KR100585426B1 - Device for lengthening life span of storage battery by adjusting amplitude of pulse current according to storage power status - Google Patents

Abstract

The present invention relates to an apparatus for extending the life of a battery for controlling the magnitude of a pulse current according to an electrical storage state. The present invention relates to an apparatus for extending the life of a battery connected to a battery, wherein the battery is extended by a user by operating the battery. An operating voltage setting unit for setting an operating voltage which may be; An operating voltage comparing unit which compares an externally input voltage with an operating voltage set by the operating voltage setting unit; A battery voltage detector detecting a charge voltage of the battery; A battery voltage comparing unit comparing the output voltage of the battery voltage detecting unit with a reference voltage; A pulse control signal generator for outputting an operation control signal in response to an output signal of the battery voltage comparator, and adjusting an on time of the operation control signal according to the magnitude of the output signal of the battery voltage detector; And a DC pulse generator configured to generate a DC pulse current in response to the pulse control signal output from the pulse control signal generator and apply the DC pulse current to the storage battery, and to adjust the magnitude of the DC pulse current according to an on time of the pulse control signal. In this case, when the state of the battery is bad, the magnitude of the pulse current is increased, and in the case of good condition, the magnitude of the pulse current is reduced to suppress the flow of unnecessary current, thereby effectively extending the life of the battery.

Description

Device for lengthening life span of storage battery by adjusting amplitude of pulse current according to storage power status}

BRIEF DESCRIPTION OF THE DRAWINGS In order to better understand the drawings cited in the detailed description of the invention, a brief description of each drawing is provided.

1 is a block diagram of a life extension device of a storage battery of the present invention connected to a storage battery.

FIG. 2 is a circuit diagram of an operating voltage comparator shown in FIG. 1.

3 is a circuit diagram of a storage battery and a voltage detector shown in FIG. 1.

4 is a circuit diagram of the battery and the DC pulse generator shown in FIG. 1.

5 is a block diagram of a life extension method of a storage battery according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for extending the life of a battery, and more particularly to an apparatus for extending the life of an automobile battery.

Storage batteries (lead storage batteries) supply direct current power by converting chemical energy into electrical energy. If the battery is used for a long time, the sulphation phenomenon in which the sulphate adheres to the positive electrode occurs, which shortens the life of the battery. Thus, various methods for extending the life of the battery have been studied.

Patent (Registration No. 338897) relates to a life extension device for efficient use of a battery, and is composed of a state monitor and a pulse generator to extend the life of the battery.

According to the conventional life extension device configured as described above, when the vehicle is started, a DC voltage of 13.2 to 13.8 volts is applied to the battery by converting the AC voltage generated from the generator, and the state monitoring unit is applied between the positive and negative poles of the battery. The driving signal is detected by generating a voltage of 13.2 volts or more, and the pulse generator generates a DC pulse and supplies the positive electrode of the battery to reactivate the sulfate accumulated in the electrode plate of the battery to return to the electrolyte.

However, according to the conventional battery life extension device as described above, since the DC pulse of the same size is always applied to the battery from the pulse generator during the operation of the vehicle, it is not effective to the unnecessary current flow. In addition, when the state of the battery is extremely poor, the recovery speed is slow, so that the battery does not function properly.

The present invention is to solve the disadvantages of the prior art, it is an object to provide a more effective battery life extension device by adjusting the size of the DC pulse applied to the battery according to the state of charge of the battery.

The present invention to achieve the above object

A lifespan extension device for a storage battery connected to a storage battery, comprising: an operation voltage setting unit for setting an operating voltage for operating the lifespan extension device of the storage battery; An operating voltage comparing unit which compares an externally input voltage with an operating voltage set by the operating voltage setting unit; A battery voltage detector detecting a charge voltage of the battery; A battery voltage comparing unit comparing the output voltage of the battery voltage detecting unit with a reference voltage; A pulse control signal generator for outputting an operation control signal in response to an output signal of the battery voltage comparator, and adjusting an on time of the operation control signal according to the magnitude of the output signal of the battery voltage detector; And a DC pulse generator configured to generate a DC pulse current in response to the pulse control signal output from the pulse control signal generator and apply the DC pulse current to the storage battery, and to adjust the magnitude of the DC pulse current according to an on time of the pulse control signal. It provides a life extension device of a storage battery provided.

