DE102023200005A1 - surge protection device - Google Patents

Abstract

The present invention relates to an overvoltage protection device, comprising: a housing; a first stack of a plurality of first insulative frames and a plurality of electrode plates, the plurality of first insulative frames receiving the electrode plates and being stacked one on top of the other, and the first stack being disposed in a first portion of the housing; a second stack of a plurality of second insulating frames, a plurality of electrode plates and an electrode frame, wherein the plurality of second insulating frames and the electrode frame receive the electrode plates and are stacked one on top of the other, and wherein the second stack is in a second section of the Housing is arranged; and a conductive bridge electrically coupling one of the electrode plates in the first stack to the electrode frame.

Description

technical field

The present invention relates to the field of electrical devices and more particularly to an overvoltage protection device.

State of the art

With the rapid development of the communication industry, the rapid evolution of the terminal and mobile Internet into the upcoming 5th generation makes a higher demand on the progress of the mobile network. Higher density cellular base stations are needed to achieve the acceleration and intellectualization of communications. According to the practical needs of the assembly site, these multiple base stations are required to be very small in thickness and volume, easy to install and manufacturability, and high in performance. Therefore, many components suitable for miniaturized base stations with a long range, easy installation, and low power consumption, including a miniaturized onboard surge protective device (also called lightning protection device, hereafter abbreviated as SPD (Surge Protective Device)) are increasingly appearing.

The previous cellular base stations mostly use SPD, which can be inserted and removed through guide rail. The SPD of this type is based on the principle of a varistor, a radio link or a gas discharge tube and has the characteristics such as a large flow capacity, an indicator of functionality and easy replacement. At the same time, however, this also has a large volume because of the limitation of the structure and element. With the further development of the communication industry, the guide-rail pluggable and removable SPD is replaced by the PCB-mounted SPD, which has a smaller volume. This PCB welded product still adopts the design of the varistor and gas discharge tube, but omits the guide rail and a socket to meet the downsizing requirement to some extent.

A common approach for a PCB-installed SPD involves a varistor forming a series circuit along with a gas discharge tube. In particular, a gas discharge tube mostly has only a single spark gap. For an AC system, arc quenching can usually be accomplished by zero crossing of the AC current. For a DC system, on the other hand, because of the very small drop (typically only about a dozen volts) in the arc voltage after dissipation in a single spark gap, the DC current cannot freewheel, so the gas discharge tube is turned on at a small resistance and is damaged by overheating . With a series connection of the varistor and the gas discharge tube, freewheeling can be interrupted if necessary.

In the application of the high voltage DC power in the communications industry, downsizing is faced with achieving higher throughput and higher working voltage by means of SPD approach installed on PCB. Specifically, the SPD installed on PCB is a varistor and gas discharge tube based approach where the area of the varistor is proportional to the flow rate and the thickness is proportional to the voltage. With a higher voltage and larger flow rate, a thicker, larger varistor must be used to meet the parameter requirement.

Therefore, there is a need for designing a lightning protection device that has a high flow rate, a high operating voltage, and the DC freewheel interrupting function in a small volume.

Disclosure of Invention

The present invention relates to an overvoltage protection device, comprising: a housing; a first stack of a plurality of first insulative frames and a plurality of electrode plates, the plurality of first insulative frames receiving the electrode plates and being stacked one on top of the other, and the first stack being disposed in a first portion of the housing; a second stack of a second plurality of insulating frames, a plurality of electrode plates and an electrode frame, wherein the plurality of second insulating frames and the electrode frame receive the electrode plates and are stacked one on top of the other, and wherein the second stack is in a second section of the Housing is arranged; and a conductive bridge electrically coupling one of the electrode plates in the first stack to the electrode frame.

In the overvoltage protection device described above, it is further provided that the number of the first insulating frames is A and the number of the second insulating frames is B, the first stack being A insulating frames and A + 1 electrode plates spaced apart by the A insulating frames, includes, wherein the second stack comprises B insulative frames and B+2 electrode plates spaced apart by the B insulative frames, and wherein the conductive bridge electrically couples the electrode plate innermost in the housing in the first stack to the electrode frame.

In the case of the overvoltage protection device described above, it is also provided that the electrode frame is arranged between two insulating frames.

The above-described overvoltage protection device is further provided to further have a plurality of draining electrodes, comprising: a first electrode electrically coupled to the outermost electrode plate in the case in the first stack; a second electrode electrically coupled to the outermost electrode plate in the second stack in the housing; and a third electrode electrically coupled to the innermost electrode plate in the housing in the second stack.

In the overvoltage protection device described above, it is further provided that the first electrode is one of the L electrode and the N electrode and the second electrode is the other of the L electrode and the N electrode, or that the first electrode is a of the positive electrode and the negative electrode and the second electrode comprises the other of the positive electrode and the negative electrode, the third electrode being a grounding electrode.

In the overvoltage protection device described above, it is also provided that the number of insulating frames in the second stack is greater than the number of insulating frames in the first stack.

