KR20220043852A - Device for automatic switching battery of electric mobility and system comprising the same - Google Patents

Abstract

The present invention relates to a device for automatically switching between the batteries of e-mobility and a system comprising the same. A problem to be solved is to control a dual battery so that the same can be charged or discharged without a separate operation, prevent damage due to a reverse voltage when the dual battery is charged or discharged using a MOSFET, and minimize a reduction in battery life due to over-discharge through simultaneous discharge of the dual battery at a charge level or lower. For example, the device comprises: a connecting line including a first line for connecting respective positive terminals of a first battery, a second battery, and a motor controller; a second line for connecting a negative terminal of the first battery and a negative terminal of the motor controller, and a third line for connecting a negative terminal of the second battery and the negative terminal of the motor controller; a first switch unit connected to the second line and for connecting the negative terminal of the first battery and the negative terminal of the motor controller; and a second switch unit connected to the third line and for connecting the negative terminal of the second battery and the negative terminal of the motor controller. The first switch unit and the second switch unit are complementarily turned on and off according to a control signal to connect one of the first battery and the second battery to the motor controller, and are simultaneously turned on according to a control signal to connect the first battery and the second battery to the motor controller in parallel.

Description

Device for automatic battery switching of e-mobility and system including same

An embodiment of the present invention relates to an automatic battery switching device for e-mobility and a system including the same.

In general, an e-mobility device is a popular means of transportation consisting of parts such as a motor, a controller, a battery, a drive system, a throttle, a light device, and an instrument panel.

Currently, in the case of a general electric scooter distributed in the market, a single battery or a dual battery is applied.

However, in the case of an e-mobility device to which a dual battery is applied, it is inconvenient to change the battery using a separate operation switch. is inconvenient to operate, and when charging dual batteries, it is inconvenient to charge through a separate operation after charging one battery is completed.

Laid-open Patent Publication No. 10-2002-0006788 (published date: January 26, 2002) Laid-open Patent Publication No. 10-2020-0001784 (published date: January 07, 2020)

In an embodiment of the present invention, it is possible to control the dual battery to be charged and discharged without a separate operation, and the MOSFET is applied to prevent damage due to reverse voltage during charging and discharging, and simultaneous operation of the dual battery under a certain state of charge. Provided are a battery automatic switching device for e-mobility that can minimize a decrease in battery life due to overdischarge through discharging, and a system including the same.

The device for automatically switching the battery of e-mobility according to an embodiment of the present invention includes a first line for connecting between each positive terminal of a first battery, a second battery, and a motor controller, a negative terminal of the first battery, and a motor controller a connection line including a second line for connecting the negative terminal of the , and a third line for connecting the negative terminal of the second battery and the negative terminal of the motor controller; a first switch unit connected to the second line and connecting the negative terminal of the first battery and the negative terminal of the motor controller; and a second switch unit connected to the third line and connecting between the negative terminal of the second battery and the negative terminal of the motor controller, wherein the first switch unit and the second switch unit complement each other according to a control signal is turned on and off to connect one of the first battery and the second battery to the motor controller, and is turned on at the same time according to a control signal to connect the first battery and the second battery to the motor controller in parallel, and the first switch unit , a first MOSFET of the NPN type and a second MOSFET of the PNP type connected in series between the negative terminal of the first battery and the negative terminal of the motor controller, wherein the second switch unit includes the negative terminal of the second battery and the motor controller and a third MOSFET of the PNP type and a fourth MOSFET of the NPN type connected in series between the negative terminals, wherein a high level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low level to the second MOSFET A level control signal is applied to turn on the second MOSFET, the negative terminal of the first battery and the negative terminal of the motor controller are connected, and a high level control signal is applied to the third MOSFET to turn on the third MOSFET is turned off, and a low-level control signal is applied to the fourth MOSFET to turn off the fourth MOSFET, the connection between the negative terminal of the second battery and the negative terminal of the motor controller is cut off, so that only the first battery is supplied to the motor controller When power is supplied, a low-level control signal is applied to the first MOSFET to turn off the first MOSFET, and a high-level control signal is applied to the second MOSFET to turn off the second MOSFET. 1 The connection between the negative terminal of the battery and the negative terminal of the motor controller is cut off, a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and a high-level control signal is applied to the fourth MOSFET As the fourth MOSFET is turned on, the negative terminal of the second battery and the motor controller is connected, only the second battery supplies power to the motor controller, a high-level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low-level control signal to the second MOSFET is applied and as the second MOSFET is turned on, the negative terminal of the first battery and the negative terminal of the motor controller are connected, and a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and the third MOSFET is turned on. As the high-level control signal is applied to the 4 MOSFET and the fourth MOSFET is turned on, the negative terminal of the second battery and the negative terminal of the motor controller are connected, and the first battery and the second battery are connected in parallel to the motor controller for power to supply

