KR19980087629A - Method and device for displaying the battery usage time on the battery pack - Google Patents

Abstract

[Objective] Allows you to display the remaining battery life directly on the battery pack.

[Configuration] The driving power is supplied to the microcontroller U1 and the current counter U2 through a power supply, and the lithium-ion batteries B1 and B2 have a protection integrated circuit U3 and an electric field effect. The protection circuit is composed of transistors FET1 and FET2. When overcharged, the gate voltage of the field effect transistor FET2 is inverted from logic 1 to logic 0 so that the field effect transistor FET2 is turned off to prevent overcharging. The gate voltage of the field effect transistor (FET1) is inverted from logic 1 to logic 0 to turn off the field effect transistor (FET1) to prevent over discharge, and through the sensor, the current counter (U2) and the microcontroller (U1). By detecting the charge / discharge of the battery and calculating the accumulated amount of current and time, the available time to use the battery in the future is configured to be displayed on the LCD display in units of numerical values (hours: minutes). It is easy to install in a variety of electronic devices to ever can be installed directly to the battery pack regardless of the size of the body.

Description

Method and device for displaying the battery usage time on the battery pack

[TECHNICAL FIELD OF THE INVENTION]

The present invention relates to a method and a device for displaying a usable residual amount of a battery directly in a battery pack.

Conventional Technology and Problems

For example, in the case of a mobile phone or a camcorder, when the switch is pressed on the battery pack through communication between the main body and the battery, the current battery absolute amount is not displayed directly on the battery pack, but is displayed as a bar graph on the main body. Or a time display on the monitor of the main body in communication with the main body. In the above bar graph, there is a limit to equal parts, so it is difficult to know the specific time, and since the display amount indicates the absolute capacity of the battery, it is impossible to know how much it can be used as the current consumed in the future. The range of use is limited because the main body and the battery pack must be designed to match 1: 1 to communicate with the main body, and the communication circuit between the main body and the battery pack has to be installed. In addition, in this display method, the power consumption of the battery itself is large, and thus, the consumption of power due to the discharge of the battery itself is a problem even when not in use, and the battery must be replaced with a new battery during overdischarge. Due to the characteristics of the (Li-ion) battery, there is a problem such as the risk of explosion and communication is lost when over-discharge over a certain limit during a call.

In view of the above-mentioned drawbacks of the present invention, the present invention continuously monitors the accumulated residual amount during battery charging and discharging in a small space called a battery pack, calculates the absolute residual amount (mAh), and detects the current used during use to use the residual amount. By displaying the battery pack directly on the battery pack as much as possible, it is possible to avoid unexpected downtime. Technically, the circuit for performing the above operation constitutes a circuit for minimizing power consumption, and the risk of the lithium-ion battery. To complement it, it also serves as a protection circuit. Therefore, the microcontroller is mounted to minimize the power consumption of the circuit when charging and discharging occurs. Also, the display device also adopts a low power consumption LCD to achieve the purpose and to display the display on the battery pack. By attaching it, it is impossible to display the specific actual usage time, which is a disadvantage of the prior art. It can be installed on the device and the actual usable capacity can be displayed in time.

To do this, the software turns off the display when the battery is not in use, reducing power consumption and delaying the display of the total current and available time on the display. By delaying the display, it is possible to predict the possible time due to the time difference.

1 is a block explanatory diagram for explaining the present invention;

2 is an electrical circuit diagram of an embodiment;

3 is a block diagram of a microcontroller;

4 is a block diagram of a current counter;

5 is a block diagram of a protection integrated circuit.

* Explanation of symbols in the drawings *

B1 and B2 are Lithium-ion batteries, U3 is a protection integrated circuit, SH1 is a sensing resistor, Q1 and Q2 are field effect transistors, U1 is a microcontroller, U2 is a current counter, and an LCD display is installed directly on the battery pack. Jang Ji, U4 is a regulator, D1 and D2 are diodes, R1 to R9 are resistors, C1 to C7 are capacitors, and V + and V- are external terminals of the pack.

