JPH05111156A - Switching circuit for power on control and power on control method - Google Patents

Abstract

PURPOSE:To prevent the decrease of voltage given from a power source when a relay is turned on. CONSTITUTION:A relay contact 10B is connected between a power source and load, and an auxiliary transistor Q3 is connected in parallel with this relay contact 10B. The auxiliary transistor Q3 following the time constant of a time constant circuit 11 shifts gradually from broken condition to continuity condition. Hereby, the voltage added to the load increases gradually. When the auxiliary transistor Q3 gets in substantially conducting state, the relay contact 10B is turned on, and voltage is given to the load through the relay contact 10B.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power-on control switching circuit and method.

[0002]

2. Description of the Related Art An example of a conventional power-on control switching circuit is shown in FIG.

A commercial AC voltage is supplied to the stabilized DC power supply 23 from an AC outlet / plug 21 connected via a fuse 22. DC stabilized power supply 23 to DC 5V (V
1) is output. The output terminal of the DC stabilized power supply 23 is C
The PU 24 is connected, and the operating voltage is directly supplied to the CPU 24 from the stabilized DC power supply 23. DC stabilized power supply
A load 30 is further connected to the output terminal of 23 via a relay contact 25B of the relay 25.

The collector of a transistor Q is connected to a relay coil 25A included in the relay 25. When a control signal is applied to the base of the transistor, the transistor Q is turned on, the relay coil 25A is energized, and the relay contact 25B is turned on. When the relay contact 25B is turned on, the operating voltage is supplied to the load 30.

[0005]

However, in the switching circuit shown in FIG. 4, when the relay contact 25B is turned on, as shown in FIG.
Output voltage may drop. This makes the CPU 24
May malfunction.

It is an object of the present invention to prevent the output voltage of a DC stabilized power supply from decreasing due to an inrush current when the switch is turned on.

[0007]

According to the first aspect of the present invention, a relay contact of a main relay connected between a constant voltage power supply circuit and a load and a predetermined time constant in response to an input of a power-on control signal are provided. A time-constant circuit whose output voltage increases, connected in parallel to the relay contact of the main relay, controlled by the output voltage of the time-constant circuit, and changed from a cut-off state to a conducting state as the output voltage of the time-constant circuit increases. The auxiliary semiconductor three-terminal control element that gradually shifts to, and after the time required for the auxiliary semiconductor three-terminal control element to transition to the conductive state from the input time in response to the power-on control signal, A timer circuit for energizing a relay coil of a main relay to turn on the relay contact is provided.

The increase in the output voltage of the time constant circuit is a concept that includes both an increase in the positive direction and an increase in the negative direction.

According to the first aspect, when the power-on control signal is input, the output voltage of the time constant circuit gradually increases in response to the input. The auxiliary semiconductor three-terminal control element controlled by this output voltage gradually shifts from the cutoff state to the conduction state. Therefore, the power supply voltage supplied to the load from the constant voltage power supply circuit through the auxiliary semiconductor three-terminal control element also gradually increases.

When the auxiliary semiconductor three-terminal control element becomes conductive, a voltage obtained by subtracting the voltage drop in the three-terminal control element from the output voltage of the constant voltage power supply circuit is applied to the load. At this point, the timer circuit energizes the relay coil, turning on the relay contact.

Since the voltage drop at the relay contact is much smaller than the voltage drop at the three-terminal control element, the constant voltage of the constant voltage power supply circuit is supplied to the load through the relay contact which is turned on.

In the first stage, a gradually increasing voltage is applied to the load through the three-terminal control element. Then, in the second stage, the power supply voltage is applied to the load through the relay contacts. In this way, the voltage applied to the load gradually increases and never increases sharply, so that it is possible to avoid the occurrence of inrush current as in the conventional case. Therefore, a situation in which the output voltage of the constant voltage power supply circuit drops suddenly does not occur, and it is possible to prevent malfunction of the CPU or the like connected to the constant voltage power supply circuit in the preceding stage of this switching circuit. it can.

