JP2010211928A - Spd with breaker plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thin-type low-cost SPD (Surge Protective Device) with a breaker plate for detaching zinc oxide-form varistors quickly and without fail in case of abnormal heat generation caused by deterioration or the like of zinc oxide-form varistors. <P>SOLUTION: The SPD includes two pieces of zinc oxide-form varistors 20 juxtaposed in an insulating case 10 and connected in series between a single-phase AC-operated electric apparatus and the ground, a thermal fuse 30 made of low-temperature molten metal and connected between the two zinc oxide-form varistors 20 which melts by abnormal heat generated at least by one of the zinc oxide varistors 20, and an insulating breaker plate 40 arranged between the zinc oxide varistors 20 for displacing itself so that the thermal fuse 30 is cut off at a softening time of the thermal fuse 30 caused by abnormal heat generation of the zinc oxide varistors 20. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention incorporates a zinc oxide varistor, and is suitable for direct lightning protection that protects electrical equipment from the direct lightning by absorbing surge voltage due to direct lightning strike, and failure or deterioration of the zinc oxide varistor. The present invention relates to a SPD (Surge Protective Device) with a shield plate having a thermal fuse function as protection against the above.

  For example, for the purpose of preventing lightning damage due to direct lightning strikes, an SPD is installed as a device that shunts surge current by limiting transient overvoltage due to direct lightning strikes between electrical equipment and the ground in a single-phase 400V AC circuit. . This direct lightning SPD includes a structure in which a zinc oxide varistor is incorporated.

  When a lightning surge is repeatedly applied, the zinc oxide varistor deteriorates with time depending on the current level of the lightning surge. When the zinc oxide varistor deteriorates, the leakage current increases and heat is generated, causing smoke and ignition due to thermal runaway. For this reason, SPD has been proposed that has a thermal fuse function as protection for preventing smoke and ignition due to thermal runaway of a zinc oxide varistor (see, for example, Patent Document 1).

  The SPD disclosed in Patent Document 1 has a structure in which a low melting point metal alloy plate is connected between one terminal of a zinc oxide varistor and its electrode terminal. This low-melting-point metal alloy plate exhibits a thermal fuse function, so that when the zinc oxide varistor is abnormally heated due to failure or deterioration, the zinc oxide varistor can be disconnected from the power supply circuit.

  For example, when abnormal heat generation occurs in the zinc oxide varistor due to deterioration of the zinc oxide varistor, heat is transferred from the terminal of the zinc oxide varistor to the low melting point metal alloy plate. When the temperature of the connecting portion between the low melting point metal alloy plate and the terminal exceeds the melting point of the low melting point metal alloy plate, the low melting point metal alloy plate is melted and the zinc oxide varistor terminal and the electrode terminal are fused. By melting the low-melting point metal alloy plate, the zinc oxide varistor is disconnected from the power supply circuit to prevent smoke ignition due to thermal runaway of the zinc oxide varistor.

JP 2006-179842 A

  By the way, in the above-mentioned conventional SPD, when the connecting portion between the terminal of the zinc oxide varistor and the low melting point metal alloy plate reaches the melting point of the low melting point metal alloy plate, the low melting point metal alloy plate melts, The zinc varistor is disconnected from the power circuit. Therefore, the zinc oxide varistor cannot be separated in the softening temperature state of the terminal and the low melting point metal alloy plate due to abnormal heat generation of the zinc oxide varistor. However, as a protection against the deterioration of the zinc oxide varistor, it is preferable to separate the zinc oxide varistor when the softening temperature is reached before the low melting point metal alloy plate is melted from the viewpoint of ensuring safety.

  The reason is as follows. In the conventional SPD, the connection portion between the terminal of the zinc oxide type varistor and the low melting point metal alloy plate is melted, so that the zinc oxide type varistor is separated from the power supply circuit. If the melted part of the low melting point metal alloy plate flows after the melted state, the means for securing the separation distance between the terminal and the low melting point metal alloy plate, or the melted part is connected to other charged parts. This is because it is necessary to take care not to adversely affect the intrusion. Furthermore, since there is a difference in the time to reach the softening point temperature and the melting point temperature of the low melting metal alloy sheet, the quick disconnect of the zinc oxide type varistor improves safety. It is more desirable to separate the alloy plate when it softens.

