DE102017124219A1 - Surge protection device - Google Patents

Abstract

Shown and described is an overvoltage protection device (1) with a housing (4, 5), with at least two overvoltage limiting components (6a, 6b), with at least two separation devices, and with a switch (7) having a telecommunications contact for remote notification of the state of the surge protection device (1), wherein the separating devices are movably arranged in the housing (4) and a respective disconnecting device is associated with a surge limiting device (6a, 6b) and electrically disconnects it upon overload of the associated overvoltage limiting device (6a, 6b) by disconnecting the disconnecting device In the inventive overvoltage protection device (1) thereby remote notification of the state of the surge protective device (1) is simple and with few components possible that a connecting element (12) is movably disposed in the housing (4, 5) , and that the switch (7 ) is in operative connection with the at least two separating devices via the connecting element (12) in such a way that the at least two separating devices are each in their first position, while the switch (7) has a different switching position when at least one severing device is in its second position.

Description

The invention relates to an overvoltage protection device having a housing, with at least two overvoltage limiting components, with at least two disconnecting devices, and with a switch as a remote signaling contact for the remote indication of the state of the overvoltage protection device. The separation devices are movably arranged in the housing, wherein a respective separation device is assigned to a surge-limiting component and, in the event of overloading of the associated surge-limiting component, electrically disconnects the latter by moving the separation device from a first position to a second position.

Overvoltage protection devices are widely used in various design variants for the protection of electrical circuits, systems, machines and devices. Depending on the application and protection level, the overvoltage protection devices have different overvoltage limiting components and different designs. In particular, spark gaps, gas-filled surge arresters and varistors and combinations of these components are used as overvoltage limiting components.

Due to aging and intermittent overvoltages (TOV) in seconds, there is an undesirable increase in the leakage current of the varistor at operating voltage, in particular with overvoltage protection devices with a varistor as arrester. Overvoltage protection devices with a varistor as arrester therefore generally have a thermal separation device, by means of which a varistor which is no longer functioning properly is disconnected from the current path to be monitored. In known overvoltage protection devices, the monitoring of the state of the varistor according to the principle of a temperature switch, wherein overheating of the varistor - for example, due to leakage currents occurring - a provided between the varistor and a conductive connection element solder connection is separated, resulting in electrical separation of the varistor.

The DE 695 03 743 T discloses such a surge protection device with two varistors connected in parallel, each of which can be separated individually at the end of their lives. For this purpose, two conductive connecting elements designed as resilient separating tongues are provided, the first end of which is fastened in the normal state of the varistor in each case via a soldering point to a connection tongue of the varistor, while the second end of each is fixedly connected to a connection contact. If there is an inadmissible heating of a varistor, this leads to a melting of the solder joint. Since the resilient separation tongue is deflected in the soldered state (normal state of the varistor) from its rest position and thus biased, the free end of the separation tongue on softening of the solder joint from the connection tongue of the varistor away, whereby the varistor is electrically disconnected.

An overvoltage arrester with a thermal disconnector is also out of the DE 20 2004 006 227 U1 also known here according to an exemplary embodiment ( 5 ) a varistor is used as arrester. That from the DE 20 2004 006 227 U1 Known overvoltage protection element, in addition to a conductive connecting element and a thermally disconnecting compound on an insulating separator, which is slidably disposed in the housing and can be moved by the force of a spring element from a first position to a second position. The first connection contact is permanently electrically connected to the first terminal of the varistor. The second connection contact is conductively connected to the first end of the conductive connection element. In the normal state of the overvoltage protection element, ie when the varistor is not heated inadmissible, the second end of the conductive connection element is connected via the thermally disconnecting connection to the second terminal of the varistor. In addition, the insulating separating element is held in its first position against the spring force of the spring element by the soldering connection realized between the second end of the conductive connecting element and the second terminal of the varistor.

If the surge arrester has heated up so much due to a permanent overloading of the varistor that a predetermined limit temperature is exceeded, then the solder joint breaks down. In this case, the insulating separating element is moved by the force of the spring element in its second position, in which a portion of the separating element between the second end of the conductive connecting element and the second terminal of the varistor is arranged, so that the varistor is electrically disconnected. Due to the movement of the separating element into its second position, an arc which possibly arises when the separating point is opened is also extinguished by the insulating separating element entering the separating point.