In the overvoltage protection device described above, it is also provided that the electrode frame is arranged in a middle position of the second stack.

In the overvoltage protection device described above, it is further provided that the case includes an outer case and a lower case, the lower case including: a base, a first side wall and a second side wall extending from the base, and an insulating plate, located between the first sidewall and the second sidewall and oriented substantially perpendicular thereto, wherein the insulating plate, the first sidewall, and the second sidewall are configured to form a first cavity and a second cavity in the lower case; wherein the first stack is disposed in the first cavity of the lower case and the second stack is disposed in the second cavity of the lower case.

In the surge protection device described above, it is further provided that the conductive bridge comprises a first blade and a second blade that are at an angle to each other, wherein a first mounting hole is provided in the first side wall of the lower housing, the first blade of the a conductive bridge extending from an exterior of the first sidewall through the first mounting hole into the first cavity, the first lamina of the conductive bridge having one side abutting the insulating plate and the other side electrically coupled to the electrode plate closest to the insulating plate in the first stack is.

In the overvoltage protection device described above, it is further provided that a first metal part is stacked on the electrode plate lying closest to the insulating plate in the first stack; and the other side of the first lamina of the conductive bridge is in electrical contact with the first metal piece to electrically couple to the electrode plate closest to the insulating plate in the first stack.

In the overvoltage protection device described above, it is further provided that the second blade of the conductive bridge extends along the outside of the first side wall, the second blade of the conductive bridge comprising a first hole, the electrode frame having an extension extending from the second cavity to extending to the outside of the first sidewall, the extension of the electrode frame being inserted into and welded to the first hole of the second lamination of the conductive bridge to establish an electrical connection between the conductive bridge and the electrode frame.

In the surge protection device described above, it is further provided that the second lamina of the conductive bridge comprises a second hole, with a bulge being provided on the outside of the first side wall of the lower housing, which bulge corresponds to the shape of the second hole, so that the bulge extends into the second hole can be used to attach the conductive jumper.

In the overvoltage protection device described above, it is further provided that a second mounting hole is provided in the second side wall of the lower housing, wherein the third electrode extends from an exterior side of the second sidewall into the second cavity through the second mounting hole, the third electrode having one side abutting the insulating plate and the other side electrically coupled to the electrode plate closest to the insulating plate in the second stack.

In the overvoltage protection device described above, it is further provided that a second metal part is stacked on the electrode plate lying closest to the insulating plate in the second stack, the other side of the third electrode being in electrical contact with the second metal part in order to connect to the electrode plate closest to the electrically couple insulating plate lying electrode plate in the second stack.

In the surge protection device described above, it is further contemplated that the third electrode includes a conductive terminal extending from the base of the lower housing.

In the surge protection device described above, it is further provided that there is also a pair of fixed plates, a first fixed plate by fastening means at first ends of the first side wall and the second side wall and a second fixed plate by fastening means at second ends of the first side wall and the second side wall is attached.

In the overvoltage protection device described above, it is further provided that the second electrode is electrically coupled to the electrode plate located furthest from the insulating plate in the second stack, and that the second electrode is fixed by the fixing means between the electrode plate and the second fixed plate.

In the case of the overvoltage protection device described above, it is also provided that the first electrode is at least partially welded to the first fixed plate.

In the overvoltage protection device described above, it is further provided that the first electrode comprises: a main part, a welding part, a bending part which connects the main part and the welding part to each other, and a pin which extends from the main part, the bending part having a parallel and allows staggered arrangement of the main part and the welding part, and wherein the welding part is welded to the first fixed plate.

In the overvoltage protection device described above, it is further provided that the welding part of the first electrode is welded to the first fixed plate by low-temperature solder, so that the low-temperature solder is melted when the overvoltage protection device is overheated.

The overvoltage protection device described above is further provided to further comprise: a spring, and an arc insulating plate mounted between the first electrode and the first fixed plate and on which a structure for fixing one end of the spring is provided, wherein the the other end of the spring is fixed to the first fixed plate and the spring is in tension when the spring is fixed to the first fixed plate and to the arc isolating plate; wherein when the low-temperature solder is melted, the welding part of the first electrode is detached from the first fixed plate while the spring pulls the arc insulating plate so that the arc insulating plate is moved through a welding point between the welding part of the first electrode and the first fixed plate to release the first electrode from disconnect from the circuit.

In the overvoltage protection device described above, it is further provided that the arc insulating plate comprises a main structure and an extension structure which extends at an angle to the main structure, and at least the extension structure has one color, wherein an opening is provided in the outer housing, the position of which is such arranged so that the colored extension structure of the arc isolating panel is visible through the opening after the arc isolating panel is pulled to an end position by the spring.

In the case of the overvoltage protection device described above, it is also provided that it also comprises a printed circuit board which is welded to capacitors on a first side and to triggerable resilient elements on a second side.

In the surge absorbing device described above, it is further provided that each of the fixed plates includes a welding pin, and that the circuit board is welded and fixed to the fixed plate by the welding pin.

