KR100532293B1 - Multiple Battery Charger And Charge Control Method - Google Patents

Abstract

The present invention relates to a charger for a rechargeable battery, and in particular, when charging a battery mounted in a plurality of pockets so that it can be charged corresponding to the type of battery.

When the rechargeable batteries mounted in the first and second pockets are simultaneously charged, the type of battery mounted in the first pocket is recognized. Then, the voltage according to the recognized battery type is supplied to the first pocket, and the voltage according to the recognized battery type is dropped to the set level so as to be supplied to the second pocket to enable simultaneous charging.

Description

Multiple Battery Charger And Charge Control Method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charger for a rechargeable battery, and more particularly to a multiple battery charger and a charging control method thereof capable of charging corresponding to a type of battery when charging a battery mounted in a plurality of pockets.

In general, a charger is used to charge a rechargeable battery installed in a portable communication device, and when a plurality of batteries having a limited charging voltage such as lithium-ion (Li-ion) are charged at the same time, a DC power source ( DC Power Source) required as many batteries as were simultaneously charged. Because the rechargeable battery such as Li-ion is limited to 4.1V or 4.2V depending on the type, the manufacturer of the terminal that needs the battery is the reason for supply, price, capacity, etc. This is because there is no room to apply either 4.1V or 4.2V. Therefore, in developing a charger, since both 4.1V or 4.2V cells should be considered, there must be a DC power source as much as the number of charges.

Accordingly, an object of the present invention is to provide a multiple battery charger and a charge control method thereof that can reduce the size and price of the charger to solve the above problems.

Another object of the present invention is to provide a multiple battery charger capable of simultaneously charging a plurality of rechargeable batteries of different types and a charging control method thereof.

Still another object of the present invention is to provide a multiple battery charger capable of sequentially charging a plurality of rechargeable batteries of different types and a charging control method thereof.

The present invention for achieving the above object in the charger having a plurality of pockets in accordance with the priority to recognize the type of rechargeable battery mounted in the plurality of pockets to control the corresponding voltage is supplied to the type of the battery to charge It is characterized by.

The present invention for achieving the above object is to recognize the type of the battery mounted in the first pocket when the rechargeable battery mounted in the first and second pocket at the same time, the voltage according to the type of the recognized battery is first The battery is supplied to the pocket, and the voltage according to the recognized battery type is dropped to a set level so that the battery is supplied to the second pocket so that simultaneous charging is possible.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1A to 1C are circuit diagrams of a multiple battery charger according to an exemplary embodiment of the present invention.