  On the other hand, the SPD used in the single-phase 400V AC circuit has a built-in zinc oxide varistor rated for 400V AC circuit specifications. The zinc oxide varistor rated for 400V AC circuit is thick, and the SPD It will also be thickened. Moreover, the zinc oxide type varistor rated for the 400V AC circuit specification is not general and expensive. In the SPD used in such a 400V AC circuit, a thin and inexpensive one that can quickly and surely separate the zinc oxide varistor when there is an abnormal heat generation due to deterioration of the zinc oxide varistor or the like is desired. .

  Therefore, the present invention has been proposed in response to the above-mentioned demand, and the purpose of the present invention is to quickly and reliably disconnect the zinc oxide varistor when an abnormal heat generation occurs due to deterioration of the zinc oxide varistor or the like. An object of the present invention is to provide a thin and inexpensive SPD with a shielding plate.

  As technical means for achieving the above-mentioned object, the present invention includes two zinc oxide varistors connected in series between an electric device and a ground in a single-phase AC circuit, and juxtaposed in an insulating case, The zinc oxide type varistor is connected between the two zinc oxide type varistors, and is disposed between the zinc oxide type varistor and a temperature fuse made of a low melting metal that blows off due to abnormal heat generation of at least one of the zinc oxide type varistors. And an insulating insulating plate that is displaced so as to sever the thermal fuse when the thermal fuse is softened due to abnormal heat generation of the varistor.

  For example, in the case of a 400V AC circuit SPD, the 400V AC circuit specification rated zinc oxide varistor is thick and expensive, whereas the 200V AC circuit specification rated zinc oxide varistor generally used is 400V. It is thin and inexpensive, with a thickness about half that of the rated AC circuit specifications. Therefore, in the present invention, two zinc oxide varistors having a 200V AC circuit specification rating are connected in series between an electric device and a ground in a single-phase AC circuit and juxtaposed in an insulating case, so that the SPD is thin. It is easy to realize reduction and cost reduction.

  Also, if abnormal heat generation occurs due to deterioration of at least one of the zinc oxide varistors, the temperature fuse connected between the two zinc oxide varistors will melt, but it will soften before the temperature fuse melts. At that time, the insulating breaker disposed between the two zinc oxide varistors is displaced to break the thermal fuse. As a result, the two zinc oxide varistors can be separated quickly, ensuring protection of the zinc oxide varistor and ensuring safety. In addition, when the thermal fuse is divided by the insulating breaker plate, the insulating breaker plate is interposed between the two divided thermal fuse pieces, so that insulation at the melting point of the thermal fuse can be secured. The individual zinc oxide varistors can be reliably separated.

  The insulating blocking plate according to the present invention has a plate shape having a through-hole through which a thermal fuse is inserted, and presses the thermal fuse at the periphery of the through-hole by the elastic force of an elastic member disposed between the insulating case and the insulating case. A structure is desirable. With such a structure, when abnormal heat generation occurs due to deterioration of the zinc oxide type varistor, the thermal insulation can be quickly displaced when the thermal fuse is softened, and the thermal fuse can be divided. An insulating insulating plate can be reliably interposed between the two thermal fuse pieces.

  In addition, the insulating blocking plate according to the present invention preferably has a structure having a deterioration display portion that protrudes from the insulating case due to the displacement. In this way, when abnormal heat generation occurs due to deterioration of the zinc oxide varistor, etc., the deterioration display part protrudes from the insulating case, so that abnormality such as deterioration of the zinc oxide varistor can be visually confirmed. it can.

  According to the present invention, two zinc oxide varistors are connected in series between an electric device and a ground in a single-phase AC circuit, and are juxtaposed in an insulating case, so that it is easy to realize a thin and inexpensive SPD. I have to.

  Also, in the event of abnormal heat generation due to deterioration of the zinc oxide varistor, etc., when the thermal fuse connected between the two zinc oxide varistors is softened before melting, the two zinc oxide varistors are Displacement of the insulating insulating plate placed to break the thermal fuse enables quick disconnection of the zinc oxide varistor, ensuring protection of the zinc oxide varistor and ensuring safety. .

