KR101282355B1 - Apparatus and method for controlling battery current - Google Patents

Abstract

A device connected to the battery to be controlled to control the charging current and the discharge current of the battery to be controlled, and compares the voltages associated with each of the battery and the control battery connected to the battery to control any one of the first output and the second output. And a charging current controller configured to control an amount of charging current flowing to the battery to be controlled by varying a resistance value based on an output of the comparing unit.

Description

Battery current control device and method {APPARATUS AND METHOD FOR CONTROLLING BATTERY CURRENT}

The present invention relates to an apparatus and method for controlling battery current.

An electric double layer capacitor (EDLC) is a battery using a phenomenon in which charge is stored in an electric double layer generated between an electrode and an electrolyte, and is called an ultracapacitor or a supercapacitor. Electric double layer capacitors are a popular energy store because of their high power and fast response. An electric double layer capacitor module is a battery pack in which a plurality of electric double layer capacitors are connected for an appropriate voltage. The electric double layer capacitor module is connected to the vehicle auxiliary battery to respond quickly to the momentary load of the vehicle.

When the electric double layer capacitor module is connected to the vehicle auxiliary battery, the terminal voltage of the auxiliary battery is applied to the electric double layer capacitor, and the electric double layer capacitor module repeatedly charges and discharges. At this time, if the specific electric double layer capacitor is overcharged due to the voltage deviation of the individual electric double layer capacitor, the performance of the entire module may be reduced and the life may be shortened. In addition, the electric double layer capacitor discharges in response to the load instantaneously, but the charging is also instantaneously can cause a secondary battery and the alternator. In addition, when the fully charged electric double layer capacitor module is connected to the fully charged vehicle auxiliary battery, a spark may occur due to a voltage difference between the auxiliary battery and the electric double layer capacitor module. In this case, a large amount of charging current flows into the fully discharged electric double layer capacitor module, which may affect the performance of the auxiliary battery and the electric double layer capacitor module.

Publication No. 2006-0086024 (published Jul. 31, 2006) Publication No. 2004-0097500 (published Nov. 18, 2004)

An object of the present invention is to provide a battery current control device and method for controlling the current flowing to the controlled battery based on the voltage difference between the external battery and the controlled battery.

An apparatus connected to a battery under control according to an embodiment of the present invention for controlling the charging current and the discharge current of the battery under control, by comparing voltages associated with each of the battery under control with an external battery connected to the battery under control And a comparator for outputting any one of a first output and a second output, and a charge current controller configured to control the amount of charge current flowing to the battery to be controlled by varying a resistance value based on the output of the comparator.

When the charging current controller receives the first output from the comparator, the charging current controller flows the charging current to the resistance of the first resistance value, and when the second output is received from the comparator, the charging current controller is used as the resistance of the second resistance value. The first resistance value may be greater than the second resistance value while the charging current flows.

When the charging current controller receives the first output from the comparator, when the charging current flows to the first resistance of the first resistance value, and when the second output is received from the comparator, the charge current controller is connected in parallel. Charge current may flow through the first resistor and the second resistor.

The charging current controller may further include a transistor configured to control the parallel connection between the first resistor and the second resistor by receiving and opening the first output and closing the second output.

The comparison unit may compare any difference between the divided voltage of the external battery and the divided voltage of the control target battery and output one of the first output and the second output.

The comparison unit transfers the first output to a charge current controller when the divided voltage of the external battery is greater than the divided voltage of the battery to be controlled, and charge current when the divided voltage of the external battery is less than the divided voltage of the battery to be controlled. The second output may be transmitted to the controller.

The comparator may adjust the divided resistance ratio of the external battery and the divided resistance ratio of the control target battery to output the first output until the control target battery voltage reaches a predetermined voltage.

The comparison unit may adjust the divided resistance ratio of the external battery and the divided resistance ratio of the controlled battery based on the voltage transfer rate of the controlled battery voltage with respect to the external battery voltage.

The apparatus may further include a discharge current output unit configured to output a discharge current from the battery to be controlled.

The discharge current output unit may include a diode that operates when the battery to be controlled has a higher voltage than the external battery.

The charging current controller may include a diode that operates when the battery to be controlled has a lower voltage than the external battery.

A method of controlling a current of a battery to be controlled by a battery current control apparatus according to another embodiment of the present invention, the method comprising: receiving an external battery voltage connected to the battery to be controlled, receiving a voltage of the battery to be controlled, and partial voltage Comparing the divided voltage of the external battery output by the resistor with the divided voltage of the battery to be controlled, and controlling the amount of charging current flowing to the battery to be controlled by varying the resistance value based on the comparison result. .