In the case of the overvoltage protection device described above, it is also provided that the electrode plate comprises a graphite plate.

character list

• 1 ist eine schematische Ansicht eines zusammengesetzten Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 2 zeigt eine Explosionsansicht des in 1 gezeigten Überspannungsschutzgerätes;
• 3 zeigt eine erste schematische Ansicht eines unteren Gehäuses eines Gehäuses des Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 4A zeigt eine zweite schematische Ansicht eines unteren Gehäuses eines Gehäuses des Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 4B zeigt eine dritte schematische Ansicht eines unteren Gehäuses eines Gehäuses des Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 4C zeigt eine vierte schematische Ansicht eines unteren Gehäuses eines Gehäuses des Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 5 zeigt einen Schnitt in Draufsicht auf ein zusammengesetztes Überspannungsschutzgerät gemäß einem Ausführungsbeispiel der Erfindung;
• 6 zeigt eine schematische Ansicht eines zusammengesetzten Überspannungsschutzgerätes ohne Gehäuse gemäß einem Ausführungsbeispiel der Erfindung;
• 7 zeigt eine schematische Ansicht einer leitfähigen Überbrückung eines Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 8 zeigt eine schematische Ansicht einer befestigten Platte eines Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung;
• 9 zeigt eine schematische Ansicht einer der Elektroden eines Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung; und
• 10 zeigt eine schematische Ansicht einer Lichtbogenisolierungsplatte eines Überspannungsschutzgerätes gemäß einem Ausführungsbeispiel der Erfindung.

In order to further explain the exemplary embodiments of the present invention, they are described in more detail in connection with the attached figures. It is to be understood that these figures represent only the typical embodiments of the invention and therefore should not be taken as limiting the scope of the invention.

• 1 Fig. 12 is a schematic view of an assembled surge protector according to an embodiment of the invention;
• 2 shows an exploded view of the in 1 shown overvoltage protection device;
• 3 shows a first schematic view of a lower housing of a housing of the overvoltage protection device according to an embodiment of the invention;
• 4A shows a second schematic view of a lower housing of a housing of the overvoltage protection device according to an embodiment of the invention;
• 4B shows a third schematic view of a lower housing of a housing of the overvoltage protection device according to an embodiment of the invention;
• 4C 12 shows a fourth schematic view of a lower housing of a housing of the overvoltage protection device according to an embodiment of the invention;
• 5 shows a section in top view of an assembled overvoltage protection device according to an embodiment of the invention;
• 6 shows a schematic view of an assembled overvoltage protection device without housing according to an embodiment of the invention;
• 7 shows a schematic view of a conductive bridging of a surge protection device according to an embodiment of the invention;
• 8th Fig. 12 shows a schematic view of a fixed plate of a surge protection device according to an embodiment of the invention;
• 9 shows a schematic view of one of the electrodes of an overvoltage protection device according to an embodiment of the invention; and
• 10 12 is a schematic view of an arc isolation panel of a surge arrester according to an embodiment of the invention.

Detailed Embodiments

The following description is made in detail in connection with the attached figures. The figures represent, by way of example, the specific example embodiments in which the claimed subject matter may be practiced. It is to be understood that the following specific embodiments are for the purpose of explanation only, to describe the typical examples in detail and should not be taken as a limitation of the present invention. Given the full understanding of the spirit and concept of the invention, one skilled in the art can make reasonable modifications and changes to the disclosed embodiments without departing from the spirit and scope of the objects of the invention.

In the specific description that follows, many details are set forth in order to provide a thorough understanding of the described embodiments. However, it should be apparent to those skilled in the art that various embodiments of the invention may be practiced without these specific details. Unless otherwise specified, the technical and scientific terms used herein are intended to have the same meaning as commonly understood by those skilled in the art to which the disclosure pertains. The term “couple” can include “electrically connect” and “electrically contact” both directly and indirectly.

The terms "first", "second", etc. in the specification and claims of the application do not imply any order, number or importance, but are only used to distinguish different components or features. One embodiment is an example implementation or example. Reference to "embodiment", "an embodiment", "some embodiments", "various embodiments", "other embodiments" in the specification means that the particular feature, structure or characteristic described in connection with the embodiment or embodiments in may be included in at least some, but not necessarily all, embodiments of the application. Mentions of “embodiment,” “an embodiment,” or “some embodiments” in different instances are not necessarily all referring to the same embodiment or embodiments. A An element or aspect from one embodiment may be combined with an element or aspect from another embodiment.

Based on the description in the "Prior Art" section and taking into account the complexity in wiring on site, in the invention a surge protection device with bridging electrodes is used, through which the number of columns for each electrode is increased in order to improve the electrical properties of the product and at the same time effectively reducing the size of the product. In addition, an arc isolation device is designed at the L electrode of the surge arrester of the invention to enhance the DC freewheel interrupting capability. The present invention is described in more detail in connection with the figures.

