KR102258556B1 - Apparatus and method for dualized of battery - Google Patents

Abstract

According to the present invention, the voltage or current supplied to the load from the battery cells constituting the battery can be supplied in a dual manner inside the battery, so that even when a sudden failure occurs in the battery, power is individually supplied to the load from the normally operable battery cells. By supplying, it relates to a battery dualization device and method capable of preventing the power supply of a load from being cut off irregularly due to a sudden failure of the battery.

Description

Battery dualization device and method {APPARATUS AND METHOD FOR DUALIZED OF BATTERY}

The present invention relates to a battery dualization device and method, and by enabling the voltage or current supplied to a load from a battery cell constituting a battery to be dually supplied inside the battery, even when a sudden failure of the battery occurs, it can operate normally The present invention relates to a battery dualization apparatus and method capable of separately supplying power to a load from a battery cell, thereby preventing the load from being cut off irregularly due to a sudden failure of the battery.

In recent years, as an electric driving source in an electric vehicle (EV, Electric Vehicle), hybrid vehicle (HV, Hybrid Vehicle) or uninterruptible power supply (UPS), etc. A battery having characteristics is used.

Such batteries can dramatically reduce the use of primary energy such as petroleum and coal, and do not generate by-products from energy use, so they are spotlighted as an eco-friendly and efficient new energy source.

However, batteries generally used only function to supply power to the load and do not have other functions. Therefore, when power supply is limited due to a sudden failure, the load is supplied with power from the battery and operated. There was a problem that the power was cut off irregularly.

On the other hand, recently, in order to solve this problem, an apparatus or method for supplying power to a load from an auxiliary battery in the event of a sudden failure of the main battery by installing a plurality of batteries has been proposed. Such an apparatus or method includes a plurality of batteries Since the and load must be individually connected, not only the equipment becomes complicated, but also there is a problem that high cost is generated for installation and operation.

In addition, when a plurality of batteries are composed of batteries of different capacities, a separate facility for balancing each battery needs to be additionally installed, so installation and operation are cumbersome, and there is a problem that additional costs may be generated. .

In order to solve this problem, the inventors of the present invention, by making the voltage or current supplied to the load from the battery cells constituting the battery to be supplied in a binary manner inside the battery, even when a sudden failure occurs in the battery, in a normally operable battery cell By individually supplying power to the load, a battery dualization device and method have been developed that can prevent the load from being cut off irregularly due to a sudden battery failure.

Republic of Korea Patent Publication No. 10-2014-0013250

It is an object of the present invention to provide a dual voltage or current supplied to a load from a battery cell constituting a battery inside the battery, so that even in the event of a sudden failure in the battery, the battery cells that can operate normally are individually supplied to the load. An object of the present invention is to provide a battery dualization device and method capable of supplying power to prevent the power of a load from being cut off irregularly due to a sudden failure of the battery.

In addition, it is to provide a battery dualization device and method capable of supplying auxiliary power to the load without a separate additional battery or additional equipment according thereto by being configured to supply the voltage or current supplied from the battery to the load in a dual manner inside the battery.

A battery dualization device according to an embodiment of the present invention includes a battery unit comprising one or more battery cells and having a first output module and a second output module for supplying power to a load, and between the first output module and the load. A switch unit for conducting or blocking the flow of current between the second output module and the load, a sensing unit for detecting a power supply state of the first output module or the second output module, and a switch unit to control the first output A control unit for individually energizing or blocking the flow of current between the module and the load or between the second output module and the load, interrupting when the power supply state is detected as an abnormal state, and energizing when the normal state is detected. can

In an embodiment, when the amount of voltage or current supplied from the first output module or the second output module deviates from a predetermined range from the reference voltage or amount of current, the first output The power supply state of the module or the second output module may be detected as an abnormal state.

In an embodiment, the sensing unit detects the power supply state of the first output module or the second output module when voltage or current is not supplied from the first output module or the second output module for a preset time. It can be detected as an abnormal state.

In an embodiment, the sensing unit measures a change in temperature of the first output module or the second output module, and based on a pre-stored temperature, the temperature of the first output module or the second output module is a reference temperature When it deviates from a predetermined range, the power supply state of the first output module or the second output module may be detected as an abnormal state.

In an embodiment, the control unit may conduct a current flow between the blocked first output module and the load or between the second output module and the load after a preset time period.

