KR101902308B1 - battery management system - Google Patents

Abstract

The present invention relates to a battery management system capable of extending a service life of a battery. According to the present invention, the battery management system comprises a control unit (102); first, second, and third pull-up lines (104, 106, 108); a first connection line (110) electrically connected to one end of a first battery cell (202); a second connection line (112) spaced apart from the first connection line (110) at a predetermined interval to be electrically connected to one end of a second connection line (112); a first operating photocoupler (114) connected to the second connection line (112) and the second pull-up line (116), and connected to the control unit (102) to be turned on in charging of the first battery cell (202); and a first light amount measurement photocoupler (116) connected to the first connection line (110) and the first pull-up line (104), and connected to the first operating photocoupler (114) and the control unit (102) to be turned on when the first operating photocoupler (114) is turned so as to display the level of charging voltage of the first battery cell (202) as light.

Description

A battery management system

[0001] The present invention relates to a battery management system, and more particularly, to a battery management system capable of easily determining whether a battery cell is abnormal by measuring a battery cell voltage with a light amount, and controlling cell balancing using a photo- And a battery management system for preventing the leakage of the battery due to the absence of the dark current flowing in the balancing unit, thereby extending the service life of the battery.

Generally, in order to manufacture a large capacity battery, a plurality of battery cells are often connected in series or in parallel. In this case, as the charge / discharge is repeated while using the battery, the voltage difference between the battery cells becomes larger and the unbalance tends to occur. In this case, the life of the entire battery is shortened by some of the deteriorated battery cells, and even the risk of fire or explosion increases. Among the battery control technologies, the BMS (Battery Management System) monitors the current, voltage, temperature, and remaining capacity of each battery cell and performs an alarm or power off function when an abnormal condition is detected.

Such a battery management system is a battery management system in which overcharging (overcharge voltage and overcharge current), overdischarge (overdischarge voltage and overdischarge current), a battery cell in which a capacity has changed (hereinafter referred to as a poor battery cell) It is focused on.

In particular, a poor battery cell is characterized by faster discharging and faster charging than other battery cells, which means that the capacity is different from that of other battery cells, and such a poor battery cell has a great problem in charging and discharging the battery .

For example, in the case of discharging, when a discharge occurs, the inferior battery cell is discharged first from other battery cells to reach the overdischarge reference voltage. However, since the entire battery is in a dischargeable state, the discharge continues. Accordingly, the defective battery cell tries to keep falling below the overdischarge reference voltage, and the other battery cell discharges more current than the original normal operation current to compensate. Repeating this process will shorten the life span of the entire battery, and in severe cases, it will cause heat and explosion.

In order to solve the above problems, the present invention was filed with the application No. 10-2014-0042328 (name of the invention: battery management apparatus and method) of April 09, 2014, A cell balancing unit for balancing individual cells of the plurality of battery cells, a voltage balancing unit for individually selecting the plurality of battery cells of the battery pack, Calculating a current accumulation amount of the current charging state corresponding to the total voltage of the battery pack detected by the voltage detecting unit based on a matching table between the total voltage-charging cumulative amount stored in advance, Current accumulation amount calculated by the charge accumulation amount obtained by the product of the charge current and the time when the charge current is applied, Calculates a total current integrated amount, calculates a reference voltage corresponding to the total current integrated amount calculated based on a pre-stored total current integrated amount-reference voltage matching table, and outputs the calculated reference current to the voltage detection unit And a control unit for controlling the cell balancing unit to perform cell balancing of the battery cell in which a voltage greater than the reference voltage is detected by comparing the voltages of the individual battery cells detected by the battery balancing unit.

However, in the conventional battery management apparatus and method, a cell balancing unit for performing individual cell balancing of a plurality of battery cells is provided,

Since the dark current flows through the cell balancing unit to cause leakage, the life of the battery is shortened.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above problems occurring in the prior art, and it is an object of the present invention to enable easy determination of an abnormality of a battery cell by measuring a battery cell voltage with a light amount, And a battery management system for preventing battery leakage by preventing a dark current from flowing in a cell balancing unit due to control of cell balancing using a photocoupler.

However, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a battery management system including:

A control unit 102;

A first pull-up line 104 provided at a predetermined interval from the control unit 102;

A second pull-up line (106) spaced apart from the first pull-up line (104);

A third pull-up line 108 spaced apart from the second pull-up line 106;

A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;

A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;

And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;

The first driving photocoupler 114 is disposed at a predetermined interval from the first driving photocoupler 114 and is connected to the first connecting line 110 and is connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the first driving photocoupler 114 is turned on so that the amount of charge voltage of the first battery cell 202 becomes a first light quantity And a photocoupler 116 for measurement.

As described above, in the battery management system according to the present invention, leakage current is prevented because the dark current does not flow in the cell balancing unit, thereby extending the service life of the battery.

The present invention has the effect of easily determining whether the battery cell is abnormal by measuring the battery cell voltage at a light amount.

1 is a schematic view of a battery management system according to the present invention.

Hereinafter, a preferred embodiment of the battery management system according to the present invention will be described.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a schematic view of a battery management system according to the present invention.

As shown in FIG. 1, the battery management system 100 according to the present invention includes:

A control unit 102;

A first pull-up line 104 provided at a predetermined interval from the control unit 102;

A second pull-up line (106) spaced apart from the first pull-up line (104);

A third pull-up line 108 spaced apart from the second pull-up line 106;

A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;

A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;

And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;

The first driving photocoupler 114 is disposed at a predetermined interval from the first driving photocoupler 114 and is connected to the first connecting line 110 and is connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the first driving photocoupler 114 is turned on so that the amount of charge voltage of the first battery cell 202 becomes a first light quantity A photocoupler 116 for measurement;

The first photocoupler 114 is connected to the second connection line 112 and is connected to the third pull-up line 108. The first photocoupler 114 is connected to the third photocoupler 116, A second driving photocoupler 118 connected to the control unit 102 and turned on when the first battery cell 202 is discharged;

The second driving photocoupler 118 is connected to the first connecting line 110 and the second connecting line 112 and is connected to the second driving photocoupler 118, A first N-type MOSFET 120 for turning on the first photo-coupler 118 when the second photo-coupler 118 is turned on to discharge the first battery cell 202;

A third connection line 122 electrically connected to one end of the second battery cell 204 at a predetermined interval from the first N-type MOSFET 120;

A fourth connection line 124 electrically connected to one end of the second battery cell 204 at regular intervals from the third connection line 122;

And a third driving unit connected to the fourth connection line 124 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the second battery cell 204 is charged A photocoupler 126;

The third driving photocoupler 126 is provided at a predetermined distance from the third driving photocoupler 126 and is connected to the third connecting line 122 and connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the third driving photocoupler 126 is turned on so that the amount of the charged voltage of the second battery cell 204 is changed to a second amount of light A photocoupler 128 for measurement;

The third photocoupler 126 is connected to the fourth connection line 124 and is connected to the third pull-up line 108. The third driving photocoupler 126 is connected to the fourth photocoupler 128, A fourth driving photocoupler 130 connected to the control unit 102 and turned on when the second battery cell 204 is discharged;

The first driving photocoupler 130 is connected to the third connecting line 122 and the fourth connecting line 124 and is connected to the fourth driving photocoupler 130, A second N-type MOSFET 132 for turning on the first photo-coupler 130 to turn on the second battery cell 204;

A fifth connection line 134 electrically connected to one end of the third battery cell 206 at regular intervals from the second N-type MOSFET 132;

A sixth connection line 136 electrically connected to one end of the third battery cell 206 at regular intervals from the fifth connection line 134;

A fifth driving unit connected to the sixth connection line 136 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the third battery cell 206 is charged, A photocoupler 138;