First be on 1 and 2 referred. 1 12 is a schematic view of an assembled surge protector 100 according to an embodiment of the invention, and 2 is an exploded view of the in 1 shown overvoltage protection device 100. In summary, the overvoltage protection device 100 can comprise a housing, an electrode frame 16, a stack of a plurality of insulating frames 18 and in the insulating frame 18 and in the electrode frame 16 arranged electrode plates 17, and an electrically conductive bridge 15.

The housing can be an insulating housing made of an industrially flame-retardant insulating material. In a specific embodiment, the material for the housing may be one or more of a ceramic material and an insulating polymeric material. These materials have a variety of appearances, impact resistance, good workability and reliability, and ensure the safe insulating electrical properties with respect to the other electronic elements during the product's operation.

The overvoltage protection device 100 can have a plurality of columns and a multi-layer stack of a plurality of insulating frames 18 and electrode plates 17 arranged in the insulating frame 18, as is shown in FIG 2 and 5 shown include. The material for the insulative frame 18 can be one or more of an insulative polymeric material, rubber, polytetrafluoroethylene (PTFE), and ceramic. The material for the electrode plate 17 can be selected from materials having suitable properties such as resistance to high temperature, arc resistance, and high current density. The material for the electrode plate 17 can be either a metallic or non-metallic material. For example, the material for the electrode plate 17 can be graphite, a metallic material, or a metal alloy. In a preferred embodiment, the electrode plate 17 may comprise a graphite plate.

According to the exemplary embodiment of the invention, two stacks can be included, ie a first stack and a second stack, which are described below in connection with 5 to be discribed. Each of the stacks may include multiple insulating frames 18 and corresponding multiple electrode plates 17 . The stacks can have different numbers of layers. The stacks can each be placed in different, separate parts of the housing. The term "separate" herein means that these two parts of the housing are electrically isolated from each other. Any suitable technology can be used to electrically isolate these two parts of the housing from each other. A preferred embodiment of the invention is presented below.

5 FIG. 1 shows a section in plan view of an assembled overvoltage protection device 100 according to an exemplary embodiment of the invention. In 5 It can be seen that the overvoltage protection device 100 comprises two stacks which are insulated from one another by the insulating plate 212 described in more detail below, i.e. a left, first stack and a right, second stack in 5 .

The electrode frame 16 can be arranged in the second stack, for example between two insulating frames. The electrode frame 16 may preferably comprise a low impedance electrically conductive material. The electrode frame 16 can be flat. The two sides of the electrode frame 16 can each be electrically coupled to an electrode plate 17 or be in direct electrical contact with it. A main part of the electrode frame 16 can have a size substantially the same as the size of the insulating frame 18 so that it can be stacked in the second stack and the electrode plate 17 can be inserted into the electrode frame 18 as shown in FIG 5 shown. The electrode frame 16 may preferably be arranged in a middle position of the second stack.

The number of isolating frames 18 in the first stack may be A and the number of isolating frames 18 in the second stack may be B. The first stack may have A insulative frames 18 and A+1 electrode plates 17 spaced apart by the A insulative frames 18 are, include. As in 4C and 5 1, the electrode plate 17 closest to the insulating plate 212 may be inserted into the shape formed by the insulating plate 212, which is similar to the shape of the insulating frame 18. The second stack may comprise B insulative frames 18 and B+2 electrode plates 17 spaced apart by the B insulative frames 18 and the electrode frames 16 . Also, the electrode plate 17 closest to the insulating plate 212 in the second stack may be laid in the shape formed by the insulating plate 212 which is similar to the shape of the insulating frame 18 .

As in 5 Further shown, the conductive bridge 15 may be configured to electrically couple the innermost within the housing (e.g., closest to the insulating plate 212) electrode plate 17 in the first stack to the electrode frame 16 in the second stack, as will be discussed in more detail below is described. The conductive bridge 15 may preferably comprise a low impedance electrically conductive material.

In another embodiment, the case may comprise an outer case 1 and a lower case 2 . In an exemplary embodiment, the outer casing 1 may be a pentagonal shell, with holes provided on some surfaces, as will be described in more detail below. The outer case 1 is mounted on the lower case 2 . 3 and 4C show the schematic views of a lower housing 2 of the overvoltage protection device according to an embodiment of the invention. As in 3 and 4C shown, the lower case 2 may have a base 206, a first side wall 208 and a second side wall 210 extending from the base 206, and an insulating plate 212 located between the first side wall 208 and the second side wall 210 and im is aligned essentially perpendicular to it ( 4C ). The insulating plate 212 , the first side wall 208 and the second side wall 210 may be configured to form a first cavity 201 and a second cavity 202 in the lower case 2 . The material for the insulating plate 212 can be an insulating material such as. B. the same material as the material described above for the housing, or be a different insulating material.