A second invention is that the output voltage increases with a predetermined time constant in response to a relay contact of a main relay connected between a constant voltage power supply circuit and a load and a power-on control signal input. 1 time constant circuit, which is connected in parallel to the relay contact of the main relay, is controlled by the output voltage of the first time constant circuit, and changes from the cut-off state to the conductive state as the output voltage of the time constant circuit increases. Auxiliary semiconductor three-terminal control element that gradually shifts to
When the coil and its drive circuit, and the power-on control signal or the output voltage of the first time constant circuit are given, the drive circuit of the relay coil is turned on when the auxiliary semiconductor three-terminal control element shifts to the conductive state. A second time constant circuit having a time constant determined to generate an output voltage to be activated is provided.

When the power-on control signal is input, in response to this, the output voltage of the first time constant circuit gradually increases. The auxiliary semiconductor three-terminal control element controlled by this output voltage gradually shifts from the cutoff state to the conduction state. Therefore, the power supply voltage supplied to the load from the constant voltage power supply circuit through the auxiliary semiconductor three-terminal control element also gradually increases.

When the auxiliary semiconductor three-terminal control element becomes conductive, a voltage obtained by subtracting the voltage drop in the three-terminal control element from the output voltage of the constant voltage power supply circuit is applied to the load. At this point, the drive circuit of the relay coil is driven by the second time constant circuit, and the relay contact is turned on.

Since the voltage drop at the relay contact is much smaller than the voltage drop at the three-terminal control element, the constant voltage of the constant voltage power supply circuit is supplied to the load through the relay contact that is turned on.

Also in the present invention, in the first stage, a gradually increasing voltage is applied to the load through the three-terminal control element. Then, in the second stage, the power supply voltage is applied to the load through the relay contacts. In this way, the voltage applied to the load gradually increases and never increases sharply, so that it is possible to avoid the occurrence of inrush current as in the conventional case. Therefore, a situation in which the output voltage of the constant voltage power supply circuit drops suddenly does not occur, and it is possible to prevent malfunction of the CPU or the like connected to the constant voltage power supply circuit in the preceding stage of this switching circuit. it can.

A third aspect of the present invention is a relay contact of a main relay connected between a constant voltage power supply circuit and a load, and a first auxiliary semiconductor device connected in parallel to the relay contact of the main relay. A terminal control element, a time constant circuit whose output voltage increases with a predetermined time constant in response to an input of a power-on control signal, and an output voltage of the time constant circuit is given to a control terminal and is controlled by this output voltage A semiconductor three-terminal control element, and a relay of the main relay connected between one input / output terminal of the second semiconductor three-terminal control element and the control terminal of the first semiconductor three-terminal control element. It is characterized by having a coil.

The increase of the output voltage of the time constant circuit is a concept including both increase in the positive direction and increase in the negative direction.

When the power-on control signal is input, the output voltage of the time constant circuit gradually increases in response to this. The second semiconductor three-terminal control element controlled by this output voltage gradually shifts from the cutoff state to the conduction state. Since the output voltage of the second semiconductor three-terminal control element is given to the control terminal of the first semiconductor three-terminal control element via the relay coil, the first three-terminal control element also gradually changes from the cut-off state to the conductive state. It will shift. Therefore, the voltage supplied from the constant voltage power supply circuit to the load via the first three-terminal control element also gradually increases. When the first three-terminal control element becomes almost conductive, the relay coil is excited by the current flowing from the control terminal to the second three-terminal control element, and the relay contact is turned on. After that, the voltage is supplied from the constant voltage power supply circuit to the load via the relay contact that is turned on.

Also according to the present invention, in the first stage, the first
A gradually increasing voltage is applied to the load through the three-terminal control element. Then, in the second stage, the power supply voltage is applied to the load through the relay contacts. Since the voltage applied to the load gradually increases, no inrush current occurs. Since the output voltage of the constant voltage power supply circuit does not drop sharply, it is possible to prevent malfunction of the CPU or the like connected to the preceding stage of the switching circuit.

According to a fourth aspect of the present invention, a relay contact of a main relay is connected between a constant voltage power supply circuit and a load, and an auxiliary semiconductor three-terminal control element is connected in parallel with the relay contact to supply a power-on control signal. In response to the control signal, a control signal is applied to the control terminal so that the semiconductor three-terminal control element gradually shifts from the cut-off state to the conductive state, and when the semiconductor three-terminal control element becomes almost conductive, the main relay The relay
It is characterized in that an exciting current is passed through the coil to turn on the relay contact.

