KR20210106666A - Error testing method for charger of electric vehicle - Google Patents

Abstract

The present invention relates to an error testing method for a charger of an electric vehicle. An error rate is calculated in consideration of power loss caused by a power cable withdrawn from a charger, and power is supplied by applying the calculated error rate, thereby improving the reliability and accuracy of power metering. Test can be prepared simply to reduce unnecessary time and costs for error rate test. A reference pulse number predicting step (S40) calculates an expected pulse number (Nnom) using formula 1 and simultaneously an error rate calculating step (S50) calculates the error rate of charging power by substituting the expected pulse number (Nnom), which has been calculated by formula 1, for formula 2, thereby improving the speed and accuracy of calculation.

Description

Error testing method for charger of electric vehicle

The present invention relates to a method for testing an error of an electric vehicle charging device, and in detail, an error rate is calculated in consideration of power loss due to a power cable drawn from a charger, and then power is supplied by applying the calculated error rate. It relates to an error test method of an electric vehicle charging device that can increase the reliability and accuracy of electric power metering by doing so.

Recently, as environmental problems have emerged and technologies for electric energy have been developed, interest in electric vehicles (EVs) that use electric energy stored in batteries as a vehicle power source is rapidly increasing.

Such an electric vehicle (EV) includes a vehicle body and accessories provided in a typical vehicle, a battery charged with electricity, an electric motor for generating power using the electric power charged in the battery, and installed on one side of the vehicle body to external Since it consists of a charging plug connected to the charging plug, when the battery is discharged, the vehicle cannot be driven, and thus the battery must be periodically charged with power.

Accordingly, various studies on electric charging systems for supplying electric power to electric vehicles are being conducted, and the penetration rate is gradually increasing.

1 is a configuration diagram showing a charging device for an electric vehicle disclosed in Korean Patent Application Laid-Open No. 10-2014-0061603 (Title of the Invention: Charging Device for Electric Vehicle).

The charging device for an electric vehicle (hereinafter referred to as the prior art) 100 of FIG. 1 is independently installed in a position adjacent to the charger 110 and outputs a light pulse proportional to the amount of power supplied to the electric vehicle. and a switch 103 installed inside the charger 110 to open and close the power line 112 drawn out from the digital watt-hour meter 120, and the electric power according to the charging cost input by the user is supplied to the electric vehicle, and the digital The light-receiving sensor unit 111 installed to face the active power metering pulse unit 125 of the watt-hour meter 120 and receiving the light pulse signal emitted from the active power metering pulse unit 125, and the charging drawn out from the charger 110 It consists of a cable 118 and a plug 119 installed at the end of the charging cable 118 .

The prior art 100 configured as described above receives an optical pulse signal whose amplitude is variable according to the amount of power from the digital watt-hour meter 120, detects the amount of active power, and then charges the battery by being configured to supply power according to the detected amount of active power. For this purpose, it has the advantage of increasing the user's confidence in the charging rate by giving an error between the amount of power supplied to the vehicle and the amount of power charged.

In general, power supplied to the charger 110 through the power line 112 is supplied to the electric vehicle through the plug 119 via the charging cable 118 . At this time, since the charging cable 118 is generally formed to a predetermined length of at least 0.5 m or more, when power is supplied through the charging cable 118, power loss due to the characteristics of the charging cable 118 and the plug 119 itself. characteristics that occur.

However, the prior art 100 does not take into account the characteristics of the charging cable 118 and the plug 119 at all, and the amount of power supplied by the digital watt-hour meter 120 and the amount of power output through the actual plug 119 are different. There is a problem, and accordingly, a charging fee that is higher than the amount of power supplied to the electric vehicle is charged, thereby reducing the accuracy and reliability of the charging service.

For example, assuming that the amount of power supplied from the digital watt-hour meter 120 to the charger 110 through the power line 112 is 220V, the digital watt-hour meter 120 transmits an optical pulse corresponding to 220V to the charger 110 . In addition, the charger 110 charges a charging charge for 220V according to the light pulse transmitted through the light receiving sensor unit 111, but the amount of power supplied to the vehicle through the plug 119 is actually the charging cable 118. And power loss is generated by the plug 119, so that power of less than 220V is supplied.