The input terminal 10 is a terminal for inputting power of AC 110 to 220V. The full wave rectifier 12 includes bridge diodes D1 to D4, a resistor R1, and a capacitor C1, and rectifies AC power applied from the input terminal 10 to output a smoothed DC voltage. Resistor R2 is a starting resistor for initial operation. Zener diode ZD1 and diode D5 block a high voltage above a set voltage. The transformer 18 inputs the DC voltage output from the full wave rectifying unit 12 and induces it from the primary side coil L1 to the secondary side coils L2, L3, and L4. The power switch 14 switches the voltage level induced from the primary coil L1 of the transformer 18 to the secondary coils L2, L3, L3, and L4 by switching on / off according to a predetermined switching control signal. Control to adjust. The first rectifier 16 includes a resistor R3, a diode D6, and a capacitor C2, and rectifies a voltage induced by the secondary coil L2 of the transformer 18 to output a stable DC voltage. The operating voltage of the power switch 14 is provided. The second rectifier 20 includes a diode D7 and a capacitor C6, and rectifies and outputs the voltage induced by the secondary coil L3 of the transformer 18. The smoothing part 24 is composed of the choke coil CL1 and the capacitor C8, and smoothes the voltage rectified from the second rectifying part 20 to supply the charging voltage of the battery. The third rectifier 22 includes a diode D8 and a capacitor C7, and rectifies the voltage induced by the secondary side coil L4 of the transformer L4 to provide the regulator 26. The regulator 26 receives the voltage rectified from the third rectifier 22 and adjusts the voltage to a predetermined voltage level to provide the power supply voltage Vcc for operating the charger. The charge detection unit 30 includes resistors R5, R6, R7, and R8, a transistor Q1, and an operational amplifier OP1, and detects a current value of the DC power supplied from the smoothing unit 24 to detect a constant current. While controlling the flow, a voltage for detecting the charge amount is output in accordance with the flowing current value. The charging voltage supply control unit 28 supplies or blocks the charging voltage by the charging on / off control signal output from the microprocessor 36. The charging voltage supply control unit 28 may include a charging voltage drop unit connected to a first charging voltage switching unit 31, a second charging voltage switching unit 33, and a front end of the second charging voltage switching unit 33. 32). The first charge voltage switching unit 31 is composed of a diode D9, a resistor R9, a transistor Q5, and a FET Q3 and is connected to the pocket A by a charge on / off control signal output from the microprocessor 36. The charging voltage is supplied or cut off to the mounted first battery. The second charge voltage switching unit 33 includes a resistor R10, a transistor Q6, and a FET Q4, and includes a second battery mounted in the pocket B by a charge on / off control signal output from the microprocessor 36. Supply or cut off the charging voltage. The charging voltage drop unit 32 may include one or several diodes or transistors, and is configured to set the charging voltage supplied through the charging amount detector 30 when the charging voltage drop unit 32 is switched on by the second charging voltage switching unit 33. Drop it. The voltage adjusting unit includes a first charging voltage setting unit 38, a second charging voltage setting unit 40, an output voltage selection switch 42, and a charging voltage control unit 34. The first charging voltage setting unit 38 includes resistors R15, R16, and R17, a variable resistor VR1, and a transistor Q7. The first charging voltage setting unit 38 sets the first charging voltage according to the type sensing of the battery mounted in the pocket A. do. The second charging voltage setting unit 40 includes resistors R18, R19, and R20, a variable resistor VR2, and a transistor Q8, and sets a second charging voltage according to the type of battery mounted in the pocket B. do. The output voltage selection switch 42 selects and outputs one of the voltages set by the first charging voltage setting unit 38 or the second charging voltage setting unit 40 under the control of the microprocessor 36. The charging voltage controller 34 includes resistors R11, R12, R13, and R14, operational amplifiers OP2 and OP3, a transistor Q2, and a photocoupler PC1, and from the output voltage selection switch 42. The power switch 14 is controlled by outputting a switching control signal so that a charging voltage corresponding to the type of battery is constantly supplied by comparing the selected charging voltage with a preset reference voltage. The microprocessor 36 has a resistor R13 and a resistor R14 connected to the power supply voltage VCC and connected to the C / F terminals of the first and second batteries, according to the type of battery in the first and second batteries. Recognizing the type of battery by recognizing the installed resistance value, outputs the first and second charging voltage setting control signal according to the recognized battery type, switching for selecting the charging voltage of Pocket A or Pocket B A display for outputting a control signal, sensing a voltage value detected by the charge amount detecting unit 30 to recognize a fully charged state, outputting a charge on / off control signal, and displaying a state of charge of the first and second batteries Output a control signal. The first LED 44 and the second LED 46 are composed of a pair of red LEDs and green LEDs, respectively, and indicate a charging state under the control of the microprocessor 36. When fully charged, the green LEDs are turned on. When charging, red LED turns on. When the rechargeable batteries mounted in the pocket A and the pocket B are simultaneously charged, the red LED and the green LED are both turned on to display the charging state of the second battery in yellow so that the second charging voltage is lower than the first charging voltage. Make sure you are informed.

2 is a flowchart illustrating a charging control when a plurality of batteries are mounted in a battery pocket according to an exemplary embodiment of the present invention.

3 is a flowchart illustrating a charging control when one battery is mounted in a battery pocket according to an exemplary embodiment of the present invention.

4 is a waveform diagram of a charge voltage and a charge current detection according to an embodiment of the present invention.

301 is a voltage waveform charged by a battery mounted in pocket A, 302 is a voltage waveform charged by a battery mounted in pocket B, 303 is a current waveform change example charged by a battery mounted in pocket A, and 304 This is an example of changing the current waveform charged by the battery mounted in the pocket B.

The operation of the preferred embodiment of the present invention will be described in detail with reference to FIGS. 1A to 1C and FIGS. 2 to 4.

