KR0117851Y1 - Shut-off compensated circuit for a timer - Google Patents

Abstract

The long-time power failure compensation circuit for the timer is to maintain the setting state of the timer by causing the timer clock to operate by using the backup power of the system when the main power supply is in an electronic system having a timer function. To this end, a microcomputer for controlling all functions of the electronic system and detecting whether power is applied to the electronic system; A battery charged by an applied power source; Instantaneous power failure prevention means for preventing instantaneous power failure of the battery due to power failure; And a reset circuit for resetting the system when the discharge voltage of the battery drops to a predetermined value.

Description

Long time outage compensation circuit for timer

1 is a circuit diagram according to the present invention.

2a and b show the relationship between the power supply and the backup power supply for the power failure detection time.

3A and 3B show the relationship between the power supply and the backup power supply in time instantaneous power failure compensation.

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

10-microcom 20-current limit circuit

30-Overcharge protection measures 40-Instantaneous power failure prevention measures

50-over-discharge protection means 60-reset circuit

B01-Battery D01-, D02-Diode

SW1-reset switch

The present invention relates to a long time outage compensation circuit for a timer for operating a timer clock even in a long time outage in an electronic system having a timer function.

In general, the timer mounted on the electronic system has a problem that when the main power is turned off, a timer clock does not occur and thus the clock must be set again when the power is turned on.

Accordingly, an object of the present invention is to provide a long-time power outage compensation circuit for a timer for maintaining a timer setting state by operating a timer clock by using a backup power supply of the system when the main power supply is out of power.

In order to achieve the above object, the present invention provides a long-time power failure compensation circuit for a timer of an electronic system equipped with a timer clock generator; A microcomputer for controlling all functions of the electronic system and detecting whether power is applied to the electronic system; A battery charged by the applied power; Instantaneous power failure prevention means for preventing instantaneous power failure of the battery due to power failure of the power source; And a reset circuit for resetting the system when the discharge voltage of the battery drops to a predetermined value.

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

1 is a circuit diagram according to the present invention, and is applied to a general electronic system equipped with a timer. In this case, the electronic system generally includes a video cassette tape or a cassette.

The configuration of FIG. 1 includes a timer clock generator X01 for generating a timer clock by the power supplied from the microcomputer 10, a system clock generator X02 for generating a system clock like the timer clock generator X01, and a power source. The current limiting circuit 20 and the diode D02 for limiting the direction of the current connected between the applied input terminal and the electrostatic detection port of the microcomputer 10 to flow from the input terminal to the microcomputer 10, The diode D01 and the cathode terminal of the diode D01 and the backup power supply of the microcomputer 10 connected to the input terminal to which an anode terminal is applied and the cathode terminal of the backup power supply terminal Bu B ⁺ of the microcomputer 10 are connected. One side contact is connected to the connection point between the anode terminal of the diode D01 and the power input terminal of the battery B01 which connects the positive terminal to the connection point between the applying terminal Bu B ⁺ , and the other one contact is connected to the connection point of the battery B01. Contact to the negative terminal Is connected between the overcharge protection means 30 and the overcharge protection means 30 and the power input terminal to prevent the instantaneous power failure of the battery B01 when the power is turned off. The battery B01 is over-connected in series between the contact point and the ground potential between the prevention means 40 and the contact point between the backup power input terminal Bu B ⁺ of the microcomputer 10 and the positive terminal of the battery B01. The input terminal is connected to a contact between the over discharge protection means 50 for protecting from the entire state, the contact point to which the over discharge protection means 50 is connected, and the one contact of the over discharge protection means 50, and the microcomputer ( A reset circuit 60 for automatically resetting the microcomputer 10 when the voltage discharged from the battery B01 reaches a predetermined voltage by connecting the output terminal to the reset terminal RESET of 10); Reset of the output terminal of the set circuit 60 and the microcomputer 10 Here (RESET) comprises a resistor (R5) and the control switch (SW1) connected in series between the connection point and the ground voltage between. The control switch SW1 is a reset button for artificially resetting the microcomputer 10.

More specifically, the overcharge protection means 30 includes a resistor R2 connected in series between the negative terminal of the battery B01 and the electropotential, a connection point between the resistor R2 and the negative terminal of the battery B01, and a diode. And a resistor R1 connected in series with the connection point between the power supply terminal D01 and D01.

The instantaneous power failure prevention means 40 includes a resistor R3 connecting one terminal to a connection point between a diode D01 to which one terminal of the resistor R1 is connected and a power input terminal and another connection point between the power input terminal and the power supply terminal. And a transistor (Q1) connecting a resistor (R3) to a base terminal and a selector terminal connected to a connection point between a resistor (R2) and a resistor (R1), and an emitter and a base of the transistor (Q1). Resistor R4.

In the over discharge protection means, the condenser C01 and the resistor R6 are connected in series.

FIG. 2a illustrates a relationship between power and time applied from a power input terminal, and FIG. 2b illustrates a relationship between power and time applied to a backup power input terminal Bu B ⁺ of the microcomputer 10.

FIG. 3a illustrates the same state as FIG. 2a, and FIG. 3b illustrates a state in which power applied to the backup power input terminal Bu B ⁺ applied to the microcomputer 10 is converted by an instantaneous power failure state.

Next, the operation of FIG. 1 will be described with reference to FIGS. 2 and 3.

First, it is assumed that the power applied through the input terminal is 5.8V as shown in FIGS. 2 and 3 and the charging voltage of the battery B01 is 3V.

When such power is applied through an input terminal, the power is transferred to the passage where the diode D02 and the current limiting circuit 20 are connected, the passage where the diode D01 is connected, and the instantaneous power failure prevention means 40.