DETAILED DESCRIPTION OF THE INVENTION The present invention will now be described in detail with reference to the accompanying drawings.

First, the micro-controller described below to help understand the present invention has an on-chip OSC that can oscillate inside the chip as shown in the block diagram of FIG. It can be operated by generating a clock, ROM (Random Access Memory) and RAM (Random Access Memory) is built-in, all the functions of the present invention can be programmed and stored, the current accumulated directly by communicating with the current counter to be described later Capable of collecting and calculating the capacity so that it can be displayed by transmitting time data on the display window, and it is programmed to be in the sleep mode to minimize the power consumption when the battery pack is not used. Among the functions of the invention, it detects the flow of current, calculates and stores the charged and discharged amount of the microphone described above A chip having a function of transmitting data by communicating with a furnace controller is shown in block diagram in FIG. In other words, it consists of CPU, X-tal Oscilator, EEPROM, and Current A / D Converter.The built-in CPU collects current DATA, calculates it, stores it in EEPROM, and uses external pin (DQ). It transmits and receives DATA, and by flowing out the precise hourly current flow, the X-tal Osciletor can oscillate by connecting the crystal oscillator to terminals X1 and X2, and the terminals of the Current A / D Convertor (SENS +, SENS-). Is connected to a sophisticated current detection resistor to detect the current and converts it to a digital data signal with an A / D converter to transfer it to the CPU. A protection IC is shown in the block diagram of FIG. As described above, the SENS terminal detects the voltage and controls the gate of the external field effect transistor described below between terminals DO and CO to protect the battery from overcharge, overdischarge, and overcurrent. In order to prevent malfunction due to instantaneous noise, the ICT terminal has a delay circuit built in so as to be delayed by connecting a cone sensor.

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

FIG. 1 is a block diagram illustrating the present invention, and a terminal (V +, for charging and discharging a battery B1, B2, which is a battery of a lithium-ion battery (abbreviated as B1, B2 or less)) or from the outside. It supplies the power to the current counter and the microcontroller through the power supply to which V-) is connected. The batteries B1 and B2 are connected to the protection integrated circuit and the premise. The protection circuit is composed of effect transistors (FET1, FET2) and a sensor, and the circuit is compacted by directly constructing the circuit in the battery pack itself so that the output is digitalized by the microcontroller (CPU) and displayed on the display (LCD). .

That is, in the above embodiment, when the battery is overcharged, the gate G2 voltage of the field effect transistor FET2 is inverted from logic 1 to logic 0 so that the field effect transistor FET2 is turned off to prevent further charging. When the discharge is overdischarged, the gate G1 voltage of the field effect transistor FET1 is inverted from logic 1 to logic 0 so that the field effect transistor FET1 is turned off so that it is no longer discharged. In addition, the sensor, current counter and microcontroller continuously detect the current during charging and discharging of the battery and calculate the accumulated amount of current and time to digitalize the available time of the battery in the future. In order to display (hour: minute) on the LCD display, the power supply unit POWER manages the power supply so that a minimum current is used while supplying an operating current to the current counter or microcontroller.

2 is an electrical circuit diagram of an embodiment to describe the present invention in more detail.

That is, in FIG. 2, the positive pole of the battery B1 is connected through the resistor R1, the negative pole of the battery B2 is directly connected, and the common pole of the cells B1 and B2 is respectively integrated through the resistor R2. Is connected to an input pin of the circuit U3, and the output of the protection integrated circuit U3 is connected to the gates G1 and G2 of the field effect transistors Q1A and Q1B through resistors R11 and R12, respectively. The drains D1B and D2B of the field effect transistors Q1A and Q1B are connected to each other and the source S1 of the field effect transistor Q1A is connected to the negative pole of the battery B2 and the source of the field effect transistor Q1B. S2) is connected to the V-terminal outside the pack through the sensing resistor SH1 to form a path for charging and discharging, and overcharging or overdischarging the batteries B1 and B2 and shorting the external terminals V + and V-. When the current flows, a small voltage in proportion to the amount of current across the sensing resistor (SH1) is generated to connect the value to the input pin of the current counter (U2). The current flowing in the discharging process is precisely detected and the detected signal SENS + is calculated and stored in the current counter U2 so as to calculate the charge / discharge amount of the current and transferred to the microcontroller CPU U1.