First, the operation of charging when both batteries are installed in the pocket A or the pocket B will be described with reference to the flowchart of FIG. 2. In step 101, the microprocessor 36 stores the battery in the pocket A. FIG. If the battery is not installed in the pocket A, go to step 102. In step 102, the microprocessor 36 checks whether the battery is installed in the pocket B. If the battery is installed in the pocket B, the microprocessor 36 proceeds to step 103 to perform the single battery charging routine shown in FIG. However, if the battery is installed in the pocket A in step 101, the flow proceeds to step 104 and checks whether the battery is installed in the pocket B. If the battery is not installed in the pocket B, the flow proceeds to step 103. However, if the battery is installed in the pocket B, the process proceeds to step 105, the microprocessor 36 checks whether the battery mounted in the pocket A is 4.1V cell (Cell). At this time, the microprocessor 36 recognizes whether the battery is 4.1V or 4.2V. In the battery, different resistors are connected to the C / F terminal and connected to the ground according to the type of battery. Therefore, since the divided voltage between the resistor R13 and the resistor installed inside the battery is applied to the microprocessor 36, the microprocessor 36 may recognize the type of battery mounted in the pocket A. FIG. If the battery mounted in the pocket A is not a 4.1V cell, the process proceeds to step 106 and the microprocessor 36 outputs the battery charge selection signal of the pocket A to the selection terminal of the output voltage selection switch 42 through the port P0. do. The output voltage selector switch 42 then switches between the common terminal c and the terminal a. Thereafter, in step 107, the microprocessor 36 outputs a low signal through the port P6 to set the output voltage applied to the pocket A to 4.2V. When the high signal is output to the port P6 of the microprocessor 36, the transistor Q7 is turned off. When the transistor Q7 is turned off, the divided voltage by the resistor R16, the variable resistor VR1, and the resistor R17 is detected, and the divided voltage corresponds to a charging voltage corresponding to the type of the rechargeable battery of the pocket A. Used to set the voltage. In this case, the divided voltage detected by the first charging voltage setting unit 38 is applied to the inverting terminal (-) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. The voltage is induced to the secondary side of the transformer 18 to be lowered, and when the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the photocoupler PC1 is turned off. The light emitting diode PCa does not emit light, and the light receiving transistor PCb is turned off to control the power switch 14 so that the voltage induced at the secondary side of the transformer 18 is increased. By repeating quickly, the output voltage is constantly limited to 4.2V, the set level.

However, if the battery mounted in the pocket A is 4.1V cell in step 105, the microprocessor 36 proceeds to step 108 and the microprocessor 36 selects the output voltage selector switch 42 through the port P0. Output to the terminal. The output voltage selector switch 42 then switches between the common terminal c and the terminal a. Thereafter, in step 109, the microprocessor 36 outputs a low signal through the port P6 to set the output voltage of the pocket A to 4.1V. When the low signal is output to the port P6 of the microprocessor 36, the transistor Q7 is turned on. When the transistor Q7 is turned on, the combined resistance by the resistors R15 and R16 and the divided voltage by the variable resistor VR1 and the resistor R17 are detected, and the divided voltage corresponds to the type of the rechargeable battery of the pocket A. It is used as the voltage to set the corresponding charging voltage. The divided voltage detected by the first charging voltage setting unit 38 is applied to the inverting terminal (−) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 emits light. Since the light receiving transistor (PCb) is turned off, the output voltage is increased by controlling the power switch 14. By repeating this operation rapidly, the output voltage is constantly set to 4.1V, which is a set level. Then, in step 110, the microprocessor 36 outputs a high signal, which is a charge-on signal, through the ports P1 and P2 to start charging, and the first LED 44 indicating the charging state is red. The second LED 46 is controlled to be yellow, and the transistors Q5 and Q6 are turned on when the high signal, which is a charge-on signal, is output through the ports P1 and P2 of the microprocessor 36. When the transistors Q5 and Q6 are turned on, a low potential is applied to the gates of the FETs Q3 and Q4 so that the FETs Q3 and Q4 are turned on so that the charging voltage output from the smoothing part 24 is applied to the resistor R5. It is supplied to the battery mounted in the pocket A via the diode D9, and is supplied to the battery mounted in the pocket B via the diode D10 and the voltage drop unit 32. At this time, the voltage drop unit 32 is a diode ( The charging voltage outputted through D10) is dropped to a preset level so that when the batteries mounted in the pocket A and the pocket B are charged at the same time, the battery mounted in the pocket A is larger than the battery mounted in the pocket B. As seen from the time point T1 of the voltage detection waveform diagram of 4, Low charging is completed After the charging is started, it is necessary to check whether the charging is completed, but the charging completion check recognizes the voltage applied to the resistor R8 to recognize the preset current value and checks it from the smoothing part 24. When the charging voltage is supplied, a current flows through the resistor R5, and the current value is amplified by the operational amplifier OP1 and applied to the base of the transistor Q1. Accordingly, the transistor Q1 linearly changes the output voltage according to the current amplifier value of the operational amplifier OP1. According to the operating state of the transistor Q1, the voltage applied to the resistor R8 changes linearly, and the microprocessor 36 recognizes the voltage applied to the resistor R8 and converts it into a current value, thereby providing resistance R5. The current value flowing in can be recognized. Thus, in step 111, the microprocessor 36 recognizes the voltage applied to the resistor R8 through the port Io and checks whether it is smaller than 120 mA, which is a preset charging current. If the charging current is larger than 120 mA, the charging is not completed yet. Determine and continue charging. However, when the charging current is less than 100 mA, the microprocessor 36 recognizes that the charging of the battery mounted in the pocket A is completed, and in step 112, the microprocessor 36 outputs a low signal that is the battery charging off signal of the pocket A through the port P1. The first LED 44 is displayed in green to indicate that charging of the battery of the pocket A is completed. When the low signal, which is a battery charge-off signal, is output to the port P1 of the microprocessor 36, the transistor Q5 is turned off, and when the transistor Q5 is turned off, the FET Q3 is turned off to thereby resist. The charging voltage applied to the battery of the pocket A applied through R5 is cut off to complete the charging of the battery mounted in the pocket A.

