KR100649658B1 - Charge and discharge voltage control module and method of high capacity storage battery - Google Patents

Abstract

A method for controlling a charging/discharging voltage of a large-capacity battery is provided to control plural voltages applied on plural condensers at the same time by coupling capacitors corresponding to the respective condensers in parallel with one another. A first switching circuit(10) is series-connected to one side of one of series-connected condensers through a first input terminal. A second switching circuit(20) is connected to the other side of one of the series-connected condensers via a second input terminal in series. A capacitor(C) is parallel-coupled with the condenser via the first and second switching circuits. A third switch circuit(30) is connected to one side of the condenser, series-connected to the first switching circuit, and coupled with the other side of the condenser via a first output terminal. A fourth switch circuit(40) is connected to the other side of the condenser, series-connected to the second switching circuit, and coupled with one side of the condenser via a second output terminal. A signal generator(50) outputs a control signal for controlling a switching process of the first and second switching circuits. An inverter circuit(60) inverts the control signal from the signal generator and controls the switching process of the third and fourth switching circuits according to the inverted control signal.

Description

Charging and Discharge Voltage Control Module and Method of High Capacity Storage Battery

1 is a block diagram of an apparatus for controlling charge and discharge voltage of a large capacity storage battery according to the present invention.

2 is a detailed circuit diagram of the control module of FIG.

Figure 3 is a block diagram showing a voltage control device for a conventional high capacity storage battery of nickel hydrogen or lithium ion.

Explanation of symbols on the main parts of the drawings

10: first switching circuit 11: first input terminal

20: second switching circuit 21: second input terminal

30: third switching circuit 31: first output terminal

40: fourth switching circuit 41: second output terminal

50: signal generator 60: inversion circuit

The present invention relates to a charge / discharge voltage control device for a large capacity battery, and more particularly, a capacitor corresponding to each individual battery constituting the large capacity battery is connected in parallel, and the plurality of batteries and the capacitors are switched. By controlling the voltage of the corresponding battery through the capacitor, by using the capacitor as an accumulating element, the loss of energy can be reduced to a minimum, and it is relatively inexpensive, simple in configuration, and charged and discharged in a plurality of batteries. Voltage can be controlled evenly.

In general, secondary batteries used in notebooks, power tools, or electric vehicles (hereinafter, used with batteries) are large capacity batteries having a relatively large capacity, and in this case, by combining several to several tens of batteries in parallel. The charging capacity is increased.

However, in the case of a large capacity battery configured by connecting a plurality of batteries as described above, since a plurality of batteries connected in parallel have different capacity deviations, even if the same charge / discharge current flows, any one or more of the batteries Excessive charge and discharge is made, and any other one or more storage battery is not enough charge and discharge.

Therefore, since the capacity deviation, the service life, and the like, which are characteristics of each battery, are different from each other, there is a problem in that the rated capacity and the service life of the entire large-capacity storage battery are deteriorated when the battery is out of an individual service limit.

In order to solve this problem, the lead-acid battery and the Ni-Cad battery among the storage battery, when the charge exceeds the rated capacity, the excess energy is dissipated by heat dissipated due to the characteristics. At the level where there is a possibility of variation, it charges with low current.

In other words, when continuously charging while reducing the amount of heat generated by overcharging, only the uncharged battery is continuously charged, and eventually the power storage control method using the principle that all are equally charged over time.

In the case of nickel hydride batteries and lithium ion (LiB, LiPB) batteries, there is a high risk of explosion during overcharging, so a precise charge / discharge control circuit is configured to detect potentials individually. By discharging through the discharge resistance, it is evenly charged.

That is, as shown in FIG. 3, the voltage across the storage battery B is monitored through the control circuit 70, and when the storage battery B is overcharged, the control circuit 70 turns on the switching circuit 80. Through the discharge resistor 90, a part of the charging voltage of the storage battery B is dissipated.

However, in the case of the lead-acid battery and the Ni-Cd battery, as the overcharge is repeated, the life and performance of the battery may be drastically deteriorated and the life of the battery may be reduced. The nickel-hydrogen battery and the lithium ion battery are overcharged using discharge resistance. Even when heat dissipating a voltage corresponding to the voltage, due to the heat dissipation limit inside the battery pack, the effect was inevitable.