The well-known surge protection device consists of a device provided with terminals bottom part and designed as a "plug part" over-voltage protection element that can be easily attached to the bottom of the device. These are in the Overvoltage protection element, the terminal contacts designed as plug pins or plug-in swords, which are arranged in the lower part of the device corresponding sockets, which are connected to terminals for electrical connection of the overvoltage protection device. In addition, the known overvoltage protection device has a visual status indication and a changeover contact as a signal transmitter for remote signaling of the state of the overvoltage protection element, wherein both the changeover contact in the lower part of the device and the optical status indicator on the connector part via a common mechanical actuation system can be actuated.

Also the DE 10 2009 036 125 A discloses an overvoltage protection element with a varistor which is cut off in the event of unacceptable heating by a thermally disconnecting connection. In this overvoltage protection element, the conductive connecting element is connected to an insulating separating element in such a way that when the thermal connection is interrupted, the insulating separating element is moved between a terminal of the varistor and the associated connecting contact. The connecting element is preferably formed as a metal piece and arranged in the separator formed by a rigid insulating plate.

For displacing the separating element, a spring-loaded release carriage is arranged within the housing, through which the insulating separating element is moved to the second position when the thermal connection is interrupted. In the release carriage, a bore is also formed, in which a trigger pin for actuating a telecommunications contact is arranged. The lower end of the release pin protrudes in the normal state of the overvoltage protection element from an opening arranged in the bottom of the housing, so that a switch of a telecommunications contact arranged in the device lower part can be actuated by the release pin.

The known overvoltage protection devices enable safe separation of a damaged overvoltage limiting component, in particular a varistor. In addition, the overvoltage protection elements partially have a visual indication of the state and additionally also enable a remote indication of the state of the overvoltage protection device. The disadvantage here, however, that the surge protective devices to relatively many components require, whereby the assembly is complex and therefore expensive. This applies in particular if the overvoltage protection device not only has a surge-limiting component, but at least two overvoltage-limiting components, which are to be monitored independently of one another and disconnected in the event of damage. In order to keep the user's wiring effort as low as possible, overvoltage protection devices with two or more overvoltage limiting components only have a remote indication. Although all over-voltage limiting components are monitored, the switches associated with the individual components are connected in series, so that an error message is output via the remote message if at least one overvoltage-limiting component has been switched off. By using several switches for remote signaling, the number of components increases further.

The present invention is based on the object to provide an overvoltage protection device described above with at least two arranged in the housing overvoltage limiting components available, which is as simple as possible and thus can be produced inexpensively. In particular, the remote notification of the state of the overvoltage protection device should be simple and reliable, even if the overvoltage protection device has more than one overvoltage limiting component.

This object is achieved in the above-described overvoltage protection device with the features of claim 1. In the case of the overvoltage protection device according to the invention, a connecting element is movably arranged in the housing, via which the switch of the telecommunication contact is in operative connection with the at least two separating devices, such that the switch has a first switching position, when the at least two separating devices are each in their first position, while the switch has a different switching position when at least one separating device is in its second position. If the at least two separating devices are each in their first position, this means that the overvoltage limiting components are not overloaded and therefore not electrically disconnected, so that a corresponding signal can then be output via the switch in the first switching position that the overvoltage protection device is functional. If, on the other hand, at least one separating device is in its second position, this means that the associated overvoltage limiting component is electrically cut off due to a detected overload. This then leads via the operative connection between the separating devices and the switch to the fact that the switching position of the switch changes, so that then a corresponding error message can be output via the switch.

The inventive design of the overvoltage protection device and the above-described arrangement of the connecting element, via which the at least two separating devices are in operative connection with the one switch, the possibility has been created to detect the position of at least two separating devices with only one switch, so that Remote notification of the state of an overvoltage protection device with at least two overvoltage limiting components only one switch is required as a remote signaling contact.

It has previously been stated that the overvoltage protection device has at least two overvoltage limiting components and at least two disconnection devices. Although it is possible in principle that the overvoltage protection device has more than two overvoltage limiting components, for example three or four overvoltage limiting components, it is subsequently always assumed that the overvoltage protection device has two overvoltage limiting components and two disconnection devices, wherein one disconnecting device is assigned to one overvoltage limiting component is. It is also conceivable, however, that the overvoltage protection device, with more than two overvoltage limiting components, also has more than two disconnecting devices which are then in operative connection with the switch of the telecommunication contact via the connecting element.