According to another embodiment of the present invention, an automatic battery switching device for e-mobility according to an embodiment of the present invention includes a first line, a first line for connecting between each positive terminal of a first battery, a second battery, and a motor controller 1 a connection line including a second line for connecting the negative terminal of the battery and the negative terminal of the motor controller, and a third line for connecting the negative terminal of the second battery and the negative terminal of the motor controller; a first switch unit connected to the second line and connecting the negative terminal of the first battery and the negative terminal of the motor controller; a second switch unit connected to the third line and connecting between the negative terminal of the second battery and the negative terminal of the motor controller; and according to the charging states of the first battery and the second battery, the first switch unit and the second switch unit are complementarily turned on and off so that any one of the first battery and the second battery is connected to the motor controller, a switch control unit for outputting control signals to the first switch unit and the second switch unit, respectively, so as to simultaneously turn on the first switch unit and the second switch unit to connect the first battery and the second battery to the motor controller in parallel; The first switch unit includes a first MOSFET of the NPN type and a second MOSFET of the PNP type connected in series between the negative terminal of the first battery and the negative terminal of the motor controller, wherein the second switch unit includes a second and a third MOSFET of the PNP type and a fourth MOSFET of the NPN type connected in series between the negative terminal of the battery and the negative terminal of the motor controller, wherein the switch control unit applies a high-level control signal to the first MOSFET to Turn on the first MOSFET and apply a low-level control signal to the second MOSFET to turn on the second MOSFET so that the negative terminal of the first battery and the negative terminal of the motor controller are connected, and the third MOSFET to turn off the third MOSFET by applying a high-level control signal to the , and apply a low-level control signal to the fourth MOSFET to turn off the fourth MOSFET control to supply power to the motor controller only by the first battery by blocking the connection between the negative terminals of the to turn off the second MOSFET by applying a high-level control signal to to turn on the third MOSFET and turn on the fourth MOSFET By applying a level control signal to turn on the fourth MOSFET, the negative terminal of the second battery and the negative terminal of the motor controller are connected, so that only the second battery supplies power to the motor controller, and the first A high-level control signal is applied to the MOSFET to turn on the first MOSFET, and a low-level control signal is applied to the second MOSFET to turn on the second MOSFET, so that the negative terminal of the first battery and the motor controller As the cathode terminals are connected, a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and a high-level control signal is applied to the fourth MOSFET to turn on the fourth MOSFET By connecting the negative terminal of the second battery and the negative terminal of the motor controller, the first battery and the second battery are connected in parallel to the motor controller to supply power.

According to the present invention, it is possible to control the dual battery to be charged and discharged without a separate operation, and by applying a MOSFET, damage caused by reverse voltage during charging and discharging is prevented, and simultaneous discharging of the dual battery under a certain state of charge is prevented. Through this, it is possible to provide an automatic battery switching device for e-mobility that can minimize a decrease in battery life due to overdischarge and a system including the same.

1 is a diagram showing a circuit configuration of an automatic battery switching system of e-mobility according to an embodiment of the present invention.
2 is a diagram illustrating an operation for supplying power through a first battery connection of an automatic battery switching system of e-mobility according to an embodiment of the present invention.
3 is a diagram illustrating an operation for supplying power through a second battery connection of an automatic battery switching system of e-mobility according to an embodiment of the present invention.
4 is a diagram illustrating an operation for supplying power through connection of a first battery and a second battery of an automatic battery switching system of e-mobility according to an embodiment of the present invention.
5 is a photograph showing a test waveform of an automatic battery switching system of e-mobility according to an embodiment of the present invention.

Terms used in this specification will be briefly described, and the present invention will be described in detail.

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, which 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.