In other words, there is an urgent need to research a charging device for electric vehicles in order to reduce the error between the amount of power supplied to the actual vehicle and the amount of power applied to charging charges.

The present invention is to solve this problem, and the problem of the present invention is to calculate an error rate in consideration of power loss due to a power cable drawn from a charger, and then apply the calculated error rate to supply power. The purpose of this study is to provide an error test method for an electric vehicle charging device that can increase the reliability and accuracy of measurement.

In addition, another solution of the present invention is that the reference system pulse quantity prediction step (S40) calculates the expected pulse quantity (N _nom ) using Equation 1 below, and the error rate calculation step (S50) is calculated by Equation 1 To provide an error test method of an electric vehicle charging device that can improve the speed and accuracy of calculation processing by substituting the estimated pulse quantity ( N _{nom ) into the following Equation 2 to calculate the error rate of the charging power amount} .

[Equation 1]

At this time, ' N _dut ' is the number of pulses generated from the electric vehicle charger (or module), ' f _nom ' is the frequency generated in proportion to the power in the reference watt-hour meter, and ' m ' is the constant of the reference watt-hour meter (eg, single-phase - 1) , 3 phase - 3), ' U _r ' is the voltage supplied to the reference watt-hour meter, ' I _r ' is the current supplied to the reference watt-hour meter, and ' C _m ' is the meter constant of the electric vehicle charger (or module) ( pulse/kWh).

[Equation 2]

At this time, 'δ W _dut ' is the charging wattage error rate (%), ' N _act ' is the pulse quantity generated from the reference watt-hour meter, and ' N _nom ' is the expected pulse quantity generated from the reference system of the electric vehicle charging device for the same time.

The solution of the present invention for solving the above problem is that the power cable is drawn in from the outside to one side, the charging cable having the charging plug installed at the end is drawn out to the other side, and the wattage error rate of the electric vehicle charging device in which the reference system is installed inside In the error test method (S1) for testing: In the error test method (S1), the reference watt-hour meter is electrically connected to the charging plug, and then a current is connected to the electric vehicle charging device and the reference watt-hour meter so that the current is A voltmeter/current device installation step (S10) of moving the electric vehicle charging device and the reference watt-hour meter in order, and connecting a voltage device with the electric vehicle charging device and the reference watt-hour meter in parallel; A pulse counter connecting the pulse counter to the reference system and the reference watt-hour meter of the electric vehicle charging device so that the pulse counter counts a pulse according to the power supply of the electric vehicle charging device and a pulse according to the power supplied through the charging plug installation step (S20); a pulse count measuring step (S30) in which the pulse counter counts the pulse through the reference meter and the pulse through the reference watt-hour meter; The terminal connected to the pulse counter includes an error rate calculation step (S50) of calculating an error rate by using the pulse coefficient of the electric vehicle charging device and the pulse coefficient of the reference watt-hour meter.

In addition, in the present invention, the voltage device/current device installation step (S10) is a voltage device that connects the voltage device with the electric vehicle charging device and the reference watt-hour meter in parallel so that the same voltage is applied to the electric vehicle charging device and the reference watt-hour meter installation step (S11); a current device installation step (S12) of connecting the current device in series to the electric vehicle charging device and the reference watt-hour meter so that the same current flows to the electric vehicle charging device and the reference watt-hour meter; It is preferable to further include a line connection step (S13) for electrically connecting the charging plug and the reference watt-hour meter.