That is, in more detail, when the voltages of the batteries B1 and B2 are applied to the pins of the protection integrated circuit U3 through the resistors R1 and R2, the electric field effect is higher than or equal to a predetermined voltage. The charging or discharging is stopped by controlling the transistor Q1A or Q1B. For example, when the voltage of the battery B1 or B2 is an overvoltage, the voltage of the gate G2 of the field effect transistor Q1B is 0 volts. When the charging is completed and the voltage of the battery B1 or B2 is lower than the predetermined voltage, the gate G1 of the field effect transistor Q1A is controlled to discharge the battery. When the external terminals V + and V- are shorted to each other, the voltage applied to the Tun ON resistors of the field effect transistors Q1A and Q1B is applied to the CPU U3, which is a protective integrated circuit, through the resistor R4 to sense them. Thus, when a constant current or more flows, the gate G1 of the field effect transistor Q1A is controlled to terminate the discharge. At this time, the capacitor C3 is a capacitor for adjusting the control time, and the capacitors C1, C2, C4, C5, and C6 are noise removing capacitors.

The current counter U2 is an integrated circuit that manages the integration of the current, the symbol X1 is an oscillator for controlling the time of the current counter U2, and the capacitors C7 and resistors R6 and R8 are current counters. It is to protect the function of U2). Therefore, the CPU (U1), a microcontroller, controls the overall function and manages the display on the display, and calculates the available time when the current remaining amount is divided by the current flowing so as to display on the LCD display. In the figure, U4 is a regulator that supplies power to each circuit. When the voltage of the battery falls below a certain voltage, the power is cut off. The resistors (R4, R5, R7, and R9) are the microcontroller CPU ( Is a resistor to assist the function of U1), and when the voltage of the battery drops below a certain voltage, the power supply of the regulator U4 is cut off, and the accumulated residual amount up to this time is stored inside the current counter U2. This is to reserve power for a while to store in non-volatile memory.

As described above, according to the present invention, since the circuit is simple and can be directly installed in the battery pack unlike the conventional one, it can be installed in the battery pack itself regardless of the main body. It can be installed in a laptop, auto camera, portable recorder, video camera, etc. In particular, the battery pack can be designed regardless of the size of the main body of the electronic device. Therefore, even if the main body and the battery pack are not matched 1: 1, the battery pack can be realized by matching the external shape. It is a useful invention.

Claims (3)

To supply power to the CPU, which is a current controller and a microcontroller, Lithium-ion batteries consist of a protective integrated circuit and a protective circuit through field effect transistors and sensors. The current counter, the microcontroller and the sensor detects the current during charging and discharging of the battery, calculates a cumulative amount of current and time, and displays the available time of the battery on the liquid crystal display window. How to display available time. The driving power is supplied to the current counter U2 and the microcontroller U1 through the power supply unit Power. Lithium-ion batteries B1 and B2 are composed of a protection integrated circuit U3, a field effect transistor Q1A and Q1B, and a sensing resistor SH1. The current counter U2, the microcontroller U1, and the sensing resistor SH1 detect the charging and discharging of the batteries B1 and B2 to calculate a cumulative amount of current and time to display the available time in the future. Battery life time display device, characterized in that configured to display on the (LCD Display). A battery usable time display device in a battery pack provided with an available time display device according to claim 2, wherein a display window for displaying the available time of use of a battery and a circuit driving the battery are installed directly in the battery pack.