The first stack and the second stack described above can be arranged in the first cavity 201 and in the second cavity 202, respectively. According to practical needs, the respective number of layers in the first and second stacks (the number of insulating frames and electrode plates) can be adjusted. In a preferred embodiment of the invention, the number of layers in the second stack located in the second cavity 202 may be greater than the number of layers in the first stack located in the first cavity 20 . As a non-limiting example, as in 5 As shown, the first stack comprises 5 columns (5 insulating frames 17 and 6 electrode plates 18) and the second stack comprises 9 columns. The electrode frame 16 described above may preferably be arranged such that the second stack in the second cavity 202 is divided into a left part with 5 columns (5 insulating frames 17 and 6 electrode plates 18) and a right part with 4 columns (4 insulating frames 17 and 5 electrode plates 18) are subdivided. The two sides of the electrode frame 16 described above may be in direct electrical contact with electrode plates 18 on respective sides. Accordingly, the volume of the second cavity 202 used to house the second stack may be greater than the volume of the first cavity 201 used to house the first stack.

As in 1 shown, the overvoltage protection device 100 according to the invention can preferably comprise three conductive electrodes, ie a first electrode 11 , a second electrode 12 and a third electrode 13 . The first electrode 11 may be an L electrode in an AC circuit and the second electrode 12 may be an N electrode in the AC circuit. Alternatively, the first electrode 11 may be a positive electrode in a DC circuit and the second electrode 12 may be a negative electrode in the DC circuit. The third electrode 13 may be a ground electrode (hereinafter referred to as PE). Alternatively, the first electrode 11 may be an N-electrode in an AC circuit and the second electrode 12 may be an L-electrode in the AC circuit. Alternatively, the first electrode 11 may be a negative electrode in a DC circuit and the second electrode 12 may be a positive electrode in the DC circuit. For example, in order to facilitate the description, the application will be explained in the former case. As in 5 1, the first electrode 11 may be configured to electrically couple to the outermost electrode plate in the first stack (e.g., furthest from the insulating plate 212) in the first stack. The third electrode 13 may be configured to electrically couple to the innermost in the housing (e.g. closest to the insulating plate 212) electrode plate in the second stack. The second electrode 12 can do this be directed to electrically couple to the outermost in-housing electrode plate (e.g., furthest from insulating plate 212) in the second stack.

As in 1 As shown, the surge protector 100 may further include a pair of fixed plates 7 . 8th shows a schematic view of a fixed plate 7 of a surge protection device 100 according to an embodiment of the invention. As shown in the figure, the fixed plate 7 may preferably include a welding pin 71. The fixed plate 7 may preferably comprise an electrically conductive material. Referring to 1 , a fixed plate 7 (a first fixed plate) is extended by fasteners 9 at ends (such as the A-direction ends 1 ) of the first side wall and the second side wall of the lower case 2 and another fixed plate 7 (a second fixed plate) by fasteners 9 at the other ends (such as the B-directional ends out 1 ) of the first side wall and the second side wall of the lower case 2. The fasteners 9 can be any fasteners available in the area and according to the invention no limitation is enforced. In a preferred embodiment, the fasteners 9 may be screws or rivets. In an alternative embodiment, the fixed plate 7 can be fixed to the lower housing 2 without fasteners 9. Rather, the fixed plate 7 can be fixed to the lower case 2 by welding, bonding, joining, etc.

As in 2 As shown, the overvoltage protection device 100 may further include a circuit board (hereinafter referred to as PCB) 5 as a tripping circuit board. A first side of the PCB 5 is provided with a plurality of capacitors 4 and a second side of the PCB 5 with a plurality of triggerable resilient elements (in 2 not shown) welded. The PCBs 5 are electrically connected to the two stacks by the releasable resilient elements. The capacitors 4 and the triggering resilient elements can be arranged so that one end of the triggering resilient element is fixed to the PCB and the other end is in contact with the electrode plate 17 to protect the connected electrical equipment through the overvoltage protection device, as stated by the Expert can be realized. The triggering resilient element may comprise a resilient metal piece, a metal header, a metal resilient pin or the like. The ends of the PCB 5 in the A and B directions can be connected to the welding pins 71 of the fixed board 7 (as in Fig 8th shown) welded to attach to the lower housing 2 and electrically connect to the two stacks. In addition, a pressure plate 6 may be mounted between the PCB 5 and the insulating frame 18 to stabilize the mounting structure.

7 shows a schematic view of a conductive bridge 15 of a surge protection device according to an embodiment of the invention. As in 7 As shown, the conductive bridge 15 of the present invention may preferably include a first lamina 152 and a second lamina 154 which are at an angle to one another. More preferably, the angle between the first louver 152 and the second louver 154 is approximately 90 degrees. As in 3 1, a first mounting hole 204 is provided in the first side wall 208 of the lower case 2. As shown in FIG. The first lamina 152 of the conductive bridge 15 extends from an outside of the first side wall 208 through the first mounting hole 204 into the first cavity 201 and it is off 5 It can be seen that one side of the first lamina 152 of the conductive bridge 15 abuts the insulating plate 212 and the other side is electrically coupled to the electrode plate closest to the insulating plate 212 in the first stack. In a preferred embodiment of the invention, the electrode plate closest to the insulating plate 212 in the first stack may have a first metal piece 14A stacked thereon. The first blade 152 of the conductive bridge 15 is in electrical contact with the metal portion 14A such that the first blade 152 of the conductive bridge 15 is electrically coupled through the metal portion 14A to the electrode plate closest to the insulating plate 212 in the first stack.

