JPH08126213A - Insulating power supply - Google Patents

Abstract

PURPOSE: To provide an insulating power supply capable of providing electrical insulation between a power supply and a circuit, and further feeding power from the power supply to the circuit. CONSTITUTION: Two or more batteries 11, 12 are placed between a circuit 2 and a power supply 10. Contacts a S1A, S2A are placed between the batteries 11, 12 and the circuit 2, respectively; and contacts b S1B, S2B are placed between the power supply 10 and the batteries, respectively. A controller 13 operates to switch the contacts a and b to alternately connect the batteries 11, 12 to the power supply terminals of the circuit 2. One of the batteries that is not connected to the circuit 2 is connected to the power supply 10 and charged. One of the contacts on the circuit 2 side or power supply 10 side of each battery is off, and thus the circuit 2 and the power supply 10 are electrically insulated from each other.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insulated power supply device which is connected between a power supply and a circuit and which supplies electric power from the power supply to the circuit while electrically insulating the power supply from the circuit.

[0002]

2. Description of the Related Art A conventional power supply device will be described by taking a power supply device for a pressure sensor of GIS (gas insulated switchgear) as an example. GIS is a highly insulating insulating gas (SF ₆ gas, etc.)
This is a switchgear consisting of multiple compartments insulated from each other. When an arc flash accident occurs inside for some reason, it is necessary to promptly detect the compartment where the accident has occurred and recover the accident. For this reason, the internal gas pressure in each section of the GIS is constantly monitored, and the pressure increase due to the arc generated during an internal accident is detected to evaluate the accident section.

FIG. 3 shows a circuit diagram of a pressure sensor in a conventional GIS. In the figure, 1 is a GIS, 2 is a pressure sensor, and the internal pressure of the GIS 1 is transmitted to the pressure sensor 2 via a pipe 4. The pressure sensor 2 converts the internal pressure of the GIS 1 into an electric signal and outputs the electric signal to the accident point rating device 5 through the control cable 6. Further, power is supplied from the accident point rating device 5 through the control cable 6.

In the pressure sensor 2 described above, the pressure sensor 2 and the accident point evaluation device 5 are placed at the ground potential, so that when an internal accident occurs in the GIS 1, the pressure sensor 2 and the accident point evaluation device are affected by a high voltage surge. 5 needs to be protected. Therefore, the insulating seat 3 is provided in the pipe 4 between the GIS 1 and the pressure sensor 2 to insulate the GIS 1 from the pressure sensor 2. This insulator 3 is a pressure sensor 2 at ground potential.
A large insulation distance was needed to protect the s from high voltage surges.

Further, the control cable 6 between the pressure sensor 2 and the accident point rating device 5 is covered with a high withstand voltage tube 7 to prevent flashover between the control cable 6 and the ground E. Further, in the accident point evaluation device 5, the isolation amplifier 8 is used as the input amplifier so that the high voltage surge does not enter the electronic circuit.

[0006]

In the pressure sensor 2 described above, since the pressure sensor 2 is at the ground potential, the large insulating seat 3, the high withstand voltage tube 7 and the insulating amplifier 8 are required. On the other hand, if the pressure sensor 2 can be a float circuit, the insulator 3 can be downsized,
The high withstand voltage tube 7 and the isolation amplifier 8 can be eliminated.

To make the pressure sensor 2 a float circuit,
It is necessary to insulate both the signal transmission path and the power supply circuit. The path for transmitting a signal from the pressure sensor 2 to the accident point evaluation device 5 can be electrically highly insulated by using an optical fiber. However, none of the conventional power supply circuits can insulate the pressure sensor 2 and the accident point evaluation device 5 well. For example, an insulating transformer is sometimes used to provide electrical insulation, but the insulating transformer cannot prevent the transmission of high-voltage surge because of the capacitance between the windings.

An object of the present invention is to provide an insulated power supply device capable of supplying electric power from a power supply to a circuit while electrically insulating the power supply from the circuit.

[0009]

In order to achieve the above object, the present invention provides a power supply device, which is connected between a power source and a circuit and supplies power from the power source to the circuit, with two or more batteries. Each battery is connected to a circuit by a circuit side contact, each battery is connected to a power source by a power source side contact, and a control means for controlling opening / closing of the circuit side contact and the power source side contact is provided.

In the present invention, a capacitor may be used instead of the battery.

[0011]

By the operation of the control means, the circuit side contact is turned on for a certain battery among two or more batteries,
Power is supplied from the battery to the circuit. At this time, the power source side contact of the battery is turned off. For other batteries, the contacts on the power supply side are turned on and the batteries are charged from the power supply. At this time, the circuit side contact of the battery is turned off.

