JPWO2006114882A1 - Gas tube arrester and circuit device - Google Patents

Abstract

A sealed wall that seals a space sandwiched between a plurality of electrodes in an airtight state, a gas sealed in the sealed space, a marker that is provided in the sealed space and changes color in response to outside air By providing the gas tube arrester, it is possible to visually determine the gas loss. In particular, the gas tube arrester includes a plurality of electrodes and a transparent gas pipe that seals the rare gas, and a marker that is provided in the transparent gas pipe and changes color irreversibly in response to oxygen. As a result, when the rare gas in the gas pipe escapes and the outside air containing oxygen enters the gas pipe, the marker in the gas pipe reacts with the oxygen and changes color. It is possible to judge automatically.

Description

  The present invention relates to a gas tube arrester for protecting a circuit affected by a surge voltage from the surge voltage, and a circuit device using the gas tube arrester.

In the conventional lightning impulse voltage protection element described in Japanese Patent Application Laid-Open No. 2002-152966, the thermal ink is applied to the outer coating, and the replacement time of the protection element is determined by looking at the color of the thermal ink. Is possible.
That is, when a lightning impulse voltage is applied to the lightning impulse voltage protection element, a large current flows through the lightning impulse voltage protection element, and the thermal ink applied to the protection element is irreversibly due to Joule heat generated by the large current. Therefore, the maintenance inspector can determine whether or not the lightning impulse is applied to the lightning impulse voltage protection element by looking at the color of the thermal ink.

However, in such a conventional lightning impulse voltage protection element, when the protection element is a gas tube arrester, it has not been possible to accurately determine whether or not gas has escaped from the protection element.
JP 2002-152966 JP

  The present invention has been made in view of the above circumstances, and it is possible for a maintenance inspector to visually determine whether or not gas has escaped from the gas tube arrester, and to make the determination as accurately as possible. An object is to obtain a gas tube arrester and a circuit device using the gas tube arrester.

  The gas tube arrester according to the present invention includes a plurality of electrodes, a sealing wall that hermetically seals a space between the plurality of electrodes, a gas sealed in the sealed space, and the sealed space. And a marker that changes color in response to outside air.

  A gas tube arrester according to the present invention includes a gas tube arrester comprising a plurality of electrodes, a sealing wall that seals a space sandwiched between the plurality of electrodes in an airtight state, and a gas sealed in the sealed space, A container into which the gas tube arrester is inserted; and a marker that is provided inside the container outside the sealed wall and changes color in response to the gas sealed in the sealed space.

  A gas tube arrester according to the present invention is a gas tube arrester comprising a plurality of electrodes, a sealing wall that seals a space sandwiched between the plurality of electrodes in an airtight state, and a gas sealed in the sealed space. And the said sealing wall produces the damage which can be visually recognized before the said gas tube arrester loses the function as a lightning surge protection element by the gas escape from the said space.

  The gas tube arrester according to the present invention includes a plurality of electrodes, a sealing wall that hermetically seals a space between the plurality of electrodes, a gas sealed in the sealed space, and the sealed space. It is provided with a marker that changes color in response to the outside air, so that a maintenance inspector can visually determine whether or not gas has escaped from the gas tube arrester, and make the determination as accurately as possible. A gas tube arrester that can be performed can be obtained.

  A gas tube arrester according to the present invention comprises a plurality of electrodes, a sealing wall that seals a space sandwiched between the plurality of electrodes in an airtight state, and a gas tube arrester that is sealed in the sealed space; Maintenance is provided with a container into which the gas tube arrester is inserted, and a marker that is provided in the container outside the sealed wall and changes color in response to the gas sealed in the sealed space. It is possible for the inspector to visually determine whether or not gas has escaped from the gas tube arrester, and to obtain a gas tube arrester that can make the determination as accurately as possible.

  A gas tube arrester according to the present invention is a gas tube arrester comprising a plurality of electrodes, a sealing wall for sealing a space sandwiched between the plurality of electrodes in an airtight state, and a gas sealed in the sealed space. The sealing wall causes visible damage before the gas tube arrester loses its function as a lightning surge protection element due to gas escaping from the space. It is possible to obtain a gas tube arrester that can visually determine the presence or absence of outgassing.

It is a figure which illustrates the gas tube arrester in Embodiment 1 by this invention. It is a figure which shows the example of a circuit using the gas tube arrester by this invention. It is a figure which illustrates the gas tube arrester in Embodiment 2 by this invention. It is a figure which illustrates the gas tube arrester in Embodiment 3 by this invention.