  Furthermore, when the thermal fuse is divided by the insulating breaker plate, the insulating breaker plate interposed between the two separated thermal fuse pieces can ensure insulation at the melting point of the thermal fuse, and the zinc oxide The varistor can be cut off reliably. Moreover, a small and inexpensive SPD can be provided by providing one insulating blocking plate common to two zinc oxide varistors.

It is an assembly disassembled perspective view which shows the whole structure of SPD with a shielding board in embodiment of this invention. It is sectional drawing which shows an internal structure in the assembly completion state of SPD with a shielding board of FIG. It is sectional drawing which follows the AA line of FIG. (A) is an expanded partial perspective view which shows the thermal fuse and insulating insulating board of FIG. 2, (b) is sectional drawing of (a). FIG. 3 is a cross-sectional view showing an operating state of the blocking plate of the SPD with blocking plate in FIG. It is sectional drawing which follows the BB line of FIG. (A) is an expanded partial perspective view which shows the thermal fuse and insulating insulating board of FIG. 5, (b) is sectional drawing of (a).

  Embodiments of the SPD with a blocking plate according to the present invention will be described in detail below. INDUSTRIAL APPLICABILITY The present invention is suitable for a direct lightning SPD that absorbs a surge voltage caused by a direct lightning strike with a zinc oxide varistor and protects an electrical device from the direct lightning strike. 1 is an exploded perspective view of an SPD with a blocking plate, FIG. 2 is a sectional view of the SPD with a blocking plate that has been assembled, and FIG. 3 is a sectional view taken along line AA in FIG.

  The SPD with a blocking plate of the embodiment shown in FIGS. 1 to 3 exemplifies a 400V AC circuit, for example, in a resin insulating case 10, two zinc oxide varistors 20 having a 200V AC circuit specification rating, A structure in which the thermal fuse 30 and the insulating shielding plate 40 are accommodated as main components is provided.

  The insulating case 10 has a half structure composed of a pair of case halves 11, and the two zinc oxide varistors 20, the thermal fuse 30, and the insulating breaker are formed by joining and integrating the case halves 11. Main components including the plate 40 are stored. The case half 11 is formed with a slit 12 for removing gas generated when the zinc oxide varistor 20 fails.

  The aforementioned zinc oxide varistor 20 has a substantially rectangular parallelepiped shape, and the electrodes 21 and 22 (see FIG. 1) are exposed on both opposing side surfaces (vertical direction in FIG. 2). An electrode terminal 72 is attached to one electrode 21 of the zinc oxide type varistor 20 via a metal fitting 71 and led out of the insulating case 10. Two zinc oxide varistors are connected in series between the electrical equipment and the ground in a single-phase 400V AC circuit.

  A thermal fuse 30 is attached to the other electrode 22 of the zinc oxide varistor 20 via a metal fitting 81. The temperature fuse 30 is installed at the tip of a metal fitting 81 extending from the electrodes 22 of the two zinc oxide varistors 20. The thermal fuse 30 is made of a low melting metal that melts due to abnormal heat generation due to deterioration of the zinc oxide varistor 20 or the like and does not melt due to self-heating when a surge current is below the rated withstand voltage.

  The insulating blocking plate 40 is disposed between the opposing side surfaces of the two zinc oxide varistors 20 and has a strip shape extending in the vertical direction in the figure. ), A through hole 41 through which the thermal fuse 30 arranged so as to be orthogonal to the extending direction of the insulating blocking plate 40 is inserted is formed. A spring 60, which is an elastic member, is interposed between the base end portion of the insulating blocking plate 40 and the insulating case 10, so that the insulating blocking plate 40 can be displaced upward in the drawing by the elastic force of the spring 60. Is energized.

  In addition, a cylindrical deterioration display portion 42 is provided at the distal end portion of the insulating blocking plate 40 and is disposed in the hole 13 of the insulating case 10. Furthermore, a lever portion 43 is provided at the distal end portion of the through hole 41 of the insulating blocking plate 40 so as to project perpendicularly to the direction in which the insulating blocking plate 40 extends, and an insulating property is provided at the tip of the lever portion 43. Protrusions 44 that can contact the contacts 50 disposed at the corners of the case 10 are formed. The contact 50 is used to take out as an alarm signal that abnormal heat generation has occurred due to deterioration of the zinc oxide varistor 20 or the like.

