KR102538406B1 - Electric vehicle charging system for vehicle to vehicle charging - Google Patents

Abstract

The present invention relates to a charging system for an electric vehicle.
The charging system of the present invention includes a battery for both charging and discharging, a step-up unit for boosting the output voltage of the battery to a predetermined voltage, and a charging terminal for receiving or supplying power from the outside of the charging system. And, a switch that directly connects the battery and the charging terminal or connects the booster and the charging terminal according to the charging or discharging mode of the charging system, and a control unit for controlling the switch according to the charging or discharging mode of the charging system include,
The control unit controls a switch to directly connect the charging terminal and the battery when the charging system is in the charging mode so that the battery is charged with power supplied from the outside, and when the charging system is in the discharging mode, the output of the battery is The power of the battery is supplied to the outside by controlling a switch to be connected to the charging terminal via the boosting unit.

Description

Charging system for electric vehicles capable of charging between vehicles {ELECTRIC VEHICLE CHARGING SYSTEM FOR VEHICLE TO VEHICLE CHARGING}

The present invention relates to battery charging technology for electric vehicles, and in particular, to research and improvement related to the IEC 61851-23 (DC electric vehicle charging station) standard.

As the electric vehicle is in the limelight as an eco-friendly means of transportation, research related to it has been actively conducted recently.

Electric vehicles have a disadvantage in that they have a shorter mileage compared to internal combustion engine vehicles using fossil fuels due to limitations in battery capacity. Despite such a short mileage, the reality is that charging stations for electric vehicles are far less than gas stations for internal combustion engine vehicles, so electric vehicle drivers always have anxiety about battery discharge while driving.

In order to improve the problems caused by the short mileage of electric vehicles, research to increase the mileage including increasing the capacity of the battery continues, and the government continues to increase the number of charging stations for electric vehicles.

However, there is still no countermeasure for the situation in which the electric vehicle is discharged while driving. Even if fuel is exhausted while driving, an internal combustion engine vehicle can drive to a nearby gas station by using an insurance company's emergency refueling service or purchasing a small amount of fuel from a nearby gas station and injecting it directly into the vehicle. On the other hand, electric vehicles have no choice but to tow to a nearby charging station because there is no way to supply electricity for charging in such a simple way.

Hyundai Motor Company, one of the domestic electric vehicle manufacturers, provides emergency dispatch and charging services for electric vehicles to cope with such situations. However, this service is still only provided in Seoul and Jeju, so there are regional restrictions, and it requires a vehicle equipped with a separate system for charging, so there is a limit to coping with the discharge situation while driving. In addition, there is the inconvenience of waiting at the site until the dedicated vehicle for charging arrives.

The inventors of the present invention have been studying a method for charging an electric vehicle that has been discharged while driving. The present invention has been completed after much effort to complete a system that proceeds with charging in a discharged situation using not a specially manufactured vehicle for charging but a general electric vehicle around.

An object of the present invention is to implement a charging system that can be used universally in a discharge situation while driving an electric vehicle.

Such a charging system of the present invention proposes a charging system using a battery and a charging terminal of a conventional electric vehicle as they are so that power can be supplied to another vehicle using a general electric vehicle.

In addition, another object of the present invention is to reduce standby time in an emergency situation by supplying power to a discharged electric vehicle through the above charging system.

Meanwhile, other unspecified objects of the present invention will be additionally considered within the scope that can be easily inferred from the following detailed description and effects thereof.

The present invention is a charging system for an electric vehicle comprising:

a battery for storing power supplied from the outside or supplying the stored power to the outside;

a boosting unit for boosting the voltage output from the battery to a predetermined potential;

A charging terminal for connection to the outside when charging or discharging the battery;

a switch for selectively connecting the charging terminal and the battery or the step-up unit; and

The switch is controlled according to the charging mode or the discharging mode of the battery. When the battery is in the charging mode, the switch is controlled so that the charging terminal and the battery are connected, and when the battery is in the discharging mode, the charging terminal and the and a control unit controlling the switch so that the boost unit is connected.

In the charging system according to a preferred embodiment of the present invention, the charging terminal includes a recognition unit for determining the coupling direction of the charging cable, and the recognition unit transfers the determination result to the control unit so that the control unit determines the direction according to the determination result. The switch can be controlled.

In addition, the charging system according to another preferred embodiment of the present invention further includes a charging cable connected to the charging terminal, the charging cable includes a recognition device indicating the coupling direction of the cable on one side, the recognition unit It is characterized in that the coupling direction of the cable is determined according to the presence or absence of a recognition device.

According to the problem-solving means of the present invention as described above, since the present invention can supply power to other vehicles using a general electric vehicle rather than a dedicated charging system, the effect of charging a discharged electric vehicle using a nearby general electric vehicle there is

In addition, there is an advantage in that waiting time for charging can be reduced because there is no need to wait for a vehicle equipped with a dedicated charging system to arrive.

