JP2568530B2 - Electronic device having IC unit - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device having an IC unit, and more particularly to a control device for supplying power to an IC unit prior to supplying power to a load.

2. Description of the Related Art In recent years, the development of large-scale integrated circuits (hereinafter referred to as ICs) has been remarkable, and has been widely used in various electronic devices to make electronic devices smaller and more operable and lower in price. I have.

Some electronic devices, such as electronic flash devices for photography, are loaded with a capacitor that is charged by the output of a DC-DC converter that boosts the terminal voltage of a supplied DC power supply. It is well known that in the case of a load, the terminal voltage of a DC power supply decreases while the capacitor is being charged by the DC-DC converter.

This terminal voltage drop is extremely large immediately after the start of charging of the capacitor load.Therefore, when the DC power supply is used as the power supply of the IC, the various types of information stored in the IC due to the terminal voltage drop immediately after the start of the charge There is a risk that the contents of the file will be erased.

For this reason, when it is necessary to store the state before the IC at the time of power supply to the load, etc., the power for storing the contents is secured by effectively using the charging energy of the capacitor. And one of them is disclosed in JP-A-58-102223.

This capacitor is charged by a power battery to a capacitor (generally called a backup capacitor) that becomes the power source for the IC, and the voltage of the terminal of the power battery is reduced due to the charging by supplying power to the capacitor as a load. The voltage detection circuit detects that the voltage of the power supply capacitor has dropped, and when the voltage of the capacitor for the IC power supply reaches a level that hinders the storage operation, the charging operation to the load is stopped and the IC stops charging. When the IC power supply capacitor recovers to a sufficient voltage again by stopping the charging, the charging of the load is restarted. That is, the voltage detection of the IC power supply capacitor and the load based on the detection result are performed. The IC power is maintained by intermittently charging the battery.

Problems to be Solved by the Invention However, in the conventional device described above, in order to secure the IC power supply during the charging of the load (especially immediately after the start of charging), the backup capacitor is always charged by the DC power supply even when the device is not used. And the energy of the DC power supply is lost.

The present invention has been made in order to solve such a problem, and provides an electronic device capable of always securing an IC power supply during the charging of a load, particularly immediately after the start of charging, without causing energy loss of a DC power supply at all times. It is intended to do so.

Means for Solving the Problems In order to achieve the above object, an electronic device having an IC unit according to the present invention includes a DC power supply and a capacitor charged by a current from the DC power supply, wherein the capacitor is a predetermined capacitor. A power supply circuit that outputs an operation voltage by being charged at a level or higher, an operation control unit that starts operation at the same time as turning on a power switch and generates an operation signal after a lapse of a predetermined time, and the operation voltage is supplied, In addition, the semiconductor device includes an IC unit that operates when the operation signal is applied, and an oscillation control circuit that is connected to an output terminal of the IC unit and causes the oscillation circuit to perform an oscillating operation when the IC unit operates.

In the electronic device having the IC unit according to the present invention, the oscillation control is performed after the power supply circuit supplies the operating voltage to the IC unit and the operation signal generated by the operation control unit is applied to the IC unit. The circuit causes the oscillation circuit to oscillate.
That is, the electronic device according to the present invention is in a state where a sufficient operating voltage is supplied to the IC unit by the power supply circuit at the time when the oscillation operation is started. Even if the terminal voltage decreases, the operating voltage of the IC section can be secured without any problem.

The operation voltage is secured after the power supply circuit supplies the operation voltage to the IC unit, that is, after the power switch is turned on. Therefore, energy loss when the power switch is turned off is completely lost. Absent.

FIG. 1 is a block diagram showing an embodiment of a power supply device having an IC unit according to the present invention. In FIG. 1, 1 is a DC power supply, 2 is a power switch, 3 is a power supply circuit of the IC unit, and 4 is an IC unit. An operation control unit that generates an operation signal and operates the IC unit, 5 is an oscillation control circuit that is controlled by the IC unit to control the oscillation operation of the oscillation circuit, 6 is an oscillation circuit that boosts the DC power supply, and 7 is A load 8 is an IC unit.