In the entire specification, when a part "includes" a certain element, this means that other elements may be further included, rather than excluding other elements, unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or software, or a combination of hardware and software. .

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

1 is a diagram showing a circuit configuration of an automatic battery switching system of e-mobility according to an embodiment of the present invention.

1, the automatic battery switching system 100 of e-mobility according to an embodiment of the present invention includes a connection line (L), a first switch unit (SW1), a second switch unit (SW2), and a switch control unit ( 10) may include at least one of.

The connection line (L) is a first line (L1) for connecting between the positive terminals of the first battery (A), the second battery (B) and the motor controller (C), the first battery (A) A second line (L2) for connecting the negative terminal (C-) and the negative terminal (C-) of the motor controller (C), and the negative terminal (B-) of the second battery (B) and the motor controller (C) may include a third line L3 for connecting the negative terminal C- of It may be connected to the negative terminal (C-).

The first switch unit SW1 is connected on the second line L2 and connects between the negative terminal A- of the first battery A and the negative terminal C- of the motor controller C can

The first switch unit SW1 is an NPN-type first MOSFET (MOSFET1) sequentially connected in series between the negative terminal A- of the first battery A and the negative terminal C- of the motor controller C ) and a PNP-type second MOSFET (MOSFET2), and respectively input a control signal from the switch controller 10 through the gate terminals of the first MOSFET (MOSFET1) and the PNP-type second MOSFET (MOSFET2) and the turn-on/turn-off operation may be controlled according to the control signal.

The second switch unit SW2 is connected on the third line L3 and connects between the negative terminal B- of the second battery B and the negative terminal C- of the motor controller C can

This second switch unit SW2 is a PNP type third MOSFET (MOSFET3) sequentially connected in series between the negative terminal (B-) of the second battery (B) and the negative terminal (C-) of the motor controller (C). ) and an NPN-type fourth MOSFET (MOSFET4), and respectively input a control signal from the switch control unit 10 through the gate terminals of the third MOSFET (MOSFET3) and the NPN-type fourth MOSFET (MOSFET4) and the turn-on/turn-off operation may be controlled according to the control signal.

The switch control unit 10 complementarily turns on/off the first switch unit SW1 and the second switch unit SW2 according to the state of charge of the first battery A and the second battery B to control Only one battery (A) is connected to the motor controller (C), or only the second battery (B) is connected to the motor controller (C), and the first switch unit (SW1) and the second switch unit (SW) are connected at the same time A control signal can be output to the first switch unit SW1 and the second switch unit SW2, respectively, to be turned on to connect both the first battery A and the second battery B to the motor controller C in parallel. there is.

The switch control unit 10 may be a BMS (Battery Management System) capable of monitoring the SOC (State Of Charge) of the first and second batteries A and B. It may be designed to output a control signal.

Hereinafter, an automatic battery switching operation through switching control according to a battery charge state of the automatic battery switching system for e-mobility according to an embodiment of the present invention will be described.

2 is a diagram illustrating an operation for supplying power through a first battery connection of an automatic battery switching system of e-mobility according to an embodiment of the present invention, and FIG. 3 is an e-mobility according to an embodiment of the present invention. It is a diagram illustrating an operation for supplying power through a second battery connection of the automatic battery switching system for mobility, and FIG. 4 is the first battery and the second battery of the automatic battery switching system for e-mobility according to an embodiment of the present invention. 2 It is a diagram illustrating an operation for supplying power through a battery connection.

As shown in FIG. 2 , the switch control unit 10 applies a high-level control signal to the first MOSFET (MOSFET1) to turn on the first MOSFET (MOSFET1), and applies a low-level control signal to the second MOSFET (MOSFET2). By applying the control signal to turn on the second MOSFET (MOSFET2), it is possible to control the connection between the negative terminal (A-) of the first battery (A) and the negative terminal (C-) of the motor controller (C).

Also, at this time, the switch control unit 10 turns off the third MOSFET (MOSFET3) by applying a high-level control signal to the third MOSFET (MOSFET3) as shown in FIG. By applying a low-level control signal to turn off the fourth MOSFET (MOSFET4), the connection between the negative terminal (B-) of the second battery (B) and the negative terminal (C-) of the motor controller (C) is cut off can be controlled as much as possible.

