KR102550198B1 - In-cable control box and charging method using the same - Google Patents

Abstract

The present invention relates to a portable slow charging device and method.
In addition, the present invention includes a sensing unit that measures the temperature of the charging plug when charging of the electric vehicle starts, a leakage current cutoff unit that detects leakage current and cuts off power, and a power cutoff unit that cuts off power according to a control command; Charging by having a control unit that determines whether an arc is generated using the measurement value of the sensing unit, and if an arc occurs, stops charging of the electric vehicle and cuts off the power using at least one of the leakage current blocking unit and the power blocking unit. When arcing occurs in the plug, safety accidents can be prevented in advance by stopping charging of the electric vehicle and cutting off power before the charging plug reaches a dangerous temperature.

Description

Portable slow charging device and method {In-cable control box and charging method using the same}

The present invention relates to a portable slow charging device and method.

In general, a portable slow charging device is used to charge an electric vehicle, and is connected to an outlet to which AC power is supplied to supply charging power to the electric vehicle.

Such a conventional portable slow charging device has a function of detecting overheating of the charging plug, and when an arc occurs in the charging plug and the temperature of the charging plug rises above a preset dangerous temperature, the power is automatically cut off. It prevents safety accidents that occur during charging of electric vehicles.

Meanwhile, a conventional portable slow charging device measures the temperature of a charging plug using a temperature sensor and cuts off power when the measured temperature exceeds a dangerous temperature. Since it is installed at a spaced position and the conductivity around the terminal is low, the transfer of heat to the temperature sensor is slow, and the measured temperature of the temperature sensor is lower than the actual temperature.

That is, since the conventional portable slow charging device cannot accurately measure the temperature of the charging plug, the charging plug reaching a dangerous temperature may melt or cause a fire.

In this case, not only the charging plug itself is damaged, but also the outlet to which the charging plug is connected may be damaged, and it may develop into a human accident that threatens the safety of the user.

In addition, a conventional portable slow charging device uses a method of turning off a relay to cut off power. In this case, there is a problem in that power cannot be cut off when a relay is fused.

That is, since the power is not cut off even after the arc is generated and the power for charging the electric vehicle continues to flow through the charging plug, safety accidents occurring during charging of the electric vehicle cannot be prevented.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a portable slow charging device and method capable of cutting off power before a charging plug reaches a dangerous temperature.

Another object of the present invention is to provide a portable slow charging device and method capable of more reliably cutting off power when an arc is generated.

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

The present invention for achieving the above object is a sensing unit for measuring the temperature of the charging plug when charging of the electric vehicle starts; Leakage current blocking unit for detecting leakage current and cutting off power; A power cut-off unit that cuts off power according to a control command; and calculating the amount of change in temperature of the charging plug from the measured value of the sensing unit, determining whether an arc has occurred based on the calculated amount of change in temperature, and if it is determined that an arc has occurred, after stopping the charging of the electric vehicle, the leakage current A portable slow charging device including a control unit that cuts off power using a cut-off unit and, if the power is not cut off within a predetermined time, cuts off the power again through the power cut-off unit.

In a preferred embodiment, the control unit compares the current temperature measured by the sensing unit with a previous temperature, and if the current temperature is higher, calculates the temperature change amount of the charging plug, and if the calculated temperature change amount exceeds a threshold value, It is determined that an arc has occurred in the charging plug.

In a preferred embodiment, a leakage current self-generating unit for generating leakage current inside the portable slow charging device by introducing power output from a relay to an electric vehicle into a ground line, and the control unit further includes the leakage current. By controlling the current self-generating unit to generate leakage current, the leakage current blocking unit performs an operation to cut off power.

In a preferred embodiment, the power cut-off unit, a control command output unit for outputting a control command according to the control request of the control unit; and a switch unit including a switch that is turned off by the control command and blocks power being supplied.

In addition, the present invention is a slow charging method performed by a controller of a portable slow charging device, comprising: a receiving step of starting charging of an electric vehicle by controlling a relay and receiving a measurement value obtained by measuring a temperature of a charging plug; a determination step of calculating a temperature change amount of the charging plug from the received measurement value and determining whether an arc is generated based on the calculated temperature change amount; And if it is determined that an arc has occurred, stopping the charging of the electric vehicle and generating a leakage current to cut off the power, and if the power is not cut off within a predetermined time, cutting off the power again through a control command; including A slow charging method is provided.

