BR112014010904B1 - trigger mechanism for peak voltage stabilizer and peak voltage stabilizer - Google Patents

Abstract

TRIGGER MECHANISM FOR VOLTAGE PEAK STABILIZER AND VOLTAGE PEAK STABILIZER. The present invention relates to a trigger mechanism for use in a peak voltage stabilizer and the peak voltage stabilizer comprising the trigger mechanism. The firing mechanism (100) comprises a frame support (110) for use in containing at least one metal oxide rheostat (200), a firing rod (120) pivotally arranged on the frame support and connected to an electrode (210) of the metal oxide rheostat through a low temperature weld, and a sliding block (120) slidably arranged on the frame support between a first position and a second position and angled press in the direction of a firing position . In a normal operating state, the slide block is held in the first position by the firing rod, reacting to the tilt pressure. In a trip state, the sliding block slides towards the second position under the effect of tilt pressure, causing the trip rod to pivot along the direction away from the metal oxide rheostat electrode. Due to the trigger mechanism pivoting away from the electrode (...).

Description

TECHNICAL FIELD

[001] This invention relates to a peak voltage stabilizer and mainly refers to a trigger mechanism for the peak voltage stabilizer.

BACKGROUND OF THE INVENTION

[002] Voltage stabilizers are commonly used in electrical circuits used in families, offices and industrial installations, etc., to prevent damage to electrical equipment caused by instantaneous overvoltage in the circuits. When peak voltage or current suddenly occurs in electrical circuits or communication lines due to external disturbance, the peak voltage stabilizer can conduct and split the current in an extremely short time, in order to avoid damage to another device in circuits caused by the surge voltage.

[003] The most commonly used peak voltage stabilizer comprises an element called a metal oxide varistor (MOV) to transfer redundant voltage. The metal oxide varistor has a high resistance in the normal working state and, therefore, substantially shows an off state. When the voltage in the circuit exceeds the predetermined value, for example, under lightning, etc., the resistance of the MOV decreases dramatically and, thus, the varistor is almost in a conductive state and transfers a large volume of current to eliminate redundant voltage.

[004] However, after a long time of use, the metal oxide varistor will age and thus generate heat. In order to prevent the metal oxide varistor from being damaged due to overheating, and to avoid disasters such as fire due to temperature rise, it is common to provide a trigger mechanism in the peak voltage stabilizer, the triggering mechanism and the metal oxide varistor are connected in series so that the metal oxide varistor disconnects from the circuit when the temperature rises.

[005] Figure 1 shows a triggering mechanism adopted by the prior art. The firing mechanism mainly comprises a firing rod substantially in the shape of a plate 1, the firing rod 1 is mounted on a frame support 2 by means of a pivot 3 provided on the frame support 2 of the peak voltage stabilizer , in order to be able to swing, and an upper end 11 of the firing rod 1 is tilted in the direction of the right side of Figure 1, that is, in the firing direction, by bias springs 4. A signal switch lever remote 12 is integrally formed at the lower end of the trigger rod 1, the lever of the remote signal switch 12 cooperates with a remote signal switch (not shown) to drive the remote signal switch. In addition, the middle part of the firing rod 1 is welded to MOV 5 via low temperature solder (not shown), the firing rod 1 is still connected to a terminal 9 of the surge protector via a conductor 8, and terminal 9 connects to an external circuit. The other electrode of the MOV 5 connects to the other terminal 10 of the surge protector, and thus the surge protector is connected to the circuit.

[006] An indicator holder 6, which indicates the current state of the peak voltage stabilizer, is provided on an upper side of the frame holder 2, and the indicator holder 6 is tilted towards the right side of Figure 1 by another bias spring 7, that is, the direction of inclination is the same as the direction of inclination that the bias springs 4 incline the firing rod 1. One of the ends of the indicator support 6 is an indication part, usually in green, the indication part can be exposed through an opening provided in a housing (not shown) of the peak voltage stabilizer and thus the indication part is visible at from the outside. Likewise, a red indication part is formed on the frame support 2 in a position corresponding to the green indication part.