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Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a block diagram of a battery life extension device according to the present invention. Referring to FIG. 1, the battery life extension device 105 includes an operating voltage setting unit 111, an operating voltage comparing unit 121, a battery voltage detecting unit 151, a battery voltage comparing unit 161, and a pulse control signal generating unit. 131, a DC pulse generator 141, a state display unit 171, and a power supply unit 181.

The operating voltage setting unit 111 sets an operating voltage Va for operating the life extension device 105 of the storage battery, and transmits the set operating voltage Va to the operating voltage comparing unit 121. The operating voltage Va of the operating voltage setting unit 111 is initially set by the manufacturer, but may be adjusted by the user. The operating voltage Va of the operating voltage setting unit 111 is determined by the voltage charged in the storage battery 101. For example, since the battery 101 used in a vehicle is 12 volts, the operating voltage Va is set to about 13 volts, and the battery 101 used in a bus, truck, etc. is 24 volts, so the operating voltage Va is set to about 25 volts. Since the storage battery 101 used in the electric forklift truck operating in an airport, etc. is 36 volts and 48 volts, the operating voltage Va is set to about 33 volts and 44 volts, respectively, and even in the case of the storage battery 101 used in communication equipment. The operating voltage setting applies equally.

The operating voltage comparing unit 121 compares the voltage Vext input from the outside with the operating voltage Va set by the operating voltage setting unit 111. That is, the operating voltage comparison unit 121 outputs a high level signal Vb when the external voltage Vext is higher than the operating voltage Va set by the operating voltage setting unit 111, and outputs an external voltage (Vb). When Vext is lower than the operating voltage Va of the operating voltage setting unit 111, a low level signal is output.

When the battery 101 is used in a motor vehicle, the charging voltage generated from the generator of the motor vehicle is applied to the battery 101, so that the external voltage Vext at this time is the voltage applied to the battery 101 from the generator. The operating voltage comparison unit 121 will be described in detail with reference to FIG. 2.

The battery voltage detector 151 detects the voltage charged in the battery 101. By detecting the voltage charged in the battery 101, the state of charge of the battery 101, that is, the internal impedance of the battery 101 can be known. The battery voltage detector 151 will be described in detail with reference to FIG. 3.

The battery voltage comparator 161 compares the output voltage Vc of the battery voltage detector 151 with a reference voltage, for example, 1.8 volts. That is, the battery voltage comparator 161 outputs a high level signal when the output voltage Vc of the battery voltage detector 151 is higher than the reference voltage, and outputs the output voltage of the battery voltage detector 151. When Vc) is lower than the reference voltage, a low level signal is output.

In addition, the reference voltage includes two reference voltages, that is, a first reference voltage and a second reference voltage (higher than the first reference voltage), and the output voltage Vc of the battery voltage detector 151 is the first reference voltage. When it is lower than the low level signal is output, when the output voltage (Vc) of the battery voltage detector 151 is higher than the first reference voltage and lower than the second reference voltage, and outputs a signal of the intermediate level, the battery voltage detector 151 When the output voltage (Vc) of the higher than the second reference voltage can be configured to output a high level signal. For example, the first reference voltage and the second reference voltage may be set to 1.8 volts and 2.3 volts, respectively.

As such, by comparing and comparing the output voltage Vc of the battery voltage detector 151 in various stages, the amount and time of the pulse current for charging the battery 101 can be adjusted step by step, thereby effectively improving the battery life extension device. Can be used.

The status display unit 171 may display the current voltage state of the storage battery 101 by using a light emitting diode (LED). That is, when the state of charge of the battery 101 is good, the green LED is turned on. When the state of charge of the battery 101 is medium, the yellow LED is turned on. When the state of charge of the battery 101 is poor, the red LED is turned on.

In addition, the status display unit 171 includes a single LED connected to the pulse control signal generator 131 to turn on the single LED only when the battery life extension device 105 is operating, thereby allowing the user to turn on the LED. It can also be seen that the battery life extension device 105 is in a normal operating state by watching the LED turn on.

The pulse control signal generator 131 generates the pulse control signal Ve in response to the output signal Vb of the operation voltage comparator 121 and the output signal Vd of the battery voltage detector 151. In other words, when the output signal Vb of the operation voltage comparator 121 is at a high level, the pulse control signal generator 131 may generate a pulse control signal according to the magnitude of the output signal Vd of the battery voltage detector 151. Adjust the output time of Ve). When the output voltage Vd of the battery voltage comparator 161 is at a low level, the pulse control signal generator 131 lengthens the pulse control signal Ve to be 5 [us] or longer, for example, and the battery voltage comparator 161. If the output voltage Vd of the?) Is at an intermediate level, the pulse control signal Ve is output at an intermediate time, for example, 2 to 5 [us], and if the output voltage Vd of the battery voltage comparator 161 is at a high level. The pulse control signal Ve is made shorter than 2 [us].