Thereafter, in step 113, the microprocessor 36 checks whether the battery mounted in the pocket B is a 4.2V cell. At this time, since the divided voltage between the resistor R14 and the resistor installed inside the battery is applied to the microprocessor 36, the microprocessor 36 may recognize the type of battery mounted in the pocket B. If the battery mounted in the pocket B is not a 4.2V cell, the process proceeds to step 114 and the microprocessor 36 outputs the battery charge selection signal of the pocket B to the selection terminal of the output voltage selection switch 42 through the port P0. do. The output voltage selector switch 42 then switches between the common terminal c and the terminal b. Thereafter, in step 115, the microprocessor 36 outputs a low signal through the port P7 to set the output voltage of the pocket B to 4.1V. When the low signal is output to the port P7 of the microprocessor 36, the transistor Q8 is turned on. When the transistor Q8 is turned on, the resistors R18 and R19 detect the divided voltages of the composite resistors, the variable resistors VR2 and the resistors R20, and the divided voltages correspond to the type of the rechargeable battery of the pocket B. It is used as the voltage to set the corresponding charging voltage. In this case, the divided voltage detected by the second charging voltage detector 40 is applied to the inverting terminal (−) of the comparator OP2 of the charging voltage controller 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator OP2 is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 does not emit light. Then, the light receiving transistor PCb is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.1 V, which is a set level.

However, if the battery mounted in the pocket B is 4.2V cell in step 113, the microprocessor 36 proceeds to step 116 and the microprocessor 36 selects the output voltage selector switch 42 through the port P0. Output to the terminal. The output voltage selector switch 42 then switches between the common terminal c and the terminal b. Thereafter, in step 117, the microprocessor 36 outputs a high signal through the port P7 to set the output voltage of the pocket B to 4.2V. When the high signal is output to the port P7 of the microprocessor 36, the transistor Q8 is turned off. When the transistor Q8 is turned off, the divided voltage by the resistor R19, the variable resistor VR2, and the resistor R20 is detected, and the divided voltage corresponds to the charging voltage corresponding to the type of the rechargeable battery of the pocket B. Used to set the voltage. In this case, the divided voltage detected by the second charging voltage setting unit 40 is applied to the inverting terminal (-) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 emits light. The light receiving transistor (PCb) is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.2 V, which is a set level. After setting the charging voltage according to the type of battery mounted in B, the microprocessor 36 controls the second LED 46 displaying the charging state to be displayed in red in step 118. The charging voltage output from the active part 24 is applied to the battery mounted in the pocket B via the resistor R5 via the diode D10 and the voltage drop part 32. Thus, the battery mounted in the pocket B is shown in Fig. 4. Charging is completed at the time T2, as shown in the waveform diagram of the charging voltage detection of the microprocessor 36. After the charging is started, the microprocessor 36 recognizes the voltage applied to the resistor R8 through the port Io in advance in step 119. If the charging current is greater than 120mA, it is determined that the charging is not completed yet.If charging current is less than 120mA, the charging is continued. In step 120, the microprocessor 36 outputs a low signal that is a battery charge-off signal of the pocket B through the port P1, and the first LED 44 is displayed in green. When the low signal, which is the battery charge-off signal, is output to the port P1 of the microprocessor 36, the transistor Q6 is turned off and the transistor Q6 is displayed. When is turned off, the FET Q4 is turned off and applied to the battery of the pocket B through the resistor R5, the diode D10, and the voltage drop unit 32. When the device having the large voltage drop is used in the voltage drop unit 32, the batteries mounted in the pocket A and the pocket B may be sequentially charged, and when the device having the small voltage drop (for example, 0.1 V) is used, the pocket You can charge A and Pocket B at the same time.

