JPH06295638A - Interlock circuit - Google Patents

Abstract

PURPOSE:To reduce rush-in current generated due to floating capacity of power line by providing an opening/closing means and a coil in series between a power source and a load. CONSTITUTION:An interlock switch 4 opened or closed in association with the mechanical operation of device is inserted in a power line 3 composed of harness or the like positioned between a power supply 1 and a load 2, and in the vicinity thereof a coil 11 is positioned. At the output portion of the power supply 1, a capacitor C1 is arranged and in a load 2, a capacitor C2 is arranged. In one embodiment according to this invention, a load 5 is connected to the power line upstream of the switch 4, and a capacitor C3 is provided. A capacitor C4 shows the floating capacity of power line positioned upstream of the switch 4 while a capacitor C5 shows the floating capacity of power line positioned downstream of the switch 4. When the switch 4 is disposed on a printed circuit board 12, it is desirable that the coil 11 is on the same board. With this constitution, all rush-in current caused by closure of the switch 4 can be reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an interlock circuit that opens and closes a power supply line to a load by means of an interlock switch or relay contact, and particularly reduces an inrush current generated when the interlock switch or relay contact is closed. The present invention relates to an interlock circuit that can be activated.

[0002]

2. Description of the Related Art In a device having a load that uses a high voltage or a load that generates a high temperature, a power source for the above load is provided when the door of the device is opened in order to prevent electric shock or burns. A safety interlock circuit is provided to shut off the supply.

In this interlock circuit, an interlock switch that opens and closes in conjunction with mechanical operation of the device such as opening and closing a door is inserted in series between a power source and a load,
There is a relay in which the power supply to the relay coil is turned on and off in association with the mechanical operation of the device, and the contact of this relay is inserted in series between the power supply and the load.

By the way, in the interlock circuit as described above, a transiently excessive rush current flows through the current line when the interlock switch or the relay contact is closed. This rush current causes malfunction of the load and generation of noise. Therefore, in order to reduce the inrush current,
The following two methods were mainly adopted.

FIG. 3 is a circuit diagram showing an interlock circuit using the first conventional method. In this interlock circuit, an interlock switch 4 that opens and closes in synchronization with the mechanical operation of the device is inserted in series with a power supply line 3 including a harness between a power supply 1 and a load 2. A capacitor C ₁ is provided at the output part of the power source 1,
A capacitor C ₂ is often provided in the load 2. In addition, a load 5 that does not interrupt the power supply by the interlock switch 4 is connected to the power supply line on the upstream side of the interlock switch 4, and a capacitor C ₃ may be provided in the load 5 as well. The first conventional method for reducing the inrush current is to insert the coil L ₁ in series with the output portion of the power supply 1.

In the figure, C ₄ indicates the stray capacitance of the power supply line on the upstream side of the interlock switch 4, and C ₅ indicates the stray capacitance of the power supply line on the downstream side of the interlock switch 4.

FIG. 4 is a circuit diagram showing an interlock circuit using the second conventional method. As shown in this figure,
The second conventional method of reducing an inrush current, instead of inserting the coil L ₁ to the output portion of the power source 1, a coil L ₂ in series with the power input of the load 2 located downstream of the interlock switch 4 Is inserted.

3 and 4, instead of the interlock switch 4, a relay contact for turning on / off the power supply to the relay coil in association with the mechanical operation of the device may be provided. Needless to say.

[0009]

However, in the first conventional method shown in FIG. 3, the capacitor C ₁ in the power source 1 is
Although it is possible to reduce the rush current flowing from the interlock switch 4 to the downstream side of the interlock switch 4, it is effective for the stray capacitance C ₄ on the upstream side and the rush current flowing from the capacitor C ₃ in the load 5 on the upstream side to the downstream side. There is a problem that there is no. Further, the coil L ₁ a current flows to all of the load connected to the output of the power supply 1, a large coil is disadvantageously necessary with thick winding as a coil L _1.

Further, in the second conventional method shown in FIG. 4,
Can be reduced inrush current flowing from the upstream side of the interlock switch 4 to the capacitor C ₂ in the load 2, a problem that there is no effect on the inrush current from the upstream side to the floating capacitance C ₅ on the downstream side There is a point. In addition, there is a problem in that coils may be required for the number of loads that incorporate capacitors in the power input section.

Incidentally, Japanese Patent Laid-Open No. 2-37261 discloses that
In an interlock circuit in which a large capacity capacitor is inserted immediately after the interlock switch to reduce ripple, a coil is inserted in series between the interlock switch and the capacitor to reduce the inrush current to the capacitor. The technique that was done is shown. However,
In this case, since the rush current to the capacitor becomes a large current, the power supply voltage drops, and there is a problem that a coil having a very large inductance is required to prevent malfunction of the load due to the drop.

Therefore, an object of the present invention is to provide a simple structure,
In particular, it is an object of the present invention to provide an interlock circuit capable of reducing the inrush current due to the stray capacitance of the power supply line.

[0013]

The interlock circuit of the present invention is provided in series with a power supply line between a power supply and a load without having a capacitor in the vicinity thereof, and opens and closes in conjunction with the mechanical operation of the device. And a coil provided in series in the power supply line in the vicinity of the opening / closing means.

In this interlock circuit, the inrush current due to the stray capacitance of the power supply line is reduced by the coil provided near the switching means. Here, the opening / closing means is
It may be an interlock switch that opens and closes in conjunction with the mechanical operation of the device, or a contact of a relay that turns on and off the power supply to the relay coil in conjunction with the mechanical operation of the device.

[0015]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram showing an interlock circuit according to an embodiment of the present invention.