In the preferred embodiment of the overvoltage protection device according to the invention, in which two overvoltage limiting components and two separation devices are provided, three different states of the separation devices are possible. In the first state, both separating devices are each in their first position, so that the switch assumes its first switching position via the connecting element. According to the second possible state, one of the two separating devices is in its first position while the other separating device is in its second position. About the connecting element and this state is transmitted to the switch, so that the switch can take a different, second switching position. In the third possible state, both separating devices are in their second position, wherein this state is also transmitted via the connecting element to the switch, so that the latter can assume a third switching position deviating from the first switching position.

Depending on the design of the switch, it is possible that the switch has two or three switching positions. In the first case, the second switching position and the third switching position are identical, so that the switch can only distinguish between the first switching position and another, second switching position. In the second case, the second switching position and the third switching position are different, so that a distinction between the second and the third state is possible via the switch, so a distinction as to whether only one separating device or both separating devices are in their second position. Both possibilities can be realized in the overvoltage protection device according to the invention.

The above-described operative connection between the two separating devices and the switch via the connecting element can be realized structurally in different ways. According to a first embodiment, the connecting element acts as a kind of rocker, wherein it is arranged with its center on the switch, while the two separating devices are in their first position in each case with one of the two ends of the connecting element in contact. Are the two separating devices in their first position, the switch is held against a spring force by the connecting element in its first switching position. If at least one of the two separating devices is in its second position, then the switch can be moved by the spring force from the first position into another, second position.

Only when both separation devices are in their first position, is also the connecting element and thus also its center in its first position, in which the switch is held against a spring force in its first switching position. Moves at least one separating device from its first position to its second position, this leads to the fact that even acting as a kind of rocker connection element is no longer fixed in its first position, but can change its position. In this case, the center of the connecting element can then be moved by the spring force from its first position to a second position, so that the switch can also assume its second switching position.

In a second embodiment variant of the overvoltage protection device according to the invention, the connecting element is connected at both ends to a disconnecting device. In this case, the center of the connecting element contacts the switch, so that the switch is held against a spring force in its first switching position when the two separating devices are in their first position. The contact of the switch through the center of the connecting element can be done directly or via an additional actuator, ie the center of the The connector does not need to be in direct contact with the switch when the two disconnect devices are in their first position. All that is decisive is that the switch is held in its first switching position via the connecting element and possibly an actuating element arranged therebetween when the two separating devices are in their first position. If, on the other hand, at least one of the two separating devices is in its second position, then the switch is no longer held in its first switching position, so that it can be brought into a second switching position by a spring force.

According to a particularly preferred embodiment of the invention, which can be used in both embodiments described above, the separating devices each have a conductive connecting element and an insulating separating element. In the normal state of a surge-limiting component, a connection of the overvoltage-limiting component is electrically conductively connected via a thermally disconnecting connection to a first end of the associated conductive connection element, wherein the associated insulating separation element is then held by the conductive connection element against a force acting on it in a first position is. When a predetermined limit temperature of the overvoltage limiting component is exceeded, the thermal connection is severed, so that the separating element is moved by the force acting on it into a second position, in which a separating section of the separating element between the first terminal of the overvoltage limiting component and the first End of the conductive connection element is arranged, whereby the overvoltage limiting component is electrically separated.

The disconnecting device is thus a thermal separation device known from its basic structure and its mode of operation, in which the connection of the overvoltage limiting component normally takes place via the electrically conductive connecting element, while this connection is prevented by excessive heating of the overvoltage limiting component Separator is interrupted by the insulating separator moves between the corresponding terminal of the surge limiting device and the end of the conductive connecting element.

If the overvoltage protection device according to the invention has two corresponding disconnecting devices for two overvoltage limiting components, the switch is preferably in operative connection with the two separating elements of the two disconnecting devices via the connecting element, i. the two separating elements are in communication with the connecting element. In the preferred embodiment of the overvoltage protection device according to the invention, the two separating elements thus not only ensure a secure separation of a damaged overvoltage limiting component by being spent in disconnected thermal connection between each associated overvoltage limiting component and the corresponding connecting element, but the connecting elements also provide for an active Change in the position of the connecting element, if at least one connecting element changes its position.