In addition, in the present invention, the error test method (S1) further includes a reference system pulse quantity prediction step (S40) that is performed after the pulse coefficient measuring step (S30), and the reference system pulse quantity prediction step (S40) is performed by the following math Calculate the expected pulse quantity (N _nom ) generated from the reference system of the electric vehicle charging device by using Equation 1, and the error rate calculation step (S50) includes the following Equation 2 and the reference system pulse quantity prediction step (S40) It is preferable to calculate the error rate of the amount of charging power using the expected pulse number ( N _{nom ) calculated by .}

[Equation 1]

At this time, ' N _dut ' is the number of pulses generated from the electric vehicle charger (or module), ' f _nom ' is the frequency generated in proportion to the power in the reference watt-hour meter, and ' m ' is the constant of the reference watt-hour meter (eg, single-phase - 1) , 3 phase - 3), ' U _r ' is the voltage supplied to the reference watt-hour meter, ' I _r ' is the current supplied to the reference watt-hour meter, and ' C _m ' is the meter constant of the electric vehicle charger (or module) ( pulse/kWh),

[Equation 2]

At this time, 'δ W _dut ' is the charging wattage error rate (%), ' N _act ' is the pulse quantity generated from the reference watt-hour meter, and ' N _nom ' is the expected pulse quantity generated from the reference system of the electric vehicle charging device for the same time. Lim

According to the present invention having the above problems and solutions, the error rate is calculated in consideration of the power loss caused by the power cable drawn out from the charger, and then power is supplied by applying the calculated error rate, whereby reliability and accuracy of power metering can increase

In addition, according to the present invention, test preparation is made simple, and unnecessary time and cost consumption due to the error rate test can be reduced.

In addition, according to the present invention, the reference system pulse quantity prediction step (S40) calculates the expected pulse quantity (N _nom ) using Equation 1, and at the same time, the error rate calculation step (S50) calculates the expected pulse quantity calculated by Equation 1 ( N _nom ) is substituted in Equation 2 to calculate the error rate of the amount of charging power, thereby improving the speed and accuracy of the arithmetic processing.

1 is a configuration diagram showing a charging device for an electric vehicle disclosed in Korean Patent Application Laid-Open No. 10-2014-0061603 (Title of the Invention: Charging Device for Electric Vehicle).
2 is a schematic diagram illustrating an electric vehicle charging device applied to an error testing method for an electric vehicle charging device according to an embodiment of the present invention.
3 is a flowchart illustrating an error test method for an electric vehicle charging device according to an embodiment of the present invention.
Fig. 4 is a schematic diagram showing Fig. 3;
FIG. 5 is a flowchart showing the steps of installing the voltage device/current device of FIG. 3 .
6 is a configuration diagram illustrating a charging management system to which the error test method of the electric vehicle charging device of FIG. 3 is applied.
7 is a block diagram illustrating the controller of FIG. 6 .
8 is a block diagram illustrating the collection data selection module of FIG. 7 .

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a schematic diagram illustrating an electric vehicle charging device applied to an error testing method for an electric vehicle charging device according to an embodiment of the present invention.

As shown in FIG. 2 , the electric vehicle charging device 1 applied to the present invention is formed as a housing to connect the power cable 10 from the outside, and opens and closes the power supply to the power cable 10 drawn into the inside. An opening/closing member 11, such as a switch, is installed to

In addition, a reference system 12 such as a strategy measurement module is installed inside the electric vehicle charging device 1, and the reference system 12 is electrically connected to the internal power line of the electric vehicle charging device 1 to charge the electric vehicle charging device 1 ) to detect the amount of power.

In this case, the reference system 12 is preferably installed at a point adjacent to the end of the internal power line of the electric vehicle charging device 1 so that the power supplied from the electric vehicle charging device 1 to the charging cable C is measured.

In addition, the charging cable (C) is drawn out from the other side of the electric vehicle charging device (1), and the charging plug (5) is installed at the end of the charging cable (C).

At this time, in the present invention, a reference watt-hour meter 3 for detecting the amount of power supplied through the charging plug 5 is installed in order to implement the error test method S1 of the electric vehicle charging device of FIG. 3 to be described later.

The electric vehicle heavy electric device 1 configured in this way is electrically connected to the electric vehicle connector (not shown) at the same time as the opening and closing member 11 is closed and the charging plug 5 is electrically connected to the electric vehicle through the charging plug 5 during charging. As an electric vehicle, power is supplied according to a reservation or input from a user.

