits the reverse connection signal to a separate display device mounted outside the battery so that the user can recognize that the power is reversed. Here, the separate display device means an alarm sound, an indicator light, or a monitor of a server that manages the ESS.

Therefore, the method of driving the overall overcurrent inflow prevention system 100 is that when the pole of the inverter is reversely connected to the battery when the battery and the inverter are connected, the (+) pole of the battery becomes a (-) pole, and the ground (GND) terminal is It becomes a (+) pole and an overcurrent flows in through the power inflow path, and the incoming overcurrent passes through the diode 121 .

The overcurrent passing through the diode 121 passes through the first resistor unit 122, and the overcurrent having the voltage reduced through the first resistor unit 122 is connected to the Zener diode 123 and the second resistor in parallel. 2 is divided into the resistor unit 124 and the overcurrent inflow prevention switch unit 125 .

When the voltage of the overcurrent entering the overcurrent inflow prevention switch unit 125 is equal to or greater than a predetermined value, the overcurrent inflow prevention switch unit 125 is turned on and passes through the Zener diode 123 and the second resistor unit 124. The overcurrent having the reduced voltage flows from the source terminal to the drain terminal of the overcurrent inflow prevention switch unit 125 .

Accordingly, the current flowing from the source terminal to the drain terminal of the overcurrent inflow prevention switch unit 125 flows to the gate terminal and the source terminal of the discharge switch unit 110 to conduct, and the discharge switch unit 110 is automatically short-circuited. make it stand out

In addition, when turned on in the overcurrent inflow prevention switch unit 125 , the notification unit in the overcurrent inflow prevention circuit unit 120 transmits a reverse connection signal to the BMS connected to the discharge switch unit 110 .

Upon receiving the reverse connection signal, the BMS transmits the reverse connection signal to a separate display device to notify the user of the reverse connection of the inverter.

<Example 2>

Next, a method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention will be described.

The method of configuring an overcurrent inflow prevention system of the present invention is a method of efficiently configuring an overcurrent inflow prevention system by calculating and setting reference values of each part of the overcurrent inflow prevention system.

2 is a flowchart of a method for configuring an overcurrent inflow prevention system according to an embodiment of the present invention.

Referring to FIG. 2 , the method for configuring an overcurrent inflow prevention system according to an embodiment of the present invention first measures the voltage value of the overcurrent flowing in when the power is reversed (current and voltage measurement step: S210), and based on the measured voltage value to set the selection reference value of the diode 121 (diode reference value setting step: S220).

In addition, based on the voltage measured in the current and voltage measurement step, a selection reference value of the first resistor unit 122 is set (first resistance reference value setting step: S230), and through the set first resistance reference value Based on the reduced voltage, selection reference values of the Zener diode 123 and the second resistor unit 124 are set (Zener diode and second resistor reference value setting step: S240).

As described above, each part of the overcurrent inflow prevention system 100 may be configured based on the values set in each step.

Each step of the method of configuring the overcurrent inflow prevention system will be described in more detail below.

The current and voltage measuring step ( S210 ) is a step of measuring the current and voltage values of the overcurrent flowing in when the power is reversed, and is repeated a predetermined number of times. Here, the predetermined number is set to 7 as an example, but is not limited thereto.

Thereafter, the highest value among the voltage values measured after repeating a predetermined number of times is set as the value used in the diode reference value setting step S220 and the first resistance reference value setting step S230 .

In addition, the diode reference value setting step ( S220 ) is a step of setting a selection reference value of the diode 121 based on the current and voltage values measured in the current and voltage measurement step ( S210 ).

This is when the diode 121 disposed in a forward direction from the third side to the fourth side of the overcurrent inflow prevention circuit unit 120 on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit unit 120 is reversely connected to the power. A value greater than the voltage value measured in the current and voltage measuring step ( S210 ) is set as the selection reference value to have a withstand voltage level sufficient to withstand the generated overcurrent.

For example, when the maximum voltage value in the current and voltage measuring step S210 is measured to be 10V, the selection reference value of the diode 121 is set to 11V, so that when the diode 121 is selected, the withstand voltage level of 11V or more Make sure the parts you have are selected.

In addition, the first resistance reference value setting step (S230) is a step of setting a selection reference value of the first resistor unit 122 based on the voltage value measured in the current and voltage measurement step (S210), This is a step of setting a resistance value for reducing the voltage of the overcurrent flowing into the overcurrent inflow path of the overcurrent inflow prevention circuit unit 120 .

In addition, since the overcurrent passing through the first resistor unit 122 flows directly into the gate terminal of the overcurrent inflow prevention switch unit 125 , the voltage value of the overcurrent passing through the first resistor unit 122 is the overcurrent inflow prevention switch A selection reference value of the first resistor unit 122 is set to be less than the withstand voltage of the unit 125 .

Here, the overcurrent inflow prevention switch unit 125 is preselected as a component having a high withstand voltage and a low price.

In addition, in the method of calculating the selection reference value of the first resistor unit 122 , the voltage value remaining after subtracting the withstand voltage level of the photo relay 121 from the maximum voltage value measured in the current and voltage measuring step ( S210 ) is calculated. It is calculated by dividing by the current value.

For example, when the maximum voltage value in the current and voltage measuring step S210 is measured to be 10V, the withstand voltage of the overcurrent inflow prevention switch unit 125 is 6V and the overcurrent flows to 2A, the first resistor The minimum value of negative 122 is calculated as 2Ω. This means that in order to protect the overcurrent inflow prevention switch unit 125 , the selection reference value of the overcurrent protection resistor unit 122 must be set to a value exceeding 2Ω.