In the flowchart of FIG. 2, an operation of charging when both batteries are installed in the pockets A and B is described. However, in the flowchart of FIG. 3, an operation when only one battery is installed in the pocket A or the pocket B is described.

In step 201, the microprocessor 36 checks whether the battery is installed in the pocket A. If the battery is installed in the pocket A, the microprocessor 36 proceeds to step 202. In step 202, the microprocessor 36 checks whether the battery installed in the pocket A is a 4.2V cell. At this time, since the divided voltage between the resistor R13 and the resistor installed inside the battery is applied to the microprocessor 36, the microprocessor 36 may recognize the type of battery mounted in the pocket A. FIG. If the battery mounted in the pocket A is not a 4.2V cell, the microprocessor 36 proceeds to step 205 and the microprocessor 36 outputs the battery charge selection signal of the pocket A to the selection terminal of the output voltage selection switch 42 through the port P0. do. The output voltage selector switch 42 then switches between the common terminal c and the terminal a. Thereafter, in step 206, the microprocessor 36 outputs a high signal through the port P6 to set the output voltage of the pocket A to 4.2V. When the high signal is output to the port P6 of the microprocessor 36, the transistor Q7 is turned off. When the transistor Q7 is turned off, the divided voltage by the resistor R15, the variable resistor VR1, and the resistor R17 is detected, and the divided voltage corresponds to a charging voltage corresponding to the type of the rechargeable battery of the pocket A. Used to set the voltage. In this case, the divided voltage detected by the first charging voltage setting unit 38 is applied to the inverting terminal (−) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 does not emit light, thereby receiving a light receiving transistor. (PCb) is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.2V, which is a set level.

However, if the battery installed in the pocket A is not a 4.2V cell in step 202, the microprocessor 36 proceeds to step 203, and the microprocessor 36 outputs the battery charge selection signal of the pocket A through the port P0. Output to the selection terminal of). The output voltage selector switch 42 then switches between the common terminal c and the terminal a. Thereafter, in step 204, the microprocessor 36 outputs a low signal through the port P6 to set the output voltage of the pocket A to 4.1V. When the low signal is output to the port P6 of the microprocessor 36, the transistor Q7 is turned on. When the transistor Q7 is turned on, the combined resistance of the resistors R15 and R16 and the divided voltage by the variable resistor VR1 and the resistor R17 are detected, and the divided voltage corresponds to the type of the rechargeable battery of the pocket A. It is used as the voltage to set the charging voltage. In this case, the divided voltage detected by the first charging voltage setting unit 38 is applied to the inverting terminal (−) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 does not emit light, thereby receiving a light receiving transistor. (PCb) is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.1 V, which is a set level.

Thereafter, in step 207, the microprocessor 36 outputs a high signal, which is a charge-on signal, through the port P1 to start charging, and controls the first LED 44 displaying the charging state to be displayed in red. The transistor Q5 is turned on when the high signal, which is a charge-on signal, is output through the port P1 of the microprocessor 36. When the transistor Q5 is turned on, a low potential is applied to the gate of the FET Q3 so that the FET Q3 is turned on so that the charging voltage output from the smoothing part 24 passes through the diode D9 through the resistor R5. It is charged by the battery installed in Pocket A. After doing this, in step 208, the microprocessor 36 recognizes the voltage applied to the resistor R8 through the port Io and checks whether it is smaller than the preset charging current of 100 mA. If the charging current is larger than 100 mA, the charging is not completed yet. It is judged to continue charging. However, if the charging current is less than 100mA, the microprocessor 36 recognizes that the charging of the battery installed in the pocket A is completed, and outputs a low signal indicating the battery charging off signal of the pocket A through the port P1 in step 209. The first LED 44 is displayed in green to indicate that charging of the battery of the pocket A is completed. When the low signal, which is a battery charge-off signal, is output to the port P1 of the microprocessor 36, the transistor Q5 is turned off, and when the transistor Q5 is turned off, the FET Q3 is turned off to thereby resist. The charging voltage applied to the battery of the pocket A is cut off through the R5 and the diode D9 to complete the charging of the battery mounted in the pocket A.