The DC pulse generator 141 generates a DC pulse current in response to the pulse control signal Ve output from the pulse control signal generator 131 and applies the DC pulse current to the storage battery 101, and outputs the pulse control signal Ve. Adjust the magnitude of DC pulse current according to time. That is, when the pulse control signal Ve is short, the DC pulse generator 141 applies a DC pulse current of 1 to 2 amps to the storage battery 101, and the pulse control signal Ve is 2 to 4 amps during the intermediate time. DC pulse current is applied to the storage battery 101, and when the pulse control signal Ve becomes long, a DC pulse current of 4 to 6 amp is applied to the storage battery 101.

The power supply unit 181 receives the voltage from the battery 101 and operates the voltage setting unit 111, the operation voltage comparator 121, the pulse control signal generator 131, the battery voltage comparator 161, and the state display unit 171. Supply the required power voltage. The power supply unit 181 includes a constant voltage circuit and always outputs a constant voltage.

The pulse control signal generator 131 and the battery voltage comparator 161 may be configured using one microprocessor.

As described above, when the voltage charged in the battery 101 is good, the DC pulse current applied to the battery 101 is reduced to reduce the magnitude of the current, and when the voltage charged in the battery 101 is normal, the battery 101 The DC pulse current to be applied to the battery is medium, and if the voltage charged in the battery 101 is poor, the DC pulse current applied to the battery 101 is increased to suppress unnecessary current flow, thereby preventing the electrode plate of the battery 101. Sulfate accumulated in the reactivated quickly, the battery 101 is quickly charged, and eventually the life of the battery is extended.

FIG. 2 is a circuit diagram of the operating voltage comparison unit 121 shown in FIG. 1. Referring to FIG. 2, the operation voltage comparator 121 may include a first resistor for inputting an external voltage Vext, a second resistor 212 connected between the first resistor 211 and a ground terminal GND, and a first resistor. A first capacitor N1 connected to the resistor 211 and the second resistor 212 and a first capacitor connected in parallel to the second resistor 212 to bypass an AC component included in the external voltage Vext ( 221, the first zener diode 231 connected between the first node N1 and the ground terminal GND, and the operating voltage Va of the operating voltage setting unit 111 and the voltage of the first node N1. And a comparator 241 for inputting and outputting the signal Vb.

The first zener diode 231 is energized when the voltage of the first node N1 reaches a first predetermined level, for example, 5 volts or more. As such, the first zener diode 231 prevents the overvoltage from being input to the comparator 241 by controlling the voltage of the operating voltage comparator 121 not to exceed the first predetermined level.

The comparator 241 outputs a high level voltage when the voltage of the first node N1 is higher than the voltage of the operating voltage setting unit 111, and the voltage of the first node N1 is determined by the operating voltage setting unit 111. If the voltage is lower than the operating voltage Va, a low level voltage is output.

3 is a circuit diagram of the battery voltage detection unit 151 connected to the storage battery 101 shown in FIG. Referring to FIG. 3, the battery voltage detector 151 is connected to a first diode 341 and a cathode of the first diode 341 connected to the positive electrode of the battery 101 and output from the first diode 341. A second capacitor 321 for bypassing the AC component included in the capacitor, a third resistor 311 connected in series to the first diode 341, and a fourth resistor connected between the third resistor 311 and the ground terminal GND. The second node N2 connecting the resistor 312, the third resistor 311 and the fourth resistor 312, and the second zener diode 331 connected between the second node N2 and the ground terminal GND. ).

The second zener diode 331 is turned on when the voltage of the second node N2 reaches a second predetermined level, for example, 5 volts or more. Accordingly, the output voltage Vc of the battery voltage detector 151 is controlled not to exceed the second predetermined level to prevent the overvoltage from being applied to the battery voltage comparator 161.

4 is a circuit diagram of a DC pulse generator 141 connected to the storage battery 101 shown in FIG. Referring to FIG. 4, the DC pulse generator 141 may include a PTC device 461, a first inductor 451 connected to the PTC switch 461, a second inductor 452 connected to the first inductor 451, and a first inductor 452. A second node having a third node N3 connecting the first inductor 451 and the second inductor 452 and a second anode connected to the other end of the second inductor 452 and having a cathode connected to one end of the first inductor 451. 441, the N-channel MOS field effect transistor 471, the fifth resistor 411 connected between the gate and the ground terminal GND of the MOS field effect transistor 471, and the third node N3 and the ground terminal ( And a third capacitor 421 connected between the GNDs.