3 is a flowchart illustrating an error test method for an electric vehicle charging device according to an embodiment of the present invention, and FIG. 4 is a schematic diagram showing FIG. 3 .

An embodiment of the present invention, the electric vehicle charging device error test method (S1) is to reduce the error between the amount of power applied to the charging charge and the amount of power actually supplied to the vehicle to increase the accuracy and reliability of the charging service.

In addition, the electric vehicle charging device error test method (S1), as shown in FIG. 3, includes a voltage/current meter installation step (S10), a pulse counter installation step (S20), a pulse count measurement step (S30), a reference system pulse It consists of a quantity prediction step (S40) and an error rate calculation step (S50).

The voltmeter/current device installation step (S10) is, as shown in FIG. 4, the voltmeter 13 and the current device 14 that supply a voltage source and a current source to the electric vehicle charging device 1 and the reference watt-hour meter ( 3) is the step to connect each.

FIG. 5 is a flowchart showing the steps of installing the voltage device/current device of FIG. 3 .

The voltage/current device installation step (S10) includes a voltage device installation step (S11), a current device installation step (S12), and a line connection step (S13).

In the voltmeter installation step (S11), the voltmeter 13 is connected in parallel with the electric vehicle charging device 1 and the reference watt-hour meter 3 so that the same voltage is applied to the electric vehicle charging device 1 and the reference watt-hour meter 3 make it possible

That is, the same voltage is applied to the electric vehicle charging device 1 and the reference watt-hour meter 3 through the voltage device installation step S11.

At this time, Figure 4 is composed of a simplified schematic diagram for explaining the present invention, but is not shown, the voltmeter 13 is the amount of power at the end P of the charging plug 5 is detected by the reference watt-hour meter 3, the electric vehicle It is configured to apply a voltage to the charging device 1 and the reference watt-hour meter 3 in consideration of the voltage drop loss.

In the current meter installation step (S12), the reference watt-hour meter 3 and the electric vehicle charging device 1 are connected in series to the current meter 14 so that the same current flows through the reference watt-hour meter 3 and the electric vehicle charging device 1 make it possible

That is, the current generated by the current device 14 through the current device installation step S12 moves in the order of the reference watt-hour meter 3 -> the electric vehicle charging device 1 .

The line connection step (S13) proceeds after the voltage device installation step (S11) and the current meter installation step (S12), and the charging plug 5 installed at the end of the charging cable C is connected to the reference watt-hour meter 3 make it

That is, the current generated by the electric current device 14 moves to the electric vehicle charging device 1 -> the charging plug 5 -> the reference watt-hour meter (3).

In the pulse counter installation step (S20), the pulse counter 7 is connected to the reference system 12 of the electric vehicle charging device 1, so that the pulse counter 7 is a cycle (T) according to the power supply of the electric vehicle charging device 1 ) to count the pulses during

In addition, the pulse counter installation step (S20) connects the pulse counter 7 with the reference watt-hour meter 3 . At this time, the pulse counter 7 counts the pulses during the period T generated according to the power supplied through the end P of the charging plug 5 .

In addition, in the pulse counter installation step (S20), when the pulse counter 7 is installed, the terminal 9 is connected to the pulse counter 7 to be connected.

In general, as the charging cable (C) drawn out from the electric vehicle charging device (1) is manufactured to have a length of at least 0.5 m or more, the power supplied from the electric vehicle charging device (1) is the charging cable (C) and the charging plug (5) ), power loss is caused by its own load, and accordingly, the actual amount of power supplied to the vehicle through the charging plug 5 is reduced than the amount of power supplied from the electric vehicle charging device 1 .

The present invention is to solve this problem, and the pulse counter 7 counts the pulses according to the amount of power supplied from the electric vehicle charging device 1 and simultaneously counts the pulses according to the amount of power supplied through the charging plug 5 By being configured to count, it is possible to accurately count pulses for the actual amount of electric power supplied to the vehicle through the charging plug 5 and the amount of electric power supplied from the electric vehicle charging device 1 .