On the other hand, even if the effects are not explicitly mentioned here, it is added that the effects described in the following specification expected by the technical features of the present invention and their provisional effects are treated as described in the specification of the present invention.

1 shows a configuration example of an electric vehicle charging system according to the prior art.
Figure 2 is a view showing Figure 1 in more detail.
3 shows an example of the configuration of a charging system according to a preferred embodiment of the present invention.
4 shows an example of the configuration of a system when charging another electric vehicle according to an embodiment of the present invention.
5 shows an example of the configuration of a system when power is supplied from a charging station according to an embodiment of the present invention.
6 shows an example of the configuration of a system for automatically recognizing charge/discharge according to another embodiment of the present invention.
※ It is revealed that the accompanying drawings are illustrated as references for understanding the technical idea of the present invention, and thereby the scope of the present invention is not limited.

1 shows a configuration example of an electric vehicle charging system according to the prior art.

According to the prior art, the charging system 110 is required to charge the electric vehicle 120 .

The prior art charging system 110 includes a step-up converter 112, a control unit 114 and a charging terminal 116.

The charging system 110 converts AC or DC power 150 supplied from a power grid or household power into DC power 130 and, if necessary, boosts the output voltage to a predetermined output voltage and supplies it to the electric vehicle 120. The IEC 61851-23 (DC electric vehicle charging station) standard, one of the standards for these charging systems, stipulates the maximum input voltage and output DC voltage.

To this end, the charging system 110 converts the input power 150 into DC in the case of AC power through the step-up converter 112 and converts the power 130 into electricity by converting it into a voltage determined for charging the electric vehicle 120. It is transmitted to the car 120. A high voltage such as 400V or 500V is used as the voltage for charging.

For charging, the charging system 110 and the electric vehicle 120 exchange control signals 140 with each other. For this purpose, controller area network (CAN), multimedia oriented systems transport (MOST), local interconnect network (LIN), etc. A variety of vehicle communication schemes may be used.

The electric vehicle 120 receives power from the charging system 110 and stores it in the battery 122 to use for vehicle operation.

2 shows a structure in which power and control signals are transmitted and received between a charging system and an electric vehicle in more detail.

Figure 3 shows a configuration example of the electric vehicle charging system 300 of the present invention according to any preferred embodiment of the present invention.

An electric vehicle charging system (300) according to the present invention for vehicle-to-vehicle charging includes a controller 310, a battery 320, a booster 330, a switch 340, a charging terminal 350, and a diode 360 consists of

The battery 320 is used to store power supplied from a power source outside the electric vehicle or to supply the stored power to the outside.

As described above, a high voltage of 400V to 500V is required to charge other electric vehicles. In addition, when the battery voltage of the fully charged electric vehicle is lower than the battery voltage of the discharged electric vehicle, the charging operation may not be performed normally. Accordingly, the step-up unit 330 is used to increase the output voltage of the battery 320 to a required voltage.

For vehicle-to-vehicle charging, the battery 320 of the charging system 300 must have bidirectionality capable of both charging and discharging, and for versatility, the charging terminal 350 is used both during charging and discharging. A switch 340 is required for this.

The switch 340 selectively connects the charging terminal 350 and the battery 320 under the control of the controller 310 . That is, when the charging system 300 is in the charging mode, the switch 340 is controlled so that the charging terminal 350 and the battery 320 are directly connected, and external power is supplied to the battery 320 through the charging terminal 350. and charging proceeds. On the other hand, when the charging system 310 is in the discharging mode, the switch 340 is controlled so that the charging terminal 350 and the boosting unit 330 are connected, and the power of the battery 320 is boosted to a required voltage and supplied to the outside.

The charging terminal 350 is used for connection of a charging cable (not shown) and is a power terminal for charging or discharging the battery 320 and for communication between the control unit 310 and a charging system such as another electric vehicle or charging station. Includes communication terminals.

The controller 310 determines a charging mode according to a user's manipulation or through communication with another charging system, and controls the switch 340 according to the charging mode.

The diode 360 blocks reverse current due to a connection error of the switch 340 of the charging system 300 . This is to prevent malfunction when a user selects a charging mode incorrectly or when a charging mode is selected differently from the connection of the charging system 300 due to a communication error or the like. That is, when the switch 340 is connected to the boosting unit in the charging mode or the switch 340 is connected to the battery in the discharging mode, charging may not be performed or the charging system 300 may be prevented from being damaged by blocking the reverse current.

4 shows the configuration of a system in the case of supplying power to another electric vehicle according to a preferred embodiment of the present invention.