Explanation of symbols

  1,31,41 Gas tube arrester, 2a electrode, 2b electrode, 3,43 sealed wall, 4,34 marker, 5 space, 6 outside air, 7 printed circuit board, 38 container.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a gas tube arrester according to Embodiment 1 of the present invention. In the figure, 1 is a gas tube arrester, 2a and 2b are electrodes, 3 is a sealing wall that seals the space 5 sandwiched between the electrodes 2a and 2b in an airtight state, 4 is provided in the sealed space 5 and the outside air 6 A marker 7 that changes color when touched is a printed circuit board. At least a part of the sealing wall 3 is transparent, and the color of the marker 4 is visible from the outside through the transparent part. A gas (not shown) that generates arc discharge when a high voltage is applied is sealed in the sealed space 5. The gas tube arrester 1 is fixed on the printed circuit board 7 so that the color of the marker 4 is visible from above the printed circuit board 7. The marker 4 has a heat resistance characteristic that does not change or discolor due to Joule heat generated by a lightning surge current flowing through the space 5.

More specifically, 3 is, for example, a transparent gas pipe, and 4 is a sheet whose color changes irreversibly when it comes into contact with oxygen. The sheet 4 is affixed inside the gas pipe 3. A rare gas is sealed in the gas pipe 3, and outside air 6, that is, air 6 exists around the gas pipe 3. In the normal gas tube arrester 1, a rare gas is sealed in the gas pipe 3, and oxygen is hardly present in the gas pipe 3. Therefore, the color of the sheet 4 in the gas pipe 3 is not changed or hardly changed. On the other hand, when the rare gas in the gas pipe 3 is out of gas, the air 6 is mixed into the gas pipe 3, and the sheet 4 in the gas pipe 3 reacts with oxygen contained in the air 6 and changes color. .
As a result, the maintenance manager of the gas tube arrester 1 can visually determine whether or not the rare gas in the gas pipe 3 is missing simply by looking at the color of the sheet 4 in the gas pipe 3. Become.

The operation of the normal gas tube arrester 1 will be described. Here, it is assumed that a circuit to be protected from lightning surge voltage is connected to the electrode 2a side, and the electrode 2b side is grounded.
In a normal gas tube arrester, a rare gas is sealed in the gas pipe 3, and when a high voltage such as a lightning surge voltage is applied between the electrodes 2a and 2b, arc discharge occurs between the electrodes 2a and 2b. . In this arc discharge, since the voltage between the electrodes 2a and 2b is stabilized at a low voltage, the circuit connected to the electrode 2a is protected from the high voltage. Further, when the voltage applied between the electrodes 2a and 2b is a low voltage equal to or lower than the discharge start voltage of the rare gas, almost no current flows between the electrodes 2a and 2b (however, it is extremely called dark current) A weak current may flow), and the low voltage is applied as it is to the circuit connected to the electrode 2a.

  On the other hand, when the gas tube arrester is out of gas and no or rare gas is present in the gas pipe 3, when a high voltage such as a lightning surge voltage is applied between the electrodes 2a and 2b, Arc discharge does not occur in the gas pipe 3, and the high voltage is applied to the circuit connected to the electrode 2a as it is, and the circuit is damaged.

  FIG. 2A and FIG. 2B are diagrams illustrating circuit examples using the gas tube arrester in the first embodiment. 2A illustrates the case where the normal voltage Vsig is input to the device 21, and FIG. 2B illustrates the case where the lightning surge voltage Vp is input to the device 21.

  2 (a) and 2 (b), the same reference numerals as those in FIG. 2A and 2B, the apparatus 21 includes a gas tube arrester 1, a varistor 22, a diode 23, an internal circuit 24, a signal line 25, and a signal line 26. Vsig is a normal voltage (signal voltage) input from the external device 27 to the device 21, and Vp is a lightning surge voltage input to the device 21.

  2A and 2B, the first gas tube arrester 1 is provided between the signal line 25 and the ground, and the second gas tube arrester 1 is provided between the signal line 26 and the ground. Is provided. In addition, a first varistor 22 is provided between the signal line 25 and the signal line 26 on the side of the internal circuit 24 relative to the first and second gas tube arresters 1. Further, the second varistor 22 is provided between the signal line 25 and the ground, and the third varistor 22 is provided between the signal line 26 and the ground, on the internal circuit 24 side of the first varistor 22. It has been. A first diode 23 is provided between the signal line 25 and the ground on the side of the internal circuit 24 relative to the second and third varistors 22, and a second diode is provided between the signal line 26 and the ground. 23 is provided. In FIG. 2A and FIG. 2B, the second and third varistors and the first and second diodes can be omitted.