The second blade 154 of the conductive bridge 15 extends along the outside of the first sidewall 208 . The second blade 154 of the conductive bridge 15 may include a first hole 1542 . The electrode frame 16 can have an extension 1602 (as in 2 1) comprise the main part of the electrode frame 16 and the extension 1602 may extend from the second cavity 202 to the outside of the first sidewall 208. The extension 1602 of the electrode frame 16 may be inserted into and welded to the first hole 1542 of the second lamination of the conductive bridge 15 to establish an electrical connection between the conductive bridge 15 and the electrode frame 16 .

The second lamina 154 of the conductive bridge 15 may further include a second hole 1544 . On the outside of the first side wall 208 of the lower case 2, a bulge 2082 corresponding to the shape of the second hole 1544 may be provided so that the bulge Device 2082 is insertable into the second hole 1544 to attach the conductive bridge 15.

4A until 4C each show an additional schematic view of a lower housing of a housing of the overvoltage protection device according to an embodiment of the invention. As in 4A 1, a second mounting hole 203 may be provided in the second side wall 210 of the lower case 2. As shown in FIG. In a preferred exemplary embodiment, the third electrode 13 can be composed of a plurality of electrode plates or can be designed in one piece, as in FIG 2 shown. The third electrode 13 may extend from an outside of the second side wall 210 into the second cavity through the second mounting hole 203 . One side of the third electrode 13 may abut against the insulating plate 212 (as in 4C shown) and the other side may be electrically coupled to the electrode plate 17 closest to the insulating plate 212 in the second stack.

In a preferred embodiment, a second metal piece 14B may be stacked on the electrode plate 17 closest to the insulating plate 212 in the second stack, as shown in FIG 5 shown. The other side of the third electrode 13 may be in electrical contact with the second metal piece 14B such that the third electrode 13 is electrically coupled through the second metal piece 14B to the electrode plate closest to the insulating plate 212 in the second stack.

The composition of the third electrode 13 of multiple plate-shaped structures described above allows the third electrode 13 to further extend along the second side wall 210 of the lower case 2 and the base 206 and includes a conductive terminal 1302 protruding from the base 206 of the lower case 2 , as in 4B shown.

As in 2 and 5 As shown, the second electrode 12 may be in electrical contact with the outermost in the housing (such as, for example, farthest from the insulating plate 212) electrode plate in the second stack, and the second electrode 12 may be secured by the fasteners 9 or a other fixing method mentioned above can be fixed between the electrode plate and the fixed plate 7.

As already described above, the first electrode 11 can be arranged to electrically couple to the electrode plate 17 lying outermost in the housing (e.g. farthest from the insulating plate 212) in the first stack. The first electrode may be arranged to be disconnected from the circuit in the event of overheating caused by overloading of the overvoltage protection device in order to protect the electrical device.

9 shows a schematic view of the first electrode 11 of an overvoltage protection device according to an embodiment of the invention. The first electrode 11 may be at least partially welded to the first fixed plate 7 . As in 9 As shown, in a preferred embodiment of the invention, the first electrode 11 may include a body portion 1102, a weld portion 1104, a flexure portion 1106 connecting the body portion 1102 and the weld portion 1104, and a pin 1108 extending from the body portion 1102 . The bending part 1106 encloses an angle (preferably an obtuse angle) with the main part 1102 and the welding part 1104, ie the main part 1102 and the welding part 1104 are arranged parallel to one another and offset.

The welding part 1104 can be welded to the first fixed plate 7 . In a preferred embodiment, the welding part 1104 of the first electrode 11 can be welded to the fixed plate 7 by low-temperature solder, so that the low-temperature solder can be melted if the overvoltage protection device is overheated.

The surge protector may further include a spring 8 and an arc isolating plate 3 . The arc insulating board 3 may preferably be made of an insulating material having temperature resistance including, but not limited to, engineering plastic, ceramic material, and mica. The arc insulating plate 3 is mounted between the first electrode 11 and the first fixed plate 7 (as in Fig 6 shown). 10 12 shows, more specifically, a schematic view of an arc insulating panel 3 of a surge arrester according to an embodiment of the invention. The arc insulating panel 3 may include a main structure 302 . A structure 304 to which one end of the spring is fixed may be further provided on the arc insulating plate 3 . The other end of the spring 8 is fixed to the fixed plate 7 . A pair of flanges 306 for receiving the main part 1102 of the first electrode 11 may also be provided on the arc insulating plate 3 . When the ends of the spring 8 are fixed to the fixed plate 7 and the arc insulating plate 3, respectively, the spring 8 is in a tensioned state. With the low-temperature solder melted, the welding portion 1104 of the first electrode 11 is detached from the fixed plate 7, and at this time, the spring 8 pulls the arc insulating plate 3 in FIG 6 C-direction shown, so that the arc insulating plate 3 is moved by a welding point between the welding part 1104 of the first electrode 11 and the fixed plate 7 to disconnect the first electrode 11 from the circuit and thereby protect the electric equipment.

