JPH08106839A - Intra-contact arc eliminating device of mechanical switch - Google Patents

Abstract

PURPOSE: To obtain an eliminating device for an intra-contact arc of a mechanical switch with its certain arch detection, high reliability for enabling power saving without a need to supply power to a supply circuit all the time. CONSTITUTION: An arc eliminating device is provided with a direct current power supply 20, a mechanical switch 21 connected in series to this direct current power supply 20, a semiconductor switch, 22 connected in parallel to the mechanical switch 21 for erasing an arc generated in this mechanical switch 21, a power supply circuit 23 connected to both contact points of the mechanical switch 21, a control circuit 24 interposed between the power supply circuit 23 for turning ON/OFF the semiconductor switch 22 and the semiconductor switch 22, and a time limit circuit 25 placed in connection between one side contact point of the mechanical switch 21 and the power supply circuit 23.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for erasing an arc between contacts of a mechanical switch for erasing an arc generated in a mechanical switch.

[0002]

2. Description of the Related Art As a prior art, there is Japanese Utility Model Publication No. 4-47876, which is shown in FIG. In FIG. 7, reference numeral 1 denotes a bushing which is attached to the case 2 in a penetrating state and is made of porcelain or the like, and a contact mount 3 is fixed to the tip located in the case. The contact mount 3 is connected to an electric wire on the power source side through a stud bolt (not shown) inserted through the center of the bushing 1. 4 is a vertical mounting portion 4a
Is a fixed contact of a butt contact composed of a slanted contact portion 4b, and its mounting portion 4a is connected to the tip surface 3a of the contact mounting base 3 by a bolt 5. Reference numeral 6 is a U-shaped iron piece provided so as to surround the outer peripheral surface of the contact portion. Also,
Reference numeral 7 denotes a movable contact of a butt contact, which is a U-shaped contact portion 7a made of arc-resistant metal and a U-shaped contact portion surrounding the outer peripheral surface of the contact portion 7a at a position facing the contact portion 4b of the fixed contact 4. The iron pieces 8 are provided, and when the large current is applied, the iron pieces 6 and 8 of the contacts 4 and 7 attract each other by the current flowing through the contacts to prevent chattering. A movable conductive bar 9 is connected by a screw-shaped connecting pin 10 and a coil spring 11 so that the movable contact 7 can be swung. The movable conductive bar 9 is electrically connected to the movable contact 7. When the fixed contact 4 and the fixed contact 4 are in the closed state, the auxiliary contact 14 made of a stainless steel plate or a phosphor bronze plate is elastically contacted with the upper portion 13a of the auxiliary contact piece 13 of the arc extinguishing device 12 described later from above. There is. The movable contact 7 is ultimately connected to a load side distribution line (not shown) via a movable conductive bar 9. Reference numeral 12 denotes an arc extinguishing device that is attached and connected to the fixed contact 4, and is attached and connected to the attachment portion 4a of the fixed contact 4 by a bolt 5 in a suspended manner via an L-shaped terminal 15.
The arc-extinguishing device 12 is composed of a main body 16 composed of thyristors connected in antiparallel, the terminal 15 also serving as the above-mentioned mounting metal fitting connected to one of the main bodies 16, and a spring member connected to the other main body 16 such as stainless steel or phosphor bronze. A ring-shaped auxiliary contact piece 13 and an optical fiber 17 for triggering the thyristor.
6 is electrically interposed between the fixed contact 4 and the movable contact 7, and the optical fiber 17 has a detecting portion 17a between the contacts so as to detect an arc generated between the contacts 4 and 7 when separated. It is installed in the vicinity.

[0003]

By the way, in the above-mentioned prior art, the optical fiber 1 is provided between the movable contact 7 and the fixed contact 4.
7 is provided, and when the movable contact 7 separates from or contacts the fixed contact 4, an arc generated between the two contacts 7, 4 is introduced as light, and the introduced light also causes the movable contact 7 to move.
The thyristor connected in parallel with the fixed contact 4 is turned on to extinguish the arc. However, this method has a problem that the arc is not constant due to environmental conditions and is easily unstable, so that the light of the arc cannot be reliably captured, so that the thyristor cannot be turned on even when the arc occurs.

A first object of the present invention is to reliably detect an arc, to provide a highly reliable arc, and to eliminate the need for energizing the power supply circuit at all times to save electric power. To provide an erasing device. A second object of the present invention is to provide a device for eliminating arcs between contacts of a mechanical switch that can prevent re-arcing of the mechanical switch. A third object of the present invention is to provide a device for eliminating arcs between contacts of a mechanical switch capable of quickly causing charges accumulated in a capacitor of a timed circuit to flow through a diode and quickly resetting the circuit. is there. A fourth object of the present invention is to provide a device for eliminating arcs between contacts of a mechanical switch, which can shorten the time the arc is blown to the mechanical switch and prevent damage to the mechanical contacts.

