ES2611404T3 - Trigger mechanism for surge protector and surge protector - Google Patents

Abstract

A trigger mechanism (100) for a surge protector, the trigger mechanism (100) comprising: a chassis mount (110) for receiving at least one metal oxide varistor (200); and a firing rod (120) pivotally arranged on the chassis mount (110) and connected to an electrode (210) of the metal oxide varistor by low temperature welding, in which the firing mechanism (100) comprises furthermore a sliding block (130) slidably arranged on the frame (110) of the chassis, the sliding block (130) being able to slide between a first position and a second position and being pushed towards a firing position; maintaining, in a normal working state, the sliding block (130) in the first position by the firing rod (120) that opposes the pushing pressure, and causing, in a firing state, the sliding movement of the block (130) sliding towards the second position under the action of the pushing pressure that the firing rod (120) pivots in a direction away from the electrode (210) of the metal oxide varistor (200), characterized in that the block (130) Slider is located between the electrode (210) and the firing rod (120) when the sliding block (130) is in the second position.

Description

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DESCRIPTION

Trigger mechanism for surge protector and surge protector Technical field

The present invention relates to a surge protector, and especially refers to a trigger mechanism for surge protection.

Background of the invention

Some surge protectors are generally used in electrical circuits used in families, offices, and industrial areas, etc. to prevent damage to electrical appliances caused by the instantaneous overvoltage of the circuits. When a sudden peak of current or voltage occurs in the electrical circuits or in the communication lines due to external disturbances, the surge protector can conduct and divide the current in an extremely short period of time to avoid damage to other devices of the circuits caused by the overvoltage.

The most commonly used surge protector comprises an element called metal oxide varistor (MOV) to transfer the redundant voltage. The metal oxide varistor has a very wide resistance in the normal working state and, therefore, substantially shows a deactivated state. When the circuit voltage exceeds the predetermined value, for example, in circumstances of electric device discharge, etc., the resistance of the MOV drops dramatically and, thus, the MOV is almost in a conductive state and transfers a large volume of the current to eliminate redundant voltage.

However, after a long period of use, the metal oxide varistor will age and, therefore, generate heat. In order to prevent the metal oxide varistor from being damaged due to overheating and to prevent disasters such as fires due to temperature rise it is usual to provide a trigger mechanism in the surge protector, the trip mechanism and the Metal oxide varistor are connected in series so that the metal oxide varistor disconnects with the circuit when the temperature rises.

Fig. 1 shows a firing mechanism adopted by the prior art. The firing mechanism mainly comprises a substantially rod-shaped firing rod 1, the firing rod 1 is mounted on a frame 2 of the chassis by means of a pivot 3 disposed on the mount 2 of the surge protector chassis to be able to oscillate, and the upper end 11 of the firing rod 1 is pushed to the right side of Fig. 1, that is, towards the firing direction, by some pushing springs 4. A remote signal switching lever 12 is integrally formed at a lower end of the firing rod 1, the remote signal lever 12 cooperates with a remote signal switch (not shown) to drive the remote switch. The remote signal. Likewise, the average portion of the firing rod 1 is welded to the MOV 5 by means of a low temperature weld (not shown), the firing rod 1 is also connected to a terminal 9 of the surge protector through a cable 8, and terminal 9 connects to an external circuit. The other electrode of MOV 5 connects to the other terminal 10 of the surge protector and, thus, the surge protector is connected to the circuit.

An indicator mount 6, which indicates the current state of the surge protector is arranged on an upper side of the frame mount 2, and the indicator mount 6 is pushed to the right side of Fig. 1 by another spring 7 of thrust, that is, the thrust direction is the same as the thrust direction that the thrust springs 4 push the firing rod 1. One end of the mount 6 of the indicator is an indication piece, generally green, the indication piece is exposed through an opening disposed on the housing (not shown) of the surge protector and, thus, the Indication piece is visible from the outside. Similarly, a red indication piece formed on the chassis mount 2 in a position corresponding to the green indication piece.