In a preferred embodiment, the determining step may include a comparison step of comparing a current temperature measured at the charging plug with a previous temperature based on the received measurement value; a calculation step of calculating a temperature change amount of the charging plug from the difference between the current temperature and the previous temperature, if the current temperature is higher; and an arc determination step of determining that an arc has occurred in the charging plug when the calculated temperature change amount exceeds a threshold value.

In a preferred embodiment, the step of shutting off the power further includes a leakage current self-generating step of generating a leakage current, detecting the generated leakage current, and performing an operation of cutting off the power.

In a preferred embodiment, the step of cutting off the power further includes a step of performing a control command in which a switch is turned off by the control command to cut off power being supplied.

According to the above-described means for solving the problems, the present invention provides a sensing unit for measuring the temperature of the charging plug when charging of the electric vehicle starts, a leakage current blocking unit for detecting leakage current to cut off power, and a control command to cut off power. The temperature change amount of the charging plug is calculated from the measured values of the power cut-off unit and the sensing unit, and based on the calculated temperature change amount, it is determined whether an arc has occurred, and if it is determined that an arc has occurred, after stopping the charging of the electric vehicle, By providing a control unit that cuts off power using the leakage current cut-off unit and, if the power is not cut off within a predetermined time, cuts off the power again through the power cut-off unit, when an arc occurs in the charging plug, charging of the electric vehicle is stopped and power is turned on. There is an effect of preventing the occurrence of safety accidents in advance by performing a blocking operation.

In addition, the present invention determines whether an arc is generated based on the temperature change of the charging plug, thereby preventing damage to the charging plug by cutting off power before the charging plug reaches a dangerous temperature and melts or causes a fire. It works.

In addition, the present invention cuts off power by sequentially operating the leakage current blocking unit and the power blocking unit, so that the power can be cut off more reliably than simply turning off the relay to cut off the power, and the relay is fused to cut off the power. A situation in which blocking cannot be achieved can be prevented in advance, and also, there is an effect of safely stopping the charging of the electric vehicle.

1 is a view for explaining a portable slow charging device according to an embodiment of the present invention.
2 is a view for explaining the detailed configuration of a portable slow charging device according to an embodiment of the present invention.
3 is a diagram for explaining a power cut-off unit of a portable slow charging device according to an embodiment of the present invention;
4 is a view for explaining a slow charging method according to an embodiment of the present invention;

In the following description, specific details of the invention are set forth to provide a thorough understanding of the invention, but it is common knowledge in the art that the invention may readily be practiced without and with variations thereof. It will be self-evident to those who have

Hereinafter, a preferred embodiment according to the present invention will be described in detail with reference to the accompanying FIGS. 1 to 4, focusing on parts necessary for understanding the operation and operation according to the present invention.

1 is a diagram for explaining a portable slow charging device according to an embodiment of the present invention, FIG. 2 is a diagram for explaining the detailed configuration of a portable slow charging device according to an embodiment of the present invention, and FIG. It is a drawing for explaining the power interruption unit of the portable slow charging device according to an embodiment of the present invention.

1 to 3, a portable slow charging device 100 according to an embodiment of the present invention includes a sensing unit 110, a leakage current blocking unit 120, a power blocking unit 130, and leakage current self-generating. It is configured to include a unit 140 and a control unit 150.

Here, the portable slow charging device 100 according to an embodiment of the present invention is used for charging an electric vehicle, and has a charging plug 10 at one end connected to a power cable and a charging connector 20 at the other end. is provided and connected with a power cable, and a relay is provided inside.

At this time, the above-described charging plug 10 is connected to an outlet to which AC power is supplied, and the above-described charging connector 20 can be connected to an electric vehicle, connecting the charging plug 10 and the portable slow charging device 100. The power cable is provided with a power line including L and N lines through which AC power flows and a ground line, and the power cable connecting the charging connector 20 and the portable slow charging device 100 is in addition to the L, N and ground lines, A signal line for transmitting and receiving a Control Pilot (CP) signal is further provided, and a PD (Proximity Detection) port may be further provided in the charging connector 20 .

The portable slow charging device 100 according to an embodiment of the present invention receives AC power through a charging plug 10 connected to an outlet, supplies the supplied AC power to an electric vehicle connected to the charging connector 20, and Electric vehicles can be charged.

The sensing unit 110 is provided in the charging plug 10 and measures the temperature of the charging plug 10 when charging of the electric vehicle starts.

The sensing unit 110 may be provided as a temperature sensor, and the measured value of the temperature measured by the charging plug 10 is output to the control unit 150 to be described later.

The leakage current blocking unit 120 detects leakage current and cuts off power supplied to the relay.