  The circuit operation in FIG. 2A will be described. In FIG. 2A, the normal voltage Vsig is input to the device 21 from the external device 27. At this time, only a very small amount of leakage current IL called dark current flows through the gas tube arrester 1, varistor 22, and diode 23, and the normal voltage Vsig input to the device 21 is input to the internal circuit 24 almost as it is. The

  On the other hand, in FIG. 2B, when a lightning surge voltage Vp is input to the device 21, the impedance of each protective element such as the gas tube arrester 1, the varistor 22, and the diode 23 rapidly decreases, and lightning is applied to each protective element. A surge current Ip flows. As a result, it is possible to avoid the voltage input to the internal circuit 24 being lowered to the clamp voltage Vc (Vc << Vp) and the lightning surge voltage Vp being directly input to the internal circuit 24.

  As described above, the gas tube arrester according to Embodiment 1 is a gas tube arrester in which a space sandwiched between a plurality of electrodes is hermetically sealed, and gas is sealed in the sealed space. A marker that changes color in response to outside air is provided so that it can be seen from the outside of the gas tube arrester. In addition, it is possible to make the determination as accurately as possible.

Embodiment 2. FIG.
FIG. 3 is a diagram illustrating a gas tube arrester according to an embodiment of the present invention.
In FIG. 3, 31 is a gas tube arrester, 2a and 2b are electrodes, 3 is a sealing wall that hermetically seals the space 5 sandwiched between the electrodes 2a and 2b, 38 is a container into which the gas tube arrester 31 is inserted, 34 Is a marker provided at a position outside the gas tube arrester 31 and inside the container 38, and 7 is a printed circuit board.
A gas (not shown) that generates an arc discharge when a high voltage is applied is sealed in the sealed space 5, and 34 is a marker that changes color in response to the gas sealed in the space 5. . At least a part of the container 38 is transparent, and the color of the marker 34 is visible from the outside of the container 38 through the transparent part. Thus, the gas tube arrester 31 inserted into the container 38 is fixed on the printed circuit board 7 so that the color of the marker 34 can be seen from above the printed circuit board 7.

More specifically, 3 is, for example, a transparent gas pipe, and a rare gas is sealed in the gas pipe 3. 34 is a paint that changes irreversibly when it touches the rare gas sealed in the gas pipe 3, and is applied to the inside of the container 38. The container 38 is an insulating container having a transparent side surface, for example, and a gas (for example, air) that does not change the color of the paint 34 is sealed in the space between the container 38 and the gas tube arrester 31. Although FIG. 3 shows an example in which the paint 34 is applied to a part of the inside of the container 38, the paint 34 may be applied to the entire inside of the container 38.
In the normal gas tube arrester 1, the rare gas in the gas pipe 3 does not leak out of the gas pipe 3, and the paint 34 does not touch the rare gas. Therefore, the color of the paint 34 is not changed or hardly changed. On the other hand, when a rare gas in the gas pipe 3 leaks into the container 38 due to a lightning surge voltage flowing in the gas pipe 3, the paint 34 reacts with the rare gas and changes color.
Thereby, the maintenance manager of the gas tube arrester 31 can visually determine whether or not the rare gas in the gas pipe 3 is out of gas by looking at the color of the paint 34 in the container 38. It is.

  The gas tube arrester 31 with a container shown in FIG. 3 can be used in place of the gas tube arrester 1 in the circuits shown in FIGS. 2 (a) and 2 (b). In the circuit shown in FIG. 2B, the gas tube arrester 1 and the gas tube arrester 31 with a container may be mixed.

  As described above, the gas tube arrester according to the second embodiment is a gas tube arrester in which a space sandwiched between a plurality of electrodes is hermetically sealed and gas is sealed in the sealed space. While placing the arrester in the container, a marker that changes color in response to the gas leaked from the gas tube arrester is provided inside the container and outside the gas tube arrester so as to be visible from the outside of the container. Therefore, it is possible for the maintenance inspector of the gas tube arrester to visually determine whether or not gas has escaped from the gas tube arrester, and to make the determination as accurately as possible.

Embodiment 3 FIG.
FIG. 4 is a diagram illustrating a gas tube arrester according to an embodiment of the present invention.
In FIG. 4, 41 is a gas tube arrester, 2a and 2b are electrodes, 43 is a sealing wall that hermetically seals the space 5 sandwiched between the electrodes 2a and 2b, and 7 is a printed circuit board. A gas (not shown) that generates arc discharge when a high voltage is applied is sealed in the sealed space 5. In the third embodiment, the sealing wall 43 of the gas tube arrester 41 is made of a material that easily cracks, and before the gas tube arrester 41 loses its own function as a lightning protection element and reaches the end of its life. In addition, the sealing wall 43 is configured to crack.