The interlock circuit of this embodiment is provided with a power supply 1
An interlock switch 4 that opens and closes in tandem with the mechanical operation of the device is inserted in series with a power supply line 3 formed of a harness or the like between the load 2 and the load 2.
The coil 11 is provided in the vicinity of without the capacitor. In many cases, the output portion of the power source 1 is provided with a capacitor C ₁ and the load 2 is provided with a capacitor C ₂ . In addition, the interlock switch 4 is connected to the power line on the upstream side of the interlock switch 4.
There is a case where a load 5 that does not shut off the power supply is connected by this, and a capacitor C ₃ is also provided in the load 5. Further, in the figure, C ₄ indicates the stray capacitance of the power supply line on the upstream side of the interlock switch 4, and C ₅ indicates the stray capacitance of the power supply line on the downstream side of the interlock switch 4.

Here, the coil 11 may be provided on the upstream side or the downstream side of the interlock switch 4 as long as it is near the interlock switch 4, or on both the upstream side and the downstream side. Further, when the interlock switch 4 is provided on the printed circuit board 12, it is preferable that the coil 11 is provided on the same printed circuit board. When the interlock switch 4 is connected to the power source 1 or the load 2 by a wire such as a harness,
The distance between the interlock switch 4 and the coil 11 is preferably within 50 cm in terms of the total length of the wire and the conductive portion such as the conductive pattern on the printed circuit board.

As described above, according to this embodiment, since the coil 11 is provided in the vicinity of the interlock switch 4, it is possible to reduce all the inrush currents generated by closing the interlock switch 4. In particular, in this embodiment, it is possible to reduce the inrush current due to the stray capacitances C ₄ and C ₅ of the power supply line, which cannot be reduced by the conventional first and second methods. Further, since the current flowing through the load 5 on the upstream side of the interlock switch 4 does not flow through the coil 11, the coil 11 may have a minimum necessary capacity for the current. Further, the coil 11 does not need to be provided for each load having a built-in capacitor in the power input section as in the example shown in FIG.

By the way, Japanese Unexamined Patent Publication No. 2-33261 discloses an interlock circuit in which a capacitor and a coil are provided in the vicinity of the interlock switch. The interlock circuit of this publication and the interlock circuit of the present invention are different from each other. There are the following differences.

(1) First, in the interlock circuit of the publication, the coil is provided to reduce the inrush current to the large-capacity capacitor provided near the interlock switch. This is necessary because there is a capacitor near the switch, and is not provided by the coil alone. On the other hand, in the interlock circuit of the present invention, only the coil is provided without providing the capacitor near the interlock switch.

(2) In the interlock circuit of the publication, since a large-capacity capacitor is provided near the interlock switch, the inrush current becomes large and the power supply voltage decreases, compared with the case where the capacitor is not provided. It happens and requires a coil of high inductance to prevent it. On the other hand, in the interlock circuit of the present invention, since a large-capacity capacitor is not provided near the interlock switch, it is not necessary to prevent the power supply voltage from being lowered, and a coil having a large inductance is not necessary.

(3) As shown in FIG. 2 (a), the inrush current 21 due to a large-capacity capacitor provided near the interlock switch in the interlock circuit of the publication.
And the inrush current 22 due to the stray capacitance of the power supply line in the interlock circuit of the present invention, the inrush current 21 due to the capacitor passes through all the inductance components and resistance components of the harness from the power supply to the capacitor. Since it contains a lot of low frequency components, a coil with a large inductance is required to prevent this. Also,
The power supply cannot maintain a constant voltage because it lasts for a long time until the capacitor is charged. On the other hand, the rush current 22 due to the stray capacitance contains a large amount of high frequency components due to the small amount of inductance and resistance passing therethrough, which causes noise that adversely affects the electronic circuit, but the duration is short and the power supply voltage is low. Does not decrease. To prevent this, a coil having a relatively small inductance may be used. In the experiment, it was effective at 100 μH to 300 μH.
FIG. 2B shows a rush current 21 due to the capacitor and a rush current 22 due to the stray capacitance when a coil having a relatively small inductance is provided near the interlock switch. As shown in this figure, the inrush current 22 due to the stray capacitance is reduced by the coil having a relatively small inductance, but the inrush current 21 due to the capacitor is hardly reduced.

As described above, the interlock circuit of the publication is technically different from the interlock circuit of the present invention.

In the above description, the case where the interlock switch is provided in the power supply line has been described, but instead of the interlock switch, the power supply to the relay coil is turned on and off in synchronization with the mechanical operation of the device. A relay contact may be provided.

As described above, according to the present invention, the opening / closing means for opening / closing in synchronization with the mechanical operation of the device is provided in series with the power supply line between the power supply and the load, and the vicinity of this opening / closing means. In addition, since the coil is provided in series with the power supply line without providing the capacitor, the inrush current due to the stray capacitance of the power supply line can be reduced with a simple configuration.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of an interlock circuit according to an embodiment of the present invention.

FIG. 2 is a characteristic diagram for comparing an inrush current due to a capacitor in the interlock circuit of the publication and an inrush current due to a stray capacitance of a power supply line in the interlock circuit of the present invention.

FIG. 3 is a circuit diagram showing a configuration of an example of a conventional interlock circuit.

FIG. 4 is a circuit diagram showing a configuration of another example of a conventional interlock circuit.

[Explanation of symbols]

1 ... Power supply, 2 5 ... Load, 3 ... Power supply line, 4 ... Interlock switch, 11 ... Coil, 12 ... Printed circuit board

Claims (1)

[Claims] 1. An opening / closing means which is provided in series in a power supply line between a power supply and a load without a capacitor in the vicinity thereof and opens / closes in conjunction with a mechanical operation of the device, and the opening / closing means near the opening / closing means. An interlock circuit comprising: a coil provided in series with a power supply line.