According to the fourth aspect of the invention, the control signal is applied to the control terminal so as to gradually shift the semiconductor three-terminal control element from the cut-off state to the conductive state in response to the power-on control signal. The power supply voltage supplied will also gradually increase.

When the semiconductor three-terminal control element becomes conductive, a voltage obtained by subtracting the voltage drop in the three-terminal control element from the output voltage of the constant voltage power supply circuit is applied to the load. At this point, the main coil relay coil excitation current is passed and the relay contacts are turned on.

Since the voltage drop at the relay contact is much smaller than the voltage drop at the three-terminal control element, the constant voltage of the constant voltage power supply circuit is supplied to the load through the relay contact that is turned on.

Also according to the present invention, in the first stage, a gradually increasing voltage is applied to the load through the three-terminal control element. Then, in the second stage, the power supply voltage is applied to the load through the relay contacts. Since the voltage applied to the load gradually increases, no inrush current occurs. Since the output voltage of the constant voltage power supply circuit does not drop sharply, it is possible to prevent malfunction of the CPU or the like connected to the preceding stage of the switching circuit.

[0027]

1 is a circuit diagram of a switching circuit, and FIG. 2 is a graph showing the relationship between voltage and time in the circuit shown in FIG.

FIG. 1 is a circuit diagram of a portion corresponding to the relay 25 and the transistor Q of the conventional switching circuit shown in FIG. 4, and compared with the circuit shown in FIG.
Illustration of the PU 24 and the controlled load 30 is omitted.

A relay contact 10B of the main relay 10 is connected between the power source and the load, and an auxiliary transistor Q3 is connected in parallel to the relay contact 10B. The collector terminal of the driving transistor Q1 of the transistor Q3 is connected to the base terminal of the transistor Q3. The collector terminal of the transistor Q3 for driving the transistor Q3 is connected to the power supply via the resistor R. The collector terminal of the relay driving transistor Q2 is connected to the relay coil 10A of the main relay 10.

The switching circuit includes a first time constant circuit 11 and a second time constant circuit 12. An ON / OFF control signal for controlling the supply of the operating voltage V2 to the load is applied from the CPU to the first time constant circuit 11.
The output voltage of the first time constant circuit 11 is applied to the second time constant circuit 12 and the base terminal of the transistor Q3 driving transistor Q1.

When the operating voltage V2 is supplied to the load, a control signal is output from the CPU and given to the time constant circuit 11. This starts the operation of the time constant circuit 11,
As shown in FIG. 2 (A), the output voltage increases with a predetermined time constant. When the output voltage of the time constant circuit 11 gradually rises, the base potential of the transistor Q3 driving transistor Q1 also gradually rises, and the transistor Q3 driving transistor Q1
The collector potential of gradually decreases. Since the collector potential of the transistor Q3 for driving the transistor Q3 gradually decreases, the base potential of the auxiliary transistor Q3 also gradually decreases. Thus the auxiliary transistor Q3 shifts to gradually conducting state from the cutoff state (time t _1). Therefore, as shown in FIG. 2B, the voltage V2 supplied to the load also gradually increases. When the auxiliary transistor Q3 becomes conductive, a voltage obtained by subtracting the voltage drop of the auxiliary transistor Q3 from the output voltage V1 of the power supply is applied to the load.

The output voltage of the time constant circuit 11 is a time constant circuit.
As shown in FIG. 2 (C), the output voltage of the time constant circuit 12 gradually rises with a delay further than the output voltage of the time constant circuit 11. Relay drive transistor Q2 is turned on at time t ₂ after the time when the auxiliary transistor Q3 becomes conductive. This makes the relay coil 10A
An exciting current flows through the relay contact 10B and turns on. When the relay contact 10B is turned on, the voltage V1 of the power supply is applied to the load via the relay contact 10B. Relay contact 10B
Is lower than the voltage drop of the auxiliary transistor Q3, and the output voltage of the power supply is almost applied to the load.

FIG. 3 shows another embodiment.

Compared to the switching circuit shown in FIG. 1, the switching circuit shown in FIG. 3 has a relay coil 10A instead of the resistor R connected to the collector terminal of the transistor Q3 driving transistor Q1. Driving transistor Q2 and second time constant circuit
12 is omitted.

