WO2024252685A1 - Lightning surge countermeasure device and power supply system - Google Patents

Abstract

A lightning surge countermeasure device used for a DC power supply system comprises: a first impedance part for increasing the impedance on the polarity side of any one of a positive electrode and a negative electrode; a lightning arrester on the positive electrode side; and a lightning arrester on the negative electrode side.

Description

Lightning surge protection devices and power supply systems

The present invention relates to technology for protecting DC power supply systems against lightning surges.

As a measure against lightning surges in DC power supply systems (e.g. DC/DC converters), it is known to install an SPD (Surge protective device) such as a zinc oxide varistor (hereafter referred to as varistor) on the output side (where lightning surges enter) of the DC power supply system. Note that surge protection devices may also be called lightning arresters.

For example, by installing the varistor described in Non-Patent Document 1 between the positive and ground electrodes of a DC power supply system, and between the negative and ground electrodes, it is possible to dissipate lightning surges that enter through cables connected to the DC power supply system to the ground via the varistor.

https://industrial.panasonic.com/jp/products/pt/surge-components, searched on May 31, 2020 https://article.murata.com/ja-jp/article/basics-of-noise-countermeasures-lesson-6, retrieved on May 31, 2020

However, conventional lightning surge countermeasures have the problem that if a lightning surge penetrates a cable connected to a DC power supply system, it can cause a breakdown in the internal circuitry of the DC power supply system. In other words, conventional technologies that use varistors, etc., have the problem that they are not very effective at countering lightning surges.

The present invention was made in consideration of the above points, and aims to improve the effectiveness of measures against lightning surges in DC power supply systems.

According to the disclosed technology, there is provided a lightning surge protection device for use in a DC power supply system, comprising:
a first impedance section for increasing the impedance of one of the positive and negative polarities;
A positive lightning arrester;
A negative lightning arrester;
There is provided a lightning surge protection device comprising:

The disclosed technology makes it possible to improve the effectiveness of measures against lightning surges in DC power supply systems.

FIG. 13 is a diagram showing a configuration example of a power supply system including a varistor as a measure against a lightning surge. FIG. 1 is a diagram for explaining a problem. FIG. 1 is a diagram for explaining a problem. FIG. 1 is a diagram for explaining a problem. 1 is a diagram illustrating a first configuration example of a power supply system according to an embodiment of the present invention. FIG. 11 is a diagram illustrating a second configuration example of a power supply system according to an embodiment of the present invention. 1 is a diagram illustrating an example of the configuration of a lightning surge protection device 100. FIG.

Below, an embodiment of the present invention (present embodiment) will be described with reference to the drawings. The embodiment described below is merely an example, and the embodiment to which the present invention is applied is not limited to the following embodiment. Below, a varistor is used as an example of a lightning arrester (surge protection device), but the technology according to the present invention can also be applied when a lightning arrester other than a varistor is used.

First, the conventional technology and its problems will be described in detail below, and then the technology related to this embodiment will be described in detail. Note that, regarding the conventional technology, the technology itself disclosed in Non-Patent Documents 1 and 2 is publicly known, but the contents of the description of the conventional technology and the description of the problems below are not publicly known.

(Regarding the Prior Art)
As mentioned above, a known method of countering lightning surges in DC power supply systems such as DC/DC converters is to install a varistor on the output side (where lightning surges enter) of the DC power supply system.

Fig. 1 shows an example of the configuration of a power supply system that includes a varistor as a countermeasure against lightning surges. In the example configuration shown in Fig. 1, on the output side of a DC power supply system 10 that includes an internal circuit 11, a varistor 22 is installed between the positive pole (any point on the cable on the positive pole side) and the ground pole, and a varistor 21 is installed between the negative pole (any point on the cable on the positive pole side) and the ground pole. This makes it possible for a lightning surge that has entered through the cable to escape to the ground via varistors 21 and 22.

(Regarding the issues)
However, when the internal circuit on the output side of the DC power supply system 10 (similar on the input side) is asymmetric, the solution of installing varistors 21, 22 between the positive electrode and the ground electrode and between the negative electrode and the ground electrode as shown in FIG. 1 may cause the problem shown in FIG. 2.

In FIG. 2, a diode 12 connected to an internal circuit 11 in a DC power supply system 10 is shown. The diode 12 is one of the internal circuits in the DC power supply system 10. The diode 12 may be described as the "internal circuit 12." The internal circuit 11 and the diode 12 may be collectively referred to as the "internal circuit." In the example of FIG. 2, the anode of the diode 12 is connected to the negative electrode, and the cathode is connected to the positive electrode.

