KR19980076078A - Secondary battery charger using a microcontroller and charging method - Google Patents

Abstract

The present invention relates to a secondary battery charger using one microcontroller. One microcontroller (18) is connected to a charging unit (16, 16 ') to operate the charging current setting circuit (14,14') in main mode or parent. According to the present invention, the current can be controlled and information about the battery voltage, temperature, capacity, or type of the battery packs 12 and 12 'is input to the microcontroller 18. The present invention also provides a method of simultaneously charging a secondary battery charger using one microcontroller 18.

Description

Simultaneous charging method with a secondary battery charger using a single microcontroller

1 is a block diagram of the present invention charger

* Description of the symbols for the main parts of the drawings *

10: power supply unit 12, 12 ': battery pack

14,14 ': charging current setting circuit 16,16': charging part

18: microcontroller

The present invention relates to a secondary battery charger and a simultaneous charging method using a single microcontroller, in particular the information of the battery pack inserted into the charging pocket of the charging unit in the charger having two charging units, for example voltage, temperature, capacity of the battery pack By using the microcontroller that controls the charging current setting circuit of each charging unit by supplying information such as the type of battery pack, it is possible to set the charging mode of the charging unit and charge the battery pack which is the secondary battery at the same time according to the set charging mode. The present invention relates to a secondary battery charger and a simultaneous charging method.

Conventionally, the charging method or the simultaneous charging method of a charger for charging two secondary battery packs adopts a method of charging one of two battery packs first and then charging the other using one microcontroller, or supplying current. It adopts a method of charging two battery packs in a single microcontroller by changing the supply current by setting a constant or operating an external switch. In the former case, the charging time is long, and in the latter case, a large amount of current must be supplied.

In general, as a method of simultaneously charging two battery packs, there may be a method of supplying the same amount of current to two battery packs simultaneously and a method of supplying less current to one battery pack than the other battery pack. As mentioned earlier, if the same amount of current is supplied to two battery packs at the same time, it can be expected that the power supply unit will increase and the price will rise. On the other hand, when less current is supplied to one battery pack than the other battery pack, the charging time of the battery pack to which the current is supplied becomes too long. When charging a battery pack that is supplied with a large amount of current, charging time can be shortened by supplying a large amount of current to the battery pack with a small current flow by using an external switch, but this is very cumbersome because the user must always wait and operate the external switch. It's a method, so it's impractical

In light of this, the applicant has proposed a secondary battery charger and a simultaneous charging method using two microcontrollers in the patent application No. 96-77477 filed on December 30, 1996. When charging the battery pack first inserted into the charging pocket of one charging part by using two microcontrollers that control the charging current setting circuit of each charging part in the charger having the charging part, the microcontroller allocated for the charging control of this battery pack is mainly used. For the battery pack set to the mode and later inserted into the charging pocket of the other charging part, the microcontroller assigned for charging control of this battery pack is set to parent, so that a large amount of current is supplied to the battery pack set to the main mode and set to parented. The battery pack is supplied with a small current so that the battery pack inserted into the charging pocket is charged first. The current supply at the parent is relatively small compared to the main mode without waiting for the battery pack inserted in the pocket to be charged, but it is placed in the simultaneous charging process so that the overall charging time of the rechargeable battery pack can be shortened. A secondary battery charger and a simultaneous charging method using a microcontroller of the proposed.

In the present invention, it solves the above-mentioned problems of the typical prior art and further improves the charger and the simultaneous charging method proposed in the applicant's patent application.

In the secondary battery charger of the present invention, a charging unit having a charging current setting circuit is connected to a power supply unit and a microcontroller is connected to the charging unit in order to charge the battery pack. It is characterized in that the microcontroller recognizes the information on the battery voltage, temperature, capacity or type of the battery pack to control the charging current according to the main mode or parent by the charging current setting circuit.

In another aspect, the present invention provides a method of simultaneously charging the secondary battery charger, the information on the battery pack is input to a single microcontroller, and the charging current setting circuit controls the charging current according to the main mode or the parent by recognizing this information. do.

1 shows a secondary battery charger according to the present invention, each having a charging pocket (not shown) in which battery packs 12 and 12 'are inserted into a power supply unit 10, respectively. 14 ') connecting to the charging unit 16, 16' and each of the charging unit (16, 16 ') is connected to one microcontroller 18, which is connected to the power supply section 10, and controlled through the microcontroller 18 To be possible. The current control output according to the main mode / sub mode from the microcontroller 18 is connected to the charging current setting circuits 14 and 14 'of each charging section 16 and 16' and from each of the battery packs 12 and 12 '. Battery pack information such as voltage, temperature, capacity of the battery pack, type of battery pack, and the like can be input to the microcontroller 18. In this configuration, the power supply unit 10 supplies a DC voltage to the charging units 16 and 16 ', and the charging units 16 and 16' supply current to the battery packs 12 and 12 '. The current set by ') is supplied to the battery packs 12 and 12' by the pulse width modulation method or the linear method. The charging current setting circuits 14, 14 'set the amount of charging current for the charging section 16, 16'. The microcontroller 18 recognizes whether the battery packs 12 and 12 'are inserted into the charging pockets, and commands the charging units 16 and 16' to charge or not, and then charges the charging current setting circuits 14 and 14 '. To control.