In the switching circuit shown in FIG. 3, the collector terminal of the transistor Q3 driving transistor Q1 is connected to the base terminal of the auxiliary transistor Q3 via the relay coil 10A. Also relay coil 10A
A diode 13 is connected in parallel with. Further, as a first time constant circuit shown in FIG. 1, a resistor R1 and a capacitor C are provided.
Integrating circuit 14 and a voltage dividing circuit 15 composed of resistors R2 and R3 are included. An on / off control signal is applied to the input of integrating circuit 14, and the output voltage of voltage dividing circuit 15 is the voltage of transistor Q1. Given to the base terminal.

When the power-on control signal is input, in response to this, the output voltage of the voltage dividing circuit 15 gradually rises. Along with this, the voltage applied to the base terminal of the auxiliary transistor Q3 via the diode 13 also gradually rises. The auxiliary transistor Q3 shifts from the cutoff state to the operating state, and the voltage V2 applied to the load also gradually increases.

When the auxiliary transistor Q3 becomes almost conductive, the relay coil 10A is excited by the current flowing from the base terminal of the auxiliary transistor Q3 to the collector terminal of the transistor Q3 driving transistor Q1, and the relay contact 10B is turned on. It Then, the voltage from the power source is applied to the load via the relay contact 10B.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a switching circuit according to an embodiment of the present invention.

FIG. 2 is a graph showing the relationship between the voltage applied to each circuit portion of the circuit shown in FIG. 1 and time.

FIG. 3 shows another embodiment.

FIG. 4 shows an example of a conventional switch circuit.

FIG. 5 is a graph showing how the output voltage of the voltage source decreases.

[Explanation of symbols]

 10 relay 10A relay coil 10B relay contact 11,12 time constant circuit Q1 transistor Q3 drive transistor Q2 relay drive transistor Q3 auxiliary transistor

Claims (4)

[Claims] 1. A relay contact of a main relay connected between a constant voltage power supply circuit and a load, a time constant circuit for increasing an output voltage with a predetermined time constant in response to an input of a power-on control signal, Three auxiliary semiconductor terminals that are connected in parallel to the relay contacts of the main relay, are controlled by the output voltage of the time constant circuit, and gradually shift from the cutoff state to the conductive state as the output voltage of the time constant circuit increases. In response to the control element and the power-on control signal, the relay coil of the main relay is energized after the time required for the auxiliary semiconductor three-terminal control element to transition to the conductive state from the time of its input. A switching circuit for power-on control, which includes a timer circuit that turns on the relay contact. 2. A relay contact of a main relay connected between a constant voltage power supply circuit and a load, and a first time constant for increasing an output voltage with a predetermined time constant in response to an input of a power-on control signal. Circuit, connected in parallel to the relay contacts of the main relay, controlled by the output voltage of the first time constant circuit, and gradually transitions from the cutoff state to the conductive state as the output voltage of the time constant circuit increases. The auxiliary semiconductor three-terminal control element, the relay coil of the main relay and its drive circuit, and the power-on control signal or the output voltage of the first time constant circuit, and the auxiliary semiconductor three-terminal control element When the relay becomes conductive,
A switching circuit for power-on control, comprising: a second time constant circuit having a time constant determined to generate an output voltage for activating a coil drive circuit. 3. A relay contact of a main relay connected between a constant voltage power supply circuit and a load, an auxiliary first semiconductor three-terminal control element connected in parallel with the relay contact of the main relay, A time constant circuit in which the output voltage increases with a predetermined time constant in response to the input of a power-on control signal, and the output voltage of the time constant circuit is applied to the control terminal, and the second semiconductor three terminal is controlled by this output voltage Control element,
And a relay coil of the main relay connected between one input / output terminal of the second semiconductor three-terminal control element and the control terminal of the first semiconductor three-terminal control element. Switching circuit for control. 4. A main circuit between the constant voltage power supply circuit and the load.
Connect the relay contact of the relay, connect the auxiliary semiconductor three-terminal control element in parallel to this relay contact, and gradually shift the semiconductor three-terminal control element from the cut-off state to the conductive state in response to the power-on control signal. As described above, a control signal is applied to the control terminal, and when the semiconductor three-terminal control element becomes almost conductive, an exciting current is passed through the relay coil of the main relay to turn on the relay contact. ..