In the controlling of the charging current amount, when the divided voltage of the external battery is greater than the divided voltage of the controlled battery, the charging current flows to the first resistor, and if the divided voltage of the external battery is smaller than the divided voltage of the controlled battery, The charging current flows to the first and second resistors connected in parallel, and the first resistor may be a resistor having a larger resistance value than the second resistor.

The comparing of the divided voltages may output one of a high output and a low output by comparing a difference between the divided voltage of the external battery and the divided voltage of the control target battery.

Comparing the divided voltage may include: the divided resistance ratio of the external battery and the divided voltage of the controlled battery so that the divided voltage of the controlled battery becomes higher than the divided voltage of the external battery when the controlled battery voltage exceeds a predetermined voltage. The resistance ratio can be set.

Comparing the divided voltage may calculate the constant voltage based on the voltage transfer rate of the control target battery voltage with respect to the external battery voltage.

According to an embodiment of the present invention, when the control target battery is discharged, it may be discharged in a quick response, and when the control target battery is charged, the charging current is controlled based on a voltage difference between the external battery and the control target battery. Protect your battery.

1 is a view showing a charge and discharge system according to an embodiment of the present invention.
2 is a block diagram of a battery current control apparatus according to an embodiment of the present invention.
3 is a circuit diagram of a battery current control device according to an embodiment of the present invention.
4 is a view showing the operation of the battery current control device during discharge according to an embodiment of the present invention.
5 is a view showing the operation of the battery current control device during charging according to an embodiment of the present invention.
6 is a view showing the operation of the battery current control device during charging according to another embodiment of the present invention.
7 is a flowchart of a battery current control method according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

Now, a battery current control apparatus and method according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a view showing a charge and discharge system according to an embodiment of the present invention.

Referring to FIG. 1, the charge / discharge system includes a control target battery 100 and a battery current control device 200. The control target battery 100 is connected to the external battery 300 to repeat the charging and discharging.

The control target battery 100 is connected to the battery current control device 200 to adjust the current flowing during charging and discharging. The control target battery 100 may be a battery having fast response characteristics. For example, the control target battery 100 may be an Electric Double Layer Capacitor (EDLC) module. The electric double layer capacitor module is a battery pack in which a plurality of electric double layer capacitors are connected for an appropriate voltage. An electric double layer capacitor is a battery using a phenomenon in which charge is stored in an electric double layer generated between an electrode and an electrolyte, and is called an ultracapacitor or a supercapacitor. The control target battery 100 may include a cell balancing circuit for reducing the deviation of each electric double layer capacitor.

The battery current control device 200 controls the charging and discharging currents of the control target battery 100. The battery 100 to be controlled discharges and charges in response to instantaneous characteristics. In particular, when the voltage difference between the control target battery 100 and the external battery 300 is large, a large amount of charging current may suddenly flow into the control target battery 100. Therefore, the battery current control device 200 adjusts the amount of charging current flowing to the control target battery 100 by varying the resistance based on the voltages of the control target battery 100 and the external battery 300. That is, since the voltage difference between the control target battery 100 and the external battery 300 is large at the initial stage of charging of the control target battery 100, the battery current control device 200 reduces the amount of charging current by using a large resistance value. Therefore, the battery current control device 200 can reduce the amount of heat generated at the beginning of charging. In addition, when the voltage of the battery 100 to be controlled reaches a predetermined level of the external battery 300, the battery current control apparatus 200 may be charged using a resistance value smaller than that at initial charging because the voltage difference is small.

The external battery 300 is connected to the control target battery 100 to charge and discharge. Here, the external battery 300 may be a vehicle auxiliary battery.

2 is a block diagram of a battery current control apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the battery current control device 200 includes a discharge current output unit 210, a comparator 230, and a charge current controller 250. The battery current control device 200 is connected to the terminal electrode of the battery 100 to be controlled.

The discharge current output unit 210 outputs a discharge current from the control target battery 100 when the control target battery 100 is discharged. The discharge current output unit 210 may be configured as a diode that operates when the voltage of the battery 100 to be controlled is higher than the voltage of the load connected to the battery 100 to be controlled, for example, the external battery 300. .