The fifth driving photocoupler 138 is connected to the fifth connecting line 134 and is connected to the first pull-up line 104 and the fifth driving photocoupler 138 And is connected to the control unit 102 to be turned on when the fifth driving photocoupler 138 is turned on so that the amount of the charged voltage of the third battery cell 206 is changed to a third amount of light A photocoupler 140 for measurement;

The first photocoupler 138 is connected to the sixth connection line 136 and is connected to the third pull-up line 108. The fifth photocoupler 138 is connected to the sixth photocoupler 140, A sixth driving photocoupler 142 connected to the control unit 102 and turned on when the third battery cell 206 is discharged;

The sixth driving photocoupler 142 is connected to the fifth connecting line 134 and the sixth connecting line 136 and is connected to the sixth driving photocoupler 142, A third N-type MOSFET 144 for turning on the third photocoupler 142 when the sixth photocoupler 142 is turned on to discharge the third battery cell 206;

A seventh connecting line 148 electrically connected to one end of the fourth battery cell 208 at regular intervals from the third N-type MOSFET 144;

An eighth connection line 150 electrically connected to one end of the fourth battery cell 208 at regular intervals from the seventh connection line 148;

A seventh driving unit connected to the eighth connecting line 150 and connected to the second pull-up line 106 and connected to the control unit 102 to turn on the fourth battery cell 208 when the fourth battery cell 208 is charged, A photocoupler 152;

The seventh driving photocoupler 152 is connected to the seventh connecting line 148 and is connected to the first pull-up line 104. The seventh driving photocoupler 152 is connected to the seventh connecting line 148, And is connected to the control unit 102 to be turned on when the seventh driving photocoupler 152 is turned on so that the amount of the charged voltage of the fourth battery cell 208 is changed to a fourth amount of light A photocoupler 154 for measurement;

The fourth photocoupler 152 is connected to the seventh connection line 150 and is connected to the third pull-up line 108. The seventh driving photocoupler 152 is connected to the seventh driving photocoupler 154, An eighth driving photocoupler 156 connected to the control unit 102 and turned on when the fourth battery cell 208 is discharged;

The first driving photocoupler 156 is connected to the seventh connecting line 148 and the eighth connecting line 150 and is connected to the eighth driving photocoupler 156, And a fourth N-type MOSFET 158 for turning on the fourth photovoltaic converter 156 to turn on the fourth battery cell 208 when the photocoupler 156 is turned on.

Here, the second, fourth, sixth, and eighth driving photocouplers 118, 130, 142, and 156 may be referred to as a balancing unit for balancing the battery cells.

The manufacturing process and operation of the battery management system 100 according to the present invention will now be described.

Here, the manufacturing process of the battery management system 100 according to the present invention can be changed as much as the manufacturer.

First, a battery 200 having a first battery cell 202, a second battery cell 204, a third battery cell 206, and a fourth battery cell 208 is installed.

A control unit 102 for controlling the battery management system 100 is installed at predetermined intervals from the battery 200 according to a preset program.

A first pull-up line 104, a second pull-up line 106 and a third pull-up line 108 are provided between the controller 102 and the battery 200 at regular intervals.

After the first connection line 110 is electrically connected to one end of the first battery cell 202 at a predetermined interval from the third pull-up line 108, the first connection line 110 is disconnected from the first connection line 110 at a predetermined interval The second connection line 112 is electrically connected to one end of the first battery cell 202. [

The first driving photocoupler 114 is turned on when the first battery cell 202 is charged to the second connection line 112, the second pull-up line 106 and the control unit 102 Connect electrically.

The first connection line 110, the first pull-up line 104, the first driving photocoupler 114 and the first driving photocoupler 114 are connected to the first driving photocoupler 114 at a predetermined interval, The first photocoupler 116 for turning on the ON photocoupler 114 and turning on the charging voltage of the first battery cell 202 as the light is electrically connected .