The connection between the two separating elements and the connecting element is preferably realized in that in each case an opening is formed in the two separating elements, in each of which one end of the connecting element is arranged. The connecting element thus extends with its two ends through the two openings in the two separating elements, so that one end of the connecting element is moved during a movement of a separating element from its first position to its second position.

According to a variant of the invention, the connecting element is integrally connected to the two separating elements, wherein the connecting element is at least partially flexible or flexibly connected to the two separating elements. This variant of the invention also causes the connecting element to be moved during a movement of a separating element from its first position into its second position. Due to the flexible design or the flexible connection of the connecting element to the two separating elements, it is still possible that the two insulating separating elements can independently change their position. As a result, the separation function of the two separating elements is not affected, so that both overvoltage limiting components can be separated independently. In this embodiment of the invention, the connecting element can be designed to be flexible overall or the connecting element can also have only flexible sections, with which it is connected, for example, with the insulating separating elements. The flexible sections may in particular be designed as film hinges, via which one or more rigid sections of the connecting element are connected to one another.

As overvoltage limiting components, which are electrically separated in each case by an inadmissible heating by a thermally disconnecting compound, for example be used gas-filled surge arrester. Preferably, however, the overvoltage protection device according to the invention has two varistors as overvoltage limiting components, so that subsequently mostly varistors are mentioned, without the invention being restricted thereto. The thermally disconnecting connections between the first end of a conductive connection element and the one connection of the associated varistor are preferably each designed as a solder connection, so that via a corresponding selection of the solder, the limit temperature can be set, from which the thermal connection separates.

According to a further advantageous embodiment of the invention, the separating elements are each rotatably arranged in the housing, so that the separating elements are moved from their first position to their second position by a pivoting movement. The axis of rotation of the separating elements is preferably formed by formed in the housing pivot, to which corresponding openings are formed in the separating elements. Just as well, however, corresponding pivot pins can be formed on the separating elements, which engage in corresponding openings in the housing. As an alternative to the rotatable arrangement, the separating elements can also be arranged linearly displaceable in the housing, wherein the displacement direction can extend both parallel to the longitudinal axis and perpendicular to the longitudinal axis of the overvoltage protection device.

In order for the separating elements to be able to be moved from their first position into their second position when the thermal connection has been interrupted, a force acts on the separating elements in each case. Preferably, this force is applied by at least one spring element which is arranged in the housing. The spring elements is attached with its one end to a pin in the housing and with its other end to a corresponding pin as a point of attack on the separator.

In order for the conductive connecting elements to move from their first position to their second position when the thermal connections are severed, the connecting elements are preferably each of a resilient design and are deflected out of their rest position in their first position. When disconnected thermal connection, the connecting elements then spring due to their spring force from its first position to its second position. This movement is additionally assisted by the retraction of the separating section of a separating element into the separation point between the connection of the varistor and the first end of the connecting element.

Preferably, the overvoltage protection device according to the invention not only has a switch for remote indication of the state of the overvoltage protection device, but also an optical status indication. For this purpose, the separating elements each have a marking section, so that the visual status indication is formed directly by the separating elements. The viewing window formed in the housing is dimensioned such that, depending on the position of the separating elements, the marking section of a separating element is visible from the outside through the viewing window or not. The optical indication of the state of the varistor is preferably carried out by a corresponding color display, to which the marking section or the entire separating element has a corresponding color, for example a red color.

In order that the intended movement of the separating elements from their first position to their second position is not hindered by the marking sections, the marking sections are preferably offset from one another so that one marking section covers the other marking section when both separating elements are in their second position. Alternatively, the dimensions of the marking sections could also be chosen such that both marking sections are arranged side by side both in the first position and in the second position of the separating elements. In this case it can even be visually distinguished whether only one varistor or both varistors have been cut off.

The overvoltage protection device according to the invention advantageously consists of a plug part and a device lower part, wherein the overvoltage limiting components and the disconnecting device and in the lower part of the device, the switches and terminals are arranged in the plug part. For actuating the switch, an opening is formed in the device lower part facing the underside of the plug housing, through which the switch or an end of the actuating element protrudes into the plug housing, when the plug part is attached to the lower device part. Above the opening is the connecting element, which is preferably connected with its two ends, each with a separating element. The arranged below the opening in the device base switch of the telecommunications contact can be kept so directly through the center of the connecting element or by the actuating element in its first switching position, when the two separating elements are both in their first position. If at least one separating element is in its second position, this leads to a change in the position of the center of the connecting element, so that the switch due to a spring force changed its switching position, namely occupies its second switching position.