According to this switching operation, by controlling only the first battery (A) to supply power to the motor controller (C), the motor controller (C) can use only the first battery (A).

As shown in FIG. 3 , the switch control unit 10 applies a low-level control signal to the first MOSFET MOSFET1 to turn off the first MOSFET MOSFET1 and provides a high level control signal to the second MOSFET MOSFET2. By applying a control signal of can do.

Also, at this time, the switch control unit 10 turns on the third MOSFET (MOSFET3) by applying a low-level control signal to the third MOSFET (MOSFET3) as shown in FIG. By applying a level control signal to turn on the fourth MOSFET (MOSFET4), it is possible to control the connection between the negative terminal (B-) of the second battery (B) and the negative terminal (C-) of the motor controller (C). there is.

According to this switching operation, by disconnecting the first battery (A) and controlling only the second battery (B) to supply power to the motor controller (C), the motor controller (C) only the second battery (B) can be used The switch control unit 10 may switch to use the second battery B when the SOC becomes 10% or less during use of the first battery A, but this is only an example, and the set value of the SOC can be changed .

As shown in FIG. 4 , the switch control unit 10 applies a high-level control signal to the first MOSFET (MOSFET1) to turn on the first MOSFET (MOSFET1), and applies a low-level control signal to the second MOSFET (MOSFET2). By applying the control signal to turn on the second MOSFET (MOSFET2), it is possible to control the connection between the negative terminal (A-) of the first battery (A) and the negative terminal (C-) of the motor controller (C).

Also, at this time, the switch control unit 10 turns on the third MOSFET (MOSFET3) by applying a low-level control signal to the third MOSFET (MOSFET3) as shown in FIG. By applying a level control signal to turn on the fourth MOSFET (MOSFET4), it is possible to control the connection between the negative terminal (B-) of the second battery (B) and the negative terminal (C-) of the motor controller (C). there is.

According to this switching operation, by controlling the first battery (A) and the second battery (B) to be connected in parallel to the motor controller (C) to supply power, the motor controller (C) is connected to the first battery (A) and the second battery (A) Both batteries can be used, and conversion can be made based on SOC 100% when charging.

5 is a photograph showing a test waveform of the automatic battery switching system of e-mobility according to an embodiment of the present invention, and more specifically, a waveform (conversion) converted from the first battery (A) to the second battery (B). Time 500 μs), it can be automatically switched to another battery without power-off according to the SOC of the battery being used first among the dual batteries without a separate operation by the user.

What has been described above is only one embodiment for implementing the device for automatic battery switching of e-mobility according to the present invention and a system including the same, and the present invention is not limited to the above embodiment, and is claimed in the claims below. As described above, without departing from the gist of the present invention, it will be said that the technical spirit of the present invention exists to the extent that various modifications can be made by anyone with ordinary knowledge in the field to which the invention pertains.

100: e-mobility's battery automatic switching system
L: connecting line
L1: first line
L2: second line
L3: 3rd line
SW1: first switch unit
MOSFET1: first MOSFET (NPN)
MOSFET2: Second MOSFET (PNP)
SW2: second switch unit
MOSFET3: Third MOSFET (PNP)
MOSFET4: fourth MOSFET (NPN)
10: switch control
A: first battery
B: second battery
C: motor controller

Claims (2)