[007] In the normal operating state, firing rod 1 is welded to MOV 5 by means of low temperature welding, and firing rod 1 electrically and mechanically connects to MOV 5. Meanwhile, firing rod 1 it is in the position shown in Figure 1, and the indicator support 6 is held in the position shown in Figure 1 by leaning against the upper end of the trigger rod 1; and, at the same time, the green indication part on the indicator support 6 covers the red indication part on the frame support 2 and therefore the green indication part, which indicates that the surge stabilizer it is currently in the normal operating state, it can be seen from outside the surge protector housing.

[008] When the temperature rises to a certain level, the low temperature weld melts, the firing rod 1 rotates clockwise over pivot 3 in the Figure under the action of propensity springs 4 and, thus, the electrical connection between firing rod 1 and MOV 5 is disconnected. Meanwhile, the remote signal switch lever 12 at the lower end of the trigger rod 1 activates the remote control switch by rotating the trigger rod 1 so as to send a signal indicating to the remote control device firing the firing rod 1. Furthermore, since the firing rod 1 rotates clockwise, the indicator support 6 slides to the right on the upper side of the frame support 2 under the action of the propulsion spring 7 and thus the green indication part moves to the right side to expose the red indication part provided on the frame holder 2 and therefore the red indication part, which indicates the trigger of the peak voltage, can be seen from the outside of the peak voltage stabilizer housing.

[009] However, the conventional triggering mechanism of the surge stabilizer has the following problems: the trigger rod 1 moves substantially in a plane parallel to one side of the MOV 5 and therefore, even in the case where the firing rod 1 fires, the electrical distance between the firing rod 1 and the electrode of the MOV 5 is very short, and this is disadvantageous for the electrical isolation between the firing rod 1 and the electrode of the MOV 5 in the state shooting. In addition, the level of protection and leakage current leakage capability of the standard MOV product is limited, and the costs of adopting single-sheet product from non-standard products are high. Thus, for example, when a rated discharge current of 35kA is required, two standard single-sheet MOVs of 20kA are normally used to achieve this goal, so that a solution occurs where two MOVs are used. In the case of the adoption of two or more MOVs, two or more firing mechanisms mentioned above are required, that is, another firing rod 1 is provided in a similar way on the rear side not shown in the Figure, and the other firing rod 1 is welded to another MOV located at the back of the Figure. However, when the temperature increases, the two firing rods 1 operate independently, it is difficult for the conventional firing mechanism mentioned above to satisfy the needs that two MOVs fire simultaneously. If it cannot be ensured that the two MOVs fire simultaneously, in such a case that the MOV fires while the other fails to fire, the standard 20kA signal sheet MOV can cause the MOV to explode under a peak 35kA voltage.

SUMMARY OF THE INVENTION

[010] The present invention is made based on the problems of the prior art, and an objective of the invention is to provide a trigger mechanism for a peak voltage stabilizer, the trigger mechanism can guarantee the electrical distance between a trigger rod and the MOV in the trigger state, and when a plurality of MOVs are used, simultaneously triggering the plurality of MOVs can be easily accomplished.

[011] In accordance with one aspect of the invention, a trigger mechanism is provided, the trigger mechanism comprising: a frame support for receiving at least one metal oxide varistor; and a firing rod pivotally arranged on the frame support and connected to an electrode of the electrodes of the metal oxide rheostat through low temperature welding. The firing mechanism also includes a sliding block arranged slidingly on the support structure, the sliding block can be slid between a first position and a second position and is tilted towards a disengaged position; in a normal operating state, the sliding block is held in the first position by the firing rod neutralizing the propensity pressure, and in a firing state, the sliding movement of the sliding block towards the second position under the propensity pressure action causes the firing rod to pivot in a direction away from the metal oxide varistor electrode.