In one embodiment of the invention, the arc insulating panel 3 may further include an extension structure 308 that extends at an angle (such as about 90 degrees) to the main structure 302 . At least the extension structure 308 of the arc insulating panel 3 may have a color such as black. B. be coated with a color. The color of the extension structure 308 of the arc insulating plate 3 can be set to a color different from that of the PCB 5 . Preferably, the color of the extension structure 308 of the arc insulating plate 3 may be red. An opening 102 can be provided in the outer housing 1 . The position of the opening 102 is set such that after the arc isolating plate 3 is pulled by the spring 8 to a final position, the colored (such as the red mentioned above) extension structure 308 of the arc isolating plate 3 is visible through the opening 102 to the user about the current status of the surge protection device, d. H. to inform about the disconnection of the first electrode 11 from the circuit of the overvoltage protection device because of the overload as well as overheating of the circuit of the overvoltage protection device.

It should be clear to those skilled in the art that the greater the number of gaps in the surge protector, the higher voltage and flow rate it can withstand. According to the invention, by using the conductive bridge 15, the number of gaps can be reduced to achieve improved electrical properties in a smaller volume of the device. As a non-limiting example, for example, as in 5 shown the first stack comprises 5 columns and the second stack comprises 9 columns. In addition, the electrode frame 16 divides the second stack into a left part with five columns and a right part with four columns. By electrically connecting the two stacks by means of the conductive bridge 15, 9 gaps can be achieved between, for example, the L electrode and PE and 9 gaps between the N electrode and PE, respectively. In this case, according to the invention, an overvoltage protection device with 14 columns is sufficient. In contrast, in the prior art, 18 columns might be required to achieve the same effect.

Therefore, the invention provides a surge protector having a gap-stack arrangement according to the embodiment of the invention to allow more gaps in the stack with a smaller footprint, particularly a smaller height, of the surge protector. Therefore, the overvoltage protection device according to the invention has a high flow rate and a high operating voltage with a small volume. In addition, the overvoltage protection device according to the invention has a trigger that enables rapid disconnection by thermal triggering. The surge arrester of the present invention also has a status display window, so that the user can quickly know the status of the surge arrester right from the window. Furthermore, in the case of the overvoltage protection device of the application, welding is carried out using pins. The overvoltage protection device according to the invention can meet the requirements of modern industrial power supplies such. B. Strong integration, miniaturization and the ability to mass-produce by wave soldering.

The basic concepts have been described above. Of course, the above disclosure serves only as an example for the person skilled in the art, without limiting the application. Although not clearly stated, various modifications, improvements and changes to the application can be made by those skilled in the art. These modifications, improvements, and changes are noted in the application so that they are still intended to be included within the spirit and scope of the exemplary embodiments of the application.

Claims (25)