A drain of the MOS field effect transistor 471 is connected to the second inductor 452, a source is connected to the ground terminal GND, and a gate is connected to the pulse control signal generator 131.

The PTC element 461 is a polyswitch for overcurrent protection.

The operation of the DC pulse generator 141 will be described. When the pulse control signal Ve is turned on, the MOS field effect transistor 471 becomes conductive, whereby the third capacitor 421 → the second inductor 452 → the MOS field effect transistor 471 → the third capacitor 421. Current flows through In addition, the positive terminal (+) of the battery 101 → PTC element 461 → the first inductor 451 → the second inductor 452 → the Moss field effect transistor 471 → the negative terminal of the battery 101 (−). Current flows through

Here, the conduction time of the MOS field effect transistor 471 is variable depending on the on time of the pulse control signal Ve. That is, the MOS field effect transistor 471 has a low current, for example, a current of 1 to 2 amps, when the on time of the pulse control signal Ve is short, that is, when the state of charge of the battery 101 is good. Is short, and if the ON time of the pulse control signal Ve is intermediate, that is, if the state of charge of the battery 101 is intermediate, the second inductor 452 has a medium current such as 2 to 4 amps. When the on time of the pulse control signal Ve is long, that is, when the state of charge of the battery 101 is poor, the current of the second inductor 452 is high, for example, 4 to 6 amperes. Conduct long to flow.

As described above, when the state of charge of the battery 101 is good, the amount of current for charging the battery 101 is reduced to increase the overall efficiency. When the state of charge of the battery 101 is poor, the battery 101 Effective control is possible for fast charging.

After the current having the appropriate magnitude is established in the second inductor 452, that is, after 2 to 5 [usec], the pulse control signal Ve is turned off, and thus the MOS field effect transistor 471 is turned off. During this period, the energy stored in the second inductor 452 is increased from the second diode 441 to the PTC element 461 to the positive terminal (+) of the battery 101 to the negative terminal of the battery 101 to the third. A direct current pulse current flows through the storage battery 101 through the path of the capacitor 421 to the second inductor 452. When all of the energy stored in the second inductor 452 is transferred to the battery 101, the DC pulse current becomes zero. While the MOS field effect transistor is off (471), the positive terminal (+) of the battery 101 → PTC element 461 → the first inductor 451 → the fourth capacitor 421 → the negative terminal of the battery 101 ( The current flows through-) so that the fourth capacitor 421 is charged.

5 is a block diagram of a life extension method of a storage battery 101 according to the present invention. Referring to FIG. 5, the life extension method of the storage battery 101 includes first to fourth steps. A life extension method of the storage battery 101 shown in FIG. 5 will be described with reference to FIG. 1.

In the first step 511, the battery 101 is classified into three states of good, normal, and poor according to the voltage charged in the battery 101.

In a second step 521, the voltage charged in the storage battery 101 is detected.

As a third step 531, the voltage charged in the storage battery 101 is compared to whether it is good, normal or bad. For example, the battery 101 is good if the detected voltage is 1.8 volts or less, and the battery 101 is normal if the detected voltage is between 1.8 and 2.3 volts, and the battery 101 is 2.3 volts or more. It is in a bad state.

Here, the state of the storage battery 101 can be classified in more detail according to the magnitude of the voltage or the state of charge of the voltage.

As a fourth step, the amount of DC pulse current is adjusted and applied to the storage battery 101 according to the comparison result of the third step. At this time, if the state of the battery 101 is good (533), the DC pulse current is applied less to the battery 101 (633), if the state of the battery 101 is normal (535) the DC pulse current Is applied to the storage battery 101 at an intermediate level (635), and if the state of the storage battery 101 is poor (537), a large amount of the DC pulse current is applied to the storage battery (637).

Repeat the first to fourth steps.

If the state of the storage battery 101 is satisfactory by the above method, the direct current applied to the storage battery 101 is reduced by decreasing the direct current pulse to charge the storage battery 101 and reducing the charging current. By increasing the pulse current to increase the charging current to suppress the flow of unnecessary current to reduce the current consumption of the battery 101 as well as effectively extend the life of the battery.

