KR200153244Y1 - Memory effect removing apparatus of rechargeable battery - Google Patents

Abstract

The present invention relates to a memory effect removing device of a rechargeable battery, in a charging device including a rectifier for charging a rechargeable battery, a VI converter (10) for converting the voltage output from the rechargeable battery (2) into a current (10) ), An amplifier 30 for amplifying the current converted by the VI converter 10 into a voltage signal of a predetermined level, a timer 50 for counting a predetermined time, and a current signal amplified by the amplifier 30; A microcomputer 60 for logically summing the time counted by the timer 50 to output a control signal, a decoder 40 for converting a control signal input from the microcomputer 60 into an operation signal, and varying the load; Currents applied from the rechargeable battery 2 connected to the plurality of switches 20, 22, 24 turned on or off by the operation signal of the decoder 40, and the plurality of switches 20, 22, 24, respectively. Light emitting diodes (D2) -D4), the voltage generator 80 generating the voltage rectified by the control signal of the microcomputer 60 to charge the rechargeable battery 2, and the rechargeable battery 2 stored in the microcomputer 60. Including a memory unit 70 for inputting and outputting data, the life of the rechargeable battery is extended by minimizing the memory effect remaining in the battery when charging the rechargeable battery.

Description

Memory effect remover of rechargeable battery

The present invention relates to a device for charging a rechargeable battery, and in particular, the memory effect removal device of a rechargeable battery that extends the life of the rechargeable battery by minimizing the memory effect remaining in the battery when charging the rechargeable battery with a charger. It is about.

Batteries are commonly used as a power source for various electrical appliances used in portable applications. Such a battery has a disposable battery which is limited to further reuse when it is used up after being used once, and a rechargeable battery that can be reused more than a predetermined number of times by charging a current supplied from the outside using a charger.

The rechargeable battery is converted into a constant size through a rectifier 1 for converting an AC current supplied from an external AC power source (AC110-220V) into a DC current in the configuration diagram of the AC / DC converter of FIG. 1. DC current is charged in the rechargeable battery 2. When a predetermined use time elapses, the rechargeable battery 2 cannot perform its function because the electric current output from the battery is weak and it is impossible to operate the electrical appliance. Thus, it was possible to charge using a charger having the rectifier 1.

Conventionally, when charging a rechargeable battery by smoothing an alternating current with a direct current, if a direct current is charged through the rectifier while the rechargeable battery is not completely discharged, the battery does not reach the maximum capacity to be charged. A memory effect occurs when charging is complete. That is, in a state in which the rechargeable battery that is discharged below a certain voltage is not completely discharged, a memory effect occurs in the rechargeable battery, and thus, the current charged from the outside is not fully charged. Therefore, due to the memory effect, the use time of the rechargeable battery whose charging power is reduced is shortened, thereby increasing the number of charges. Therefore, the number of times of charging and using the rechargeable battery is reduced, thereby reducing the service life.

The present invention was devised in view of the above problems, and when the discharged rechargeable battery was charged, the memory effect of the rechargeable battery was maximized by completely discharging the rechargeable battery to remove the memory effect. It is an object to provide a removal device.

1 is a configuration diagram of a conventional AC / DC converter for charging a rechargeable battery,

Figure 2 is a block diagram of a memory effect removing device of a rechargeable battery according to the present invention.

* Explanation of symbols for main parts of the drawings

10: V-I converter 20,22,24: switch

30: amplifier 40: decoder

50: timer 60: microcomputer

70: memory 80: voltage generator

D1: Reverse voltage prevention diode D2-D4: Light emitting diode

In order to achieve the above object, the present invention provides a charging device including a rectifier for charging a rechargeable battery, the VI (Voltage-Current (voltage-current)) converter for converting the voltage output from the rechargeable battery into a current And an amplifier for amplifying the current converted by the VI converter into a voltage signal of a predetermined level, a timer for counting a predetermined time, and a control signal by logically summing the current signal amplified by the amplifier and the time counted in the timer. A microcomputer for outputting, a decoder for varying the load by converting a control signal input from the microcomputer into an operation signal, a plurality of switches turned on or off by an operation signal of the decoder, and connected to the plurality of switches for charging A light emitting diode for discharging a current applied from a battery, and a voltage rectified by the control signal of the microcomputer And a memory unit for inputting and outputting data relating to the rechargeable battery stored in the microcomputer.