Accordingly, the microcomputer 10 recognizes that the power supply is applied to the current limiting circuit 20 as the power failure detection port 5.8V as shown in FIG. Is applied to the backup power input terminal Bu B ⁺ of the microcomputer 10 as 5.8V as shown in FIG. 2B, and is applied to the battery B01 to charge the battery B01.

This is because the overcharge protection means 30 distributes the applied voltage in order to prevent the overcharge state of the battery B01 so that the voltage applied to the negative terminal of the battery B01 is about 2V (this is assumed that the battery B01 is 3V). .)

Since the instantaneous power failure prevention means 40 is in a state where power is currently applied, the power applied through the resistor R3 is at a high level. Therefore, the transistor Q1 is turned off and thus has no effect on the over-discharge protection means 30.

The reset circuit 60 and the over-discharge protection means 50 and the like are operated when the battery B01 is in a discharged state, that is, when the power is turned off.

On the other hand, when the applied power is turned off and the power applied through the diode D01 and the current limiting circuit 20 gradually drops from 5.8V as shown in FIG. 2a, the microcomputer 10 is applied through the electrostatic detection port. After the attenuation phenomenon is checked for a predetermined time (the outage detection time shown in Figs. 2a and b), it is determined that the power failure is performed when the attenuation phenomenon continues or when the applied power drops to 0V as shown in Fig. 2a.

When it is determined that the power failure state, the microcomputer 10 first sets the mode to turn off the power supply to the system clock generator (X02) and to supply power only to the timer clock generator (X01) in order to minimize the power consumption.

Since no power is applied from the power input terminal, the diode D01 blocks the current discharged from the battery B01 from flowing in the direction of the power input terminal, while the power is turned off, and thus the backup power input of the microcomputer 10 is instantaneously. The voltage applied to the terminal Bu B ⁺ may drop below 0 V due to the occurrence of an instantaneous power failure state. To prevent this, the instantaneous power failure prevention means 40 uses the transistor Q1 to prevent the battery B01 from being used. The voltage at the negative terminal is connected to ground at ground potential.

That is, when no power is applied from the power input terminal, the potential applied to the base terminal of the transistor Q1 through the resistor R3 is at a low level, and thus the transistor Q1 is turned on. As a result, the ground potential connected to the emitter terminal of the transistor Q1 is connected to the negative potential of the battery B01, so that the ground potential is applied to the negative terminal of the battery B01.

Therefore, since the backup power applied to the microcomputer 10 does not fall below 0V, the backup potential of the microcomputer 10 is prevented from falling down to 0V or below due to instantaneous power failure as shown in FIG. 3B, and discharged from the battery B01. The 3V power supply will raise the 3V again.

The over-discharge prevention means 50 is applied to the backup power input terminal Bu B ⁺ of the microcomputer 10 at the moment when the power applied from all the input terminals is turned off so that the speed of discharge from the battery B01 is gradually made. The power is gradually dropped to 3V as shown in 2b. To this end, the over-discharge prevention means 50 adjusts the potential of the connection point connected to the input terminal of the reset circuit 60. That is, in order to prevent the power output from the battery B01 from being over-discharged by the load capacity, the discharge characteristics of the condenser C01 are gradually dropped as shown in FIG. 2B.

The reset circuit 60 automatically resets the microcomputer 10 when the power discharged from the battery B01 falls below a predetermined value.

Here, since the battery B01 is 3V, the reset circuit 60 resets the microcomputer 10 when the value charged by the battery B01 reaches 2.5V or less.

Here, it is generally considered that it takes about one year before the discharge power of the battery B01 drops to 2.5V.

This is because the reset circuit 60 is designed so that the amount of leakage of power supplied from the battery B01 is minimized during a power failure. Minimizing the amount of current leaking from the microcomputer 10 during such a power failure is also performed in the current limiting circuit 20 described above.

In addition, if an error occurs in the operation of the reset circuit 60 and the microcomputer 10 is not reset and the system is not normally driven after the power is turned on, the control switch SW1 is a reset button attached to the outside of the system. By using the user, the user controls the microcomputer 10 to be reset.

As described above, the present invention has the advantage of eliminating the trouble of having to reset the timer because the power is turned off for a long time by supplying power to operate the timer clock even when the power is turned off for a long time in an electronic system having a timer function. In addition, there is an advantage of minimizing the amount of leakage current during power failure so that a timer clock is generated for a long time even with a small power supply.

Claims (3)

In a circuit in which a timer clock generator is mounted in an electronic system to compensate a timer for a long time by this clock in case of a power failure, A battery charged and discharged according to whether power is applied; Instantaneous power failure prevention means for preventing instantaneous power failure of the battery due to power failure of the power source; Detects whether the power supply is out of power and receives the power to drive the timer clock generator and the electronic system when the power supply is not in a power failure state.If the power supply is detected, the electronic system is turned off and the charge is detected. A microcomputer that drives only the timer clock generator with power discharged from the battery; And And a reset circuit for applying a reset signal to the microcomputer to reset the electronic system when the discharge voltage of the battery drops to a predetermined value. The long-time power failure compensation circuit for a timer according to claim 1, further comprising a control switch for controlling the microcomputer to be artificially reset by a user when the microcomputer is not reset by the reset circuit. The transistor of claim 1, wherein the instantaneous power failure prevention means applies a base potential to the battery when the power is not applied to prevent the power applied to the microcomputer from dropping below the base potential at the moment of power failure. Long time outage compensation circuit for a timer, characterized in that consisting of.