In one embodiment, the switch unit is connected to the positive electrode of the battery unit, and a first contactor and a second contactor that conducts or blocks the flow of current between the battery unit and the load, and a current between the first output module and the load. A first auxiliary switch connected to the first output module to individually energize or cut off the flow of the second output module, and the second output module to individually energize or block the flow of current between the second output module and the load. It may include a second auxiliary switch to be connected.

In one embodiment, when the battery unit is detected as an abnormal state, and the second output module detects the abnormal state, the controller blocks the second contactor to control the flow of current between the second output module and the load. and a current may be passed from the first output module to the load using the first contactor and the first auxiliary switch.

In one embodiment, the control unit detects the battery unit as an abnormal state, and when the abnormal state is detected by the first output module, blocks the first contactor to control the flow of current between the first output module and the load. and a current may be passed from the second output module to the load using the second contactor and the second auxiliary switch.

A battery dualization method according to an embodiment of the present invention includes the steps of detecting a power supply state of a battery unit, and when the power supply state of the battery unit is detected as an abnormal state, a first output module or a second output constituting the battery unit Detecting each power supply state of the module and individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load, but when the power supply state is detected as abnormal It may include the step of shutting off, and energizing when a normal state is detected.

In one embodiment, the step of respectively detecting the power supply state of the first output module or the second output module is supplied from the first output module or the second output module based on a pre-stored voltage or current amount. The method may include detecting the power supply state of the first output module or the second output module as an abnormal state when the voltage or the amount of current is out of a predetermined range from the reference voltage or the amount of current.

In an embodiment, the step of detecting the power supply state of the first output module or the second output module, respectively, may include when voltage or current is not supplied from the first output module or the second output module for a preset time. , detecting the power supply state of the first output module or the second output module as an abnormal state.

In one embodiment, the step of detecting the power supply state of the first output module or the second output module, respectively, is to measure a change in temperature of the first output module or the second output module, and the measured temperature is stored in advance. The method may include detecting the power supply state of the first output module or the second output module as an abnormal state when the reference temperature is out of a predetermined range.

In one embodiment, the step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load is after a preset time, the blocked first output module or the second It may include the step of conducting the flow of current between the output module and the load.

In one embodiment, the step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load includes the current between one pole of the battery unit and the load or the other pole of the battery unit and the load. It may include the step of energizing or blocking the flow of.

In one embodiment, the step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load is detected as an abnormal state of the battery unit, but due to the second output module When an abnormal state is detected, blocking the flow of current between the second output module and the load, and individually energizing the flow of current between the first output module and the load.

In one embodiment, the step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load is detected as an abnormal state in the battery unit, but due to the first output module When an abnormal state is detected, blocking the flow of current between the first output module and the load, and individually energizing the flow of current between the second output module and the load.

According to one aspect of the present invention, voltage or current supplied to the load from the battery cells constituting the battery can be supplied in a dual manner inside the battery, so that even when a sudden failure occurs in the battery, the By supplying power to the load, it prevents the load from being cut off irregularly due to a sudden failure of the battery, so that the load can be used more stably.

In addition, since the voltage or current supplied from the battery to the load is dually supplied inside the battery, there is an advantage in that auxiliary power can be supplied to the load without a separate additional battery or additional equipment accordingly.

1 is a diagram schematically showing the configuration of a battery dualization device according to an embodiment of the present invention.
FIG. 2 is a diagram schematically illustrating a state in which the flow of current between the second output module and the load of the battery dualization device shown in FIG. 1 is blocked.
3 is a diagram schematically illustrating a state in which the flow of current between the first output module and the load of the battery dualization device shown in FIG. 1 is blocked.
4 is a flowchart illustrating a process of a method for dualizing batteries according to an embodiment of the present invention.

The present invention will be described in detail with reference to the accompanying drawings as follows. Here, repeated descriptions, well-known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of configurations are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

In addition, the term "...unit" described in the specification means a unit for processing one or more functions or operations, which may be implemented as hardware or software or a combination of hardware and software.

In addition, in the specification of the present invention, 'load 10' refers to a device that generates electrical or mechanical energy by receiving and consuming voltage or current, and may mean a power source such as a 'motor' or 'generator'. Note that there is

1 is a diagram schematically showing the configuration of a battery dualization device 1 according to an embodiment of the present invention, and FIG. 2 is a second output module of the battery dualization device shown in FIG. 3 is a diagram schematically showing a state in which the flow of current between the first output module and the load of the battery dualization device shown in FIG. 1 is blocked.