[0005]

The first object is to provide a DC power supply, a mechanical switch connected in series to the DC power supply, and a mechanical switch for extinguishing an arc generated in the mechanical switch. A semiconductor switch connected in parallel with the switch, a power supply circuit connected to both contacts of the mechanical switch, and a control interposed between the power supply circuit and the semiconductor switch for turning the semiconductor switch on and off. And a circuit.

A first object of the present invention is, in the apparatus for erasing an arc between contacts of a mechanical switch of the first means, a second circuit in which a time circuit is connected between one contact of the mechanical switch and the power supply circuit. It is achieved by means of.

The first object is achieved by the third means, which is a capacitor, in the apparatus for eliminating arcs between contacts of a mechanical switch of the second means.

The second object is achieved by the fourth means in which a capacitor is provided in parallel with the power supply circuit in the apparatus for eliminating arcs between contacts of the mechanical switch of the first and second means.

A third object of the present invention is that, in the arc erasing device of the mechanical switch of the second means, a diode for flowing a current due to the electric charge accumulated in the time circuit is provided in the time circuit and the semiconductor switch. This is achieved by the fifth means provided in series.

A fourth object of the present invention is to provide a booster circuit for boosting an arc voltage due to the arc in the arc erasing device of the mechanical switch of the first and second means, and to output the output of the booster circuit. This is achieved by sixth means connected to the power supply circuit.

The fourth object is achieved by the seventh means in which the booster circuit is composed of a plurality of capacitors and a changeover switch in the apparatus for eliminating arcs between contacts of a mechanical switch of the sixth means. .

[0012]

In the first to third means,
When an arc is blown to a mechanical switch, a voltage is applied to a power supply circuit connected in parallel with the mechanical switch to turn on a semiconductor switch, so that arc detection is reliable. Also, only when the arc is blown to the mechanical switch, the power supply circuit enters and drives the control circuit to turn on the semiconductor switch.
It is not necessary to energize the power supply circuit, and power can be saved.

In the fourth means, the voltage of the constant voltage circuit can be maintained for a shorter time even when the contact of the mechanical switch is opened, and the semiconductor switch can be kept on during that time. Therefore, the re-arc of the mechanical switch can be prevented. In the fifth means, the electric charge accumulated in the capacitor of the time circuit can be swiftly passed through the diode, and the circuit can be reset quickly.

In the sixth and seventh means, the boosting time can be shortened even when the driving voltage of the semiconductor switch used is high, so that the time during which the arc is blown to the mechanical switch is shortened. It is possible to prevent damage to the contacts.

[0015]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment according to the present invention. In FIG. 1, 20 is a DC power supply, 21 is a DC power supply 2
0 is a mechanical switch connected in series with 0, 22 is a semiconductor switch connected in parallel with the mechanical switch 21 in order to eliminate the arc a generated in the mechanical switch 21,
23 is a power supply circuit connected to both contacts of the mechanical switch 21, 24 is a control circuit interposed between the power supply circuit 23 and the semiconductor switch 22 for turning the semiconductor switch 22 on and off, and 25 is the mechanical switch 21. A time circuit connected between one contact and the power supply circuit 23, and a load 26 interposed between the other contact of the mechanical switch 21 and the DC power supply 20.

Next, the operation of the above embodiment will be described. When the mechanical switch 21 shown in FIG. 1 shifts from the OFF state to the ON state, an arc a occurs when the contact point of the mechanical switch 21 approaches (state of FIG. 1). When the arc a occurs, a voltage drop occurs between the contacts. Upon receiving this voltage drop, the time circuit 25 operates and becomes conductive, so that the power supply circuit 2
3 has a voltage. Then, the power supply circuit 23 drives the control circuit 24 to turn on the semiconductor switch 22. When the semiconductor switch 22 is turned on, a current flows through the semiconductor switch 22, the arc a of the mechanical switch 21 is extinguished, and the mechanical switch 21 is turned on. Then, when the mechanical switch 21 is turned on, the mechanical switch 21 and the semiconductor switch 22 have a smaller impedance, so a current flows through the mechanical switch 21 and the mechanical switch 21 Since the potentials are substantially equal at both ends, the power supply circuit 23 does not have a voltage, and therefore the control circuit 24 is not driven and the semiconductor switch 22 is turned off.