[012] Thus, in the triggering state, once the firing rod pivots away from the electrode of the metal oxide varistor, the electrical distance between the firing rod and the electrode of the metal oxide varistor is increased and thus, the reliability of the electrical insulation between the firing rod and the electrode of the metal oxide varistor is improved.

[013] The firing mechanism is additionally provided with a swing arm that is pivotally mounted on the frame support, and the sliding movement of the slide block in the direction of the second position causes the swing arm to pivot a switch. remote control.

[014] Thus, the firing of the firing rod and the swinging of the swing arm are both carried out by the movement of the sliding block, so that the structure of the entire firing mechanism is simplified, the manufacturing cost is reduced and the mechanism reliability is improved.

[015] Preferably, the sliding block is provided with a status indication part that indicates the normal operating state, and when the sliding block is in the first position, the status indication part is visible from the outside through a transparent opening or window provided in a peak voltage stabilizer housing.

[016] In addition, the frame holder is provided with a status indication part that indicates the triggering status, when the sliding block is in the first position, the status indication part that indicates the triggering status is protected by the status indication part which indicates the normal operating state provided on the sliding block, and where the sliding block is in the second position, the status indication part indicating the trip state is exposed and visible from the outside through the opening or the transparent window provided in the peak voltage stabilizer housing.

[017] Preferably, the sliding block comprises an inclined surface, the firing rod rests against the inclined surface when the sliding block is in the first position.

[018] Thus, a simple structure can be used to make the firing rod go off.

[019] Preferably, the sliding block is located between the electrode and the firing rod when the sliding block is in the second position. A channel is provided on the underside of the inclined surface, the electrode is received in the channel when the sliding block is in the second position.

[020] Thus, in the trigger state, in addition to increasing the distance between the trigger rod and the electrode, the sliding block is located between the trigger rod and the MOV electrode, and receives the electrode within its channel , further improving the electrical insulation force between the firing rod and the MOV electrode.

[021] Alternatively, the firing mechanism further includes one or more bias springs, one end of which is connected to the sliding block, and the other end of which is connected to the frame support to tilt the sliding block towards the second position .

[022] Preferably, a first end of the firing rod is pivotally connected to the frame support, 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 slot and is welded to it.

[023] The reliability of the welding between the MOV electrode and the firing rod can be improved by inserting the MOV electrode into the slot and being welded into the slot, and such a side welding method can reduce the thermal impact of the peak voltage in the MOV.

[024] According to another aspect of the invention, two metal oxide varistors are received in the frame structure of the triggering mechanism, and the respective electrodes of the two metal oxide varistors are welded in the same position on the same rod. firing, that is, the two respective electrodes of the two metal oxide varistors are both inserted into the slot of the firing rod and are welded by low temperature welding.

[025] In accordance with another aspect of the invention, a peak voltage stabilizer is provided which comprises the above triggering mechanism.

BRIEF DESCRIPTION OF THE DRAWINGS

[026] The above and previous aspects, characteristics, advantages and technical and industrial importance of this invention will be more clearly understood from the detailed description below of the preferred mode of the present invention made in conjunction with the attached drawings in what:

[027] Figure 1 is a schematic view of a trigger mechanism for a peak voltage stabilizer in the prior art;

[028] Figure 2A is an exploded perspective view showing the triggering mechanism of the peak voltage stabilizer according to a preferred embodiment of the invention, the triggering mechanism comprises a MOV;

[029] Figure 2B is a perspective view of the trigger mechanism after being mounted shown in Figure 2A;

[030] Figure 3A is a side view of the trigger mechanism shown in Figure 2B;

[031] Figure 3B is a cross-sectional view taken along line B-B in Figure 3A;

[032] Figure 3C is an enlarged view of the section circled in Figure 3B;

[033] Figure 4 is a perspective view of the trigger mechanism in the normal operating state;

[034] Figure 5 is a perspective view of the trigger mechanism in the trigger state;

[035] Figure 6A is an exploded perspective view showing the trigger mechanism of the stabilizer according to another preferable embodiment of the invention, the trigger mechanism comprises two MOVs;

[036] Figure 6B is a perspective view of the trigger mechanism after being mounted shown in Figure 6A;

[037] Figure 7A is a side view of the trigger mechanism shown in Figure 6B;

[038] Figure 7B is a cross-sectional view taken along line B-B in Figure 7A; and

[039] Figure 7C is an enlarged view of the section circled in Figure 7B.