BEST MODE FOR CARRYING OUT THE INVENTION The best embodiments have been disclosed in the drawings and specification, and the specific terminology used herein is for the purpose of describing the invention only and is not intended to be limiting or limiting the scope of the invention, which is set forth in the claims. Thus, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from these. The true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

 As described above, according to the present invention, the storage battery 101 is classified into three states according to the voltage charged in the storage battery 101, and if the voltage state of the storage battery 101 is good, the direct current applied to the storage battery 101. By reducing the pulse current, the current for charging the battery 101 is reduced, and if the voltage state of the battery 101 is normal, the DC pulse current applied to the battery 101 is about medium, and the voltage state of the battery 101 is If it is poor, by increasing the DC pulse current applied to the battery 101, unnecessary flow of current is suppressed to prevent unnecessary consumption of the current of the battery 101, and the sulfate accumulated on the electrode plate of the battery 101. This quick reactivation effectively extends the life of the battery 101.

Claims (10)

delete In the battery life extension device connected to the battery, An operating voltage setting unit configured to operate an extension device of the storage battery and to set an operating voltage that can be adjusted by a user; An operating voltage comparing unit which compares an externally input voltage with an operating voltage set by the operating voltage setting unit; A battery voltage detector detecting a charge voltage of the battery; A battery voltage comparing unit comparing the output voltage of the battery voltage detecting unit with a reference voltage; A pulse control signal generator for outputting an operation control signal in response to an output signal of the battery voltage comparator, and adjusting an on time of the operation control signal according to the magnitude of the output signal of the battery voltage detector; And In response to the pulse control signal output from the pulse control signal generator generates a direct current pulse current applied to the storage battery, and provided with a direct current pulse generator for adjusting the magnitude of the direct current pulse current according to the on time of the pulse control signal. Life extension device of a storage battery, characterized in that. delete The method of claim 2, wherein the pulse control signal generation unit When the output voltage of the battery voltage comparator is low level, the pulse control signal is turned on for a long time. If the output voltage of the battery voltage comparator is a medium level, the pulse control signal is turned on to a medium level, and the output voltage of the battery voltage comparator is high. If the level, the pulse control signal is turned on for a short time, the battery life extension device. The method of claim 2, wherein the DC pulse generating unit When the pulse control signal output from the pulse control signal generator is turned on briefly, a DC pulse current of 1 to 2 amps is applied to the storage battery. When the pulse control signal is turned on to a medium level, a DC pulse current of 2 to 4 amps is applied. Applied to the battery, if the pulse control signal is turned on for a long time life extension device of the battery, characterized in that to apply a 4 to 6 ampere DC pulse current to the battery. The method of claim 2, wherein the operating voltage comparison unit A first resistor for inputting the external voltage; A second resistor connected between the first resistor and a ground terminal; A first node connecting the first resistor and a second resistor; A first capacitor connected in parallel with the second resistor to bypass an AC component included in the external voltage; A first Zener connected between the first node and the ground terminal, the first node being turned on when the voltage of the first node is greater than or equal to a first predetermined level to control the voltage of the first node not to exceed the first predetermined level; diode; And The voltage of the first node and the output voltage of the operating voltage setting unit are input. If the voltage of the first node is higher than the voltage of the operating voltage setting unit, a high level voltage is output, and the voltage of the first node is operated. And a comparator for outputting a low level voltage when it is lower than an output voltage of the voltage setting unit. The method of claim 2, wherein the battery voltage detection unit A first diode connected to the positive electrode of the storage battery; A second capacitor connected to a cathode of the first diode and bypassing an AC component included in a voltage output from the first diode; A third resistor connected in series with the first diode; A fourth resistor connected between the third resistor and a ground terminal; A second node connecting the third resistor and a fourth resistor; And A second node connected between the second node and the ground terminal, the second node being turned on when the voltage of the second node is greater than or equal to a second predetermined level to control the output voltage of the battery voltage detector not to exceed the second predetermined level; A device for extending the life of a storage battery, comprising a zener diode. The method of claim 2, wherein the DC pulse generating unit Third node; A first inductor having one end connected to a positive electrode of the storage battery and the other end connected to the third node; A second inductor, one end of which is connected to the third node; A second diode having an anode connected to the other end of the second inductor and a cathode connected to one end of the first inductor; A MOS field effect transistor having a drain connected to the other end of the second inductor and a source connected to the ground terminal; A third capacitor connected between the third node and a ground terminal; And A fifth resistor connected between the gate and the ground terminal of the MOS field effect transistor, And the gate of the MOS field effect transistor is connected to the pulse control signal generator. delete delete

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