On the other hand, when the mechanical switch 21 shifts from the ON state to the OFF state, an arc a is generated when the contact point of the mechanical switch 21 is slightly separated (state of FIG. 1). Arc a
When occurs, a voltage drop occurs between the contacts. After receiving the voltage drop, the time circuit 25 starts operating and becomes conductive, and then the power supply circuit 23 has a voltage. And the power supply circuit 2
3 drives the control circuit 24 to turn on the semiconductor switch 22. When the semiconductor switch 22 is turned on, a current flows through the semiconductor switch 22, the arc a of the mechanical switch 21 is extinguished, and the mechanical switch 21 is turned off. After that, the time circuit 25 stops operating and becomes non-conductive with a sufficient time margin, so that the power supply circuit 23 does not have a voltage, and therefore the control circuit 24 is not driven and the semiconductor switch 22 is turned off.

In the above-described embodiment, the DC power supply 20, the mechanical switch 21 connected in series with the DC power supply 20, and the arc generated in the mechanical switch 21 are eliminated. A semiconductor switch 22 connected in parallel with the mechanical switch 21, a power supply circuit 23 connected to both contacts of the mechanical switch 21, and a power supply circuit 23 and a semiconductor switch 22 for turning the semiconductor switch 22 on and off. And a time limit circuit 25 connected between one contact of the mechanical switch 21 and the power supply circuit 23.
Since the time circuit 25 is a capacitor, when the arc a is blown to the mechanical switch 21, a voltage is applied to the power supply circuit 23 connected in parallel with the arc a to turn on the semiconductor switch 22, so that the arc a can be detected reliably. Thus, it is possible to provide a highly reliable device for eliminating arcs between contacts of a mechanical switch. Further, since the power supply circuit 23 is turned on to drive the control circuit 24 to turn on the semiconductor switch 22 only when the arc a is blown to the mechanical switch 21, it is not necessary to energize the power supply circuit 23 at all times, and power saving is possible. Will be possible.

By the way, the arc is more remarkably generated when the mechanical switch 21 is turned on.
Therefore, a modified example that can prevent re-arcing due to the semiconductor switch being turned off after the arc of the mechanical switch 21 disappears due to conduction of the semiconductor switch will be described below. FIG. 2 is a block diagram showing a modified example. The same parts as those in the above embodiment are designated by the same reference numerals and detailed description thereof will be omitted. In FIG. 2, 30 is a constant voltage circuit, 3
Reference numerals 1 and 32 are diodes and capacitors connected in parallel to the constant voltage circuit. Since the capacitor 32 is connected in parallel to the constant voltage circuit 30 when the contact of the mechanical switch 21 is opened, the voltage of the constant voltage circuit 30 is further increased even if the contact of the mechanical switch 21 is opened (the arc disappears). It can be maintained for a short time, and the semiconductor switch 22 can be kept on during that time. When the semiconductor switch is turned off when the arc of the mechanical switch 21 disappears, the re-arc of the mechanical switch 21 starts. Therefore, the re-arc of the mechanical switch 21 can be prevented. Also, FIG.
The time limit circuit 25, the semiconductor switch 22 and the diode 3 are
Since 1 forms a loop, the charge accumulated in the capacitor of the time-limit circuit 25 quickly flows through the diode 31. FIG. 3 shows an actual circuit. As shown in FIG. 3, the constant voltage circuit includes a Zener diode 40, a resistor 41,
It is composed of a capacitor 42 and a diode 43, the control circuit is composed of resistors 44 and 45 and a capacitor 46, and the time circuit is composed of a capacitor 47.

In the modified example configured as described above,
Since the capacitor 32 is connected in parallel to the constant voltage circuit 30 when the contacts of the mechanical switch 21 are opened, the constant voltage circuit 30
Since it is possible to prevent the voltage applied to the switch from being attenuated, the voltage of the constant voltage circuit 30 can be maintained for a short time even when the contact of the mechanical switch 21 is opened, and the semiconductor switch 22 is turned on during that time. Can be kept. Therefore, the re-arc of the mechanical switch 21 can be prevented. Further, in the above modification, since the diode 31 for flowing a current due to the charge accumulated in the time limit circuit 25 is provided in series with the time limit circuit 25 and the semiconductor switch 22, the charge accumulated in the capacitor of the time limit circuit 25 is Diode 3
Flows quickly through 1.

FIG. 4 shows the relationship between the arc time and the arc voltage as the arc phenomenon of the mechanical switch. A voltage at an appropriate arc time is used depending on the drive voltage of the semiconductor switch 22 used. However, if the drive voltage of the semiconductor switch 22 used is high, waiting until the voltage reaches that voltage causes the mechanical switch 21 to wait for that time.
Since the arc is flying around, the contact of the mechanical switch 21 will be greatly damaged as the waiting time becomes longer. For example, the drive voltage of the semiconductor switch 22 is 30 to 35v
Therefore, waiting for this voltage takes about 5 ms (see Fig. 4). With this, the mechanical switch 21 is damaged too much. Therefore, in order to solve this, a method of waiting 1.5 ms, increasing the arc voltage to 17 v, and doubling the arc voltage will be described. FIG. 5 is a circuit diagram showing the booster circuit in the charging period, and FIG. 6 is a circuit diagram showing the booster circuit in the discharging period.
Here, 50 is a booster circuit, SW1, SW2 and SW3 are semiconductor switches (switches), and the arc voltage V1 = 17v is applied to the capacitors C1 and C2 during the charging period shown in FIG.
Will be charged at. After this, as shown in FIG. 6, SW1,
V2 = 2 × V by connecting SW2 from ON to OFF and SW3 from OFF to ON, and connecting the capacitors C1 and C2 in series.
You get 1 = 34v.