DETAILED DESCRIPTION OF THE MODALITIES

[040] Hereinafter, the triggering mechanism according to the preferred embodiments of the invention will be described in detail with reference to the accompanying drawings.

[041] Referring to Figures 2A to 5, a firing mechanism 100 according to the first embodiment of the invention is described. The firing mechanism 100 comprises a frame support 110, the frame support 110 is substantially in the form of a square frame and is used to receive a MOV 200. A pivot 111 is formed in the upper right corner of the frame support 110 , and a firing rod 120 is pivotally arranged in the frame support 110 around pivot 111. Specifically, a circular recess or hole can be formed at one end 121 (the right end in the drawing) of the firing rod 120 , and pivot 111 is inserted into the circular recess or hole. In addition, the trigger rod 120 is connected to a terminal 300 of the surge protector via a conductor 122, and terminal 300 is used to connect the surge protector with an external circuit.

[042] As clearly shown in Figures 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 formed substantially in the middle of the flat panel towards the width of the flat panel in the form of a connecting end, and the concave platform 123 is formed with a straight slot 124 in its middle portion, the straight slot 124 can be opened at one end or both the ends of the direct slot 124 are closed.

[043] A sliding block 130 is arranged on a surface on the upper side of the frame support 110. Sliding block 130 is slidably arranged on the surface on the upper side of the frame support 110, for example, a guide portion 112 is supplied on the frame support 110, and the sliding block 130 can slide under the guidance of the guide portion 112. However, as shown in the drawings, the bias springs 140 are still provided (two springs in the drawing) , one end of the bias springs is connected to the right end of the sliding block 130, and the other end of the bias springs is connected to the pivot 111 and, therefore, the sliding block 130 is tilted towards the right side under the action of the bias springs 140, that is, it is inclined in the direction of pivot 111. At the bottom of the sliding block 130 is formed with a channel 134 along the longitudinal direction, channel 134 is used to prevent the sliding block 130 from interfering with the and letrode 210 of the MOV 200 during sliding of the sliding block 130, and this will be described later. The sliding block 130 is formed with an indication piece 131, that is, a green indication part, at its left end. As in the prior art, in the state as shown in Figure 2B, the green indication part is exposed through an opening or a window provided in the peak voltage stabilizer housing to indicate that the peak voltage stabilizer - are in a normal operating state.

[044] Another pivot 113 is formed on the underside of the frame support 110, a swing arm 150 is pivotally arranged on the frame support 110 through the pivot 113, and an end (the lower end in the drawing) of the arm oscillating 150 is formed with a switch drive part 151 to drive a remote control switch, which is not shown in the drawing. The other end (the upper end in the drawing) of the swing arm 150, as shown in Figure 4, is formed with a drive portion 152 that engages with a projection 132 provided in the slide block 130, and the projection will push the swing arm 150 to rotate clockwise around pivot 113 when sliding block 130 slides to the right.

[045] As shown in Figure 2A, the MOV 200 comprises two electrodes 210 and 220. As shown in Figures 3C and 4, in the normal operating state, the MOV 200 is received in the frame support 110, and an electrode 210 of the MOV it is inserted in the slot 124 formed in the concave platform 123 of the firing rod 120, and is connected to the firing rod 120 through a low temperature solder 400. The other electrode 220 of the MOV 200 is connected to the other terminal 500 of the es - peak voltage stabilizer, for example, through 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 through the trigger rod 120 and terminal 300 and, on the other hand, it is connected to another phase of the external circuit through the other electrode 220 and the other terminal 500 of the peak voltage stabilizer, and when the voltage between the two phases of the external circuit exceeds the predetermined voltage, the MOV 200 conducts the two phases and functions to divide the current and reduce the voltage.