The comparator 230 outputs any one of a high and a low by comparing the voltages associated with each of the external battery 300 and the control target battery 100. Here, the output of the comparator 230 has an open drain structure. The high and low outputs are transmitted to the charge current controller 250 to operate a transistor acting as a switch. In this case, the high and low outputs may be changed depending on which voltage is connected to the positive input terminal and the negative input terminal of the comparator 230. Here, the voltage related to the external battery 300 is input to the positive input terminal. The following description will be assumed.

The comparator 230 may receive the divided voltage obtained by dividing the voltage of each of the external battery 300 and the control target battery 100 with predetermined resistors, and compare the divided voltages. The comparator 230 outputs a high voltage when the divided voltage of the external battery 300 is greater than the divided voltage of the controlled battery 100, and the divided voltage of the external battery 300 is greater than the divided voltage of the controlled battery 100. If it is small, it outputs low. The comparison unit 230 receives the partial voltage of the control target battery 100 higher than the partial voltage of the external battery 300 when the control target battery 100 reaches a predetermined level of the voltage of the external battery 300. At a certain point, a low value can be output.

The charging current controller 250 controls the amount of charging current flowing to the control target battery 100 by varying a resistance value based on the output of the comparator 230. The charging current controller 250 may flow a current using resistances of different resistance values for the high output and the low output of the comparator 230. That is, when the divided voltage of the external battery 300 is higher than the divided voltage of the control target battery 100, the charging current controller 250 flows the charging current to the resistor R1. When the divided voltage of the external battery 300 is lower than the divided voltage of the battery 100 to be controlled, the charging current controller 250 flows the charging current into a resistor having a smaller resistance value than the resistor R1. In this case, the charging current controller 250 may connect a resistor R2 having a smaller value to the resistor R1 in parallel to make a resistance value smaller than that of the resistor R1. To this end, when the divided voltage of the external battery 300 is lower than the divided voltage of the battery 100 to be controlled, the charging current controller 250 operates a transistor that connects the resistor R2 to the resistor R1 in parallel. .

Next, the battery current control apparatus 200 will be described in detail.

3 is a circuit diagram of a battery current control device according to an embodiment of the present invention.

Referring to FIG. 3, the battery current control apparatus 200 includes a discharge current output unit 210, a comparator 230, and a charge current controller 250.

The discharge current output unit 210 operates when the control target battery 100 is discharged. The discharge current output unit 210 includes a diode 211 that operates when the voltage to be higher than that of the load, for example, the external battery 300, to which the control target battery 100 is connected.

The comparator 230 generates a control signal related to the operation of the charging current controller 250 by comparing the voltages associated with each of the external battery 300 and the control target battery 100. Here, the control signal is a signal capable of turning on or off the transistor of the charging current controller 250 and may be a high and low output.

The comparator 230 receives the comparator 231, the terminal voltage of the external battery 300, and the external battery voltage divider 233 for creating the divided voltage V1 using the divided resistors R3 and R4. The control target battery voltage dividing unit 235 is configured to receive the terminal voltage of the terminal 100 and generate the divided voltage V2 using the divided resistors R5 and R6.

The comparator 231 receives the divided voltage V1 of the external battery 300 and the divided voltage V2 of the control target battery 100. The comparator 231 outputs any one of a high and a low output according to the difference V1 -V2 of the input voltage. When the divided voltage V1 of the external battery 300 is greater than the divided voltage V2 of the battery 100 to be controlled, the comparator 231 outputs a high value and transmits the high value to the charging current controller 250. When the divided voltage V1 of the external battery 300 is smaller than the divided voltage V2 of the battery 100 to be controlled, the comparator 231 outputs a low value and transmits the low value to the charge current controller 250.

The comparison unit 230 divides the divided resistance ratios R3 / R4 and R5 of the external battery voltage divider 233 and the battery voltage divider 235 to be controlled so that the output is changed based on a predetermined voltage reached by the control target battery 100. / R6) can be varied. In the initial charging of the control target battery 100, since the voltage difference between the voltage of the control target battery 100 and the external battery 300 is large, the charging current is controlled by a large resistor R1, and the control target battery 100 controls the constant voltage. To reach the charging current with a small resistance (R1 // R2). When the control target battery 100 reaches a predetermined level of the voltage of the external battery 300, the comparator 230 allows the charging current to flow through the small resistance R1 // R2 thereafter. To this end, the comparator 230 uses a voltage transfer rate of the voltage of the control target battery 100 with respect to the voltage of the external battery 300. For example, when the voltage of the battery 100 to be controlled corresponds to the voltage transfer rate of the voltage of the external battery 300, for example, 85%, the divided voltage V2 of the battery 100 to be controlled is the voltage of the external battery 300. The voltage dividing resistance ratio of the external battery voltage dividing unit 233 and the control target battery voltage dividing unit 235 is adjusted to be larger than the voltage dividing voltage V1.