The second connection line 112, the third pull-up line 108, the first driving photocoupler 114, and the control unit 102 are connected to the first light quantity measuring photocoupler 116 at predetermined intervals. And electrically connects the second driving photocoupler 118 which is turned on when the one battery cell 202 is discharged.

The second driving photocoupler 118 is connected to the first connecting line 110, the second connecting line 112 and the second driving photocoupler 118 at a predetermined interval from the second driving photocoupler 118 118 are turned on to electrically connect the first N-type MOSFET 120 for discharging the first battery cell 202.

After the third connection line 122 is electrically connected to one end of the second battery cell 204 at a predetermined interval from the first N-type MOSFET 120, the third connection line 122 is electrically connected to the third connection line 122 at a predetermined interval And electrically connects the fourth connection line 124 to one end of the second battery cell 204. [

The third driving photocoupler 126 is turned on when the second battery cell 204 is charged to the fourth connection line 124, the second pull-up line 106 and the control unit 102 Connect electrically.

The third driving line is connected to the third driving line 122, the first pull-up line 104, the third driving photocoupler 126 and the control unit 102 at a predetermined interval from the third driving photocoupler 126, The second photocoupler 128 is turned on when the photocoupler 126 is turned on to electrically connect the photocoupler 128 for measuring the amount of charge of the second battery cell 204 as light.

The fourth connection line 124, the third pull-up line 108, the third driving photocoupler 126, and the control unit 102 are connected to the second light quantity measuring photocoupler 128 at predetermined intervals. And electrically connects the fourth drive photocoupler 130 that is turned on when the second battery cell 204 is discharged.

The fourth driving photocoupler 130 is connected to the third connecting line 122, the fourth connecting line 124 and the fourth driving photocoupler 130 at a predetermined interval from the fourth driving photocoupler 130 The second N-type MOSFET 132 discharging the second battery cell 204 is turned on when the first N-type MOSFET 130 is turned on.

After the fifth connection line 134 is electrically connected to one end of the third battery cell 206 at a predetermined interval from the second N-type MOSFET 132, the fifth connection line 134 is disconnected from the fifth connection line 134 at a predetermined interval And electrically connects the sixth connection line 136 to one end of the third battery cell 206. [

The fifth driving photocoupler 138 is turned on when the third battery cell 206 is charged to the sixth connection line 136, the second pull-up line 106 and the control unit 102 Connect electrically.

The fifth connecting line 134, the first pull-up line 104, the fifth driving photocoupler 138, and the fifth driving photocoupler 138 are connected to the fifth driving photocoupler 138 at regular intervals. The photocoupler 140 for turning on the third photocouler 138 is turned on to electrically connect the photocoupler 140 for measuring the amount of charge of the third battery cell 206 as light .

The sixth connecting line 136, the third pull-up line 108, the fifth driving photocoupler 138, and the second connecting photocoupler 138 are connected to the third light quantity measuring photocoupler 140 at predetermined intervals. And electrically connects the sixth driving photocoupler 142 which is turned on when the third battery cell 206 is discharged.

The sixth driving photocoupler 142 is connected to the fifth connecting line 134, the sixth connecting line 136 and the sixth driving photocoupler 142 at a predetermined interval from the sixth driving photocoupler 142 142 are turned on to electrically connect the third N-type MOSFET 144 for discharging the third battery cell 206. [

After the seventh connecting line 148 is electrically connected to one end of the fourth battery cell 208 at a predetermined interval from the third N-type MOSFET 144, the seventh connecting line 148 is disconnected from the seventh connecting line 148 at a predetermined interval And electrically connects the eighth connection line 150 to one end of the fourth battery cell 208.

A seventh drive photocoupler 152 for turning on the fourth battery cell 208 when the fourth battery cell 208 is charged is connected to the eighth connection line 150, the second pull-up line 106, Connect electrically.