In the normal working state, the firing rod 1 is welded to the MOV 5 through a low temperature welding, and the firing rod 1 electrically and mechanically connects with the MOV 5. On the other hand, the firing rod 1 is located in the position shown in Fig. 1, the mount 6 of the indicator is maintained in the position shown in Fig. 1 adjacent to the upper end of the firing rod 1, and at the same time, the green indication piece arranged on the mount 6 of the indicator covers the red indication piece arranged on the mount 2 of the chassis, and in this way the green indication piece, which indicates that the surge protector is currently in the normal working state, it can be seen from the outside of the surge protector housing.

When the temperature rises to a certain level, the low temperature weld melts, the firing rod 1 rotates clockwise around the pivot 3 in the figure under the action of the pushing springs 4, and in this way the electrical connection between the firing rod 1 and the MOV 5 is disconnected. On the other hand, the remote signal switching lever 12 disposed at the lower end of the firing rod 1 excites the remote control switch with the rotation of the firing rod 1 to send to the control apparatus

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remotely a signal indicative of the firing of the firing rod 1. Likewise, since the firing rod 1 rotates clockwise, the indicator mount 6 slides to the right on the upper side of the frame mount 2 under the action of the pushing spring 7 and , in this way, the green indication piece moves to the right side to expose the red indication piece arranged on the chassis mount 2, and in this way, the red indication piece, which indicates the trigger firing against the Surge, can be seen from the outside of the surge protector housing.

However, the conventional firing mechanism of the surge protector presents the following problems: the firing rod 1 travels substantially in a parallel plane of the MOV 5, and thus even in the case that the firing rod 1 is Trigger, the electrical distance between the firing rod 1 and the electrode of MOV 5 is very short, and this is disadvantageous for the electrical isolation between the firing rod 1 and the electrode of MOV 5 in the firing state. Likewise, the level of protection and the current leakage capacity of the standard MOV are limited and, the cost of adopting a non-standard single sheet product is high. Therefore, for example, when a nominal discharge current of 35kA is required, two standard single-sheet MOVs of 20kA are generally used to achieve this, therefore a solution is produced when two MOVs are used. In the case of the adoption of two or more MOVs, two or more firing mechanisms mentioned above are needed, that is, another firing rod 1 is arranged similarly on the rear side not shown in the figure, and the other rod 1 shot is welded to another MOV located on the back side of the figure. However, when the temperature rises, the two firing rods 1 operate independently, it is difficult for the above-mentioned conventional firing mechanism to satisfy the needs of the two MOVs firing simultaneously. If it is not possible to ensure that the two MOVs fire simultaneously, there may be a case where one MOV trips while the other fails, the standard single-sheet MOV of 20kA can cause the MOV to burst under a 35kA surge.

Likewise, US 2008/0043395 A1 discloses a trigger mechanism for a surge protector with a chassis mount to receive at least one metal oxide varistor and a disconnecting means arranged on the chassis mount and connected to a electrode of the metal oxide rheostat by welding. The firing mechanism comprises a slide slidably arranged on the chassis mount, the slide being sliding between a first position and a second position and being pushed towards a firing position. In a normal working state, the slide is held in the first position by the disconnecting means that opposes the pushing pressure, causing, in a firing state, that the sliding movement of the slide towards the second position under the action of the pushing pressure that the disconnecting means be flexed in a direction away from the metal oxide varistor electrode.

Summary of the invention

The present invention has been executed based on the problems of the prior art, and an object of the invention is to provide a trigger mechanism for a surge protector, the trigger mechanism can ensure the electrical distance between a firing rod and the MOV in the trigger state, when a plurality of MOVs are used, the simultaneous firing of the plurality of MOVs can easily be executed.

According to one aspect of the invention, a firing mechanism is provided, the firing mechanism comprising: a chassis mount for receiving at least one metal oxide varistor; and a firing rod pivotally disposed on the chassis mount connected to an electrode of the metal oxide varistor reostator electrodes by a low temperature weld. The firing mechanism further comprises a sliding block disposed slidably on the frame mount, the sliding block can slide between a first position and a second position and is pushed towards a firing direction; In a normal working state, the sliding block is held in the first position by the firing rod that opposes the pushing pressure, and in a firing state, the sliding movement of the sliding block towards the second position under the action Pushing pressure causes the firing rod to pivot in a direction away from the metal oxide varistor electrode.