However, if the battery is not installed in the pocket A in step 201, the microprocessor 36 checks whether the battery is installed in the pocket B. If the battery is not installed in the pocket B, the process returns to step 201. If you have a battery in Pocket B, go to step 211. In step 211, the microprocessor 36 checks whether the battery mounted in the pocket B is a 4.1V cell. At this time, since the divided voltage between the resistor R14 and the resistor installed inside the battery is applied to the microprocessor 36, the microprocessor 36 may recognize the type of battery mounted in the pocket B. If the battery installed in the pocket B is not a 4.1V cell, the microprocessor 36 proceeds to step 214 and the microprocessor 36 outputs the battery charge selection signal of the pocket B to the selection terminal of the output voltage selection switch 42 through the port P0. do. The output voltage selector switch 42 then switches between the common terminal c and the terminal b. Thereafter, in step 115, the microprocessor 36 outputs a high signal through the port P7 to set the output voltage of the pocket B to 4.2V. When the high signal is output to the port P7 of the microprocessor 36, the transistor Q8 is turned off. When the transistor Q8 is turned off, the combined resistance by the resistor R19 and the divided voltage by the variable resistor VR2 and the resistor R20 are detected, and the divided voltage corresponds to the type of the rechargeable battery of the pocket B. It is used as the voltage to set the charging voltage. In this case, the divided voltage detected by the second charging voltage setting unit 40 is applied to the inverting terminal (-) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 does not emit light, thereby receiving a light receiving transistor. (PCb) is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.2V, which is a set level.

However, if the battery mounted in the pocket B is 4.1V cell in step 211, the microprocessor 36 proceeds to step 212 and the microprocessor 36 selects the output voltage selector switch 42 through the port P0. Output to the terminal. The output voltage selector switch 42 then switches between the common terminal c and the terminal b. Thereafter, in step 213, the microprocessor 36 outputs a high signal through the port P7 to set the output voltage of the pocket B to 4.1V. When the high signal is output to the port P7 of the microprocessor 36, the transistor Q8 is turned off. When the transistor Q8 is turned off, the divided voltage by the resistor R19, the resistor R16, the variable resistor VR2, and the resistor R20 is detected, and the divided voltage corresponds to the type of the rechargeable battery of the pocket B. It is used as the voltage to set the corresponding charging voltage. In this case, the divided voltage detected by the second charging voltage setting unit 40 is applied to the inverting terminal (-) of the comparator OP2 of the charging voltage control unit 34 through the output voltage selection switch 42. As a result, the comparator OP2 outputs a low signal when the charging voltage is higher than the reference voltage set by the resistors R11 and R12, and a high signal when the comparator OP2 is low. When the output signal of the comparator OP2 is low, the transistor Q2 is turned on. When the transistor Q2 is turned on, the light emitting diode PCa of the photocoupler PC1 emits light and is received by the light receiving transistor PCb. As a result, the light receiving transistor PCb is turned on to turn on the power switch 14. When the output signal of the comparator is high, the transistor Q2 is turned off, and when the transistor Q2 is turned off, the light emitting diode PCa of the photocoupler PC1 does not emit light, thereby receiving a light receiving transistor. (PCb) is turned off to control the power switch 14. By repeating this operation quickly, the output voltage is constantly limited to 4.1 V, which is a set level. After setting the charging voltage according to the type, the microprocessor 36 controls the second LED 46 indicating the charging state to be displayed in red in step 216. In this way, before the charging is output from the smoothing unit 24 The charging resistor R5 is applied to the battery mounted in the pocket B via the diode D10 and the voltage drop unit 32. After the charging is started, the microprocessor 36 starts charging in step 217. It recognizes the voltage applied to the resistor R8 through the port Io and checks whether it is smaller than the preset charging current of 100 mA, and if the charging current is larger than 100 mA, it is determined that the charging is not completed yet. If it is smaller than 100 mA, it is recognized that the charging of the battery mounted in the pocket B is completed, and the flow proceeds to step 218. In step 218, the microprocessor 36 sends a low signal, the battery charge-off signal of the pocket B, through the port P1. Output, and the second LED 46 is displayed in green to indicate that the charging of the battery of the pocket B is completed, and to charge the battery to the port P1 of the microprocessor 36. The transistor Q6 is turned off when the low signal, which is a signal, is output. When the transistor Q6 is turned off, the FET Q4 is turned off to turn off the resistor R5, the diode D10, and the voltage drop unit 32. After that, the charging voltage applied to the battery of the pocket B is cut off to complete the charging of the battery mounted in the pocket B.