By the above-described configuration and arrangement of the two separating elements and the connecting element can also be determined by the switch in the lower part of the device also when a plug part is not attached to the lower part of the device. Also in this, the switch is not held or pressed by the connecting element in its first switching position, so that the switch assumes its second switching position and a corresponding error message is output.

• 1 eine vereinfachte Darstellung eines bevorzugten Ausführungsbeispiels eines erfindungsgemäßen Überspannungsschutzgeräts, im Normalzustand und mit elektrisch abgetrenntem Varistor,
• 2 eine Prinzipdarstellung einer ersten Variante des Betätigungsmechanismus des Schalters, in drei verschiedenen Zuständen,
• 3 eine Prinzipdarstellung einer zweiten Variante des Betätigungsmechanismus des Schalters, in zwei verschiedenen Zuständen,
• 4 eine Prinzipdarstellung einer weiteren Variante des Betätigungsmechanismus des Schalters, in zwei verschiedenen Zuständen,
• 5 eine Prinzipdarstellung einer weiteren Variante des Betätigungsmechanismus des Schalters, in zwei verschiedenen Zuständen,
• 6 eine vereinfachte Darstellung eines weiteren Ausführungsbeispiels eines Überspannungsschutzgeräts im Normalzustand und mit elektrisch abgetrenntem Varistor,
• 7 eine vereinfachte Darstellung einer Variante des Ausführungsbeispiels eines Überspannungsschutzgeräts gemäß 6, im Normalzustand und mit elektrisch abgetrenntem Varistor,
• 8 eine vereinfachte Darstellung einer Variante des Ausführungsbeispiels des Überspannungsschutzgeräts gemäß 1, im Normalzustand und mit elektrisch abgetrenntem Varistor, und
• 9 eine vergrößerte Darstellung des Steckerteils des in 8 dargestellten Überspannungsschutzgeräts, mit zwei elektrisch abgetrennten Varistoren.

In particular, there are a variety of ways to design and develop the overvoltage protection element according to the invention. Reference is made to both the claims subordinate to claim 1 and to the following description of preferred embodiments in conjunction with the drawings. In the drawing show:

• 1 a simplified representation of a preferred embodiment of an overvoltage protection device according to the invention, in the normal state and with electrically separated varistor,
• 2 3 is a schematic diagram of a first variant of the actuating mechanism of the switch, in three different states,
• 3 a schematic diagram of a second variant of the actuating mechanism of the switch, in two different states,
• 4 3 is a schematic representation of another variant of the actuating mechanism of the switch, in two different states,
• 5 3 is a schematic representation of another variant of the actuating mechanism of the switch, in two different states,
• 6 a simplified representation of another embodiment of a surge protective device in the normal state and with electrically separated varistor,
• 7 a simplified representation of a variant of the embodiment of an overvoltage protection device according to 6 , in normal condition and with electrically separated varistor,
• 8th a simplified representation of a variant of the embodiment of the overvoltage protection device according to 1 , in the normal state and with electrically separated varistor, and
• 9 an enlarged view of the plug part of in 8th represented overvoltage protection device, with two electrically separated varistors.

The 1 . 6 and 7 show three variants of preferred embodiments of an overvoltage protection device according to the invention 1 , each in a simplified representation. The surge protection device 1 can be formed in two parts, namely a plug part 2 and a device base 3 exist, as in 1 is shown. The plug part 2 can then just on the U-shaped device base 3 be attached and, for example, to replace a defective connector part 2 also simply from the device lower part 3 be deducted without that on the bottom of the device 3 connected lines must be solved. The plug part 2 has a connector housing 4 and the lower part of the device 3 a socket housing 5 on, so that with the overvoltage protection device 1 the housing from the connector housing 4 and the socket housing 5 exists, which preferably lock together when the plug part 2 on the bottom of the device 3 is plugged.

In addition, the surge protection device has 1 in particular two varistors 6a . 6b as overvoltage limiting components, which together in the illustrated embodiment in the connector housing 4 are arranged. In addition, the surge protection device 1 two separators and one in the base housing 5 arranged switch 7 as remote signaling contact for remote indication of the state of the overvoltage protection device 1 on. The two separating devices each consist of a conductive connecting element 8th and an insulating separator 9a . 9b in the plug part 2 are arranged.