Thus, in the firing state, since the firing rod pivots away from the metal oxide varistor electrode, the electrical distance between the firing rod and the metal oxide varistor electrode is increased, and thus the reliability of the electrical insulation between the firing rod and the metal oxide varistor electrode.

According to a second aspect of the invention, the sliding block is located between the electrode and the firing rod when the sliding electrode is in the second position. This further improves the reliability of electrical insulation.

The firing mechanism is also provided with an oscillating arm that is pivotally mounted on the chassis mount, and the sliding movement of the sliding block towards the second position causes the oscillating arm to pivot to drive a remote control switch.

Thus, the firing of the firing rod and the oscillation of the oscillating arm are both carried out by moving the sliding arm, so that the structure of the complete firing mechanism is simplified, the manufacturing cost is reduced and the reliability is improved. of the mechanism.

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Preferably, the sliding block is arranged in a status indication piece indicating that the normal working state, and when the sliding block is in the first position, the status indication piece is visible from the outside through a transparent opening or window disposed within the surge protector housing.

Likewise, the chassis mount is provided with a status indication piece indicating the trigger status, when the sliding block is in the first position, the status indication piece indicating that the trigger status is protected by the status indication piece indicating the normal working status arranged on the sliding block, and when the sliding block is in the second position, the status indication piece indicating the firing status is exposed and is visible from outside to through the opening or transparent window arranged on the housing of the surge protector.

Preferably, the sliding block comprises an inclined surface, the firing rod is positioned adjacent to the inclined surface when the sliding block is in the first position.

Thus, a simple structure can be used to execute the firing of the firing rod.

Preferably, a channel is arranged on the lower side of the inclined surface, the electrode is received inside the channel when the sliding block is in the second position.

Thus, in the firing state, in addition to increasing the distance between the firing rod and the electrode, the sliding block is located between the firing rod and the MOV electrode, and receives the electrode within its channel, further enhancing the resistance of the electrical insulation between the firing rod and the MOV electrode.

Alternatively, the firing mechanism also comprises one or more thrust springs, one end of which is fixed to the sliding block, and the other end is fixed to the frame of the chassis to push the sliding block towards the second position.

Preferably, a first end of the firing rod is pivotally connected to the chassis mount, and a second end of the firing rod is welded to the electrode. Specifically, the second end of the firing rod is formed with a slit, and the electrode is inserted into the slit and is welded thereto.

The reliability of the welding between the MOV electrode and the firing rod can be improved by inserting the MOV electrode into the slit and being welded into the slit, and in such a way that the side welding procedure can reduce the thermal impact of the overvoltage over the MOV.

According to another aspect of the invention, two metal oxide varistors are received within the frame of the firing mechanism mount, and the respective electrodes of the two metal oxide varistors are welded in the same position of the firing rod, this that is, the two respective electrodes of the metal oxide varistors are both inserted into the groove of the firing rod and welded therefrom by means of low temperature welding.

In accordance with another aspect of the invention, a strain relief is provided comprising the exposed trigger mechanism.

Brief description of the drawings

The aspects and other exposed, features, advantages and technical and industrial importance of the invention will be more clearly understood from the subsequent detailed description of the preferred embodiments of the present invention taken in combination with the accompanying drawings, in those who:

Fig. 1 is a schematic view of a trigger mechanism of a surge protector of the prior art;

Fig. 2A is an exploded perspective view showing the trigger mechanism of the surge protector according to a preferred embodiment of the invention, the trigger mechanism comprises an MOV;

Fig. 2B is a perspective view of the firing mechanism after being mounted shown in Fig. 2A;

Fig. 3A is a side view of the firing mechanism shown in Fig. 2B;

Fig. 3B is a cross-sectional view taken along line B-B of Fig. 3A;