As described above, the present invention senses the types of rechargeable batteries mounted in Pocket A and Pocket B, sets the voltage corresponding to the detected battery type, and uses the set voltage to charge the 4.1V or 4.2V charge voltage. Because it outputs the power supply, it does not have a separate device for generating multiple DC power sources, thereby reducing the weight, price and size of the charger.

In an embodiment of the present invention, the types of rechargeable batteries installed in the pockets A and B are determined to set the voltage corresponding to the type discrimination, and the charging voltage is stored in the pocket A regardless of the type of the battery. At the same time, the charging voltage is dropped to the set level to be supplied to the pocket B so as to be charged without departing from the scope of the present invention.

On the other hand, the detailed description of the present invention has been described with reference to specific embodiments, of course, various modifications are possible without departing from the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, in the present invention, when charging two or more batteries in a plurality of battery pockets in a multiple battery charger, each type of battery mounted in a plurality of pockets is recognized so that a voltage corresponding to the recognized battery type is set. As it is charged, it is possible to charge different kinds of batteries at the same time, and when the batteries are installed in both Pocket A and Pocket B, the charging voltage supplied to Pocket B is dropped to supply the charging voltage to the batteries of Pocket A and Pocket B. Therefore, there is an effect that can be sequentially charged.

In addition, by detecting the type of rechargeable batteries mounted in Pocket A and Pocket B, and set the voltage corresponding to the detected battery type, using the set voltage using the comparator (OP2), transistor (Q2) and photocoupler ( PC1) to control the power switch 14 to output the charging voltage for 4.1V or 4.2V, so it is possible to reduce the weight, price and size of the charger because it is not equipped with a separate device for generating multiple DC power sources.

1A to 1C are circuit diagrams of a multiple rate battery charger according to an exemplary embodiment of the present invention.

2 is a flowchart illustrating a charging control when a plurality of batteries are mounted in a battery pocket according to an exemplary embodiment of the present invention.

3 is a flow chart of charging control when one battery is mounted in a battery pocket according to an exemplary embodiment of the present invention.

4 is a waveform diagram of a charge voltage and a charge current detection according to an embodiment of the present invention.

Claims (14)