In addition, the Zener diode and second resistance reference value setting step (S240) is performed on the basis of the voltage reduced through the first resistance reference value set in the first resistance reference value setting step (S230), the Zener diode 123 and the second resistance value setting step (S240). 2 This is a step of setting a selection reference value of the resistor unit 124. More precisely, the value of the voltage flowing into the gate terminal of the overcurrent inflow prevention switch unit 125 and the Zener diode 123 and the first 2 The selection reference values of the Zener diode 123 and the second resistor unit 124 are set so that the difference (VGSS) between the voltage values of the overcurrent passing through the resistor unit 124 is within a predetermined range.

Here, the withstand voltage level of the gate terminal of the overcurrent inflow prevention switch unit 125 is greater than the withstand voltage level of the source terminal within a predetermined range.

In addition, the Zener diode 123, the second resistor unit 124, and the overcurrent inflow prevention switch unit 125 are connected in parallel so that the overcurrent passing through the first resistance unit 122 flows in dividedly, the Zener diode ( 123) and the second resistor unit 124 are significantly different from each other, as a large current flows in only one component, the selection reference values of the Zener diode 123 and the second resistor unit 124 are within an approximate range. to be set in .

For example, when the voltage value of the overcurrent passing through the first resistor unit 122 is 20V and the current value is 4A, and VGSS is 10V due to the characteristics of the FET, the Zener diode 123 and the second resistor unit 124 The selection reference value of is calculated as 5Ω so that the same current of 2A flows, respectively, and according to VGSS, it means that the selection reference value of the Zener diode 123 and the second resistor unit 124 should be set to less than 5Ω. This is to reduce the load on the overcurrent inflow prevention switch unit 125 as much as possible, and the voltage at the drain terminal of the overcurrent inflow prevention switch unit 125 is limited to zero.

On the other hand, although the technical idea of the present invention has been described in detail according to the above embodiment, it should be noted that the above embodiment is for the description and not the limitation. In addition, a person of ordinary skill in the art of the present invention will be able to various embodiments within the description of the claims described.

100: overcurrent inflow prevention system
110: discharge switch unit
120: overcurrent inflow prevention circuit unit
121: diode
122: first resistor unit
123: zener diode
124: second resistor unit
125: overcurrent inflow prevention switch unit

Claims (11)

In the overcurrent inflow prevention system for preventing the inflow of overcurrent when power is reversed,
Discharge switch unit; and
The first side is connected to the gate terminal in the discharge switch unit, the second side is connected to the source terminal in the discharge switch unit, the third side is connected to the ground (GND) where the overcurrent inflow path is formed when the power is reversely connected, and the fourth side is the battery an overcurrent inflow prevention circuit unit connected to the (+) side; consists of,
When an overcurrent flows in through the third side of the overcurrent inflow prevention circuit part, the overcurrent inflow prevention system, characterized in that the first side and the second side of the overcurrent inflow prevention circuit part conducts and the discharge switch part is short-circuited.
The method according to claim 1,
The overcurrent inflow prevention system, characterized in that a diode forwardly connected in a direction from the third side to the fourth side of the overcurrent inflow prevention circuit part is disposed on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit part.
The method according to claim 1,
The overcurrent inflow prevention circuit unit,
a first resistor connected to the overcurrent inflow path;
a Zener diode connected to the first resistor;
a second resistor connected to the first resistor; and
an overcurrent prevention switch unit connected to the first resistor unit; An overcurrent inflow prevention system comprising a.
4. The method according to claim 3,
The overcurrent inflow prevention switch unit is turned on when a current equal to or greater than a predetermined voltage value is applied to the gate terminal of the reverse connection prevention switch unit from the first resistor unit to electrically connect the source terminal and the drain terminal of the reverse connection prevention switch unit Overcurrent inflow prevention system.
4. The method according to claim 3,
and the Zener diode and the second resistor unit are connected to a gate terminal in the discharge switch unit to form a first current path, and are connected to a source terminal in the discharge switch unit to form a second current path.
4. The method according to claim 3,
The overcurrent inflow prevention circuit unit, when the overcurrent inflow prevention switch unit conducts, a notification unit for transmitting a reverse connection signal to the BMS for on/off controlling the discharge switch unit; An overcurrent inflow prevention system, characterized in that it further comprises a.
7. The method of claim 6,
The BMS receiving the reverse connection signal from the notification unit transmits the reverse connection signal to a separate display device mounted outside the battery.
In the method of configuring an overcurrent inflow prevention system that prevents an inflow of overcurrent when power is reversed,
A current and voltage measuring step of measuring the current and voltage values of the overcurrent flowing in when the power is reversed;
a diode reference value setting step of setting a selection reference value of a diode based on the current and voltage measured in the current and voltage measuring step;
a first resistance reference value setting step of setting a selection reference value of the first resistor unit based on the voltage value measured in the current and voltage measuring step; and
a Zener diode and second resistance reference value setting step of setting selection reference values of the Zener diode and the second resistor unit based on the voltage reduced through the first resistance reference value set in the first resistance reference value setting step;
A method of configuring an overcurrent inflow prevention system, characterized in that it comprises a.
9. The method of claim 8,
The current and voltage measuring step is a method of constructing an overcurrent inflow prevention system, characterized in that it is repeated a predetermined number of times.
10. The method of claim 9,
Method of constructing an overcurrent inflow prevention system, characterized in that the highest value among the voltage values measured after repeating a predetermined number of times in the current and voltage measuring step is used.
9. The method of claim 8,
The first resistance reference value in the first resistance reference value setting step, the Zener diode and the second resistance reference value in the Zener diode and second resistance reference value setting step are set according to the withstand voltage of the overcurrent inflow switching unit A method of configuring an overcurrent inflow prevention system, characterized

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