When power is supplied to another electric vehicle 400, the controller 310 determines a charging mode through communication with the electric vehicle 400 receiving power. In this case, the control unit 310 may transmit a control signal transmitted from a general electric vehicle charging station to another electric vehicle 400 using a vehicle communication protocol such as CAN communication.

When the charging mode is determined as a mode for supplying power to other electric vehicles 400, the controller 310 controls the switch 340 to connect the booster 330 and the charging terminal 350. When the switch is connected, power from the battery 320 passing through the booster 330 is supplied to the electric vehicle 400 that needs to be charged through the charging terminal 350 and the cable.

Through this, the discharged electric vehicle 400 can be simply charged without moving to a charging station or waiting for another vehicle equipped with special equipment, and can move to a charger using the charged power.

5 shows the configuration of a system when power is supplied from a charging station 500 or the like according to a preferred embodiment of the present invention.

The controller 310 determines the charging mode through communication with the charging station 500, and controls the switch 340 to directly connect the charging terminal 350 and the battery 320 when the mode is set to receive power.

In the mode of receiving power, the battery 320 is charged with power by operating in the same way as a charging method of a general electric vehicle.

6 shows a configuration example of a charging system according to another embodiment of the present invention.

Since the charging system 300 according to the present invention is capable of bi-directional charging, it is inconvenient for a user to designate a charging or discharging mode. In the case of using a general electric vehicle charging station, the charging mode can be determined through communication with the charging station, but in the case of vehicle-to-vehicle charging, it is impossible to determine which vehicle is in the charging mode and which vehicle is in the discharging mode. If the charging mode is set incorrectly, charging may not be performed or, in the worst case, the charging system may be damaged.

Accordingly, the charging system 600 according to another embodiment of the present invention may further include a dedicated charging cable 660.

The charging cable 660 is divided into a discharge-side terminal 662 and a charge-side terminal 666, and the discharge-side terminal 662 includes a recognition device 664 for determining a charging mode. For user recognition, a charging side and a discharging side may be separately displayed on the charging cable 660 .

When the charging cable is connected according to the charging direction, the recognition unit 652 included in the charging terminal 650 of the charging system 600 checks whether the recognition device 662 of the charging cable 660 is connected.

The recognition unit 652 transmits whether the recognition device 662 is connected to the controller 610, and the controller 610 controls the switch 640 according to whether the recognition device 662 is connected. In another embodiment, the recognizer 652 may directly control the switch 640 according to whether the recognizer 662 is connected. In addition, depending on whether the recognition device 662 is connected, the controller 610 may inform the user of the charging mode of the vehicle using the vehicle's display device, the user's smart phone, or a separate display device.

When a vehicle on the charging side connected to the charging side terminal 666 without the recognition device 662 is confirmed by the recognition unit that there is no recognition device, the internal switch of the charging system is controlled into the charging mode to receive power from the other vehicle.

In this way, by automatically setting the charging or discharging mode according to the connection direction of the cable, it is possible to prevent malfunction or damage caused by a user's operation mistake.

For reference, the method for controlling a charging system according to an embodiment of the present invention may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the medium may be those specially designed and configured for the present invention or those known and usable to those skilled in computer software.

Examples of computer readable media include magnetic media such as hard disks, floppy disks and magnetic tapes, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floptical disks, and ROMs, RAMs, A hardware device specially configured to store and execute program instructions, such as flash memory, may be included. Examples of program instructions include not only machine code generated by a compiler but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to act as one or more software modules to perform the operations of the present invention, and vice versa.

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the scope of protection of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention belongs.

Claims (3)

A charging system for an in-vehicle electric vehicle capable of charging between vehicles, and an electric vehicle using this charging system has the following components having bidirectionality capable of both charging and discharging:
a battery for storing power supplied from the outside or supplying the stored power to the outside;
a boosting unit for boosting the voltage output from the battery to a predetermined potential;
A charging terminal for connection to the outside when charging or discharging the battery;
a switch for selectively connecting the charging terminal and the battery or the step-up unit;
Diodes to block reverse current in case of incorrectly connected charging mode and discharging mode; and
A control unit controlling the switch according to a charging mode or a discharging mode of a charging system, wherein the control unit controls the switch so that the charging terminal and the battery are connected when the charging system is in a charging mode, and the charging system A charging system for an electric vehicle capable of charging between vehicles, characterized in that in a discharge mode, the switch is controlled so that the charging terminal and the step-up unit are connected to supply power to another electric vehicle that needs to be charged.
According to claim 1,
Wherein the charging terminal includes a recognition unit that determines the coupling direction of the charging cable, and transmits a determination result of the recognition unit to the control unit so that the control unit controls the switch according to the determination result.
According to claim 2,
Further comprising a charging cable connected to the charging terminal,
The charging cable includes a recognition device indicating the coupling direction of the cable on one side,
Wherein the recognition unit determines the coupling direction of the cable according to the presence or absence of the recognition device.

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