Surge protection device, characterized in that it comprises: a housing; a first stack of a plurality of first insulative frames and a plurality of electrode plates, the plurality of first insulative frames receiving the electrode plates and being stacked one on top of the other, and the first stack being disposed in a first portion of the housing; a second stack of a second plurality of insulating frames, a plurality of electrode plates and an electrode frame, wherein the plurality of second insulating frames and the electrode frame receive the electrode plates and are stacked one on top of the other, and wherein the second stack is in a second section of the Housing is arranged; and a conductive bridge electrically coupling one of the electrode plates in the first stack to the electrode frame. overvoltage protection device claim 1 , characterized in that the number of first insulating frames is A and the number of second insulating frames is B, the first stack comprising A insulating frames and A + 1 electrode plates spaced apart by the A insulating frames, the second Stack comprising B insulative frames and B+2 electrode plates spaced apart by the B insulative frames, and wherein the conductive bridge electrically couples the electrode plate innermost in the housing in the first stack to the electrode frame. overvoltage protection device claim 1 , characterized in that the electrode frame is arranged between two insulating frames. overvoltage protection device claim 1 , characterized in that it further comprises a plurality of conductive electrodes comprising: a first electrode electrically coupled to the housing-most electrode plate in the first stack; a second electrode electrically coupled to the outermost electrode plate in the second stack in the housing; and a third electrode electrically coupled to the innermost electrode plate in the housing in the second stack. overvoltage protection device claim 4 , characterized in that the first electrode is one of L electrode and N electrode and the second electrode is the other of L electrode and N electrode, or the first electrode is one of positive electrode and the negative electrode, and the second electrode is the other of the positive electrode and the negative electrode, and the third electrode is a grounding electrode. overvoltage protection device claim 1 , characterized in that the number of isolating frames in the second stack is greater than the number of isolating frames in the first stack. overvoltage protection device claim 6 , characterized in that the electrode frame is arranged in a middle position of the second stack. overvoltage protection device claim 4 or 5 , characterized in that the housing comprises an outer housing and a lower housing, the lower housing comprising: a base, a first side wall and a second side wall extending from the base, and an insulating plate extending between the first side wall and the second side wall and is oriented substantially perpendicular thereto, wherein the insulating plate, the first side wall and the second side wall are configured to form a first cavity and a second cavity in the lower housing; wherein the first stack is disposed in the first cavity of the lower case and the second stack is disposed in the second cavity of the lower case. overvoltage protection device claim 8 , characterized in that the conductive bridge comprises a first lamina and a second lamina which are at an angle to each other, wherein a first mounting hole is provided in the first side wall of the lower housing, the first lamina of the conductive bridge extending from an outside the first sidewall extends through the first mounting hole into the first cavity with one side of the first blade of the conductive bridge abutting the insulative plate and the other side electrically coupled to the electrode plate closest to the insulative plate in the first stack. overvoltage protection device claim 9 , characterized in that a first metal piece is stacked on the electrode plate closest to the insulating plate in the first stack; and the other side of the first lamina of the conductive bridge is in electrical contact with the first metal piece to electrically couple to the electrode plate closest to the insulating plate in the first stack. overvoltage protection device claim 9 characterized in that the second blade of the conductive bridge extends along the outside of the first sidewall, the second blade of the conductive bridge includes a first hole, the electrode frame having an extension extending from the second cavity to the outside of the first sidewall wherein the extension of the electrode frame is inserted into and welded to the first hole of the second lamination of the conductive bridge to establish an electrical connection between the conductive bridge and the electrode frame. overvoltage protection device claim 11 , characterized in that the second lamina of the conductive bridge comprises a second hole, wherein a bulge is provided on the outside of the first side wall of the lower housing, which bulge corresponds to the shape of the second hole, so that the bulge is insertable into the second hole, to attach the conductive jumper. overvoltage protection device claim 8 , characterized in that a second mounting hole is provided in the second side wall of the lower case, the third electrode extending from an outside of the second side wall into the second cavity through the second mounting hole, with one side of the third electrode abutting the insulating plate and the other side is electrically coupled to the electrode plate closest to the insulating plate in the second stack. overvoltage protection device Claim 13 , characterized in that a second metal piece is stacked on top of the electrode plate closest to the insulating plate in the second stack, the other side of the third electrode being in electrical contact with the second metal piece to attach to the electrode plate closest to the insulating plate in the to electrically couple the second stack. overvoltage protection device Claim 13 , characterized in that the third electrode comprises a conductive lead extending from the base of the lower housing. overvoltage protection device claim 8 , characterized in that it further comprises a pair of fixed panels, a first fixed panel being fixed by fixing means to first ends of the first side wall and the second side wall and a second fixed panel being fixed by fixing means to second ends of the first side wall and the second side wall. overvoltage protection device Claim 16 , characterized in that the second electrode is electrically coupled to the electrode plate furthest from the insulating plate in the second stack, and in that the second electrode is fixed by the fixing means between the electrode plate and the second fixed plate. overvoltage protection device Claim 16 , characterized in that the first electrode is at least partially welded to the first fixed plate. overvoltage protection device Claim 18 , characterized in that the first electrode comprises: a main part, a welding part, a bending part connecting the main part and the welding part together, and a pin extending from the main part, the bending part having a parallel and offset arrangement of the main part and of the welding part, and the welding part is welded to the first fixed plate. overvoltage protection device claim 19 , characterized in that the welding part of the first electrode is welded to the first fixed plate by low-temperature solder, so that the low-temperature solder is melted when overheating caused by overloading of the surge protector. overvoltage protection device claim 20 , characterized in that it further comprises: a spring, and an arc insulating plate which is mounted between the first electrode and the first fixed plate and on which a structure for fixing one end of the spring is provided, the other end of the spring being attached the first fixed plate and wherein the spring is tensioned when the spring is fixed to the first fixed plate and to the arc isolating plate; wherein when the low-temperature solder is melted, the welding part of the first electrode is detached from the first fixed plate while the spring pulls the arc insulating plate so that the arc insulating plate is moved through a welding point between the welding part of the first electrode and the first fixed plate to release the first electrode from disconnect from the circuit. overvoltage protection device Claim 21 , characterized in that the arc insulating panel comprises a main structure and an extension structure extending at an angle to the main structure, and at least the extension structure has a color, wherein an opening is provided in the outer housing, the position of which is arranged such that through the opening, the colored extension structure of the arc isolating plate is visible after the arc isolating plate is pulled to an end position by the spring. overvoltage protection device Claim 16 , characterized in that it further comprises a printed circuit board, which on a first side with Capacitors and is welded on a second side with releasable resilient elements. overvoltage protection device Claim 23 , characterized in that each of the fixed plates includes a welding pin, and the circuit board is welded and fixed to the fixed plate by the welding pin. overvoltage protection device claim 1 , characterized in that the electrode plate comprises a graphite plate.

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