In the device having the above configuration, when the power switch 2 is turned on, first, the DC power supply 1 is supplied to the power supply circuit 3 and the operation control unit 4 so that the power supply circuit 3 can supply the operation power supply voltage of the IC unit 8. The power supply voltage is supplied to the terminal a of the IC unit 8, while the operation control unit 4 starts operation by the supply of the DC power supply 1 and generates an operation signal after a lapse of a predetermined period of time.
To the terminal b.

The IC unit 8 sets the level of the terminal c to the first level by applying the operation signal.
The level is inverted from the second level to the second level, and the oscillation control circuit 5 which has been inactive when the terminal c is at the first level operates at the second level.

The operation of the oscillation control circuit 5 causes the oscillation circuit 6 to start oscillating, boost the DC power supply 1 and supply the boosted voltage to the load 7.

FIG. 2 is a specific circuit diagram of the block diagram. A power supply circuit 3 includes a capacitor 9 charged from a DC power supply 1, a constant voltage circuit 10 connected in parallel to the capacitor 9, and a constant voltage circuit 10 for outputting a constant voltage. The operation control unit 4 starts operation at the same time as the supply of the DC power supply 1 and turns on after a predetermined time.
And an operation signal generation circuit that operates when the switch circuit 12 is turned on, generates an operation signal, and applies the signal to the terminal b of the IC unit 8.
The switch circuit 12 includes a diode 14 and a charging capacitor 15 and a transistor 16 via a diode 14.
The operation signal generation circuit 13 includes a transistor 17
And a capacitor 18 that generates a pulse signal as an operation signal
And a resistor 19, and a transistor 20 connected in parallel to the parallel body.

Reference numeral 21 denotes a reset switch, and when the switch is turned on, the operation signal generation circuit 13 generates a pulse signal serving as an operation signal when the transistor 17 is in a conductive state. The oscillation control circuit 5 is a transistor 22 which is a switch whose conduction is controlled by the signal level of the terminal c of the IC unit 8.
The oscillation circuit 6 includes an oscillation transistor 25, a primary winding 26-1, and a secondary winding 26. The transistors 23 and 24 are switches that are turned on when the transistor 22 is turned on.
−2, which has an auxiliary winding 26-3 and is mainly composed of an oscillation transformer 26 and an SCR 27, and includes an oscillation transistor 25 and an oscillation transformer 26.
Is a well-known configuration, and 7 is a load, for example, a capacitor, and the charging energy of this capacitor is used, for example, for the luminous energy of a flash discharge tube.

The operation of the device of the present invention having the above configuration will be described with reference to the waveform diagram of FIG.

In FIG. 3, A is the charging voltage of the capacitor 11, B is the charging voltage of the capacitor 15, C is the operation signal, and D is the charging voltage of the capacitor 7.

Now, when turning on the power switch 2 at the time of T _1, the capacitor 15 of the switching circuit 12 will be charged as in FIG. 3 B via the diode 14, the capacitor 9 of the other power supply circuit 3 be charged When go constant voltage from the constant voltage circuit 10 at time T ₂ is to generate, it is charged from the T ₂ time point to the constant voltage VZ is charged in the capacitor 11 as shown in Figure 3 a. The constant voltage VZ of the capacitor 11 is applied to the terminal a of the IC section 8 as an operating power supply, while the charging voltage of the capacitor 15 is
Becomes a voltage value at the time of T _3, the transistor 16 is conductive,
The transistor 17 is turned on when a base current flows.

By the conduction of the transistor 17, a pulse signal as an operation signal of the IC unit 8 as shown in FIG. 3C is generated from the parallel body of the capacitor 8 and the resistor 9 and applied to the terminal b of the IC unit 8, and the IC unit 8 Put in the set state. When an operation signal is applied to the terminal b of the IC section 8, the signal level of the terminal c is inverted from the previous H level to the L level, and the transistor 22 of the oscillation control circuit 5 is turned on. When the transistor 22 is turned on, the transistors 23 and 24 are turned on sequentially, and when the transistor 24 is turned on, a voltage is applied to the gate of the SCR 27 of the oscillation circuit 6 to be turned on, and the oscillation transistor 25 starts oscillating, as is well known. A high voltage is generated in the secondary winding 26-2 of the transistor 26 and supplied to the capacitor 7 as a load.