In the second embodiment thus constructed, since the booster circuit 50 for boosting the arc voltage V1 by the arc a is provided and the output of the booster circuit 50 is connected to the power supply circuit 23, Further, the booster circuit 50 includes a plurality of capacitors C1 and C2 and changeover switches SW1 and SW.
2 and SW3, the boosting time can be shortened even when the drive voltage of the semiconductor switch 22 used is high. Therefore, the time during which the arc a is blown to the mechanical switch 21 is shortened, and It is possible to prevent damage to the contacts.

[0023]

According to the inventions of claims 1 to 3,
When an arc is blown to the mechanical switch, a voltage is applied to the power supply circuit connected in parallel with it and the semiconductor switch is turned on, so arc detection is reliable and the arc between contacts of the mechanical switch is highly reliable. A device can be provided. Also, only when the arc is blown to the mechanical switch,
Since the power supply circuit enters and drives the control circuit to turn on the semiconductor switch, it is not necessary to constantly energize the power supply circuit,
Power saving becomes possible.

According to the invention described in claim 4, the voltage of the constant voltage circuit can be maintained for a shorter time even when the contact of the mechanical switch is opened, and the semiconductor switch can be kept on during that time. Therefore, the re-arc of the mechanical switch can be prevented. According to the invention described in claim 5, the electric charge accumulated in the capacitor of the time-limit circuit can be swiftly flowed through the diode.

According to the sixth and seventh aspects of the present invention, the boosting time can be shortened even when the driving voltage of the semiconductor switch used is high, so that the time during which the arc is blown to the mechanical switch is shortened, and the mechanical contact is shortened. Can prevent damage.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment according to the present invention.

FIG. 2 is a block diagram showing a modified example of the embodiment according to the present invention.

FIG. 3 is a circuit diagram of a modified example.

FIG. 4 is an explanatory diagram showing a relationship between an arc time and an arc voltage as an arc phenomenon of a mechanical switch.

FIG. 5 is a circuit diagram showing a booster circuit during a charging period according to a second embodiment of the present invention.

FIG. 6 is a circuit diagram showing a booster circuit during a discharge period according to a second embodiment of the present invention.

FIG. 7 is an explanatory diagram showing a conventional example.

[Explanation of symbols]

 20 DC Power Supply 21 Mechanical Switch 22 Semiconductor Switch 23 Power Supply Circuit 24 Control Circuit 25 Time Circuit 30 Constant Voltage Circuit 31 Diode 32 Capacitor 50 Booster Circuit C1, C2 Capacitor SW1, SW2, SW3 Change Switch

Claims (7)

[Claims] 1. A direct current power supply, a mechanical switch connected in series to the direct current power supply, and a semiconductor switch connected in parallel with the mechanical switch for extinguishing an arc generated in the mechanical switch. A machine comprising: a power supply circuit connected to both contacts of the mechanical switch; and a control circuit interposed between the power supply circuit and the semiconductor switch for turning on and off the semiconductor switch. A device for erasing arcs between contacts of a switch. 2. The apparatus for eliminating arcs between contacts of a mechanical switch according to claim 1, wherein a time circuit is connected between one contact of the mechanical switch and the power supply circuit. A device for eliminating arcs between switch contacts. 3. The apparatus for erasing an arc between contacts of a mechanical switch according to claim 2, wherein the time limit circuit is a capacitor. 4. The apparatus for erasing an arc between contacts of a mechanical switch according to claim 1 or 2, wherein a capacitor is provided in parallel with the power supply circuit. 5. The apparatus for erasing an arc between contacts of a mechanical switch according to claim 2, wherein a diode for flowing a current due to the electric charge accumulated in the time limit circuit is provided in series with the time limit circuit and the semiconductor switch. A device for eliminating arcs between contacts of mechanical switches. 6. The apparatus for eliminating arcs between contacts of a mechanical switch according to claim 1, further comprising a booster circuit for boosting an arc voltage generated by the arc, and connecting the output of the booster circuit to the power supply circuit. A device for eliminating arc between contacts of a mechanical switch characterized by the above. 7. The inter-contact arc erasing device for a mechanical switch according to claim 6, wherein the booster circuit is composed of a plurality of capacitors and a changeover switch. Erase device.