KR0121487Y1 - Display system of battery state - Google Patents

Abstract

The present invention is a battery state display device, in particular, a switch that is turned on and off in accordance with the switch control signal of the microcomputer to supply the battery power to the regulator and the low voltage detection unit, a regulator for outputting the predetermined driving power to the power control unit by receiving the battery power, When the battery power is below the reference voltage, it is operated by the low voltage detector which applies the low voltage signal to the microcomputer, and by the microcomputer and regulator that sends the low voltage status data to the OSD and outputs the power control signal to the power controller. Power control unit that supplies power to OSD and display unit by receiving power and supplies or cuts power to internal circuit according to power control signal of microcomputer, OSD which outputs text signal to display unit by receiving low voltage status data from micom, and OSD Display by receiving text signal The display unit provided for, the battery is cut off the power supply of the internal circuit when the low-voltage condition is over-discharged, and by giving parts of OSD and the display will continue to supply the power, the user has the effect indicating the low-voltage state of the battery.

Description

Battery status display device

1 is a block diagram showing a conventional battery state display device.

Figure 2 is a block diagram showing an embodiment of a battery state display device according to the present invention.

* Explanation of symbols for main parts of the drawings

11,20: Micom 12,30,76: Regulator

13,40: low voltage detector 14,50: OSD

15,60: display unit 70: power control unit

72: OR gate 74: buffer

TR1: NPN transistor TR2: PNP transistor

SW1, SW2: switch

The present invention relates to an electronic product using a battery, and more particularly, to a battery state display device which notifies a user of a low voltage state of a battery by supplying power only to a display unit when the battery is over discharged.

Existing electronic products that use batteries have a natural discharge even if they are left in a natural state even when the battery is charged, and the battery voltage drops below the operating voltage in about six months. I could not check whether it was not working or the battery was over discharged.

FIG. 1 is a block diagram showing a conventional battery state display device. The switch is turned on and off so that the battery power source V _B is applied to the regulator 12 and the low voltage detection unit 13 according to a control signal of the microcomputer 11. And a signal for turning on and off the switch SW1 to the switch control stage SC1 as the user switches the power switch on and off, and the low voltage state signal from the low voltage detector 13. In accordance with the output of the microcomputer 11, which receives the input of S _LV ) and outputs the data (D _OSD ) indicating the low voltage state to the OSD (14), the battery power supply (V _B ) according to the output of the switch control stage (SC1) Is supplied with a regulator 12 for adjusting the output voltage V _R suitable for the OSD 14 and the internal circuit, and the battery power supply V _B in accordance with the output of the switch control terminal SCI of the microcomputer 11. the signal (S _LV) to inform it when the low voltage state is outputted to the receiving microprocessor 11 to The low voltage detector 13, a character signal to the regulator 12, the driving voltage (V _R) received is applied to the drive and the microprocessor (11) under voltage condition data display unit 15 receives input of (D _OSD) from an adjustment from ( received is a D _DISP), a drive voltage (V _R adjustment from the OSD (14) and a regulator (12) for outputting a) composed of a display section 15 for displaying a character signal (D _DISP) received from the OSD (14) do. Here, the OSD 14 is an abbreviation of On Screen Display, which is a kind of IC for displaying text data on the screen of the display unit 60.

In the conventional low voltage display device configured as described above, first, when the user operates the power switch to the ON state, the switch control terminal SC1 of the microcomputer 11 contacts one side of the battery power source V _B. A high signal is applied to the connected switch SW1 to turn it ON, and accordingly, the regulator 12 and the low voltage detector 13 are supplied with a battery power source V _B , and the regulator 12 is a battery power source. (V _B ) is adjusted to a voltage (V _R ) suitable for driving the circuit and applied to the internal circuit, the power source of the OSD 14 and the display unit 15. The low-voltage detector 13 when the while monitoring the input battery power source (V _B) is determined at a low voltage by the microcomputer 11 in a low voltage state signal is the signal applied to the (S _LV), and the microcomputer is (S _LV) voltage condition Sending the data D _OSD to the OSD 14 causes the OSD 14 to output a text signal D _DISP to the display, such that the display 15 displays the low voltage state of the battery.

However, even after the low voltage signal S _LV is output from the low voltage detector 13 in the above-described operation, the battery voltage V _B continues to be supplied because the adjustment voltage V _R output from the regulator 12 is continuously supplied to the internal circuit. When discharged, the voltage V _R supplied to the display unit 15 and the OSD 14 is also lower than the driving voltage so that no display is displayed on the display unit 15. In this case, the user cannot accept any information from the product, and thus cannot distinguish whether it is not operating due to a malfunction or not due to battery over discharge.