The leakage current blocking unit 120 is built into the portable slow charging device 100 and may be disposed between the charging plug 10 and the relay, and the power line including the L line and the N line through which AC power flows. It is detected whether leakage current flows in the ground line and the ground line, and when the leakage current is detected, power supplied to the relay from the charging plug 10 may be cut off.

In particular, the leakage current blocking unit 120 may detect leakage current intentionally generated by the leakage current self-generating unit 140 and cut off power.

The power cutoff unit 130 cuts off power according to a control command, and may be built into the portable slow charging device 100 and disposed between the charging plug 10 and the leakage current cutoff unit 120 .

The power cut-off unit 130 may include a switch unit 131, an external switch unit 132, a control command output unit 133, and a power supply unit 134.

The switch unit 131 includes a driving unit 131a that operates when a control command is received from the control command output unit 133, and a switch that turns off and turns on power supplied by the rotational operation of the driving unit 131a ( 131b), and the aforementioned switch 131b may be disposed on the L line or N line through which AC power flows. As described above, the driving unit 131a may be a motor.

The external switch unit 132 may turn on the turned-off switch 131b by rotating the shaft or rotor of the drive unit 131a according to an external manipulation.

That is, the user can release the power cut off state of the portable slow charging device 100 by manipulating the external switch unit 132 .

The control command output unit 133 outputs a control command to the driving unit 131a according to the control request of the control unit 150 . The control command output unit 133 may be provided with a dedicated processor including a micro controller unit (MCU).

The power supply unit 134 supplies power to the control command output unit 133 and may include an AC/DC converter 134a and a condenser 134b.

In the power supply unit 134, the AC/DC converter 134a connected to the L line and the N line between the switch unit 131 and the relay receives AC power supplied to the relay and converts it into DC power, and converts the DC power into DC power. Power may be supplied to the control command output unit 133 through the condenser 134b, and power may also be supplied to the aforementioned driving unit 131a in addition to the control command output unit 133.

In particular, the condenser 134b in the power supply unit 134 supplies charged power to the driving unit 131a when the switch 131b is turned off, so that the switch 131b is fully turned to a predetermined angle by the driving unit 131a. allow it to turn off

The leakage current self-generating unit 140 performs a function of generating leakage current under the control of the control unit 150.

The leakage current self-generating unit 140 can generate leakage current inside the portable slow charging device 100 by introducing power output from the relay to the electric vehicle into the ground line, and the input terminal is connected to the relay and the charging connector 20. ), and the output terminal may be formed in a structure connected to the ground line.

In addition, the leakage current self-generating unit 140 is connected to the L line and the N line between the relay and the charging connector 20 and is turned on or off according to the control of the control unit 150, the switch 141 and the switch 141 It may be configured to include a resistor 142 disposed between the ground line from.

The controller 150 controls the relay, determines whether an arc has occurred in the charging plug 10, and if it is determined that an arc has occurred, cuts off power using the leakage current blocker 120 and the power blocker 130. do.

For example, the control unit 150 controls the relay to start charging the electric vehicle, determines whether an arc is generated using the measurement value of the sensing unit 110, and stops charging the electric vehicle when it is determined that an arc has occurred. Power may be cut off by sequentially operating the leakage current blocking unit 120 and the power blocking unit 130 .

Specifically, the control unit 150 may transmit a control pilot signal to the electric vehicle to notify the start of charging, turn on a relay, and supply AC power applied from the charging plug 10 to the electric vehicle to charge the electric vehicle.

Then, after the charging of the electric vehicle starts, the current temperature measured by the sensing unit 110 and the previous temperature are compared, and if the measured current temperature is higher, the temperature change amount or temperature difference of the charging plug 10 is calculated and calculated. Check if the temperature change or temperature difference exceeds the threshold value. In this case, the controller 150 may determine that an arc has occurred in the charging plug 10 when the temperature change amount or the temperature difference exceeds a threshold value.

In addition, when an arc occurs in the charging plug 10, the control unit 150 transmits a control pilot signal to the electric vehicle to stop charging and turns off the relay to cut off power using the leakage current blocking unit 120. . At this time, the control unit 150 controls the leakage current self-generating unit 140 to generate leakage current, so that the leakage current blocking unit 120 performs an operation to cut off power.

In addition, the control unit 150 controls the leakage current self-generating unit 140 to generate leakage current, and if the power is not cut off within a predetermined time, it controls to cut off the power again through the power cutoff unit 130.