As shown in Figure 2, if a lightning surge penetrates both the positive and negative cables, the varistor 21 installed between the negative and ground electrodes will not operate, and the lightning surge that penetrated the negative cable will flow into the positive varistor 22 via the diode 12 in the internal circuit. This can destroy the internal circuit and cause the DC power supply system 10 to fail.

However, as shown in Figure 3, if a lightning surge penetrates only the positive cable, the lightning surge current does not flow into the diode 12, and the positive varistor 21 operates normally. Therefore, the internal circuit is not destroyed by the lightning surge, and the DC power supply system 10 does not break down.

To address the issue shown in Fig. 2, as shown in Fig. 4, the common mode choke coil 30 disclosed in Non-Patent Document 2 can be placed between the internal circuit 12 and the varistors 21, 22 to make the varistors 21, 22 operate effectively. However, in the configuration of Fig. 4 that includes the common mode choke coil 30, the effect cannot be obtained unless the lightning surge penetrates not only the positive cable but also the negative cable.

In particular, as shown in FIG. 4, if a lightning surge (normal mode) enters only the negative cable, the lightning surge passes through the common mode choke coil 30, destroys the diode 12, and flows into the varistor 22 on the positive side. The damage to the diode 12 causes the DC power supply system to fail.

The configuration of this embodiment for solving the above problems is described in detail below.

(Configuration Example 1)
Fig. 5 shows a first configuration example of the power supply system according to the present embodiment. In the first configuration example, an impedance unit 23 is added between the positive electrode and the ground electrode to the configuration shown in Fig. 2.

In other words, the DC power supply system 10 includes a diode 12 (internal circuit 12). A positive cable and a negative cable extend from the DC power supply system 10.

A varistor 22 is provided between the positive electrode and the ground electrode, a varistor 21 is provided between the negative electrode and the ground electrode, and an impedance unit 23 is provided between the positive electrode and the ground electrode. In the example of FIG. 5, the impedance unit 23 is provided between the positive electrode and the varistor 22, but the impedance unit 23 may be provided between the varistor 22 and the ground electrode.

The configuration (part) including the varistors 21, 22 and the impedance section 23 is called the lightning surge protection device 100.

The impedance section 23 may be of any type as long as it has the function of increasing the impedance on the positive electrode side. "Increasing the impedance on the positive electrode side" means making the "impedance on the positive electrode side when the impedance section 23 is present" higher than the "impedance on the positive electrode side when the impedance section 23 is not present." In addition, the "impedance on the positive electrode side" is, for example, the impedance between the positive electrode and the ground electrode.

For example, the impedance unit 23 is an element that increases the impedance. The element is, for example, a resistor, a coil, or both a resistor and a coil.

The impedance section 23 may be configured to increase the impedance by modifying the circuit pattern. Deforming the circuit pattern may mean, for example, narrowing the board circuit pattern on the positive side (i.e., reducing the width of the conductors that make up the pattern), lengthening the board circuit pattern (increasing the length of the conductors that make up the pattern), or making the conductors zigzag or U-shaped while ensuring sufficient separation between the conductors in the board circuit pattern.

Note that the above board circuit pattern is the circuit pattern electrically connected between the positive electrode and the ground electrode in Figure 5.

In addition to or instead of deforming the circuit pattern as described above, the cable for connecting the varistor 22 between the positive electrode and the ground electrode may be thinned, or the shape of the cable may be coiled. Methods other than these may be used as long as they can realize the impedance section 23.

As shown in FIG. 5, the provision of the impedance section 23 makes it difficult for a lightning surge entering from the negative side to flow through the inside of the DC power supply system 10 and from the varistor 22 on the positive side to ground.

The magnitude of the impedance in the impedance section 23 can be set taking into consideration the dielectric strength (voltage) or current withstand capacity between the positive and negative electrodes.

In the example of FIG. 5, the impedance unit 23 is provided on the positive side, but this is just one example. Depending on the asymmetric characteristics of the internal circuit, the impedance unit may be provided on the negative side instead of the positive side.

(Configuration Example 2)
Fig. 6 shows a second example of the system configuration according to the present embodiment. As shown in Fig. 6, the second example of the system configuration is a configuration in which an impedance unit 24 for increasing the impedance on the negative electrode side (the impedance between the negative electrode and the ground electrode) is added between the negative electrode and the ground electrode to the first example of the system configuration (Fig. 5).

The method of realizing impedance unit 24 is the same as the method of realizing impedance unit 23, as described in configuration example 1. In other words, an element may be used as impedance unit 24, a modified circuit pattern may be used, a modified connection cable may be used, or other methods may be used.

In the example of FIG. 6, the impedance section 24 is provided between the negative electrode and the varistor 21, but the impedance section 24 may also be provided between the varistor 21 and the ground electrode.