Therefore, an object of the present invention for solving the above problems is to provide a battery state display device that displays the low voltage state of the battery by supplying power only to the display unit when the battery is discharged and lowered below the reference power of the internal circuit.

In order to achieve the above object, the present invention is a battery state display device that displays a low voltage state when the battery is over-discharged and the product does not operate, the control unit is provided with a contact point to which the battery power is applied and applied to a control signal applied from the microcomputer. A switch for switching and connecting the contact to output the battery power to the regulator and the low voltage detection unit in response, a regulator for receiving the battery power from the switch and outputting a predetermined driving power to the first input terminal of the power control means, the switch Low voltage detection means for outputting a signal informing the microcomputer when a battery power is supplied from the battery, and a control signal is applied to the switch, and a low voltage state signal is input from the low voltage detection means as input to the OSD. Output power control A microcomputer that outputs a control signal to the second input terminal of the stage and the battery power is supplied to adjust a constant driving voltage to supply driving power to the OSD and display means, and supply driving power to an internal circuit according to the control signal of the microcomputer. Or a power control means for interrupting operation, receiving driving power from the power control means, and receiving low voltage state data from the microcomputer to output text signals to the display means, and receiving driving power from the power control means. And a battery state display device including display means for displaying a text signal received from the OSD.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a battery state display device according to the present invention will be described in detail.

2 is a block diagram showing an embodiment of a battery state display device according to the present invention. First, the microcomputer 20 turns on and off the switch SW2 according to the low voltage state signal S _LV applied from the low voltage detector 40, and outputs a signal S _CTR for controlling the output of the power controller 70. The low voltage status data D _OSD is output to the _OSD 50.

The regulator 30 and the low voltage detector 40 are connected to receive the battery power supply V _B when the switch SW2 is turned on. The regulator 30 is connected to the power controller 70 to adjust the voltage V. _R ) and the low voltage detector 40 outputs the low voltage signal S _LV to the microcomputer 20. The microcomputer 20 receives the low voltage signal S _LV from the low voltage detector 40 and outputs the low voltage state data D _OSD to the _OSD 50. In addition, the OSD 50 receives power from the power controller 70 and outputs the text signal D _DISP to the display 60, and the display 60 receives power from the power controller 70 and is in a low voltage state. Is displayed. The power controller 70 is configured to apply power to the OSD 50, the display 60, and internal circuits according to the control signal S _CTR of the microcomputer 20. The power controller 70 includes a regulator 76 that receives the battery power source V _B and outputs a minimum driving voltage Vcc for driving the microcomputer 20, the OSD 50, and the display unit 60. . The power controller 70 includes two transistors, an OR gate, and a buffer. The NPN type first transistor TR1 is supplied with a minimum drive voltage adjusted by the regulator 76 to the collector terminal.

The power supply control signal S _CTR of the microcomputer 20 is input to the base terminal of the first transistor TR1, and the emitter terminal is connected to the input terminal of the OR gate 72.

The OR gate 72 receives the output V _R of the regulator 30 as the first input, the emitter output of the first transistor TR1 as the second input, and outputs the result to the buffer 74. The output of 74 is applied to the emitter stage of the OSD 50, the display 60, and the second transistor TR2. The second transistor TR2, which is a PNP type, is configured to receive the power supply control signal S _CTR of the microcomputer to the base end and to output the value input from the buffer 74 to the collector end accordingly.

The operation of the present invention configured as described above will be described in more detail. Normally, the battery supplies a voltage of 12V, and when the voltage is lowered to 10V or less, the power of the battery-equipped set is turned off as it is. Therefore, in the embodiment of the present invention, the low voltage detection unit 40 outputs the low voltage signal S _LV when the battery voltage is lowered below 10V.

First, when the battery is charged, when the user turns on the power switch, the microcomputer 20 outputs a high signal to the switch control stage SC2 to turn on the switch SW2. Accordingly, the regulator 30 and the low voltage detector 40 are supplied with a battery power supply V _B of 12V. The regulator 30 outputs a voltage V _R adjusted according to the driving voltage of the internal circuit. In addition, the regulator 76 of the power supply control unit 70 receives a 12V battery power supply. The regulator 76 adjusts the battery power supply to the driving voltage Vcc of 5V and outputs the result to the microcomputer 20 and the first transistor TR1. The microcomputer 20 applies a control signal S _{CTR in a} low state to the power supply control unit 70 when the battery power source V _B is equal to or greater than the reference voltage 10V. Thus, the first transistor TR1 is turned off and the second transistor TR2 is turned on. Therefore, the drive voltage Vcc adjusted by the regulator 76 is fed back only to the microcomputer 20. At this time, only the adjustment voltage V _R of the regulator 30 is input to the OR gate 72, power is supplied to the OSD 50 and the display unit 60 through the buffer 74, and is in an ON state. The two transistors TR2 output the power V _IN applied to the internal circuit to the collector terminal. Therefore, when the battery is charged above the reference voltage, power is supplied to the OSD 50, the display unit 60, and the internal circuit.