For reference, when power is normally cut off, power supplied to the control unit 150 is also cut off and the operation of the control unit 150 must also be stopped. That is, if the control unit 150 continues to operate until a predetermined time is reached by counting the elapsed time from the time of controlling the leakage current self-generating unit 140, it may be determined that the power is not normally cut off.

Then, the control unit 150 requests the control command output unit 133 of the power cut-off unit 130 to cut off power, and the control command output unit 133 responds to the control request of the control unit 150 by the power cut-off unit ( 130) outputs a control command for power off to the drive unit 131a, the drive unit 131a receives the control command and performs a rotational operation, and the switch of the power cutoff unit 130 is performed by the rotation operation of the drive unit 131a. When (131b) is turned off, the supplied power can be cut off.

The external switch unit 132 may turn on the turned-off switch 131b by rotating the shaft or rotor of the drive unit 131a according to an external manipulation.

That is, the user can release the power cut off state of the portable slow charging device 100 by manipulating the external switch unit 132 .

On the other hand, in the portable slow charging device 100 according to an embodiment of the present invention, a communication unit provided for communication with a user terminal or an external device, or a warning unit for notifying or warning the outside whether an arc is generated and charging is stopped In this case, the control unit 150 transmits a message indicating that charging of the electric vehicle has been stopped due to the occurrence of an arc to the user terminal through the communication unit, or sends a warning notifying that the charging is stopped due to the occurrence of an arc through the warning unit. can also be printed out.

4 is a diagram for explaining a slow charging method according to an embodiment of the present invention.

Referring to FIG. 4 , a slow charging method performed in a portable slow charging device according to an embodiment of the present invention will be described.

However, since all functions performed in the slow charging method shown in FIG. 4 are performed in the portable slow charging device described with reference to FIGS. 1 to 3 , all functions described with reference to FIGS. 1 to 3 are performed without explicit explanation. It should be noted that is performed in the slow charging method according to the preferred embodiment of the present invention, and all functions described with reference to FIG. 4 are performed as they are in the portable slow charging device according to the preferred embodiment of the present invention.

First, the controller 150 of the portable slow charging device 100 starts charging the electric vehicle by controlling the relay when the charging plug 10 is connected to the outlet and the electric vehicle is connected to the charging connector 20, and the charging plug A measurement value obtained by measuring the temperature of (10) is received from the sensing unit 110 (S100).

Next, the controller 150 determines whether an arc has occurred in the charging plug 10 by using the received measurement value (S200).

At this time, the controller 150 compares the current temperature measured by the charging plug 10 with the previous temperature based on the received measurement value (S210), and if the measured current temperature is higher (S220), the charging plug 10 A temperature change amount or temperature difference of is calculated (S230), and when the calculated temperature change amount or temperature difference exceeds a threshold value, it may be determined that an arc has occurred in the charging plug 10 (S240).

Meanwhile, if the current temperature measured at the charging plug 10 in the aforementioned step S220 is equal to or lower than the previous temperature, the aforementioned step S100 is performed again while continuing to charge the electric vehicle, and the temperature change amount or temperature difference in the aforementioned step S240 is determined. Even if it is below the threshold value, the above-described step S100 may be performed again while continuing to charge the electric vehicle.

Next, the control unit 150 stops charging of the electric vehicle and cuts off power using at least one of the leakage current blocking unit 120 and the power blocking unit 130 (S300).

At this time, if it is determined that an arc has occurred (S310), the control unit 150 may stop charging of the electric vehicle and cut off power using the leakage current blocking unit 120, for example, the leakage current self-generating unit 140 When the leakage current is generated inside the portable slow charging device 100 by controlling the power output to the electric vehicle from the relay to flow into the ground line (S320), the leakage current blocking unit 120 self-generating the leakage current unit 140 The leakage current generated from is sensed and the power is cut off (S330).

On the other hand, if the power is not cut off within a predetermined time after performing the above-described step S330, the controller 150 may cut off the power again through the power cutoff unit 130 (S340).

Specifically, in step S340, the control unit 150 requests the control command output unit 133 of the power cut-off unit 130 to cut off power, and the control command output unit 133 responds to the control request of the control unit 150. Outputs a control command to cut off power to the driving unit 131a of the switch unit 131, the driving unit 131a receives the control command and performs a rotational operation, and rotates the switch unit 131 by the rotational operation of the driving unit 131a. The switch 131b of may be turned off to cut off power supplied to the portable slow charging device 100 .

Meanwhile, the power-off state of the portable slow charging device 100 may be released by manipulating a button or an input device provided in the external switch unit 132 of the power cut-off unit 130 .