Referring to FIG. 1 , the battery dualization device 1 according to an embodiment of the present invention may include a battery unit 100 , a switch unit 200 , a sensing unit 300 , and a control unit 400 .

First, the battery unit 100 is composed of one or more battery cells and may serve to supply power to the load 10 , and a first output module 110 and a second output that output voltage or current from the battery cells. It may include a module 120 .

On the other hand, the first output module 110 and the second output module 120 of the battery unit 100 are individually connected to the load 10, so that a failure occurs in the first output module 110 In this case, power can be supplied to the load 10 by using only the second output module 120 , and even when a failure occurs in the second output module 120 , only the first output module 110 is used. Thus, power can be supplied to the load 10 .

That is, the first output module 110 is characterized in that the circuit is individually connected to one pole so that even when the second output module 120 is in a closed circuit state, voltage or current can be normally supplied to the load 10 .

In addition, the second output module 120 is characterized in that the circuit is individually connected to one pole so that even when the first output module 110 is in a closed circuit state, voltage or current can be normally supplied to the load 10 .

As described above, the battery unit 100 can supply the voltage or current supplied to the load 10 in a binary manner through the first output module 110 and the second output module 120, so that the Even when a failure occurs in any one of one or more battery cells constituting the battery unit 100 , power is normally supplied to the load 10 .

Next, the switch unit 200 is connected to the battery unit 100 and serves to conduct or cut off the flow of current between the battery unit 100 and the load 10 , and the battery unit 100 . The first contactor 210 and the second contactor 220 for energizing or blocking the circuit connected to the anode of the A first auxiliary switch 230 and a second auxiliary switch 240 for energizing or blocking a circuit individually connected to the second output module 120 may be included.

Specifically, the switch unit 200 includes the first contactor 210, the second contactor 220, the first auxiliary switch 230, and the second auxiliary switch ( 240), to conduct or block the flow of voltage or current between the first output module 110 and the load 10 or between the second output module 120 and the load 10. can

Next, the sensing unit 300 serves to detect the power supply state (eg, the amount of voltage or current supplied to the load 10 ) of the battery unit 100 , and constitutes the battery unit 100 . The power supply state of the first output module 110 or the second output module 120 may be individually sensed.

Specifically, the sensing unit 300 individually detects the power supply state of the first output module 110 or the power supply state of the second output module 120, so that the control unit 400 to be described later 1 between the first output module 110 and the load 10 or between the first output module 110 and the load 10 using the switch 200 according to the respective power supply state of the first output module 110 or the second output module 120 or the second The flow of current between the output module 120 and the load 10 may be individually energized or blocked.

Meanwhile, the sensing unit 300 may receive a reference voltage or amount of current, and sense the amount of voltage or current supplied from the first output module 110 or the second output module 120 to the load 10 . .

At this time, when the sensed voltage or current amount deviates from the reference voltage or current amount within a predetermined range, the first output module in an abnormal state using the switch unit 200 in the control unit 400 to be described later by detecting this as an abnormal state ( 110) or blocks the flow of current between the second output module 120 and the load 10, and between the first output module 110 and the load 10 or the second output module 120 in a normal state The flow of current between the and the load 10 may be conducted.

In addition, when the voltage or current supplied from the first output module 110 or the second output module 120 to the load 10 is not supplied for a predetermined time, the detection unit 300 detects it as an abnormal state. By doing so, the control unit 400 to be described later uses the switch unit 200 to block the flow of current between the first output module 110 or the second output module 120 and the load 10 in an abnormal state, , it is possible to conduct a current flow between the first output module 110 and the load 10 in a normal state or between the second output module 120 and the load 10 .

Here, the reference voltage or amount of current may be a voltage or amount of current input from a user, and may be a voltage or amount of current for normal operation of the load 10 .

In addition, the predetermined range may be a range of a voltage or amount of current input from a user, and may be a range from a minimum voltage or a minimum amount of current for normal operation of the load 10 to a maximum voltage or a maximum amount of current.

In addition, the predetermined time may be a time input by a user, and may be a maximum time during which the load 10 can operate normally without supplying voltage or current to the battery unit 100 .

In addition, the sensing unit 300 may measure the temperature of the first output module 110 or the second output module 120 .

Specifically, when the temperature of the first output module 110 or the second output module 120 sensed by the sensing unit 300 is out of a predetermined temperature range, the controller detects it as an abnormal state, which will be described later. In 400, the flow of current between the first output module 110 or the second output module 120 and the load 10 in an abnormal state is blocked using the switch unit 200, and the normal state is A current may flow between the first output module 110 and the load 10 or between the second output module 120 and the load 10 .