When impedance sections (which increase the impedance) are placed on both the positive and negative sides, as in configuration example 2, a difference is created between the impedance on the positive side and the impedance on the negative side.

For example, when the impedance of the impedance section 23 on the positive side is Z _positive and the impedance of the impedance section 24 on the negative side is Z _negative , the following relationship may be established.

Z _positive > α × Z _negative
α is, for example, a real number equal to or greater than 1. α is a coefficient that depends on the device to be protected against the surge, and depends, for example, on the dielectric strength (voltage) between the positive and negative electrodes or the current withstand capacity. Alternatively, α may depend on the dielectric strength (voltage) between the positive electrode and the ground or between the negative electrode and the ground. α may be determined appropriately depending on the power supply system in which the lightning surge protection device 100 is installed.

In configuration example 2, by making the impedance on the positive electrode side higher than the impedance on the negative electrode side, it is possible to make it difficult for a lightning surge entering from the negative electrode side to flow from the varistor 22 on the positive electrode side to ground through the inside of the DC power supply system 10, just like in configuration example 1.

(Example of configuration of lightning surge protection device 100)
Fig. 7 shows an example of the configuration of the lightning surge protection device 100. The configuration shown in Fig. 7 corresponds to the configuration of Fig. 6, in which the portion of the lightning surge protection device 100 provided on the cable connected to the DC power supply system is extracted.

As shown in FIG. 7, the lightning surge protection device 100 includes a positive impedance section 110, a positive lightning arrester 120, a negative impedance section 130, a negative lightning arrester 140, and a ground electrode 150.

The impedance section 23 shown in FIG. 6 is an example of the impedance section 110, the impedance section 24 is an example of the impedance section 130, the varistor 22 is an example of the lightning arrester 120, and the varistor 22 is an example of the lightning arrester 140.

In addition, in FIG. 7, it is also possible to have only one of the positive impedance section 110 and the negative impedance section 130.

(Effects of the embodiment)
By introducing the lightning surge protection device 100 described above, even if a lightning surge penetrates both the positive and negative cables, or only the negative cable, both the positive and negative varistors will operate and the lightning surge that has penetrated the negative side will no longer flow into the positive varistor via the internal circuit, thereby increasing the effectiveness of the lightning surge protection device.

The following notes are further provided with respect to the above embodiment.

<Additional Notes>
(Additional Note 1)
A lightning surge protection device for use in a DC power supply system, comprising:
a first impedance section for increasing the impedance of one of the positive and negative polarities;
A positive lightning arrester;
A negative lightning arrester;
A lightning surge protection device equipped with:
(Additional Note 2)
2. The lightning surge protection device according to claim 1, further comprising: a second impedance section for increasing impedance on a side having a polarity opposite to that on which the first impedance section is provided.
(Appendix 3)
The lightning surge protection device according to claim 2, further comprising a difference between an impedance of the first impedance section and an impedance of the second impedance section.
(Additional Note 4)
The lightning surge protection device according to any one of appended claims 1 to 3, wherein on the side of the polarity on which the first impedance section is provided, the first impedance section is provided between a cable and a lightning arrester, or between the lightning arrester and a ground electrode.
(Additional Note 5)
A power supply system comprising: a DC power supply system; and the lightning surge protection device according to any one of claims 1 to 4.

The present embodiment has been described above, but the present invention is not limited to this specific embodiment, and various modifications and variations are possible within the scope of the gist of the present invention as described in the claims.

REFERENCE SIGNS LIST 10 DC power supply system 11 Internal circuit 12 Diodes 21, 22 Varistors 23, 24 Impedance section 100 Lightning surge protection device 110 Impedance section 120 Lightning arrester 130 Impedance section 140 Lightning arrester 150 Ground electrode

Claims (5)

A lightning surge protection device for use in a DC power supply system, comprising:
a first impedance section for increasing the impedance of one of the positive and negative polarities;
A positive lightning arrester;
A negative lightning arrester;
A lightning surge protection device equipped with: The lightning surge protection device according to claim 1 , further comprising a second impedance section for increasing impedance on a side having a polarity opposite to that on which the first impedance section is provided. The lightning surge protection device according to claim 2 , wherein a difference is provided between the impedance of the first impedance section and the impedance of the second impedance section. The lightning surge protection device according to any one of claims 1 to 3, wherein on the side of the polarity on which the first impedance section is provided, the first impedance section is provided between a cable and a lightning arrester, or between the lightning arrester and a ground electrode. A power supply system comprising a DC power supply system and the lightning surge protection device according to any one of claims 1 to 3.

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