The charging current controller 250 controls the amount of charging current flowing to the control target battery 100 by varying a resistance value based on the output of the comparator 230. The charge current controller 250 includes a diode 251, a main resistor 253, an auxiliary resistor 255, and a transistor 257 for controlling the parallel connection of the auxiliary resistor 255 to the main resistor 253.

The diode 251 is a diode that operates when the battery to be controlled 100 has a lower voltage than the external battery 300. The charging current flows from the external battery 300 to the battery 100 to be controlled through the diode 251.

The main resistor 253 is connected to the diode 251 so that a current flows during charging when the diode 251 operates. The main resistor 253 has a constant resistance value R1.

The auxiliary resistor 255 is connected to the transistor 257, and when the transistor 257 is turned on, the auxiliary resistor 255 is connected in parallel to the main resistor 253 so that current flows. When the transistor 257 is turned off, the auxiliary resistor 255 is open so that no current flows. The auxiliary resistor 255 has a smaller resistance value than the main resistor 253.

The transistor 257 is a switch that is turned on or off depending on the output of the comparator 230. The transistor 257 is turned off at the high output of the comparator 230 and turned on at the low output. That is, when the divided voltage V1 of the external battery 300 is greater than the divided voltage V2 of the battery 100 to be controlled, the transistor 257 is turned off and opened. When transistor 257 is thus turned off, charging current flows to main resistor 253. When the divided voltage V1 of the external battery 300 is smaller than the divided voltage V2 of the battery 100 to be controlled, the transistor 257 is turned on and closed. When the transistor 257 is turned off, the charging current flows to the main resistor 253 and the auxiliary resistor 255 connected in parallel. Here, the transistor 257 may be a P-channel field effect transistor (FET). A gate terminal of the transistor 257 receives and outputs an output signal of the comparator 230.

The charging current controller 250 may further include a source resistor R7 of the transistor 257 and a diode.

4 is a view showing the operation of the battery current control device during discharge according to an embodiment of the present invention.

Referring to FIG. 4, when the external battery 300 having a low voltage is connected to the battery 100 to be controlled, the battery 100 to be controlled is discharged through the battery current control device 200. At this time, the diode 251 is opened and a discharge current flows through the diode 211.

5 is a view showing the operation of the battery current control device during charging according to an embodiment of the present invention.

Referring to FIG. 5, a voltage difference between the voltage of the battery 100 to be controlled and the voltage of the external battery 300 is large when the battery to be controlled is initially charged connected to the charged external battery 300. Therefore, the divided voltage V1 of the external battery 300 is greater than the divided voltage V2 of the controlled battery 100 until the controlled battery 100 reaches a predetermined voltage. Thus, the battery current control device 200 turns off the transistor 257 based on the output result of the comparator 230. When transistor 257 is turned off, charging current flows to main resistor 253.

6 is a view showing the operation of the battery current control device during charging according to another embodiment of the present invention.

Referring to FIG. 6, the battery 100 to be controlled is charged with a current flowing through the main resistor 253 and reaches a predetermined voltage. When the control target battery 100 exceeds the predetermined voltage, the divided voltage V1 of the external battery 300 becomes smaller than the divided voltage V2 of the controlled battery 100. Thus, the battery current control device 200 turns on the transistor 257 based on the output result of the comparator 230. When the transistor 257 is turned on, the auxiliary resistor 255 is connected in parallel to the main resistor 253 so that the charging current flows to the main resistor 253 and the auxiliary resistor 255.

7 is a flowchart of a battery current control method according to an embodiment of the present invention.

Referring to FIG. 7, the battery current control device 200 receives a voltage of an external battery 300 connected to the battery to be controlled 100 (S710).

The battery current control apparatus 200 receives a voltage of the control target battery 100 (S720).

The battery current control apparatus 200 compares the divided voltage V1 of the external battery 300 output by the divided resistor and the divided voltage V2 of the battery 100 to be controlled (S730). The battery current control device 200 outputs any one of a high output and a low output as a result of the comparison. The battery current control apparatus 200 may vary the divided resistance ratio based on the voltage transfer rate of the voltage of the battery 100 to be controlled with respect to the voltage of the external battery 300.