Here, the range of the predetermined temperature may be a range from a minimum temperature input by a user to a maximum temperature, and may be a range from a minimum temperature to a maximum temperature at which the load 10 can be operated normally without cooling or overheating.

On the other hand, the sensing unit 300 detects the battery unit 100 at a predetermined period of time, and thus between the first output module 110 and the load 10 blocked by the control unit 400 to be described later or between the first output module 110 and the load 10 . 2 It is possible to re-energize the flow of current between the output module 120 and the load 10 .

Here, the preset time may be a time input by the user.

Next, the control unit 400 uses the switch unit 300 according to the power supply state of the first output module 110 or the second output module 120 detected by the sensing unit 300 . A voltage or current flowing between the first output module 110 and the load 10 or between the second output module 120 and the load 10 may be individually energized or cut off.

2 and 3 , more specifically, when an abnormal state of the second output module 120 is detected by the sensing unit 300, the control unit 400 controls the second contactor ( 220 ) may be turned off to block the voltage or current supplied from the second output module 120 to the load 10 .

Also, at this time, by turning on the first auxiliary switch 230 , the circuit connected to the first auxiliary switch 230 in the first output module 110 and the first contactor 210 . A voltage or current may be normally supplied to the load 10 through a circuit connected to .

In addition, when an abnormal state of the first output module 110 is detected by the sensing unit 300 , the control unit 400 turns off the first contactor 210 to turn off the first The voltage or current supplied from the output module 110 to the load 10 may be blocked.

Also, at this time, by turning on the second auxiliary switch 240 , the circuit connected to the second auxiliary switch 240 in the second output module 120 and the second contactor 220 . A voltage or current may be normally supplied to the load 10 through a circuit connected to .

Next, a process of the battery dualization method according to an embodiment of the present invention will be described with reference to FIG. 4 .

4 is a flowchart illustrating a process of a method for dualizing batteries according to an embodiment of the present invention.

Referring to FIG. 4 , first, the sensing unit 300 detects the power supply state of the battery unit 100 ( S201 ), and when the battery unit 100 is detected as a normal state, the load 10 is Power is supplied (S202).

On the other hand, when the battery unit 100 is detected in an abnormal state, the power supply state of the first output module 110 or the second output module 120 constituting the battery unit 100 is detected, respectively, (S203), the first output module 110 or the second output module 120 detected as an abnormal state is individually blocked (S204).

Then, after a preset time, the sensing unit 300 re-sens the power supply state of the first output module 110 or the second output module 120 (S205), and the control unit 400 is normal A voltage or current is supplied to the load 10 from the first output module 110 or the second output module 120 sensed as a state (S205).

Accordingly, it is possible to supply voltage or current to the load 10 by dividing the battery cells constituting the battery unit 100 .

Although specific embodiments of the present invention have been illustrated and described above, the technical idea of the present invention is not limited to the accompanying drawings and the above description, and various modifications are possible within the scope without departing from the spirit of the present invention. It is obvious to those of ordinary skill in the art, and such modifications will be considered to fall within the scope of the claims of the present invention without violating the spirit of the present invention.

1: Battery dualization device
10: load
100: battery unit
110: first output module
120: second output module
200: switch unit
210: first contactor
220: second contactor
230: first auxiliary switch
240: second auxiliary switch
300: sensing unit
400: control unit

Claims (16)