In the 1 and 6 to 8th is the surge protection device 1 each shown from one side, wherein both the connector housing 4 as well as the socket housing 5 are shown only very schematically and in particular the components arranged in the interior of the housing are shown visibly, even if they are in a real overvoltage protection device 1 are concealed by corresponding side walls of the housing. In addition, in these figures, only a varistor 6a and correspondingly only one conductive connecting element 8th and an insulating separator 9a shown, even if in the connector housing 4 actually two varistors 6a . 6b and correspondingly also two conductive connecting elements 8th and two insulating separator 9a . 9b are arranged. The second varistor 6b and the second connecting element and the second separating element 9b are in the 1 and 6 to 8th each in the drawing levels behind the first varistor 6a or the first connection element 8th and the first separator 9a arranged and thereby covered by this. The following description therefore primarily relates to the one, first varistor 6a . However, the same applies accordingly to the second varistor 6b ,

In the in 1a illustrated normal state of the first varistor 6a is the first connection 10 of the varistor 6a via a solder connection as a thermally disconnecting connection with the first end of the first conductive connection element 8th electrically connected. This is in the first separator 9a an opening 11 formed by the first end of the first conductive connecting element 8th over the solder connection with the first connection 10 of the varistor 6a connected is. In addition, the first separating element 9a through the solder joint between the first varistor 6a and the first connection element 8th held in its first position. This also applies accordingly to the connection of the second varistor 6b with the second connecting element and the arrangement of the second separating element 9b ,

Does it come to a heating of the varistor 6a Thus, when a predetermined limit temperature is exceeded, a separation of the thermal connection occurs, ie, a melting of the solder joint, so that the resilient connecting element 8th from its deflected, first position springs back to its relaxed, second position. In addition, the separating element 9a spent in its second position, in which a separation section of the separating element 9a between the first connection 10 of the varistor 6a and the first end of the connecting element 8th is arranged. The opening 11 in the separating element 9a is no longer above the first port 10 of the varistor 6a , This condition is in 1b shown. Quite correspondingly, the second connecting element and the second separating element behave when the temperature of the second varistor 6b exceeds the limit temperature, so that between the first terminal of the second varistor 6b and the first end of the second connection element formed solder joint melts. In this case, then also pivots the second separator 9b with its separating portion between the first terminal of the second varistor 6b and the first end of the second conductive connection element.

In the surge protection device according to the invention 1 is also a connecting element 12 provided, over that in the base housing 5 arranged switches 7 with the two separating elements 9a . 9b is in active connection. The desk 7 has a first switching position ( 1a) when the two dividers 9a . 9b each in their first position, while the switch 7 has a second switching position ( 1b) if there is at least one separator 9a . 9b located in its second position. By the arrangement of the connecting element 12 and its operative connection with the two separating elements 9a . 9b can the position of the two separating elements 9a . 9b with only one switch 7 be detected, so that to remotely report the state of an overvoltage protection device 1 with two varistors 6a . 6b just a switch 7 is required.

Possible constructive embodiments of the operative connection between the two separating elements 9a . 9b and the switch 7 are in the simplified schematic diagrams according to the 2 to 5 and will be described below.

At the in 2 shown principle representation, the connecting element acts as a kind of rocker, wherein the center of the connecting element 12 on the switch 7 is arranged. Are the two separating elements 9a . 9b according to 2a in their first position, they are each with one end 13a . 13b of the connecting element 12 in touch, leaving the switch 7 against a spring force F through the connecting element 12 is held in its first switching position.

If there is a thermal overload of a varistor, so that the associated separator 9a is spent in its second position, this leads according to 2 B to a "tilting" of the connecting element 12 , The desk 7 takes on the basis of the spring force F its second switching position, since he no longer through the connecting element 12 is prevented from moving accordingly. The middle of the connecting element 12 is doing by the switch 7 shifted towards the spring force F while the end 13b of the connecting element 12 through the second separating element 9b is held in its position. This then leads to the already mentioned "tilting" of the connecting element 12 , where the first end 13a of the connecting element 12 moved upwards, since the corresponding first separating element 9a has moved from its first position to its second, upper position.