A first line for connecting the first battery, the second battery, and each positive terminal of the motor controller, a second line for connecting the negative terminal of the first battery and the negative terminal of the motor controller, and the negative terminal of the second battery and a connection line including a third line for connecting the negative terminal of the motor controller;
a first switch unit connected to the second line and connecting the negative terminal of the first battery and the negative terminal of the motor controller; and
and a second switch unit connected to the third line and connecting between the negative terminal of the second battery and the negative terminal of the motor controller,
The first switch unit and the second switch unit are complementarily turned on and off according to a control signal to connect any one of the first battery and the second battery to the motor controller, and are turned on at the same time according to the control signal to the first battery and Connecting the second battery in parallel to the motor controller,
The first switch unit includes an NPN-type first MOSFET and a PNP-type second MOSFET connected in series between the negative terminal of the first battery and the negative terminal of the motor controller,
The second switch unit includes a third MOSFET of the PNP type and a fourth MOSFET of the NPN type connected in series between the negative terminal of the second battery and the negative terminal of the motor controller,
A high level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low level control signal is applied to the second MOSFET to turn on the second MOSFET, thereby turning on the negative terminal of the first battery and the motor The cathode terminals of the controller are connected, a high level control signal is applied to the third MOSFET to turn off the third MOSFET, and a low level control signal is applied to the fourth MOSFET to turn off the fourth MOSFET Accordingly, the connection between the negative terminal of the second battery and the negative terminal of the motor controller is cut off, so that only the first battery supplies power to the motor controller,
A low-level control signal is applied to the first MOSFET to turn off the first MOSFET, and a high-level control signal is applied to the second MOSFET to turn off the second MOSFET, thereby turning off the negative terminal of the first battery. and the negative terminal of the motor controller is cut off, a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and a high-level control signal is applied to the fourth MOSFET to turn on the fourth MOSFET is turned on, the negative terminal of the second battery and the negative terminal of the motor controller are connected, so that only the second battery supplies power to the motor controller,
A high level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low level control signal is applied to the second MOSFET to turn on the second MOSFET, thereby turning on the negative terminal of the first battery and the motor As the cathode terminals of the controller are connected, a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and a high-level control signal is applied to the fourth MOSFET to turn on the fourth MOSFET An automatic battery switching device for e-mobility, characterized in that the negative terminal of the second battery and the negative terminal of the motor controller are connected, and the first battery and the second battery are connected in parallel to the motor controller to supply power.
A first line for connecting the first battery, the second battery, and each positive terminal of the motor controller, a second line for connecting the negative terminal of the first battery and the negative terminal of the motor controller, and the negative terminal of the second battery and a connection line including a third line for connecting the negative terminal of the motor controller;
a first switch unit connected to the second line and connecting the negative terminal of the first battery and the negative terminal of the motor controller;
a second switch unit connected to the third line and connecting between the negative terminal of the second battery and the negative terminal of the motor controller; and
According to the state of charge of the first battery and the second battery, the first switch unit and the second switch unit are complementarily turned on and off so that any one of the first battery and the second battery is connected to the motor controller, a switch control unit for outputting control signals to the first switch unit and the second switch unit, respectively, so as to simultaneously turn on the first switch unit and the second switch unit to connect the first battery and the second battery to the motor controller in parallel do,
The first switch unit includes an NPN-type first MOSFET and a PNP-type second MOSFET connected in series between the negative terminal of the first battery and the negative terminal of the motor controller,
The second switch unit includes a third MOSFET of the PNP type and a fourth MOSFET of the NPN type connected in series between the negative terminal of the second battery and the negative terminal of the motor controller,
The switch control unit,
A high level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low level control signal is applied to the second MOSFET to turn on the second MOSFET, so that the negative terminal of the first battery and Connect the negative terminals of the motor controller, apply a high-level control signal to the third MOSFET to turn off the third MOSFET, and apply a low-level control signal to the fourth MOSFET to turn off the fourth MOSFET By turning off, the connection between the negative terminal of the second battery and the negative terminal of the motor controller is cut off, so that only the first battery is controlled to supply power to the motor controller,
A low-level control signal is applied to the first MOSFET to turn off the first MOSFET, and a high-level control signal is applied to the second MOSFET to turn off the second MOSFET, thereby turning off the negative electrode of the first battery. The connection between the terminal and the negative terminal of the motor controller is cut off, a low-level control signal is applied to the third MOSFET to turn on the third MOSFET, and a high-level control signal is applied to the fourth MOSFET to apply a high-level control signal to the first MOSFET. 4 By turning on the MOSFET, the negative terminal of the second battery and the negative terminal of the motor controller are connected, so that only the second battery supplies power to the motor controller,
A high level control signal is applied to the first MOSFET to turn on the first MOSFET, and a low level control signal is applied to the second MOSFET to turn on the second MOSFET, so that the negative terminal of the first battery and Connect the negative terminals of the motor controller, apply a low-level control signal to the third MOSFET to turn on the third MOSFET, and apply a high-level control signal to the fourth MOSFET to turn on the fourth MOSFET Battery auto of e-mobility, characterized in that the first battery and the second battery are connected in parallel to the motor controller to supply power by connecting the negative terminal of the second battery to the negative terminal of the motor controller conversion system.

Images