The seventh connecting line 148, the first pull-up line 104, the seventh driving photocoupler 152 and the seventh driving photocoupler 152 are connected to the seventh driving photocoupler 152 at regular intervals. The photocoupler 152 for driving light is turned on when the driving photocoupler 152 is turned on and electrically connected to the photocouler 154 for measuring the amount of charge of the fourth battery cell 208 as light .

An eighth connection line 150, a third pull-up line 108, a seventh driving photocoupler 152, and a control signal generator (not shown) are connected to the fourth light quantity measuring photocoupler 154 at predetermined intervals. And electrically connects the eighth driving photocoupler 156 which is turned on when the fourth battery cell 208 is discharged.

The eighth driving photocoupler 156 is connected to the seventh connecting line 148, the eighth connecting line 150 and the eighth driving photocoupler 156 at regular intervals from the eighth driving photocoupler 156 156 are turned on to electrically connect the fourth N-type MOSFET 158 for discharging the fourth battery cell 208. [

After manufacturing the battery management system 100 according to the present invention,

Upon charging the battery 200,

That is, upon charging the first battery cell 202, the second battery cell 204, the third battery cell 206 and the fourth battery cell 208,

The control unit 102 turns on the first, third, fifth, and seventh driving photocouplers 114, 126, 138, 152 and turns on the second, fourth, sixth And turns on the eighth driving photocouplers 118, 130, 142, and 156, respectively.

When the first driving photocoupler 114 is turned on, the first light amount measuring photocoupler 116 turns on and emits light corresponding to the charging voltage amount of the first battery cell 202.

When the third driving photocoupler 126 is turned on, the second light amount measuring photocoupler 128 turns on and emits light corresponding to the charging voltage amount of the second battery cell 204.

When the fifth driving photocoupler 138 is turned on, the third light quantity measuring photocoupler 140 turns on and emits light as much as the charging voltage of the third battery cell 206.

When the seventh driving photocoupler 152 is turned on, the fourth light quantity measuring photocoupler 154 turns on and emits light corresponding to the charging voltage amount of the fourth battery cell 208.

Therefore, the second, fourth, sixth, and eighth driving photocouplers 118, 130, 142, and 156 are turned off to isolate the first, 2, the third and fourth N-type MOSFETs 120, 132, 144, and 158 remain off.

Therefore, since the balancing portion which is the second, fourth, sixth, and eighth driving photocouplers 118, 130, 142, 156 is off, the dark current does not flow to the balancing portion, Thereby extending the service life of the battery.

Contrary,

Upon discharging the battery 200,

That is, upon discharging the first battery cell 202, the second battery cell 204, the third battery cell 206, and the fourth battery cell 208,

The control unit 102 turns on the first, third, fifth, and seventh driving photocouplers 114, 126, 138, 152 and turns on the second, fourth, sixth And the eighth driving photocouplers 118, 130, 142, and 156 are turned on.

When the second driving photocoupler 118 is turned on, the first N-type MOSFET 120 is turned on to discharge the first battery cell 202.

When the fourth driving photocoupler 130 is turned on, the second N-type MOSFET 132 is turned on to discharge the second battery cell 204.

When the sixth driving photocoupler 142 is turned on, the third N-type MOSFET 158 is turned on to discharge the third battery cell 206.

When the eighth drive photocoupler 156 is turned on, the fourth N-type MOSFET 158 is turned on to discharge the fourth battery cell 208.

Therefore, according to the present invention, since the dark current does not flow when the cell balancing unit is OFF, discharge is prevented, and the life of the battery can be extended.

The foregoing description of the invention is merely exemplary of the invention and is used for the purpose of illustration only and is not intended to limit the scope of the invention as defined in the claims or the claims.

Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Battery management system
102:
104: 1st pull-up line
106: 2nd pull-up line
108: 3rd pull-up line
110: first connection line
112: second connection line
114: first driving photocoupler
116: Photocoupler for measuring the first light amount
118: Second driving photocoupler
120: first N-type MOSFET

Claims (4)

A control unit 102;
A first pull-up line 104 provided at a predetermined interval from the control unit 102;
A second pull-up line (106) spaced apart from the first pull-up line (104);
A third pull-up line 108 spaced apart from the second pull-up line 106;
A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;
A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;
And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;
The first driving photocoupler 114 is disposed at a predetermined interval from the first driving photocoupler 114 and is connected to the first connecting line 110 and is connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the first driving photocoupler 114 is turned on so that the amount of charge voltage of the first battery cell 202 becomes a first light quantity And a measurement photocoupler (116).
A control unit 102;
A first pull-up line 104 provided at a predetermined interval from the control unit 102;
A second pull-up line (106) spaced apart from the first pull-up line (104);
A third pull-up line 108 spaced apart from the second pull-up line 106;
A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;
A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;
And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;
The first battery cell 202 is connected to the second connection line 112 and is connected to the third pull-up line 108 and is connected to the first driving photocoupler 114 and is connected to the control unit 102, A second driving photocoupler 118 which is turned on at the time of the discharge of the first driving photocoupler 118;
The second driving photocoupler 118 is connected to the first connecting line 110 and the second connecting line 112 and is connected to the second driving photocoupler 118, And a first N-type MOSFET (120) for turning on the first battery cell (202) when the second drive photocoupler (118) is turned on.
A control unit 102;
A first pull-up line 104 provided at a predetermined interval from the control unit 102;
A second pull-up line (106) spaced apart from the first pull-up line (104);
A third pull-up line 108 spaced apart from the second pull-up line 106;
A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;
A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;
And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;
The first driving photocoupler 114 is disposed at a predetermined interval from the first driving photocoupler 114 and is connected to the first connecting line 110 and is connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the first driving photocoupler 114 is turned on so that the amount of charge voltage of the first battery cell 202 becomes a first light quantity A photocoupler 116 for measurement;
The first photocoupler 114 is connected to the second connection line 112 and is connected to the third pull-up line 108. The first photocoupler 114 is connected to the third photocoupler 116, A second driving photocoupler 118 connected to the control unit 102 and turned on when the first battery cell 202 is discharged;
The second driving photocoupler 118 is connected to the first connecting line 110 and the second connecting line 112 and is connected to the second driving photocoupler 118, And a first N-type MOSFET (120) for turning on the first battery cell (202) when the second drive photocoupler (118) is turned on.
A control unit 102;
A first pull-up line 104 provided at a predetermined interval from the control unit 102;
A second pull-up line (106) spaced apart from the first pull-up line (104);
A third pull-up line 108 spaced apart from the second pull-up line 106;
A first connection line 110 electrically connected to one end of the first battery cell 202 at regular intervals from the third pull-up line 108;
A second connection line 112 electrically connected to one end of the first battery cell 202 at a predetermined interval from the first connection line 110;
And a first driving unit connected to the second connection line 112 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the first battery cell 202 is charged, A photocoupler 114;
The first driving photocoupler 114 is disposed at a predetermined interval from the first driving photocoupler 114 and is connected to the first connecting line 110 and is connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the first driving photocoupler 114 is turned on so that the amount of the charged voltage of the first battery cell 202 becomes a first light quantity A photocoupler 116 for measurement;
The first photocoupler 114 is connected to the second connection line 112 and is connected to the third pull-up line 108. The first photocoupler 114 is connected to the third photocoupler 116, A second driving photocoupler 118 connected to the control unit 102 and turned on when the first battery cell 202 is discharged;