Fig. 3C is an enlarged view of the circle section of Fig. 3B;

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Fig. 4 is a perspective view of the firing mechanism in the normal working state;

Fig. 5 is a perspective view of the working mechanism in the firing state;

Fig. 6A is an exploded perspective view illustrating the trigger mechanism of the surge protector according to another preferred embodiment of the invention, the trigger mechanism comprises two MOVs;

FIG. 6B is a perspective view of the firing mechanism after being mounted shown in Fig. 6A;

Fig. 7A is a side view of the firing mechanism shown in Fig. 6B;

Fig. 7B is a cross-sectional view taken along line B-B of a Fig. 7A; Y

FIG. 7C is an enlarged view of the circle section of Fig. 7B.

Detailed description of the forms of realization

Next, the firing mechanism according to the preferred embodiments of the invention will be described in detail with reference to the accompanying drawings.

With reference to Figs. 2A to 5, a firing mechanism 100 is disclosed according to a first embodiment of the invention. The firing mechanism 100 comprises a chassis mount 110, the chassis mount 110 is substantially in the form of a square chassis and is used to receive an MOV 200. A pivot 111 is formed in the upper right corner of the chassis mount 110 , and a firing rod 120 is pivotably disposed on the chassis mount 110 around the pivot 111. Specifically, a circular recess or a hole may be formed at one end 121 (the right end of the drawing) of the rod 120 of shot, and pivot 111 is inserted into the circular recess or hole. Likewise, the firing rod 120 is connected to a terminal 300 of the surge protector by means of a cable 122, and the terminal 300 is used to connect the surge protector with an external circuit.

As clearly shown in Figs. 4 and 5 the other end of the firing rod 120 is a connecting end, the connecting end is substantially in the form of a flat panel, a concave platform 123 is substantially formed in the middle part of the flat panel in the direction of width of the connecting end of the flat panel, and the concave platform 123 is formed with a through slot 124 in its middle portion, the through slot 124 may be open at one end or both ends of the through slot 124 are closed.

A sliding block 130 is disposed on an upper side surface of the chassis mount 110. The sliding block 130 is slidably disposed on the inner side surface of the chassis mount 110, for example, a portion 112 of the grid is arranged on the mount 110 of the chassis, and the sliding block 130 can slide below the grid of the 112 portion of grna. On the other hand, as shown in the drawings, the push springs 140 are also arranged (two springs in the drawing), one end of the push springs is fixed to the right end of the sliding block 130, and the other end of the spring of thrust is fixed to the pivot 111, and thus the sliding block 130 is pushed to the right side by the action of the thrust springs 140, that is, it is pushed towards the pivot 111. At the bottom of the sliding block 130 is formed a channel 134 along the longitudinal direction, the channel 134 is used to prevent the sliding block 130 from interfering with the electrode 210 of the MOV 200 during the sliding of the sliding block 130, and this will be described later. The sliding block 130 is formed by an indication piece 131, that is, a green indication piece, at its left end. Similarly to the prior art, in the state shown in Fig. 2B, the green indication piece is exposed through an opening or a window disposed within the surge protector housing to indicate that the protector against surges is in a normal working state.

After the pivot 113 is formed on the lower side of the chassis mount 110, an oscillating arm 150 is pivotally disposed on the chassis mount 110 through the pivot 113, and the other end (the lower end in the drawing) of the oscillating arm 150 is formed with a switch excitation piece 151 to drive a remote control switch not shown in the drawing. The other end (the upper end of the drawing) of the oscillating arm 150, as shown in Fig. 4, is formed with a drive portion 152 that fits with a projection 132 disposed on the sliding block 130, and the projection will push the swing arm 150 to rotate clockwise around pivot 113 when the sliding block 130 slides to the right side.