By appropriately switching between discharging and charging of each battery, power is supplied from the power source to the circuit and the battery is charged. During this period, in each battery, either the circuit side contact or the power source side contact is off, so that insulation is always provided between the circuit and the power source.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An example in which the insulated power supply device of the present invention is applied to a GIS pressure sensor will be described below with reference to the drawings. [Embodiment 1] FIG. 1 shows Embodiment 1 of the insulated power supply device of the present invention.
It is a circuit diagram of. In the figure, 1 is a GIS, 2 is a pressure sensor, and the internal pressure of the GIS 1 is transmitted to the pressure sensor 2 via a pipe 4. Various types of pressure sensor 2 can be used. An insulating seat 3 is provided in the middle of the pipe 4, but the insulating seat 3 can be a small insulating seat having a small insulating distance for the reason described later.

The output signal of the pressure sensor 2 is converted into an optical signal and is output to the accident point rating device 5 via the optical fiber cable 9. Two batteries 11 and 12 are provided between the pressure sensor 2 and the power supply 10. It should be noted that this battery can be an arbitrary number of two or more. The first battery 11 is connected to the power supply terminal of the pressure sensor 2 via the a contact S1A of the first relay S1, and is connected to the power supply 10 side via the b contact S1B of the same first relay S1. Similarly, the second battery 12 is also connected to the power supply terminal of the pressure sensor 2 via the a contact S2A of the second relay S2 and connected to the power supply 10 side via the b contact S2B of the same second relay S2. It As the relay contact, either a mechanical contact or an electronic contact can be used.

A controller 13 for controlling opening / closing of the first relay S1 and the second relay S2 is connected to the power source 10 side. A changeover switch SW3 is connected between the power source 10 and the batteries 11 and 12. The changeover switch SW3 changes over and connects the batteries 11 and 12 to one of the power supply 10 and the discharge circuit 14.

Further, a capacitor 15 is connected to the power supply terminal of the pressure sensor 2. Next, the operation of this power supply circuit will be described. The controller 13 alternately operates the first relay S1 and the second relay S2 at predetermined intervals. First, when the first relay S1 is turned on and the second relay S2 is turned off, the a contact S1 of the first relay S1 is turned on.
A is on, b contact S1B is off, and the second relay S
The second contact a S2A is turned off and the contact b S2B is turned on.
Therefore, electric power is supplied from the first battery 11 to the pressure sensor 2 through the a contact S1A of the first relay S1. On the other hand, through the b contact S2B of the second relay S2,
The second battery 12 is charged from the power supply 10.

Next, when the first relay S1 is turned off and the second relay S2 is turned on by the controller 13, the open / closed state of each contact is reversed. Therefore, the pressure sensor 2 is supplied with power from the second battery 12,
The first battery 11 will be charged from the power supply 10. The switching frequency and the interval of the controller 13 are determined by the capacities of the batteries 11 and 12.

During the above operation, in each of the batteries 11 and 12, a-contacts S1A and S2 connected to the pressure sensor side are connected.
Since either the A contact or the b contact S1B, S2B connected to the power supply side is turned off, the pressure sensor 2 and the power supply 10 are electrically insulated by these contacts. further,
As described above, between the pressure sensor 2 and the accident point rating device 5,
It is electrically insulated by the optical fiber cable 9.

Therefore, the pressure sensor 2 is insulated from the accident point locating device 5 and the power source 10 which are at the ground potential to form a float circuit. As a result, a high voltage surge or GIS1 generated when a ground fault or a short circuit in GIS1 occurs.
It is not affected by the floating potential of the container.
Therefore, the electronic circuit in the pressure sensor 2 will not be broken or malfunction due to the high voltage surge. Also, G
The insulator 3 provided in the pipe 4 between the IS 1 and the pressure sensor 2 may be small in size.

The pressure sensor 2 is the battery 11 or 1
Power is continuously supplied from 2 and there is no power outage. Even if the power supply for a moment stops when the batteries 11 and 12 are switched, the pressure sensor 2
Power is temporarily supplied by the capacitor 15 connected in parallel with the power supply terminal of the. The capacitor 15 can be omitted.

Next, when it becomes necessary to discharge the battery once due to deterioration of the battery, the changeover switch S
W3 is switched, and the batteries 11 and 12 are switched from the power supply 10 to the discharge circuit 14 side. Then, while the power is supplied from the one battery to the pressure sensor 2, the other battery is discharged by the discharge circuit 14 to be refreshed. It is also possible to discharge both batteries 11 and 12 together.