The second driving photocoupler 118 is connected to the first connecting line 110 and the second connecting line 112 and is connected to the second driving photocoupler 118, A first N-type MOSFET 120 for turning on the first photo-coupler 118 when the second photo-coupler 118 is turned on to discharge the first battery cell 202;
A third connection line 122 electrically connected to one end of the second battery cell 204 at a predetermined interval from the first N-type MOSFET 120;
A fourth connection line 124 electrically connected to one end of the second battery cell 204 at regular intervals from the third connection line 122;
And a third driving unit connected to the fourth connection line 124 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the second battery cell 204 is charged A photocoupler 126;
The third driving photocoupler 126 is provided at a predetermined distance from the third driving photocoupler 126 and is connected to the third connecting line 122 and connected to the first pull-up line 104, And is connected to the control unit 102 to be turned on when the third driving photocoupler 126 is turned on so that the amount of the charged voltage of the second battery cell 204 is changed to a second amount of light A photocoupler 128 for measurement;
The third photocoupler 126 is connected to the fourth connection line 124 and is connected to the third pull-up line 108. The third driving photocoupler 126 is connected to the fourth photocoupler 128, A fourth driving photocoupler 130 connected to the control unit 102 and turned on when the second battery cell 204 is discharged;
The first driving photocoupler 130 is connected to the third connecting line 122 and the fourth connecting line 124 and is connected to the fourth driving photocoupler 130, A second N-type MOSFET 132 for turning on the first photo-coupler 130 to turn on the second battery cell 204;
A fifth connection line 134 electrically connected to one end of the third battery cell 206 at regular intervals from the second N-type MOSFET 132;
A sixth connection line 136 electrically connected to one end of the third battery cell 206 at regular intervals from the fifth connection line 134;
A fifth driving unit connected to the sixth connection line 136 and connected to the second pull-up line 106 and connected to the control unit 102 to be turned on when the third battery cell 206 is charged, A photocoupler 138;
The fifth driving photocoupler 138 is connected to the fifth connecting line 134 and is connected to the first pull-up line 104 and the fifth driving photocoupler 138 And is connected to the control unit 102 to be turned on when the fifth driving photocoupler 138 is turned on so that the amount of the charged voltage of the third battery cell 206 is changed to a third amount of light A photocoupler 140 for measurement;
The first photocoupler 138 is connected to the sixth connection line 136 and is connected to the third pull-up line 108. The fifth photocoupler 138 is connected to the sixth photocoupler 140, A sixth driving photocoupler 142 connected to the control unit 102 and turned on when the third battery cell 206 is discharged;
The sixth driving photocoupler 142 is connected to the fifth connecting line 134 and the sixth connecting line 136 and is connected to the sixth driving photocoupler 142, A third N-type MOSFET 144 for turning on the third photocoupler 142 when the sixth photocoupler 142 is turned on to discharge the third battery cell 206;
A seventh connecting line 148 electrically connected to one end of the fourth battery cell 208 at regular intervals from the third N-type MOSFET 144;
An eighth connection line 150 electrically connected to one end of the fourth battery cell 208 at regular intervals from the seventh connection line 148;
A seventh driving unit connected to the eighth connecting line 150 and connected to the second pull-up line 106 and connected to the control unit 102 to turn on the fourth battery cell 208 when the fourth battery cell 208 is charged, A photocoupler 152;
The seventh driving photocoupler 152 is connected to the seventh connecting line 148 and is connected to the first pull-up line 104. The seventh driving photocoupler 152 is connected to the seventh connecting line 148, And is connected to the control unit 102 to be turned on when the seventh driving photocoupler 152 is turned on so that the amount of the charged voltage of the fourth battery cell 208 is changed to a fourth amount of light A photocoupler 154 for measurement;
The fourth photocoupler 152 is connected to the seventh connection line 150 and is connected to the third pull-up line 108. The seventh driving photocoupler 152 is connected to the seventh driving photocoupler 154, An eighth driving photocoupler 156 connected to the control unit 102 and turned on when the fourth battery cell 208 is discharged;
The first driving photocoupler 156 is connected to the seventh connecting line 148 and the eighth connecting line 150 and is connected to the eighth driving photocoupler 156, And a fourth N-type MOSFET (158) for turning on the fourth battery cell (208) upon turning on the photocoupler (156) for driving the eighth drive photocoupler (156).

Images