As shown in Fig. 2A, MOV 200 comprises two electrodes 210 and 220. As shown in Figs. 3C and 4, in the normal working state, the MOV 200 is received inside the chassis mount 110, and an electrode 210 of the MOV 200 is inserted into the groove 124 formed in the concave platform 123 of the firing rod 120, and is connected to the firing rod 120 by means of a low temperature welding 400. The other

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electrode 220 of MOV 200 is connected to the other terminal 500 of the surge protector, for example by welding, while the other terminal 500 is connected to an external circuit. On the one hand, the mOv 200 is connected to one phase of the external circuit by means of the firing rod 120, and the terminal 300, and on the other hand, it is connected to the other phase of the external circuit by means of the other electrode 220 and to the another terminal 500 of the surge protector, and when the voltage between the two phases of the external circuit exceeds the predetermined voltage, MOV 200 directs the two phases and operates to divide the current and reduce the voltage.

As shown in Fig. 4, in the normal working state, the middle part of the sliding block 130 is formed with an inclined surface 133, an edge of the connecting end of the firing rod 120 is located adjacent to the inclined surface 133 , thus preventing the sliding block 130 from moving towards the pivot 111 by means of the pushing spring 140. In said state, the sliding block 130 is located in the first position, the indication piece 131 is visible inwards from the opening or the transparent window arranged on the surge protector housing, thus indicating that the surge protector It is in a normal working state.

When the temperature of the surge protector rises and reaches or exceeds the predetermined temperature threshold value, the low temperature weld 400 melts, and at that time, the connection between the firing rod 120 and the electrode 210 of the mOv 200 is released, and thus the firing rod 120 cannot perform the function of preventing the sliding block 130 from continuing to slide. In accordance with said circumstance, the sliding block 130 slides towards the direction of the right side in the drawing under the action of the pushing pressure of the pushing springs 140, and at the same time, the inclined surface 133 of the sliding block 130 pushes the firing rod 120 upwardly to cause the firing rod 120 to rotate clockwise in the drawing around pivot 111. Fig. 5 shows the firing mechanism in the firing state. In the state shown in Fig. 5, the sliding block 130 has slid to the second position to the right side, pushing the firing rod 120 upward, and at the same time the sliding block 130 covers the electrode 210 of the MOV 200; at this time, electrode 210 is received within channel 134 and thus end 210 and firing rod 130 are electrically isolated. On the other hand, as shown in Fig. 5, the green indication piece 131 has shifted to the right, and thus a red indication piece 114, which is arranged on the chassis mount 110 and was protected by the piece 131 of green indication, is exposed. When the sliding block slides to the right, the protrusion 132 disposed on the sliding block 130 pushes the driven portion 152 of the oscillating arm 150, causing the oscillating arm 150 to swing clockwise around the pivot 113, and thus the switch excitation part 151 excites the remote control switch (not shown), sending a trigger signal to the surge protector to the remote control apparatus.

Figs. 6 and 7 show the firing mechanism according to the second embodiment of the invention, the structure of the firing mechanism is substantially the same as described above, the difference being that the frame mount 110 receives two MOVs 200. Thus, as shown in Fig. 7C, the electrodes of the MOVs 200 are both inserted into the groove 240 of the firing rod 120, and are welded to the firing rod 120 by means of a low temperature weld 400. Thus, when the temperature rises, even in the case that two MOVs 200 transfer a different amount of heat to the welding point through their respective electrodes, since the heat is applied to the same welding point, and thus the mechanism It shoots simultaneously. Since other parts of the second embodiment are the same as those of the first embodiment, the description will be omitted.

According to the firing mechanism of the invention, in the firing state, the firing rod 120 rotates in a direction away from the electrode 210 of MOV 200, as a result, the electrical distance between the firing rod 120 and the electrode 210 is increased, the viability of the electrical isolation between the firing rod 120 and the electrode 210 improves.

Likewise, according to the trigger mechanism of the invention, in the firing state, the sliding block 130 slides to a position between the firing rod 120 and the electrode 210 of the MOV 200, and covers the electrode 210 of the MOV 200, and thus the absence of electrical isolation between the firing rod 120 and electrode 210 is further enhanced.