In the above, preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited only to these specific embodiments, and can be appropriately changed within the scope described in the claims.

100: portable slow charging device
110: sensing unit
120: leakage current blocking unit
130: power cutoff
140: leakage current self-generating unit
150: control unit

Claims (10)

a sensing unit that measures the temperature of the charging plug when charging of the electric vehicle starts;
Leakage current blocking unit for detecting leakage current and cutting off power;
A power cut-off unit that cuts off power according to a control command; and
The temperature change amount of the charging plug is calculated from the measured value of the sensing unit, and based on the calculated temperature change amount, it is determined whether an arc has occurred. If it is determined that an arc has occurred, after stopping the electric vehicle charging, the leakage current is blocked. A control unit that operates the unit to cut off power and, if the power is not cut off within a predetermined time, cuts off the power again through the power cut-off unit;
The control unit,
If the control unit continues to operate until a predetermined time by counting the elapsed time from the time when the leakage current is generated so that the leakage current cutoff operates, it is determined that the power is not normally cut off and the power cutoff is operated,
The power cutoff unit,
a control command output unit outputting a control command according to the control request of the control unit;
a switch unit having a drive unit that rotates when the control command is received and a switch that is turned off by the rotation operation of the drive unit to cut off power;
an external switch unit that rotates the drive unit according to an external manipulation to release the power-off state; and
and a power supply unit having a capacitor for supplying the charged power to the drive unit when the switch is turned off.
According to claim 1,
The control unit,
When power is cut off by the leakage current blocking unit, the power supplied to the control unit is also cut off and the operation is stopped, counts the elapsed time from the time of generating the leakage current, and the control unit stops the operation while counting the elapsed time. When the preset time is reached by continuing counting without stopping, the portable slow charging device determines that the power is not normally cut off by the leakage current blocking unit and operates the power blocking unit.
According to claim 1,
The control unit,
Comparing the current temperature measured by the sensing unit with the previous temperature, calculating the temperature change amount of the charging plug if the current temperature is higher, and determining that an arc has occurred in the charging plug when the calculated temperature change amount exceeds a threshold value. Characterized by a portable slow charging device.
According to claim 1,
Further comprising a leakage current self-generating unit for generating leakage current inside the portable slow charging device by introducing power output from the relay to the electric vehicle into the ground line,
The control unit controls the leakage current self-generating unit to generate leakage current, so that the leakage current blocking unit performs an operation to cut off power.
delete A slow charging method performed by a controller of a portable slow charging device,
A reception step of controlling a relay to start charging the electric vehicle and receiving a measurement value obtained by measuring a temperature of a charging plug;
a determination step of calculating a temperature change amount of the charging plug from the received measurement value and determining whether an arc is generated based on the calculated temperature change amount; and
If it is determined that an arc has occurred, the electric vehicle is stopped charging, leakage current is generated to cut off the power, and if the power is not cut off within a predetermined time, a power cutoff step is performed to cut off the power again by operating the power cutoff unit through a control command. including;
The power cutoff step,
If the control unit continues to operate until a predetermined time by counting the elapsed time from the time of generating the leakage current, it is determined that the power is not normally cut off and the power cut-off unit is operated;
The power cutoff step,
When a power cut-off is requested, a control command for power cut-off is output to the drive unit of the switch unit, the drive unit receives the control command and performs a rotational operation, and the switch unit is turned off by the rotation operation of the drive unit to turn off the power supply. It further includes; performing a control command to block the;
The power cut-off unit supplies power charged in the condenser to the drive unit when the switch is turned off, and rotates the drive unit according to an external operation after the power is cut off to release the power-off state.
According to claim 6,
The power cutoff step,
When power is cut off using leakage current, the power supplied to the control unit is also cut off and the operation is stopped. The elapsed time is counted from the time when the leakage current is generated, and the control unit does not stop the operation while counting the elapsed time. When the predetermined time is reached through continuous counting, it is determined that the power is not normally cut off due to the leakage current, and the power cut-off unit is operated.
According to claim 6,
The determination step is
a comparison step of comparing a current temperature measured in a charging plug with a previous temperature based on the received measurement value;
a calculation step of calculating a temperature change amount of the charging plug from the difference between the current temperature and the previous temperature, if the current temperature is higher; and
An arc determining step of determining that an arc has occurred in the charging plug when the calculated temperature change amount exceeds the threshold value; the slow charging method further comprising:
According to claim 6,
The power cutoff step,
The slow charging method further comprising a leakage current self-generation step of generating leakage current and performing an operation of cutting off power by sensing the generated leakage current.
delete

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