In the pulse counting step (S30), the pulse counter 7 is connected to the reference system 12 of the electric vehicle charging device 1 to count pulses according to the amount of power supplied from the electric vehicle charging device 1, and at the same time, the reference watt-hour meter It is a step of counting the pulses according to the amount of power connected to (3) and supplied through the charging plug (5).

At this time, as described above, the charging cable C and the charging plug 5 drawn out from the electric vehicle charging device 1 have a predetermined load due to their own characteristics, and accordingly, the electric vehicle charging device 1 and the charging plug Since a predetermined power loss occurs in the section of (5), the amount of power of the reference power meter 3 is reduced than the amount of power of the electric vehicle charging device 1 .

The reference system pulse quantity prediction step (S40) proceeds when the pulse count according to the power supply of the electric vehicle charging device 1 and the charging plug 5 is completed by the pulse count measurement step (S30), and the terminal 9 is It is a step of calculating the expected number of pulses (N _nom ) generated from the reference system 12 of the electric vehicle charging device 1 during the period T by using the pulse count value received from the pulse counter 7 .

In addition, the reference system pulse quantity prediction step S40 calculates the expected pulse quantity N _nom generated from the electric vehicle charging device 1 through Equation 1 below.

At this time, ' N _dut ' is the number of pulses generated from the electric vehicle charger (or module), ' f _nom ' is the frequency generated in proportion to the power in the reference watt-hour meter, and ' m ' is the constant of the reference watt-hour meter (eg, single-phase - 1) , 3 phase - 3), ' U _r ' is the voltage supplied to the reference watt-hour meter, ' I _r ' is the current supplied to the reference watt-hour meter, and ' C _m ' is the meter constant of the electric vehicle charger (or module) ( pulse/kWh).

That is, the reference system pulse quantity prediction step S40 calculates the expected pulse quantity N _nom generated according to the power supply of the electric vehicle charging device 1 during the period T using Equation 1 described above.

The error rate calculation step (S50) is a step of calculating the error rate of the charging power amount by using the 'N _nom ' calculated by the reference system pulse quantity prediction step (S30).

In addition, the error rate calculation step (S40) calculates the error rate (δ W _dut ) of the amount of charging power by using Equation 2 below.

In this case, 'δ W _dut ' is the charging wattage error rate (%), ' N _act ' is the pulse quantity generated from the reference watt-hour meter, and ' N _nom ' is the expected pulse quantity generated from the electric vehicle charging device for the same time.

That is, in the error rate calculation step (S50), the error rate can be quickly and easily calculated using the number of pulses generated in the actual reference watt-hour meter 3 and the expected pulse quantity of the electric vehicle charging device 1 through Equation 2 .

As described above, the electric vehicle charging device error test method (S1) of the present invention is configured to calculate the error rate in consideration of the power loss due to the load of the charging plug (C) and the charging plug (9), so that the amount of electric power applied to charging charge and By reducing the error in the amount of power supplied to the actual vehicle, it is possible to increase the accuracy and reliability of the charging service.

6 is a configuration diagram illustrating a charging management system to which the error test method of the electric vehicle charging device of FIG. 3 is applied.

As shown in FIG. 6 , the charge management system 20 includes the controllers 21-1, ..., 21-N for managing and controlling the electric vehicle charging device 1 of FIG. 3 described above and , the controller 21-1, ..., the charging management server 23 that receives the charging information from the 21-N, stores it and analyzes it to detect valid information, and the charging management server 23 Data movement between the client 25 receiving the charging service in connection with the charging service platform 24 provided, and the charging management server 23 and the controller 21-1, ..., 21-N It consists of a communication network 29 that provides a path.

The communication network 29 provides a data movement path between the charging management server 23 and the controller 21-1, ..., 21-N, in detail, a wide area network (WAN), a mobile communication network , a wired communication network, LTE, 3G, 4G, 5G, and the like.