On the other hand, when the battery is continuously discharged and lowered below the reference voltage (10V), the low voltage detector 40 outputs the low voltage state signal S _LV , and the microcomputer 20 recognizes this to the switch control stage SC2. The switch SW2 is turned off by outputting a low signal, and the control signal SCTR of the high state is output to the power supply controller 70. When the switch SW2 is OFF, the regulator 30 does not operate because no driving power is applied, and thus, the adjustment voltage V _R is also not input to the power control unit 70. Therefore, only the regulator 76 is supplied with a battery voltage below the reference voltage. At this time, since the microcomputer 20 outputs a power control signal S _CTR in a high state, a high signal is also supplied to the base terminal of the first transistor TR1 to be turned on. The transistor TR1 receives a driving voltage Vcc of 5V from the regulator 76. The 5V driving voltage Vcc is input to the OR gate 72 and transferred to the buffer 74. The 5V voltage output through the buffer 74 is applied to and driven by the OSD 50 and the display unit 60. At this time, since the high signal is applied to the base terminal of the second transistor TR2, the second transistor is The power supply V _IN for driving the OFF door internal circuit is not output.

Therefore, in the battery state display apparatus according to the present invention, when the battery is over discharged and lowered to a voltage lower than the reference voltage, the power V _IN supplied to the internal circuit by the power controller 70 is cut off and the OSD 50 and the display are displayed. The unit 60 maintains the minimum driving power supply and operates to display the battery voltage state in the display unit 60 even in a low voltage state.

As described above, the present invention cuts off the power supply of the internal circuit and continuously supplies power to the OSD and the display unit when the battery is over discharged and becomes low voltage, thereby informing the user of the low voltage of the battery. It has an effect to facilitate.

Claims (4)

A battery state display device that displays a low voltage state when a product does not operate due to an over discharge of a battery. The battery state display device includes a contact point for supplying a battery power and sends the battery power supply to a regulator and a low voltage detection unit in response to a control signal from a microcomputer. A switch for switching and connecting the contact to each output; A regulator receiving battery power from the switch and outputting predetermined driving power to a first input terminal of the power control means; Low voltage detection means for receiving a battery power supply from the switch and outputting a signal informing the microcomputer when the battery power is below the predetermined reference voltage; A microcomputer that applies a control signal to the switch, receives a low voltage state signal from the low voltage detection unit, outputs low voltage state data to the OSD, and outputs a control signal to a second input terminal of the power supply control unit; Power control means for supplying driving power to the OSD and the display means by receiving the battery power and adjusting it to a constant driving voltage, and supplying or cutting off the driving power to an internal circuit according to the control signal of the microcomputer; An OSD that receives the driving power from the power control means and operates to receive the low voltage state data from the microcomputer and output a text signal to the display means; And display means for operating by receiving driving power from the power control means and displaying a text signal received from the OSD. According to claim 1, wherein the power supply control means for adjusting the battery power to a constant drive power supply and the drive power applied to the collet terminal in accordance with the power control signal of the microcomputer applied to the base end Emi A first transistor output to the terminal, an OR gate receiving the output of the regulator as the first input and receiving the emitter output of the first transistor as the second input, and outputting the buffer to the buffer; and delaying the output of the OR gate After outputting the buffer output to the emitter stage of the OSD and the display means and the second transistor and the output of the buffer applied to the emitter stage according to the power control signal of the microcomputer applied to the base stage through the emitter stage to the internal circuit. Battery status display device comprising a second transistor. The battery according to claim 1 or 2, wherein the microcomputer turns on the switch and the second transistor of the power control means when the battery power is in a charged state, turns off the first transistor of the power control means, and the battery power is over discharged. The battery state display apparatus characterized by outputting a control signal to the switch and the power control means to turn off the switch and the second transistor of the power control means and to turn on the first transistor of the power control means when in the previous state. . The display apparatus of claim 1, wherein the power control means supplies driving power to an on-screen display (OSD), display means and other internal circuits when the battery power is in a charged state, and OSD and display means when the battery power is in an over discharge state. Battery status display device, characterized in that it operates to supply the drive power only.