Another individual charging method mainly used in a large power supply device is to connect the charge and discharge control circuit independently for each battery, and the charge and discharge control circuit to control the storage battery, but each of the battery pack Since as many charging circuits are needed as the number of batteries, the total volume of the battery pack is increased and the cost is increased.

Accordingly, an object of the present invention is to solve the conventional problems as described above, by connecting a capacitor (capacitor) corresponding to each individual battery constituting a large capacity battery in parallel, and the plurality of batteries and capacitors in a switching operation It is to provide a charge and discharge voltage control device for a large-capacity battery by controlling by, by adjusting the voltage of the battery through the capacitor, it is relatively inexpensive, simple in configuration, and can control the voltage charged and discharged in a plurality of batteries evenly. .

In addition, by using the capacitor as the storage element, it is possible to reduce the loss of energy to a minimum, and to provide a charge and discharge voltage control device of a large capacity battery that can be applied to all of a variety of storage battery not limited to a specific battery.

Another object of the present invention is to provide a charge / discharge voltage control device for a large capacity storage battery, which improves convenience in use and thus improves marketability.

An apparatus for controlling charge and discharge voltage of a large capacity battery according to the present invention for achieving the above object includes a first switching circuit connected in series through a first input terminal to one side of a plurality of storage batteries connected in series; A second switching circuit connected in series through a second input terminal to the other side of the one storage battery, and a storage device connected in parallel with any one battery through the first switching circuit and the second switching circuit; A third switching circuit connected to one side of the power storage element, connected in series with the first switching circuit, and connected to the other side of the one battery through a first output terminal, and the other side of the power storage element; And a fourth switching circuit connected in series with the second switching circuit and connected to one side of the other one of the plurality of batteries through a second output terminal. And a signal generator for outputting a control signal for controlling switching operations of the first switching circuit and the second switching circuit, and an inverted control signal output from the signal generator, wherein the inverted control signal And an inverting circuit for controlling the switching operation to the third switching circuit and the fourth switching circuit.

Therefore, by using the capacitor as the storage element, it is possible to reduce the loss of energy to a minimum, and to control the voltage charged and discharged in a plurality of batteries evenly while being relatively inexpensive and simple in construction.

In addition, the ease of use is improved, and the merchandise is more improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a charge / discharge voltage control device of a large capacity storage battery according to the present invention, a plurality of storage batteries (B1) (B2) (B3) (B4) and the control module (CM) and the power storage device (C) connected in series It shows the connection of.

FIG. 2 is a detailed circuit diagram of the control module CM of FIG. 1, in which the first switching circuit 10, the second switching circuit 20, the third switching circuit 30, The connection relationship between the 4th switching circuit 40, the signal generation part 50, and the inversion circuit 60 is shown.

First, referring to the connection relationship between the elements, the first input terminal 11 and the second input terminal 21 at both ends of the battery B1 of the plurality of batteries B1, B2, B3, B4. Through the first switching circuit 10 and the second switching circuit 20 is connected.

A power storage device C having a constant capacitance is connected in parallel with the storage battery B1 through the first switching circuit 10 and the second switching circuit 20.

One side of the third switching circuit 30 is connected to one side of the power storage element C and the first switching circuit 10 as a common node, and through the first output terminal 31 to the second node. It is connected to the input terminal 21 and the storage battery B1 as a common node.

In addition, one side of the fourth switching hull 40 is connected to the other side of the power storage element C and the second switching circuit 20 as a common node, and the plurality of the plurality of through the second output terminal 41. Is connected to the other battery B2 of the batteries B1, B2, B3, and B4.

The first switching circuit 10 and the second switching circuit 20 are turned on and off by pulse waves output from the signal generator 50, and are output from the signal generator 50. The pulse wave is inverted through the inversion circuit 60 to be used as a control signal for controlling the on / off of the third switching circuit 30 and the fourth switching arc 40.

Hereinafter, the voltage control operation of the charge / discharge voltage control device for a large capacity storage battery according to the present invention will be described.