For example, 43 is a thin gas pipe, and is configured such that when a lightning surge voltage is applied to the gas tube arrester 41, cracking occurs due to Joule heat generated thereby or gas expansion in the gas pipe. It is desirable that the cracks have such a size that the rare gas is difficult to escape from the gas pipe 43 and is easily visible, and the rare gas is such that arc discharge is generated in the gas pipe within the duration of the lightning surge voltage that caused the crack. It is desirable that the cracks are sufficient to hold.
As a result, the maintenance manager of the gas tube arrester 1 can visually determine whether or not the rare gas in the gas pipe 43 has escaped by looking at the cracks in the gas pipe 43.

  As described above, the gas tube arrester according to the second embodiment is a gas tube arrester in which a space sandwiched between a plurality of electrodes is hermetically sealed and gas is sealed in the sealed space. Since the gas tube arrester is visibly damaged before the gas leaks from the arrester, it is possible for the gas tube arrester maintenance inspector to visually determine whether or not the gas tube arrester is out of gas. Become.

The present invention can be used in a gas tube arrester or the like for protecting a circuit in a device grounded outdoors from a lightning surge voltage.

Claims (20)

  A plurality of electrodes, a sealed wall for sealing a space between the plurality of electrodes in an airtight state, a gas sealed in the sealed space, and provided in the sealed space, and reacting to the outside air A gas tube arrester comprising a marker that changes color.   The gas tube arrester according to claim 1, wherein the marker changes color in response to oxygen.   2. The gas tube arrester according to claim 1, wherein at least a part of the sealing wall is transparent, and the color of the marker is visible from the outside of the sealing wall through the transparent part.   The gas tube arrester according to claim 3, wherein the marker is formed in a sheet shape and is affixed to the inside of the sealed wall.   2. The gas tube arrester according to claim 1, wherein the marker has heat resistance against Joule heat generated by a surge current flowing in the sealed space.   The gas tube arrester according to claim 1, wherein the sealing wall is a transparent tube.   A circuit device, wherein the gas tube arrester according to claim 1 is fixed on a substrate so that a marker of the gas tube arrester is visible from above the substrate. A gas tube arrester comprising a plurality of electrodes, a sealing wall that seals a space sandwiched between the plurality of electrodes in an airtight state, and a gas sealed in the sealed space;
A container into which the gas tube arrester is inserted;
A gas tube arrester with a container, comprising a marker that is provided inside the container outside the sealed wall and changes color in response to the gas sealed in the sealed space.   The gas tube arrester with a container according to claim 8, wherein the gas sealed in the space is a rare gas, and the marker changes color in response to the rare gas.   The gas tube arrester with a container according to claim 8, wherein at least a part of the container is transparent, and the color of the marker is visible from the outside of the container through the transparent part.   The marker is a paint that changes color in response to a rare gas, and the paint is applied to at least one of the inside of the container or the outside of the sealing wall. Gas tube arrester with container.   The gas tube arrester with a container according to claim 8, wherein the container is made of an insulator.   The gas tube arrester according to claim 8, wherein the container is a transparent container.   A circuit device, wherein the gas tube arrester according to claim 8 is fixed on a substrate so that a marker of the gas tube arrester is visible from above the substrate.   A gas tube arrester comprising a plurality of electrodes, a sealing wall for sealing a space sandwiched between the plurality of electrodes in an airtight state, and a gas sealed in the sealed space, wherein the sealing wall is A gas tube arrester that causes visible damage before the gas tube arrester loses its function as a lightning surge protection element due to outgassing from the space.   The gas tube arrester according to claim 15, wherein the breakage is a crack generated in the sealed wall.   The damage is caused by a decrease in strength of the sealed wall due to Joule heat generated by a surge current flowing through a gas in the sealed space or expansion of the gas due to the Joule heat. Item 16. A gas tube arrester according to Item 15.   A circuit device comprising: a circuit affected by a surge voltage; and the gas tube arrester according to claim 1 electrically connected between an input portion to the circuit and GND.   A circuit device comprising: a circuit affected by a surge voltage; and the gas tube arrester according to claim 8 electrically connected between an input section to the circuit and GND. A circuit device comprising: a circuit affected by a surge voltage; and the gas tube arrester according to claim 15 electrically connected between an input portion to the circuit and GND.

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