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

2 is a block diagram of an apparatus for maximizing charging of a battery by removing the memory effect of the rechargeable battery.

The VI converter 10 converts a weakly applied voltage signal from the rechargeable battery 2 discharged to a predetermined voltage into a current signal, and the amplifier 30 converts the current signal converted from the VI converter 10 into a constant size. Amplified by the current signal of the applied to the microcomputer 60.

The timer 50 counts a predetermined period of time, and the microcomputer 60 performs an operation on a logical sum of the current signal sensed by the amplifier 30 and the time signal counted from the timer 50 to perform the operation of the rechargeable battery. Determine the state of charge completion or complete discharge.

The memory unit 70 outputs data information on the rechargeable battery 2 to the microcomputer 60 or stores data on a charge / discharge state of the rechargeable battery 2.

The decoder 40 selects the number of connections of the load as a control signal relating to the discharge state of the rechargeable battery 2 determined by the microcomputer 60, and in a state where the discharge degree of the rechargeable battery 2 is relatively small. By reducing the number of loads to be discharged and increasing the number of loads to be discharged in a state where the degree of discharge is relatively high, the fast discharge and complete discharge of the rechargeable battery 2 are achieved.

A plurality of switches 20, 22, and 24 are connected to light emitting diodes D2-D4, which are loads that are turned on or off by the operation signal of the decoder 40 to discharge the rechargeable battery 2. A diode D1 for preventing reverse voltage is connected between the rechargeable battery 2 and the switches 20, 22, and 24 so that the rechargeable battery 2, the light emitting diodes D2-D4, or a decoder may be reversed. Prevent voltage from being applied. The light emitting diodes D2-D4 have a predetermined resistance component, and convert the current signal applied from the rechargeable battery into an optical signal to discharge the rechargeable battery 2. In place of the light emitting diodes D2-D4, a discharge element having a predetermined resistance component can be connected.

The voltage generator 80 charges a voltage to the rechargeable battery 2 with a control signal applied from the microcomputer 60, and charges the battery 2 with a current signal input from the amplifier 30 at the microcomputer 60. Is determined to be fully discharged, and when the discharged state falls below the reference value, the voltage generator 80 is driven to generate a voltage of a predetermined size to charge the rechargeable battery 2. The voltage generator 80 converts AC power applied from the outside into DC power to supply the charging voltage to the rechargeable battery 2.

The operation of the memory effect removing device of the rechargeable battery configured as described above will be described in detail.

Rechargeable batteries (2) used in portable electric appliances, etc., are discharged after a certain time or number of times of use and require recharging. Electrical appliances are discharged while the rechargeable batteries (2) are charged because the working voltage is fixed. In this case, the reference voltage at which the electrical appliance can operate falls below the reference level. At this time, if the rechargeable battery 2 discharged below the reference voltage is continuously used, the electric product may not be operated and may cause a malfunction of the electric product.

Therefore, since the rechargeable battery 2 should always be charged above a certain voltage, a charging device for charging the rechargeable battery 2 is used. However, when the rechargeable battery 2 falls below the reference voltage required by the electrical appliance, the rechargeable battery 2 cannot perform the function of the rechargeable battery 2 to be recharged. The undischarged state is maintained. When the rechargeable battery 2 is mounted in the charging device for full discharge and full charge, the residual discharge voltage in the rechargeable battery 2 is output to the V-I converter 10. The VI converter 10 converts the voltage signal sensed from the rechargeable battery 2 into a current signal, and the converted current signal is amplified into a current signal of a predetermined level through the amplifier 30 and input to the microcomputer 60. . The microcomputer 60 calculates a logical sum of the current signal input from the amplifier 30 and the time signal counted from the timer 50, compares the calculated value with data information stored in the memory unit 70, and determines a control signal. Outputs That is, the microcomputer 60 determines the discharge rate by comparing the degree of discharge of the rechargeable battery 2 with the data stored in the memory unit 70.