  In the SPD for 400V AC electric circuit in this embodiment, the zinc oxide varistor rated for 400V AC electric circuit is thick and expensive, whereas the zinc oxide varistor 20 rated for 200V AC electric circuit used in this embodiment is used. Is thin and inexpensive, having a thickness about half that of a rated voltage of 400V AC circuit. In this SPD, two zinc oxide varistors 20 having a 200 V AC circuit specification rating are connected in series and juxtaposed in the insulating case 10, thereby making it easy to reduce the thickness and cost of the SPD.

  1 to 4 (a) and 4 (b) show SPDs in a normal state where there is no abnormal heat generation due to deterioration of the zinc oxide varistor 20 or the like. At this time, the insulating blocking plate 40 is in the initial position against the elastic force of the spring 60 and is in a state of pressing the thermal fuse 30 at the periphery of the through hole 41. At this time, the deterioration display portion 42 located at the tip of the insulating blocking plate 40 does not protrude from the hole 13 of the insulating case 10, and the tip surface of the deterioration display portion 42 is flush with the outer surface of the insulating case 10. It has become. Further, the convex portion 44 of the lever portion 43 extending from the insulating blocking plate 40 is in contact with the contact 50, so that the contact is closed.

  On the other hand, FIG. 5 to FIG. 7A and FIG. 7B show a case where abnormal heat generation occurs due to deterioration of the zinc oxide varistor 20 or the like. At this time, the thermal fuse 30 connected between the electrodes 22 of the two zinc oxide varistors 20 via the metal fitting 81 is blown, but when the thermal fuse 30 is softened before melting, the two oxidized The insulating blocking plate 40 disposed between the zinc varistors 20 is displaced upward in the drawing by the elastic force of the spring 60 to divide the thermal fuse 30.

  As a result, the two zinc oxide varistors 20 can be separated quickly, and the zinc oxide varistor 20 can be reliably protected to ensure safety. Further, when the thermal fuse 30 is divided by the insulating breaker 40, the insulating breaker 40 is quickly displaced, and the two separated thermal fuse pieces 31 (see FIGS. 7A and 7B). Since the insulating blocking plate 40 is reliably interposed, it is possible to ensure the insulation at the melting point of the thermal fuse 30 and to reliably separate the two zinc oxide varistors 20.

  Further, at this time, when the insulating blocking plate 40 is displaced upward in the drawing, the deterioration display portion 42 provided at the tip thereof protrudes from the hole 13 of the insulating case 10. As described above, the deterioration display part 42 protrudes from the insulating case 10, whereby abnormality such as deterioration of the zinc oxide varistor 20 can be visually confirmed.

  Further, when the insulating blocking plate 40 is displaced upward in the drawing, the convex portion 44 of the lever portion 43 extending from the insulating blocking plate 40 is disengaged from the contact 50 so that the contact 50 is opened. Thereby, it is possible to take out as an alarm signal that abnormal heat generation has occurred due to deterioration of the zinc oxide varistor 20 or the like.

  The present invention is not limited to the above-described embodiments, and can of course be implemented in various forms without departing from the gist of the present invention. It includes the equivalent meanings recited in the claims, and the equivalent meanings recited in the claims, and all modifications within the scope.

DESCRIPTION OF SYMBOLS 10 Insulating case 20 Zinc oxide type varistor 30 Thermal fuse 40 Insulating block board 41 Through-hole 42 Deterioration display part 60 Elastic member (spring)

Claims (3)

  Two zinc oxide varistors connected in series between an electric device and the ground in a single-phase AC circuit, and juxtaposed in an insulating case, and connected between the two zinc oxide varistors, the zinc oxide type At least one of the varistors is disposed between a temperature fuse made of a low melting metal that is melted by abnormal heat generation and the zinc oxide varistor, and the temperature fuse is softened when the temperature fuse is softened by abnormal heat generation of the zinc oxide varistor. An SPD with a shielding plate, comprising an insulating shielding plate that is displaced so as to be divided.   The insulating blocking plate has a plate shape having a through hole through which the thermal fuse is inserted, and the thermal fuse is formed at the periphery of the through hole by an elastic force of an elastic member disposed between the insulating case and the insulating case. The SPD with a blocking plate according to claim 1, wherein the SPD is pressed.   The SPD with a barrier plate according to claim 1 or 2, wherein the insulating barrier plate has a deterioration display portion that protrudes from the insulating case due to the displacement thereof.

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