Are both separating elements 9a . 9b according to 2c in their second position, so are the two separating elements 9a . 9b each spaced from the associated end 13a . 13b of the connecting element 12 , where again the switch 7 is in its second switching position. It is for the switching position of the switch 7 irrelevant, whether the two separating elements 9a . 9b one after the other or simultaneously from their first position to their second position. It is also conceivable that the two separating elements 9a . 9b one end each 13a . 13b of the connecting element 12 still slightly contact, as long as through a sufficient movement of the separating elements 9a . 9b it is ensured that the switch 7 can move from its first switching position to its second switching position.

3 shows a basically second embodiment of the actuating mechanism of the switch 7 in which the connecting element 12 with both ends 13a . 13b each with a separator 9a . 9b connected is. Are the two separating elements 9a . 9b according to 3a both in their first position, so contacted the center of the connecting element 12 the switch 7 , In the embodiment according to 3 is between the connecting element 12 and the switch 7 another actuator 14 arranged so that the middle of the connecting element 12 the switch 7 not directly, but via the actuator 14 contacted.

The connection between the two separating elements 9a . 9b and the connecting element 12 is thereby realized that in the two separating elements 9a . 9b one opening each 15a . 15b is formed, in each case an end 13a . 13b of the connecting element 12 is arranged. The openings 15a . 15b are each dimensioned so that they on the one hand an entanglement of the connecting element 12 allow, if only one separator 9a . 9b On the other hand, however, ensure that during a movement of a separating element from its first position to its second position 9a . 9b the corresponding end 13a . 13b of the connecting element 12 is moved. The connecting element 12 is thus at a movement of the separating elements 9a . 9b actively involved.

Is there a separator 9a or both separators 9a . 9b ( 3b) in its second position, so will the switch 7 no longer held against a spring force F in its first position, leaving the switch 7 can take his second switching position. In the schematic diagram according to 3b is the middle of the connecting element 12 spaced from the actuator 14 , which is not mandatory. Rather, it is sufficient if, in the second position, at least one of the two separating elements 9a . 9b the middle of the connecting element 12 at least that far from the counter 7 moved away is that the switch 7 can take his second switching position. If doing the middle of the fastener 12 the actuator 14 still slightly contacted, so this is for the intentional operation of the switch 7 irrelevant.

In the in the 4 and 5 shown actuating mechanism is the connecting element 12 integral with the two separating elements 9a . 9b connected, so that similar to the variant according to 3 the connecting element 12 during a movement of a separating element 9a . 9b from his first position to his second position is actively taken. Are both separating elements 9a . 9b according to the 4a and 5a in its first position, so will the switch 7 through the middle of the connecting element 12 contacted, so the switch 7 held against a spring force F in its first switching position. If, on the other hand, there is a separating element 9a . 9b or both separators 9a and 9b in its second position, so is the middle of the connecting element 12 from the counter 7 spaced so that the switch 7 can take his second switching position. Again, the middle of the connecting element 12 the switch 7 still slightly contact, as long as this does not prevent the switch 7 can take his second switching position.

In the embodiment according to 4 is the connecting element 12 overall flexible, while in the variant according to 5 the connecting element 12 rigid sections 16 which has flexible areas in the form of film hinges 17 connected to each other. Also the connection between the separating elements 9a . 9b and the ends 13a . 13b of the connecting element 12 is about film hinges 17 realized.

The 6 and 7 both show simplified representations of a further embodiment of an overvoltage protection device 1 , in each case in the normal state and with an electrically separated varistor e While in the embodiment according to 1 the separating elements 9a . 9b each rotatable in the connector housing 4 are arranged in the embodiments according to the 6 and 7 the separating elements 9a . 9b linearly displaceable in the connector housing 4 arranged. In the embodiment according to 6 takes place while the displacement of the separating element 9a perpendicular to the longitudinal axis of the surge protective device 1 , ie from the lower part of the device 3 path. In contrast, in the embodiment according to 7 the displacement of the separating element 9a parallel to the longitudinal axis of the surge protective device 1 and thus also parallel to the lower part of the device 3 ,

In all three embodiments leads a separation of the solder joint between the one port 10 a varistor 6a and the free end of the associated connecting element 8th to that the separating element 9a by the spring force of at least one spring 18 is spent in his second position. On the one hand there is an electrical disconnection of the varistor 6a by the separating section of the separating element 9a between the connection 10 of the varistor 6a and the end of the connecting element 8th pushes. At the same time it also comes to a corresponding movement of the connecting element 12 so that the connecting element 12 no more about the actuator 14 the switch 7 holds in its first switching position. By the movement of the separating element 9a from his first position in his second position, it also comes to a movement of the switch 7 from its first switching position to its second switching position, so that it can be displayed via the remote message that the overvoltage protection device 1 no longer fully functional because at least one varistor 6a has been separated.