a battery unit comprising one or more battery cells and having a first output module and a second output module configured to supply power to a load;
a switch unit configured to conduct or cut off the flow of current between the first output module and the load or between the second output module and the load;
a sensing unit for detecting a power supply state of the first output module or the second output module; and
Control the switch unit to individually energize or cut off the flow of current between the first output module and the load or between the second output module and the load, and cut off when the power supply state is detected as abnormal, and return to a normal state. Including; a control unit that energizes when detected;
The first output module is connected to an individual circuit for supplying current or voltage to the load even when the second output module is in a closed circuit state,
The second output module is connected to an individual circuit for supplying current or voltage to the load even when the first output module is in a closed circuit state,
The normal state and the abnormal state of the power supply state are determined based on the amount of voltage or current supplied from the first output module or the second output module, and a temperature change of the first output module or the second output module, Battery dualization device. The method of claim 1,
The sensing unit,
When the amount of voltage or current supplied from the first output module or the second output module is out of a predetermined range from the reference voltage or amount of current based on the previously stored voltage or amount of current, the first output module or the second output module Detecting the power supply state as an abnormal state
Battery dualization device. The method of claim 1,
The sensing unit,
When voltage or current is not supplied from the first output module or the second output module for a preset time, the power supply state of the first output module or the second output module is detected as an abnormal state doing,
Battery dualization device. The method of claim 1,
The sensing unit,
Measuring the temperature change of the first output module or the second output module,
Based on the pre-stored temperature, when the temperature of the first output module or the second output module is out of a predetermined range from the reference temperature, the power supply state of the first output module or the second output module is set to an abnormal state. characterized by sensing,
Battery dualization device. The method of claim 1,
The control unit,
Characterized in that the flow of current between the blocked first output module and the load or between the second output module and the load is passed after a preset time period,
Battery dualization device. The method of claim 1,
The switch unit,
first and second contactors connected to the positive electrode of the battery unit and configured to conduct or block the flow of current between the battery unit and the load;
a first auxiliary switch connected to the first output module to individually conduct or cut off the flow of current between the first output module and the load; and
and a second auxiliary switch connected to the second output module so as to individually conduct or cut off the flow of current between the second output module and the load.
Battery dualization device. The method of claim 6,
The control unit,
When the battery unit detects an abnormal state and the second output module detects the abnormal state, the second contactor is cut to cut off the flow of current between the second output module and the load, and the first contactor and passing a current from the first output module to the load by using the first auxiliary switch,
Battery dualization device. The method of claim 6,
The control unit,
When the battery unit detects an abnormal state and is detected as an abnormal state by the first output module, the first contactor is cut off to cut off the flow of current between the first output module and the load, and the second contactor and passing a current from the second output module to the load by using the second auxiliary switch,
Battery dualization device. detecting a power supply state of the battery unit;
detecting a power supply state of a first output module or a second output module constituting the battery unit, respectively, when the power supply state of the battery unit is detected as an abnormal state; and
Separately energize or cut off the flow of current between the first output module and the load or between the second output module and the load, and cut off when the power supply state is detected as an abnormal state, and energize when the normal state is detected step; including,
The first output module is connected to an individual circuit for supplying current or voltage to the load even when the second output module is in a closed circuit state,
The second output module is connected to an individual circuit for supplying current or voltage to the load even when the first output module is in a closed circuit state,
The normal state and the abnormal state of the power supply state are determined based on the amount of voltage or current supplied from the first output module or the second output module, and a temperature change of the first output module or the second output module, Battery dualization method. The method of claim 9,
The step of detecting the power supply state of the first output module or the second output module, respectively,
When the amount of voltage or current supplied from the first output module or the second output module is out of a predetermined range from the reference voltage or amount of current based on the previously stored voltage or amount of current, the first output module or the second output module Detecting the power supply state as an abnormal state; characterized in that it comprises,
Battery dualization method. The method of claim 9,
The step of detecting the power supply state of the first output module or the second output module, respectively,
When voltage or current is not supplied from the first output module or the second output module for a preset time, detecting the power supply state of the first output module or the second output module as an abnormal state; characterized in that it comprises
Battery dualization method. The method of claim 9,
The step of detecting the power supply state of the first output module or the second output module, respectively,
The temperature change of the first output module or the second output module is measured, and when the measured temperature is out of a predetermined range from the pre-stored reference temperature, the power supply state of the first output module or the second output module is abnormal. Detecting the state; characterized in that it comprises,
Battery dualization method. The method of claim 9,
The step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load comprises:
After a preset time, passing the current flow between the blocked first output module or the second output module and a load; characterized in that it comprises,
Battery dualization method. The method of claim 9,
The step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load comprises:
energizing or blocking the flow of current between one pole and the load of the battery unit or between the other pole and the load of the battery unit; characterized in that it comprises a,
Battery dualization method. The method of claim 14,
The step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load comprises:
When the battery unit is detected as an abnormal state, and an abnormal state is detected by the second output module, the flow of current between the second output module and the load is cut off, and the flow of current between the first output module and the load is reduced. Individually energized; characterized in that it comprises,
Battery dualization method. The method of claim 14,
The step of individually energizing or blocking the flow of current between the first output module and the load or between the second output module and the load comprises:
When the battery part is detected as an abnormal state, and the abnormal state is detected by the first output module, the flow of current between the first output module and the load is blocked, and the flow of current between the second output module and the load is reduced Individually energized; characterized in that it comprises,
Battery dualization method.

Images