The microcontroller 18 recognizes whether one battery pack 12 is inserted into the charging pocket and sets the charging current setting circuit 14 to the main mode, and the charging current setting circuit for the other battery pack 12 '. Set (14,14 ') to the parent The charging current setting circuit 14 of the battery pack 12 recognized as the main mode outputs a TTL signal so that the current set to a large value is supplied to the battery pack 12, and the charging current of the battery pack 12 'recognized as the parent mode. The setting circuit 14 'outputs a TTL signal so that a current set to a small value is supplied.

At this time, the microcontroller 18 monitors the charging state of the main mode and the parent and whether the battery pack is detached. Switch to the parent and perform voltage compensation charging (trickle charging) or wait for the battery pack to be inserted again. At this time, the parental battery pack (for example, battery pack 12 ') changes to the main mode and the charging current setting circuit 14' outputs a TTL signal so that a large current is supplied. Of course, if the parent battery pack completes the charge first or is detected a deviation, the main mode and parent will not change. The function of the microcontroller 18 may be performed by a preprogrammed internal program, and when the battery pack is installed, the main mode and parental settings may also be preprogrammed. Such a program can be easily written by those skilled in the art.

The power supply unit 10 supplies power required for the charging system to operate. The charging unit 16 or 16 ′ starts charging by the charging start command of the microcontroller 18 and according to the mode controlled by the microcontroller according to the capacity and type of the battery pack recognized by the microcontroller 18. The current is supplied to the battery packs 12 and 12 'by the amount of charging current set by the current control signal according to the control and size, and the charging method is changed according to the type of battery. For example, nickel cadmium and nickel hydrogen batteries have a constant current charging, and lithium ion batteries have a constant current-constant voltage charging method.

In the drawing, two current control outputs according to the main mode or the parent for the charging current setting circuits 14 and 14 'are shown, respectively. However, the control of the two charging current setting circuits 14 is controlled with one output. It is possible. For example, the charging current setting circuit 14 of the battery pack 12 may be supplied with a large current when the TTL signal high is supplied and with a small current when the TTL signal low signal is supplied. In contrast to the case of the battery pack 12, the charging current setting circuit 14 ′ of the other battery pack 12 ′ has a large current supplied when the TTL signal low is supplied, and a small current is supplied when the TTL signal high is supplied. The circuit may be configured. At this time, when the microcontroller 18 outputs a signal such that a large current is supplied to the side recognized as the main mode, the charging current setting circuit operates to automatically supply a small current to the side recognized as the parent mode.

As a method of sensing the capacity of the battery pack and supplying the charging current according to the capacity, the circuit is composed of a transistor and a resistance element, and the charging current is transmitted to the hardware by the presence and resistance of the resistance element connected to the negative terminal of the battery pack. There is something to be adjusted by. In the present invention, by connecting the information of the terminal of the battery pack having information about the capacity of the battery pack to the microcontroller 18, the microcontroller senses the capacity of the battery pack to use one or more output terminals assigned to the microcontroller The amount of current supplied by the charging current setting circuits 14 and 14 'can be adjusted. The type of current amount controlled by the number of output terminals connected to each charging current setting circuit can be varied. For example, when two output terminals are provided in each charging current setting circuit, at least four kinds of current amounts can be provided. In this way, the capacity of various battery packs can be detected and external hardware can be easily configured.

In order to distinguish the types of battery packs 12 and 12 '(nickel cadmium, nickel hydrogen, lithium ion, lead-acid, lithium polymer, etc.), information is provided from the battery pack, which is also recognized by the microcontroller. When the type of pack is recognized, the program routine of the microcontroller for optimal charging of the battery pack is executed. In this way, the design of the charger becomes easy and simple, and the optimum charging according to the type of the battery pack is possible.

Claims (2)

In order to charge the battery packs 12 and 12 ', a charging unit 16 and 16' having charging current setting circuits 14 and 14 'is connected to the power supply unit 10, and a single micro to the charging unit 16 and 16'. A controller 18 is connected and a single microcontroller 18 is used to charge two battery packs at the same time, in which a large current is supplied to a battery pack 12 or 12 'set as a main mode and set as a parented battery. A method of simultaneously charging a secondary battery charger using a single microcontroller, characterized in that a small current is supplied to a pack (12 or 12 '). In order to charge the battery packs 12 and 12 ', a charging unit 16 and 16' having charging current setting circuits 14 and 14 'is connected to the power supply unit 10 and connected to the output of one microcontroller 18. (16, 16 ') to connect the signal to control the battery pack, the battery voltage, temperature, capacity or type of information to the microcontroller 18, according to the capacity of the battery recognized by the microcontroller 18 A secondary battery charger using a single microcontroller, which outputs a current control signal to the charging current setting circuits 14 and 14 'and recognizes the battery type so that the battery can be optimally charged according to the battery type. .