[046] As shown in Figure 4, in the normal operating 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 leans against the inclined surface 133 , and thus preventing the sliding block 130 from moving in the direction of pivot 111 through the bias spring 140. In such a state, the sliding block 130 is located in the first position, the indication part 131 is visible from from the outside through the opening or the transparent window provided in the peak voltage stabilizer housing, thus indicating that the peak voltage stabilizer is in a normal operating state.

[047] When the temperature in the peak voltage stabilizer rises and reaches or exceeds the predetermined temperature threshold value, the low temperature solder 400 melts and, at this point, the connection between firing rod 120 and electrode 210 of the MOV 200 is released, and thus the firing rod 120 cannot serve the function of preventing the sliding block 130 from sliding further. Under such circumstances, the sliding block 130 slides in the direction of the right side in the drawing, under the action of the bias pressure of the bias springs 140 and, at the same time, the inclined surface 133 of the sliding block 130 pushes the shank. firing 120 upwards to make the firing rod 120 rotate clockwise in the drawing around pivot 111. Figure 5 shows the firing mechanism in the firing state. In the state shown in Figure 5, the sliding block 130 slid to the second position on the right side, pushing the firing rod 120 upwards and, at the same time, the sliding block 130 covers the electrode 210 of the MOV 200; at this time, electrode 210 is received in channel 134 and therefore electrode 210 and firing rod 130 are electrically insulated. Meanwhile, as can be seen from Figure 5, the green display part 131 has moved to the right and therefore a red display part 114, which is provided on the frame holder 110 and was protected by the green indication part 131, it is exposed. As the sliding block slides to the right, the projection 132 on the sliding block 130 pushes the drive portion 152 of the swing arm 150, causing the swing arm 150 to rotate clockwise around pivot 113, and thus, the actuating part of switch 151 activates the remote control switch (not shown), sending a trigger signal from the surge voltage stabilizer to the remote control device.

[048] Figures 6 and 7 show the trigger mechanism according to the second embodiment of the invention, the structure of the present trigger mechanism is substantially the same as that described above, the difference lies in the fact that the support frame 110 receives two MOV 200. Thus, as shown in Figure 7C, the electrodes of the MOV 200 are both inserted into slot 240 of the firing rod 120, and are welded to the firing rod 120 by means of low temperature welding 400. Thus, when the temperature rises, even in the case where two MOV 200 transfer a different amount of heat to the welding point through their respective electrodes, since the heat is applied to the same point as the welding, and so the mechanism fires simultaneously. Since other parts of the second modality are the same as in the first modality, the description is omitted.

[049] According to the trigger mechanism of the invention, in the trigger state, the trigger rod 120 rotates in a direction opposite to the electrode 210 of the MOV 200, as a result, the electrical distance between the trigger rod 120 and the electrode 210 is increased, the reliability of the electrical insulation between the firing rod 120 and the electrode 210 is improved.

[050] In addition, according to the invention's triggering mechanism, in the triggering state, the sliding block 130 slides into position between the trigger rod 120 and the electrode 210 of the MOV 200, and covers the electrode 210 of the MOV 200, and thus the electrical insulating force between the firing rod 120 and the electrode 210 is reinforced.

[051] In addition, according to the invention's triggering mechanism, electrodes 210 of the two MOVs 200 are welded in the same position as the firing rod 120 by means of low temperature welding, when the temperature rises, even if two MOVs 200 transfer a different amount of heat to the welding point through their respective electrode, since the hest is applied to the same welding point, the mechanism will fire simultaneously and thus improve the trigger mechanism reliability.

[052] Furthermore, according to the present invention, both the pivoting of the firing rod 120 and the oscillation of the swing arm 150 are activated by the sliding of the sliding block 130, as a result, the structure of the entire locking mechanism. firing is simplified, the cost of production is reduced and the reliability of the entire firing mechanism is improved.