Likewise, according to the trigger mechanism of the invention, the electrodes 210 of the MOVs 200 are welded in the same position of the firing rod 120 using a low temperature weld, the temperature being raised, even if two MOVs 200 they transfer a different amount of heat to the welding point through their respective electrode, since the heat is applied to the same welding point, the mechanism will fire simultaneously and thereby improve the reliability of the firing mechanism.

Likewise, according to the present invention, both the pivoting of the firing rod 120 and the oscillation of the oscillating arm 150 are activated by the sliding of the sliding block 130, as a result, the structure of the total firing mechanism is simplified, the cost of manufacturing is saved and the reliability of the total firing mechanism is improved.

Claims (11)

5 10 fifteen twenty 25 30 35 40 Four. Five fifty 1. - A trigger mechanism (100) for a surge protector, the trigger mechanism (100) comprising: a frame (110) of the chassis to receive at least one varistor (200) of metal oxide; Y a firing rod (120) pivotally disposed on the chassis mount (110) and connected to an electrode (210) of the metal oxide varistor by low temperature welding, wherein the firing mechanism (100) further comprises a sliding block (130) slidably arranged on the frame mount (110), the sliding block (130) being able to slide between a first position and a second position and being pushed towards a firing position; maintaining, in a normal working state, the sliding block (130) in the first position by the firing rod (120) that opposes the pushing pressure, and causing, in a firing state, the sliding movement of the block (130) sliding towards the second position under the action of the pushing pressure that the firing rod (120) pivots in a direction away from the electrode (210) of the metal oxide varistor (200), characterized because the sliding block (130) is located between the electrode (210) and the firing rod (120) when the sliding block (130) is in the second position. 2. - The firing mechanism according to claim 1, characterized in that it further comprises an oscillating arm (150) pivotally mounted on the frame (110) of the chassis, and the sliding movement of the sliding block (130) towards the second position causes the swing arm (150) to pivot to excite a remote control switch. 3. - The firing mechanism according to claim 1, characterized in that the sliding block (130) is provided with a state indicating part (131) indicating the normal working state, and when the sliding block is in the First, the status indication part (131) is visible from the outside to the inside of a transparent opening or window arranged inside a housing of the surge protector. 4. - The firing mechanism according to claim 3, characterized in that the frame mount (110) is provided with a state indicating part (114) indicating the firing state, when the sliding block (130) is In the first position, the status indication part (114) indicating the firing state is protected by the status indication part (131) indicating the normal working state arranged on the sliding block (130), and when the sliding block (130) is in the second position, the status indication part (114) indicating the firing state is exposed and is visible from inside the transparent opening or window arranged on the surge protector housing . 5. - The firing mechanism according to claim 1, characterized in that the sliding block (130) comprises an inclined surface (133), the firing rod (120) is located adjacent to the inclined surface (133) when the block (130) Slider is in the first position. 6. - The firing mechanism according to claim 1, characterized in that a channel (134) is arranged on a lower side of the inclined surface (133), the electrode (210) is received inside the channel (134) when the Sliding block (130) is in the second position. 7. - The firing mechanism according to claim 1, characterized in that it also comprises one or more thrust springs (140), and one end of the spring (s) is fixed to the sliding block (130), and the other end of (the) spring (s) is fixed to the frame (110) of the chassis to push the sliding block (130) towards the second position. 8. - The firing mechanism according to claim 1, characterized in that a first end of the firing rod (120) connects pivotally with the mount (110) of the chassis, and a second end of the firing rod is welded to the electrode (210). 9. - The firing mechanism according to claim 8, characterized in that the second end of the firing rod (210) is formed with a slit (124) and the electrode (210) is inserted into the slit (124) and It's soldier to it. 10. - The firing mechanism according to any one of the preceding claims, characterized in that the two metal oxide varistors (200) are received within the frame (110) of the mount, and the respective electrodes (210) of the two Varistors (200) of metal oxide are welded in the same position of the same firing rod (120). 11. A surge protector, characterized in that the surge protector comprises at least one metal oxide varistor (200) and a firing mechanism (100) according to any one of Claims 1 to 10.