The client 25 is a terminal possessed by a user, and in detail, a desktop PC, a notebook-book, a smart phone, a tablet PC, etc. can be composed of

In addition, the client 25 requests data from the charging management server 23 in connection with the charging service platform 24 provided by the charging management server 23 according to the user's request, and provides response data corresponding to the request data. can be displayed. In this case, the charging service may include information on a parking lot equipped with an electric vehicle charging device, a charging reservation, a payment service according to charging, and the like.

In addition, software, applications and applications for providing a charging service to the user in connection with the charging service platform 8 may be installed in the client 9 .

7 is a block diagram illustrating the controller of FIG. 6 .

The controller 21 of FIG. 7 manages and controls the overall operation of the electric vehicle charging device 1 .

In addition, as shown in FIG. 7 , the controller 21 includes a control module 210 , a memory 211 , a data transmission/reception module 212 , a charge management module 213 , a test module 214 , and a data collection module ( 215), a collection data selection module 216, and a charging power information generation module 217.

The control module 210 is an OS (Operating System) of the controller 21 , and manages and manages control objects 211 , 212 , 213 , 214 , 215 , 216 , and 217 . Control.

In addition, the control unit 210 executes the test module 214 according to a preset cycle, and when the error rate is calculated by the test module 214 , the calculated error rate data is input to the charging management module 213 .

Identification information of the corresponding electric vehicle charging device 1 is preset and stored in the memory 211 .

In addition, the collection data collected by the data collection module 215 and the charging power information generated by the charging power information generating module 217 are temporarily stored in the memory 211 .

The charging management module 213 manages and controls the overall operation of the electric vehicle charging device 1 .

The test module 214 is executed at preset intervals under the control of the control module 210, and calculates an error rate using the error test method S1 of the electric vehicle charging device of FIGS. 3 to 5 described above.

At this time, the error rate calculated by the test module 214 is input to the charge management module 213 under the control of the control module 210 , and the charge management module 213 considers the error rate input from the test module 214 . The electric vehicle charging device 1 is controlled to be charged.

The data collection module 214 collects watt-hour information from the reference watt-hour meter 3 in real time.

The collection data selection module 215 selects valid data among the collection data collected by the data collection module 214 .

8 is a block diagram illustrating the collection data selection module of FIG. 7 .

As shown in FIG. 8 , the measurement data selection module 216 includes a collection data input module 2161 and a comparison and discrimination module 2162 .

The collection data input module 2161 receives the amount of power data collected by the data collection module 215 .

The comparison and determination module 2162 compares whether the amount of power data input by the collection data input module 2161 is included within a threshold range based on the amount of power previously collected by using a preset threshold range.

In addition, the comparison and determination module 2162 determines the input power amount data as valid data, which is valid data, when the input power amount is not included in the threshold range of the previous power amount.

In addition, the comparison and determination module 2162 determines the input power amount data as invalid data, which is invalid data, when the input power amount is included in the threshold range of the previous power amount.

At this time, the amount of power data selected as valid data by the comparison and determination module 2162 is input to the charging power information generation module 217 under the control of the control module 210 .

When the charging power information generation module 217 receives the charging amount data selected as valid data by the collection data selection module 216, charging power information including the input charging amount data, time information, and identification information of the electric vehicle charging device , and the generated charging power information is transmitted to the charging management server 23 through the data transmission/reception module 212 under the control of the control module 210 .

The charging management server 23 stores the charging power information received from the controllers 21-1, ..., 21-N in the database server and at the same time analyzes the big data, which is the charging power information stored in the database server, Generate and detect meaningful information. In this case, the meaningful information means the usage state of each charging station, the generation of statistical data of the charging amount of each charging device, and the like.

In addition, when the charging management server 23 does not receive charging power information from the controllers 21-1, ..., 21-N, the previous charging power of the controller is replaced with the current charging power, and the database Save it to the server.