The changeover switch SW3 and the discharge circuit 14 of the circuit for refreshing can be omitted. [Embodiment 2] Next, an example in which the battery is switched by reversing the polarity of the power source will be described with reference to FIG. In the following description, components having the same functions as those in the first embodiment described above are designated by the same reference numerals, and duplicate description will be omitted.

The relationship between the GIS 1 and the pressure sensor 2, the pressure sensor 2, the two batteries 11 and 12, the a contact S1A and the b contact S1B of the first relay S1, and the a contact S2A of the second relay S2. The relationship with the b-contact S1B is the same as in FIG. 1 of the first embodiment. The power supply 10 has a function of reversing its output polarity. The full-wave rectifier 18, the first relay S1, and the second relay S2 are connected to the power source 10 through the b contact S3B of the third relay S3. The first relay S1 and the second relay S2 are connected to the power supply 10 via diodes 16 and 17 having different polarities.

The output side of the full-wave rectifier 18 is the first relay S.
B contact S1B of 1 and b contact S2B of the second relay S2
Connected to. In addition, an a-contact S3A of the third relay S3 and a series connection body of the load 19 are connected to the output side of the full-wave rectifier 18. The operation of the third relay S3 is controlled by the battery refresh controller 19.

Next, the operation of this example will be described. First
Since the relay S1 and the second relay S2 are connected to the power supply 10 via the diodes 16 and 17 having different polarities, respectively, by switching the output polarity of the power supply 10, the first relay S1 and the second relay S2 are connected. The relay S2 operates alternately. As in the first embodiment, the power is supplied from the power supply 10 to the pressure sensor 2 in a state where the power supply 10 and the pressure sensor 2 are electrically insulated by alternately operating the two relays.

In this embodiment, the batteries 11 and 12 are
Can be controlled by one power supply circuit. Therefore, when the power supply device according to the present embodiment is applied to a plurality of pressure sensor circuits, the battery can be switched by the single power supply 10. Next, when it becomes necessary to discharge the battery once due to deterioration of the battery, the battery refresh controller 19 causes the third
Relay S3 is operated. By the operation of the third relay S3, the b-contact S3B is opened to disconnect the power source 10, and the first relay S1 and the second relay S2 are no longer excited.

As a result, the a contact S1A and the a contact S2
A is turned off, and the two batteries 11 and 12 are both disconnected from the pressure sensor 2. Further, since the b contact S1B of the first relay S1 and the b contact S2B of the second relay S2 are turned on and the a contact S3A of the third relay S3 is turned on, the batteries 11 and 12 are connected to the discharge resistor 20. It is discharged to be refreshed. In addition, it is also possible to transform so that one battery is discharged while another battery supplies power to the pressure sensor 2.

Also in the second embodiment, the circuit changeover switch SW3 for refreshing the battery, the battery refresh controller 19, and the discharge resistor 20 can be omitted. Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, but various modifications can be made within the scope of the claims.

For example, in the above embodiment, the power source 10
Is disconnected, the pressure sensor 2 and the batteries 11, 1
The a contacts S1A and S2A between the two are turned off, and the power supply to the pressure sensor 2 is stopped. On the other hand, when the power supply 10 is cut off, one of the batteries can be connected to the power supply terminal of the pressure sensor 2 so that power supply to the pressure sensor 2 can be continued.

[0030]

According to the present invention, it is possible to obtain an insulated power supply device capable of supplying electric power from a power supply to a circuit while electrically insulating the power supply from the circuit.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a first embodiment of the present invention.

FIG. 2 is a circuit diagram of a first embodiment of the present invention.

FIG. 3 is a circuit diagram of a conventional pressure sensor.

[Explanation of symbols]

 1 ... GIS 2 ... Pressure sensor 3 ... Insulator 4 ... Piping 5 ... Accident point evaluation device 9 ... Optical fiber cable 10 ... Power supply 11, 12 ... Battery 13 ... Controller 14 ... Discharge circuit 15 ... Capacitor 16, 17 ... Diode 18 ... Full wave rectifier 19 ... Battery refresh controller 20 ... Discharge resistance

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display location H02J 1/00 306 L 7346-5G

Claims (2)

[Claims] 1. A power supply device, which is connected between a power supply and a circuit and supplies power from the power supply to the circuit, is provided with two or more batteries, and each battery and the circuit are connected by a circuit side contact, An insulated power supply device, characterized in that each battery is connected to the power supply by a power supply side contact, and further control means for controlling opening and closing of the circuit side contact and the power supply side contact is provided. 2. The insulated power supply device according to claim 1, wherein a capacitor is used instead of the battery.