The battery current control apparatus 200 controls the amount of charging current flowing to the control target battery 100 by varying the resistance value based on the comparison result (S740). When the divided voltage V1 of the external battery 300 is greater than the divided voltage V2 of the control target battery 100, the battery current control device 200 flows a charging current to the main resistor 253. In addition, when the divided voltage V1 is smaller than the divided voltage V2 of the battery 100 to be controlled, the battery current control device 200 supplies the charging current to the main resistor 253 and the auxiliary resistor 255 connected in parallel. Shed. At this time, the main resistor 253 has a larger resistance value than the auxiliary resistor 255.

As described above, according to the exemplary embodiment of the present invention, when the control target battery 100 is discharged, it may be discharged in a quick response, and when the control target battery 100 is charged, the voltage of the external battery 300 and the control target battery 100 may be discharged. By controlling the charging current based on the difference, it is possible to prevent a large amount of charging current from flowing suddenly to the control target battery 100 during initial charging. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (16)

A device connected to a battery to be controlled to control the charging current and discharge current of the battery to be controlled,
A comparator configured to compare one of the first output and the second output by comparing a voltage related to each of the control target battery and an external battery connected to the control target battery;
A charge current controller configured to control a charge current flowing to the control target battery by varying a resistance value based on an output of the comparator;
Battery current control device comprising a. In claim 1,
The charging current controller
When receiving the first output from the comparator, the charging current flows to the resistance of the first resistance value, when receiving the second output from the comparator, the charging current flows to the resistance of the second resistance value, And the first resistance value is greater than the second resistance value. 3. The method of claim 2,
The charging current controller
When the first output is received from the comparator, a charging current flows to the first resistor of the first resistance value, and when the second output is transmitted from the comparator, the first resistor and the first resistor connected in parallel. Battery current control device for charging current through two resistors. 4. The method of claim 3,
The charging current controller
And a transistor configured to open and receive the first output and to close the second output to control a parallel connection between the first resistor and the second resistor. In claim 1,
The comparing unit
The battery current control device for outputting any one of the first output and the second output by comparing the difference between the divided voltage of the external battery and the divided voltage of the control target battery. The method of claim 5,
The comparing unit
When the divided voltage of the external battery is greater than the divided voltage of the battery to be controlled, the first output is transmitted to the charging current controller, and when the divided voltage of the external battery is less than the divided voltage of the battery to be controlled, the charging current controller is transmitted. Battery current control device for transmitting a second output. The method of claim 5,
The comparing unit
And controlling the divided resistance ratio of the external battery and the divided resistance ratio of the controlled target battery to output the first output until the controlled target battery voltage reaches a predetermined voltage. In claim 7,
The comparing unit
And a voltage resistance ratio of the external battery and a voltage resistance ratio of the control target battery based on a voltage transfer rate of the control target battery voltage with respect to the external battery voltage. In claim 1,
And a discharge current output unit configured to output a discharge current from the battery to be controlled. The method of claim 9,
The discharge current output unit
And a diode operating when the battery to be controlled is higher in voltage than the external battery. In claim 1,
The charging current controller
And a diode operating when the battery to be controlled is lower in voltage than the external battery. A method of controlling a current of a battery to be controlled by a battery current control device,
Receiving an external battery voltage connected to the control target battery;
Receiving a voltage of the control target battery;
Comparing the divided voltage of the external battery output by the divided resistor and the divided voltage of the battery to be controlled, and
Controlling the amount of charge current flowing to the control target battery by varying a resistance value based on a comparison result;
Battery current control method comprising a. The method of claim 12,
The controlling of the charging current amount
When the divided voltage of the external battery is greater than the divided voltage of the control target battery, a charging current flows to the first resistor, and when the divided voltage of the external battery is smaller than the divided voltage of the controlled battery, the first resistor connected in parallel. And a charging current flowing through the second resistor, wherein the first resistor is a resistor having a larger resistance value than the second resistor. The method of claim 12,
Comparing the divided voltage is
And comparing the difference between the divided voltage of the external battery and the divided voltage of the control target battery to output one of a high output and a low output. The method of claim 14,
Comparing the divided voltage is
Battery current control for setting the divided resistance ratio of the external battery and the divided resistance ratio of the controlled battery so that the divided voltage of the controlled battery becomes higher than the divided voltage of the external battery when the controlled battery voltage exceeds a predetermined voltage. Way. The method of claim 12,
Comparing the divided voltage is
And calculating a predetermined voltage based on a voltage transfer rate of the control target battery voltage with respect to the external battery voltage.

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