At this time, if the controllers 21-1, ..., (21-N) are a large quantity, the charge management server 23 is configured to control each controller 21-1, ..., (21-N) in real time. ), unnecessary network load and data consumption occur, but in the present invention, the controllers 21-1, ... The charging power information is transmitted to the charging management server 23 only when out of the critical range based on the It is possible to dramatically reduce the amount of data transmission by replacing the

S1: Electric vehicle charging device error test method
S10: Voltage device/current device installation step S11: Voltage device installation step
S12: Current device installation step S13: Line connection step
S20: Pulse counter installation step S30: Pulse counter measurement step
S40: Reference system pulse quantity prediction step S50: Error rate calculation step
1: Electric vehicle charging device 3: Standard watt-hour meter 5: Charging plug
7: Pulse counter 9: Terminal 10: Power cable
13: voltage device 14: current device

Claims (3)

In the error test method (S1) for testing the wattage error rate of an electric vehicle charging device in which a power cable is drawn in from the outside to one side, a charging cable having a charging plug installed at the end is drawn out to the other side, and a reference system is installed inside:
The error test method (S1) is
After the reference watt-hour meter is electrically connected to the charging plug, a current is connected to the electric vehicle charging device and the reference watt-hour meter so that the current moves in the order of the electric vehicle charging device and the reference watt-hour meter, and the voltage is applied to the electric vehicle. A voltmeter/current device installation step (S10) for connecting the charging device and the reference watt-hour meter in parallel;
A pulse counter connecting the pulse counter to the reference system and the reference watt-hour meter of the electric vehicle charging device so that the pulse counter counts a pulse according to the power supply of the electric vehicle charging device and a pulse according to the power supplied through the charging plug installation step (S20);
a pulse counting step (S30) in which the pulse counter counts the pulse through the reference meter and the pulse through the reference watt-hour meter;
Error test method (S1), characterized in that the terminal connected to the pulse counter includes an error rate calculation step (S50) of calculating an error rate by using the pulse coefficient of the electric vehicle charging device and the pulse coefficient of the reference watt-hour meter . The method according to claim 1, wherein the voltage/current device installation step (S10)
a voltage device installation step (S11) of connecting the voltage group to the electric vehicle charging device and the reference watt-hour meter in parallel so that the same voltage is applied to the electric vehicle charging device and the reference watt-hour meter;
an electric current device installation step (S12) of connecting the electric current device in series to the electric vehicle charging device and the reference watt-hour meter so that the same current flows to the electric vehicle charging device and the reference watt-hour meter;
Error test method (S1), characterized in that it further comprises a line connection step (S13) for electrically connecting the charging plug and the reference watt-hour meter. The method according to claim 2, wherein the error test method (S1) further comprises a reference system pulse quantity prediction step (S40) performed after the pulse coefficient measuring step (S30),
The reference system pulse quantity prediction step (S40) calculates the expected pulse quantity (N _nom ) generated from the reference system of the electric vehicle charging device using Equation 1 below,
The error rate calculation step (S50) is an error test, characterized in that the error rate of the charging power is calculated using the following Equation 2 and the expected pulse quantity (N _nom ) calculated by the reference system pulse quantity prediction step ( S40 ) Method (S1).
[Equation 1]

At this time, ' N _dut ' is the number of pulses generated from the electric vehicle charger (or module), ' f _nom ' is the frequency generated in proportion to the power in the reference watt-hour meter, and ' m ' is the constant of the reference watt-hour meter (eg, single-phase - 1) , 3 phase - 3), ' U _r ' is the voltage supplied to the reference watt-hour meter, ' I _r ' is the current supplied to the reference watt-hour meter, and ' C _m ' is the meter constant of the electric vehicle charger (or module) ( pulse/kWh),
[Equation 2]

At this time, 'δ W _dut ' is the charging wattage error rate (%), ' N _act ' is the pulse quantity generated from the reference watt-hour meter, and ' N _nom ' is the expected pulse quantity generated from the reference system of the electric vehicle charging device for the same time. Lim

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