Pulse is generated operation signal from the operation signal generation circuit 13 at time T _3, IC unit 8 is in the operating state, the oscillation operation of the oscillation circuit 6 by operation of the oscillation control circuit 5 is started, the DC power supply 1 voltage Decreases, and the voltage of the DC power supply 1 increases as the capacitor 7 charges.

Therefore, the charging voltage of the capacitor 15 due to the decrease of the DC power source 1 is gradually reduced as shown T ₃ after the time point of FIG. 3 B, the transistor 16 is inverted eventually nonconductive.

On the other hand, if the charge voltage of the capacitor 11 is set lower than the charge voltage of the capacitor 9 by setting the generated constant voltage VZ of the constant voltage circuit 10 or the capacitance value of the capacitor 9 is relatively large, T ₃
A while without lowering immediately larger oscillates the oscillation circuit 6 led to the point of maintaining the VZ, after the timing T ₄ to a constant voltage from the constant voltage circuit 10 no longer occurs in the charging voltage decreases. If the capacitance value of the capacitor 11 is set to be discharged in a relatively late time, the stored contents of the IC unit 8 can be maintained without erasing even during the oscillation operation of the oscillation circuit 6.

Reference numeral 29 denotes a reset switch that automatically returns to the off state as soon as it is turned on. When this switch is turned on, the transistor 20 conducts and the charge of the capacitor 18 is discharged instantaneously. An operation signal is generated from the parallel body and the IC unit 8 is reset.

In the present embodiment, the times when the charging voltages of the capacitors 11 and 15 reach the predetermined value are the same,
This has been done for the sake of explanation where appropriate.
There is no operational problem even if the time required for the charging voltage to be charged to the predetermined value VZ is short.

The transistor 22 of the oscillation control circuit 5 conducts when the terminal c of the IC section 8 becomes L level.
When the IC section 8 in which the terminal c of the IC section 8 becomes H level by application of the operation signal to the terminal b is used, the transistor 22
The same operation can be performed by using an NPN type one, and another SCR may be used for the switch element instead of the transistor.

Effect of the Invention As described above, in the device of the present invention, the operating power of the IC unit is not generated at all times, and is secured only after the power switch is turned on, and there is no power loss at all times when not used. .

If the load is supplied by operating the oscillation circuit simultaneously with turning on the power switch, the voltage of the DC power
Although the power supply of the IC section cannot be performed, the device of the present invention does not operate the oscillation circuit until the power supply of the IC section is secured, that is, operates reliably so that power is not supplied to the load until the power supply of the IC section is secured. Therefore, unlike the above case, even when the power supply to the load starts, the IC
The power supply to the unit can be stably performed.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the apparatus of the present invention, FIG. 2 is a specific circuit diagram of the embodiment of FIG. 1, and FIG. 3 is a waveform diagram for explaining the operation of FIG. 1 DC power supply 3 Power supply circuit 4 Operation control unit 5 Oscillation control circuit 6 Oscillation circuit 7 Load 8 IC unit

Claims (1)

(57) [Claims] 1. A power supply circuit comprising: a DC power supply; a capacitor charged by a current from the DC power supply; and a power supply circuit for outputting an operating voltage when the capacitor is charged to a predetermined level or more; At the same time, an operation control unit that starts operation and generates an operation signal after a lapse of a predetermined time, an IC unit that is supplied with the operation voltage and operates by applying the operation signal, and an output terminal of the IC unit. An electronic device having an IC unit comprising: an oscillation control circuit connected to the oscillation control circuit for causing the oscillation circuit to perform an oscillating operation by operating the IC unit.