[053] Although the invention has been described in connection with preferred embodiments of the present invention, it should be understood that the invention is not limited to the specific embodiments described, and based on the teachings, those skilled in the art can make various modifications, variations and alternatives to these modalities. Thus, the present invention is intended to cover all of these modifications, variations and alternatives, and the scope of protection of the present invention is only defined by the appended claims and their equivalents.

Claims (11)

1. Trigger mechanism (100) for a peak voltage stabilizer, the trigger mechanism (100) comprising: a frame support (2, 110) for receiving at least one metal oxide varistor; and a firing rod (1, 120, 130) pivotally arranged on the frame support (2, 110) and connected to a metal oxide rheostat electrode (210, 220) through low temperature welding, the firing mechanism (100) further comprises a sliding block (130) slidably arranged on the frame support (2, 110), the sliding block (130) being slid between a first position and a second position and being tilted towards a position of firing; in a normal operating state, the sliding block (130) being held in the first position by the firing rod (1, 120) acting against the tilt pressure, and in a firing state, the sliding movement of the sliding block (130) in the direction of the second position under the action of the tilt pressure causing the firing rod (1, 120) to pivot in a distant direction from the electrode (210, 220) of the metal oxide varistor; characterized by the fact that the sliding block (130) is located between the electrode (210, 220) and the firing rod (1, 120) when the sliding block (130) is in the second position. Firing mechanism (100) according to claim 1, characterized by the fact that it still comprises a swing arm (150) pivotally mounted on the frame support (2, 110), and the sliding movement of the sliding block (130) in the direction of the second position it causes the swing arm (150) to pivot in order to activate a remote control switch. Trip mechanism (100) according to claim 1, characterized in that the sliding block (130) is provided with a status indication part (131) indicating the normal operating state, and when the sliding block (130) is in the first position, the status indication part (131) is visible from the outside through an opening or a transparent window arranged in a peak voltage stabilizer housing. Trigger mechanism (100) according to claim 3, characterized in that the frame support (2, 110) is provided with a status indication part (131) indicating the trigger state, when the block slide (130) is in the first position, the status indication part (131) indicating the trip state is protected by the status indication part (131) indicating the normal operating state provided in the slide block (130), and when the sliding block (130) is in its second position, the status indication part (131) indicating the triggering state is exposed and is visible from the outside through the opening or transparent window provided in the peak surge stabilizer housing voltage. Firing mechanism (100) according to claim 1, characterized in that the sliding block (130) comprises an inclined surface (133), the firing rod (1, 120) is located against the inclined surface ( 133) when the sliding block (130) is in the first position. Trigger mechanism (100) according to claim 1, characterized by the fact that a channel (134) is provided on a lower side of the inclined surface (133), the electrode (210, 220) is received in the channel ( 134) when the sliding block (130) is in the second position. Firing mechanism (100) according to claim 1, characterized in that it still comprises one or more bias springs, one end of the spring (s) is connected to the sliding block (130), and the the other end of the spring (s) is connected to the frame support (2, 110) to tilt the sliding block (130) towards the second position. Firing mechanism (100) according to claim 1, characterized in that a first end of the firing rod (1, 120) pivotally connects to the frame support (2, 110), and a second end of the firing rod (1, 120) is welded to the electrode (210, 220). Firing mechanism (100) according to claim 8, characterized in that the second end of the firing rod (1, 120) is formed with a slot (124), and the electrode (210, 220) is inserted into the slot (124) and is welded to it. 10. Trigger mechanism (100) according to any one of the previous claims, characterized by the fact that the metal oxide varistors are received in the frame support (2, 110), and the respective electrodes (210, 220) of the two metal oxide varistors are welded in the same position on the same firing rod (1, 120). 11. Peak voltage stabilizer, characterized in that the peak voltage stabilizer comprises at least one metal oxide varistor and a trigger mechanism (100) as defined in any one of claims 1 to 10.

Images