First, when the first switching circuit 10 and the second switching circuit 20 is in an ON state according to the control signal of the pulse wave (High Level) output from the signal generator 50, the inversion circuit 60 Since the output signal of) is a low level with the control signal output from the signal generator 50, the third switching circuit 30 and the fourth switching circuit 40 are turned off.

In this case, the charging voltage of the battery B1 is charged to the power storage device C through the first switching circuit 10 and the second switching circuit 20, and the charging operation of the power storage device C is performed. The voltages of both ends of the battery B1 and the power storage element C are the same.

If the voltage at both ends of the power storage device C is greater than the voltage at both ends of the battery B1, the charging voltage of the power storage device C is charged to the storage battery B1.

Here, although the charging of the power storage device (C) and the battery (B1) has been described as a charging voltage, in reality, it is charged through the current flowing by the voltage of each device, it is obvious that it was described as a voltage for convenience of description. .

As described above, when the voltages at both ends of the battery B1 and the power storage device C become the same, the first switching circuit 10 is driven by a pulse wave (Low Level) generated by the signal generator 50. And the second switching circuit 20 is turned off, and the third switching circuit 30 and the fourth switching circuit 40 are turned on by a control signal (High Level) output from the inversion circuit 60.

That is, the power storage device C is disconnected from any one of the plurality of storage batteries B1, B2, B3, and B4, and electrically connected to the other storage battery B2. It is.

As described above, when the power storage device C and the other battery B2 are connected in parallel, the voltages at both ends of the power storage device C and the other battery B2 become equal as described above.

Accordingly, the first switching circuit 10, the second switching circuit 20, the third switching circuit 30, and the fourth switching circuit 40 are turned on and off by the pulse wave output from the signal generator 50. While repeating the operation, the voltages of any one of the plurality of storage batteries B1, B2, B3, and B4 and the other storage battery B2 are transferred through the storage element C. To be the same.

Therefore, as shown in FIG. 1, in the case of a large capacity battery in which a plurality of batteries B1, B2, B3, and B4 are connected in series, the circuit configuration shown in FIG. 2 is applied to each of the batteries B1, B2, and B3. By connecting to B4, the voltages across the plurality of storage batteries B1, B2, B3, and B4 can be maintained the same.

The present invention may be modified in various ways without departing from the basic concept according to the needs of those skilled in the art.

As described above, according to the present invention, a capacitor corresponding to each individual battery constituting the large-capacity battery is connected in parallel, and the plurality of batteries and the capacitors are controlled by a switching operation to correspond to each other. By regulating the voltage of the storage battery, it is possible to control the voltage charged and discharged to a plurality of batteries evenly while being relatively inexpensive and simple in construction.

In addition, by using the capacitor as the storage element, the loss of energy can be reduced to a minimum, and can be applied to various storage batteries, not limited to a specific battery, thereby improving the versatility and compatibility.

Therefore, it is a very useful invention such that the convenience in use is improved and the merchandise is more improved.

Claims (1)

A first switching circuit 10 connected in series through a first input terminal 11 to one side of a battery B1 of a plurality of batteries connected in series, A second switching circuit 20 connected in series through the second input terminal 21 to the other side of the storage battery B1; A power storage element C connected in parallel with any one of the storage batteries B1 through the first switching circuit 10 and the second switching circuit 20; Is connected to one side of the power storage element (C), is connected in series with the first switching circuit 10, the first output terminal 31 is connected to the other side of the one of the storage battery (B1) 3 switching circuit 30, It is connected to the other side of the power storage element (C), is connected in series with the second switching circuit 20, one side of the other battery (B2) of the other of the plurality of storage battery via the second output terminal 41 A fourth switching circuit 40 connected to the A signal generator 50 for outputting a control signal for controlling the switching operation of the first switching circuit 10 and the second switching circuit 20; An inversion circuit 60 for inverting a control signal output from the signal generator 50 and controlling a switching operation of the third switching circuit 30 and the fourth switching circuit 40 by the inverted control signal. Charge / discharge voltage control device for a large capacity battery, characterized in that consisting of.

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