The decoder 40 selects the light emitting diodes D2-D4, which are loads for converting a control signal output from the microcomputer 60 into an operation signal to discharge residual voltage. The decoder 40 selectively turns on the switches 20, 22, and 24 to connect the voltage remaining in the rechargeable battery 2 to the light emitting diodes D2-D4 for complete discharge. That is, a plurality of light emitting diodes D2 selected through the switched switches 20, 22, and 24 may have a residual voltage from the rechargeable battery 2 that is not fully discharged and has a voltage memorized, and has passed through the reverse voltage preventing diode D1. Discharge at -D4). Therefore, as the predetermined time elapses, the rechargeable battery 2 is completely discharged, which causes the microcomputer 60 to store the residual current of the rechargeable battery 2 applied through the VI converter 10 and the amplifier 30. This is because the judgment is made to keep the switches 20, 22, and 24 on the decoder 40 continuously.

If it is determined that the rechargeable battery 2 has been completely discharged by the light emitting diodes D2-D4, the microcomputer 60 outputs a control signal to the decoder 40 so that the switches 20, 22, and 24 are on. Off and operate voltage generator 80. The voltage generator 80 converts the AC power applied from the outside into a DC power suitable for the rechargeable battery 2 to charge the rechargeable battery 2. At this time, since the rechargeable battery 2 is completely discharged, charging is easily performed. Thus, since the rechargeable battery 2 is fully recharged and then recharged, the memory effect of the rechargeable battery 2 can be minimized.

When the rechargeable battery 2 receives the voltage from the voltage generator 80 and is fully charged, the rechargeable battery 2 is no longer charged. At this time, the microcomputer 60 temporarily stops the operation of the voltage generator 80. At this time, the microcomputer 60 determines whether the charging is completed by determining the charging current input from the charging battery 2 charged through the VI converter 10 and the amplifier 30, and the data of the memory unit 70 is determined. The charging completion state of the rechargeable battery 2 is determined using the information. Accordingly, when the microcomputer 60 determines that the charging current of the rechargeable battery 2 is less than or equal to the reference value, the microcomputer 60 continuously operates the voltage generator 80 and outputs a control signal to continue charging, but the rechargeable battery 2 When it is determined that the state of charge has been made above the reference value, the operation of the voltage generator 80 is stopped to terminate the charge.

When the device for removing the memory effect of the rechargeable battery is attached to a telephone or a portable electric appliance, the life of the rechargeable battery of the electrical appliance can be increased, and the loss of the electrical appliance can be minimized.

As described above, the present invention recharges the rechargeable battery through a voltage generator after fully discharging the rechargeable battery through a load such as a light emitting diode, thereby minimizing the memory effect of the rechargeable battery. Has the effect of increasing the filling rate and extending the service life to the maximum.

Claims (1)

In the charging device including a rectifier for charging a rechargeable battery, A V-I converter 10 for converting a voltage output from the rechargeable battery 2 into a current; An amplifier 30 for amplifying the current converted by the V-I converter 10 into a voltage signal having a predetermined level; A timer 50 for counting a certain time, A microcomputer 60 for outputting a control signal by logically summing the current signal amplified by the amplifier 30 and the time counted by the timer 50; A decoder 40 for changing a load by converting a control signal input from the microcomputer 60 into an operation signal, A plurality of switches 20, 22, and 24 turned on or off by an operation signal of the decoder 40; A light emitting diode (D2-D4) connected to the plurality of switches 20, 22, and 24 to discharge current applied from the rechargeable battery 2, A voltage generator 80 generating a voltage rectified by the control signal of the microcomputer 60 to charge the rechargeable battery 2; Memory effect removal device of the rechargeable battery, characterized in that it comprises a memory unit 70 for inputting and outputting data relating to the rechargeable battery (2) stored in the micom (60).