A charger for charging at least two rechargeable batteries, Pocket A which can attach the first battery, Pocket B which can attach a second battery, A control unit for recognizing a type of battery when the battery is mounted in the pocket A or the pocket B and outputting a control signal for setting a charging voltage corresponding to the detected battery type; A voltage adjusting unit which receives a control signal for setting the charging voltage of the controller and adjusts the charging voltage to a voltage level corresponding to the recognized battery type; And a charging voltage supply control unit for supplying the output voltage adjusted by the voltage adjusting unit to the first battery and dropping the charging voltage adjusted by the voltage adjusting unit to a predetermined level to supply the second battery to the second battery. Battery charger. The method of claim 1, wherein the charging voltage supply control unit, First and second charging voltage switching units for controlling supply and blocking of the charging voltage applied to the first battery or the second battery, respectively; And a charging voltage drop unit connected to a front end of the second charging voltage supply control unit to drop a charging voltage supplied to a predetermined level and supplying the charging voltage to a second battery mounted in the pocket B. The method of claim 2, wherein the voltage adjusting unit, A first charging voltage setting unit configured to set a charging voltage according to a type sensing of the first battery mounted in the pocket A; A second charging voltage setting unit configured to set a charging voltage according to the detection of the type of the second battery mounted in the pocket B; An output voltage selection switch for selecting and outputting one of the voltages set from the first charging voltage setting unit or the second charging voltage setting unit by a switching control signal for charging under control of the controller; And a charging voltage control unit configured to control the charging output voltage by outputting a switching control signal so that the charging voltage is uniformly supplied by comparing the charging voltage selected from the output voltage selection switch with a preset reference voltage. The method of claim 3, And a charge amount detector for outputting a voltage for detecting the charge amount of the first battery or the second battery. A charger for charging at least two rechargeable batteries, AC / DC converter which inputs AC power and converts it into DC voltage for charging and outputs it, Pocket A which can attach the first battery, Pocket B which can attach a second battery, First and second charging voltage switching for controlling the supply and blocking of a charging DC voltage to the first battery or the second battery; A first charging voltage setting unit configured to set a charging voltage according to a type sensing of the first battery mounted in the pocket A; A second charging voltage setting unit configured to set a charging voltage according to the detection of the type of the second battery mounted in the pocket B; A charge amount detector for outputting a voltage for detecting the charge amount of the first battery or the second battery according to the detection of the current value of the DC power supplied from the AC / DC converter; When the first battery and the second battery are mounted in the pocket A and the pocket B, the type of battery is recognized by recognizing resistance values installed in the first and second batteries according to the type of battery. Outputting the first and second charging voltage setting control signals according to the type, outputting a switching control signal for selecting the priority of the charging battery, sensing the voltage detected from the charging amount detection unit to recognize the fully charged state A control unit which outputs a charge on / off control signal and outputs a display control signal for indicating a state of charge of the first and second batteries; Selecting and outputting a selected voltage according to a switching control signal for selecting charging of the first and second batteries under control of the controller from among voltages set from the first charging voltage setting unit or the second charging voltage setting unit; Output voltage selector switch, And a charging voltage controller configured to control the level of the charging output voltage by outputting a switching control signal to the AC / DC converter such that the charging voltage is uniformly supplied by comparing the charging voltage selected from the output voltage selection switch with a preset reference voltage. Multiple battery charger, characterized in that. The method of claim 5, And a voltage drop unit connected to the front end of the second charging voltage supply control unit to drop the charging voltage supplied from the AC / DC converter to a predetermined level and supply the second battery mounted in the pocket B. Multiple battery chargers. The method of claim 5, And a first and a second LED for indicating a state of charge of the first and second batteries under control of the controller. The method according to claim 5, And the voltage drop unit comprises a diode. According to any one of claims 5 to 8, wherein the charging voltage control unit, A comparator for comparing a preset reference voltage with a charging voltage set from the first and second charging voltage setting units and outputting a low signal when the set charging voltage is high; A transistor switched on when a low signal is output from the comparator; And a photocoupler configured to control the AC / DC converter so that the light emitting diode emits light when the transistor is switched on to turn on a light receiving transistor to output the set output voltage. A charging control method in a charger having first and second pockets for mounting at least two rechargeable batteries, respectively, and charging the rechargeable batteries in the plurality of pockets, Recognizing a type of the rechargeable battery mounted in the first pocket; Setting a charging voltage corresponding to a type of the rechargeable battery mounted in the first pocket; The set charging voltage is supplied to the battery mounted in the first pocket, and the set charging voltage is dropped to the set level to be supplied to the second pocket to charge the batteries mounted in the first and second pockets. Initiation process, When the charging of the battery mounted in the first pocket is completed, cutting off the charging voltage supplied to the batter mounted in the first pocket and recognizing a type of the rechargeable battery mounted in the second pocket; Setting a charging voltage corresponding to a type of the rechargeable battery mounted in the second pocket; And controlling the charging voltage set corresponding to the battery mounted in the second pocket to be output, thereby completing the charging of the battery mounted in the second pocket. A charging control method in a charger having first and second pockets for mounting at least two rechargeable batteries, respectively, and charging the rechargeable batteries in the plurality of pockets, Recognizing a type of the rechargeable battery mounted in the first pocket or the second pocket; Adjusting the charging voltage corresponding to the type of the rechargeable battery mounted in the first pocket or the second pocket; And controlling charging to supply the adjusted charging voltage to the first battery or the second battery. The method of claim 11, And simultaneously installing the rechargeable battery in the first pocket and the second pocket, supplying the charging voltage to the first battery and simultaneously dropping the charging voltage to a predetermined level and supplying the rechargeable battery to the second battery. Charge control method. A charging control method in a charger having first and second pockets for mounting at least two rechargeable batteries, respectively, and charging the rechargeable batteries mounted in the first and second pockets, Detecting whether the rechargeable battery is mounted in the first pocket or the second pocket; Recognizing a type of the mounted rechargeable battery when it is detected that the rechargeable battery is mounted in the first pocket; Setting a charging voltage corresponding to a type of the rechargeable battery mounted in the first pocket; Supplying the set charging voltage to a battery mounted in the first pocket to initiate charging of the rechargeable battery mounted in the first pocket; Charging control method comprising the step of blocking the charging voltage supplied to the batter mounted in the first pocket when the charging of the battery mounted in the first pocket is completed. The method of claim 13, Recognizing a type of rechargeable battery mounted in the second pocket when it is detected that the rechargeable battery is mounted in the second pocket; Setting a charging voltage corresponding to a type of the rechargeable battery mounted in the second pocket; Dropping the set charging voltage to a set level with a battery mounted in the second pocket; Supplying the dropped charging voltage to a rechargeable battery mounted in the second pocket to start charging; And a step of blocking the charging voltage supplied to the batter mounted in the second pocket when the charging of the battery mounted in the second pocket is completed.