8th shows a variant of the overvoltage protection device 1 according to 1 in which the surge protection device 1 next to the switch 7 additionally has an optical status display for the remote message. For this purpose, the two separating elements 9a . 9b one marking section each 19a . 19b on. The marking sections 19a . 19b are only then through a window 20 in the top of the connector housing 4 visible when the corresponding separator 9a . 9b located in its second position, as in 8b is shown. The visual indication of the state of a varistor 6a . 6b can, for example, by an appropriate color choice of the marking section 19a . 19b or also the entire separating element 9a . 9b respectively.

A preferred embodiment of the separating elements 9a . 9b with the marker sections 19a . 19b is in the 9 shown. It shows 9 only the plug part 2 of in 8th shown overvoltage protection device 1 in cross section. In the in 9 shown state of the connector part 2 are both varistors 6a . 6b separated, so that both separating elements 9a . 9b are in their second position. In this second position are the marker sections 19a . 19b both separating elements 9a . 9b below the viewing window 20 in the connector housing 4 arranged. In the first position of the two separating elements 9a . 9b on the other hand are the two marking sections 19a . 19b not below the viewing window 20 arranged so that through the viewing window 20 the top 21 the two varistors 6a . 6b or one of the two varistors 6a . 6b surrounding cladding through the viewing window 20 is visible from the outside. Now has the top 21 a first color, for example, green, while the marking portions 19a . 19b a second color, such as red, so it is very quickly and easily recognizable to a user, whether the surge protective device 1 is still fully functional, or at least a varistor 6a . 6b has been separated. In the first case, the green top is 21 the varistors 6a . 6b and in the second case, a red marker section 19a . 19b through the viewing window 20 recognizable from the outside.

From the sectional view according to 9 In addition, it is recognizable that the marking sections 19a . 19b offset from one another, so that the marking section 19a of the first separating element 9a the marking section 19b of the second separating element 9b Covered when both separators 9a . 9b in their second position. The staggered arrangement of the two marking sections 19a . 19b will be at the in 9 illustrated embodiment achieved in that the respective axis of rotation 22a . 22b the two separating elements 9a . 9b are also arranged offset according to each other.

In the illustrated embodiment, the two marking sections 19a . 19b also designed as film hinges, so that both separating elements 9a . 9b may be formed the same and only during assembly of the marking section 19a of the first separating element 9a to the right and the marker section 19b of the second separating element 9b must be bent to the left. Instead of the training of the entire marking section 19a . 19b as a film hinge can also only the connection between the respective separating element 9a . 9b and the marking section 19a . 19b be designed as a film hinge. By using two identically designed separating elements 9a . 9b simplifies on the one hand the production, on the other hand, but also the installation of the surge protection plug 1 because there is no confusion of the separating elements 9a . 9b can come during assembly.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 69503743 T [0004]
• DE 202004006227 U1 [0005]
• DE 102009036125 A [0008]

Claims (12)

Overvoltage protection device (1) with a housing (4, 5), with at least two overvoltage limiting components (6a, 6b), with at least two disconnecting devices and with a switch (7) as a telecommunication contact for remote indication of the state of the overvoltage protection device (1), wherein the disconnecting devices are movably arranged in the housing (4) and in each case a separating device is assigned to a overvoltage limiting component (6a, 6b) and electrically disconnects it when the associated overvoltage limiting component (6a, 6b) is overloaded, by bringing the separating device from a first position to a second position characterized in that a connecting element (12) is movably arranged in the housing (4, 5), and that the switch (7) via the connecting element (12) in such operative connection with the at least two separating devices, that the switch (7 ) has a first switching position when the at least two Abtr each in their first position, while the switch (7) has a different switching position when at least one separating device is in its second position. Overvoltage protection device (1) after Claim 1 , characterized in that the connecting element (12) with its center on the switch (7) is arranged, and that the two separating devices in each case in its first position with one end (13a, 13b) of the connecting element (12) are in contact, so that the switch (7) against a spring force (F) by the connecting element (12) is held in its first switching position, while the switch (7) by the spring force (F) can be brought into a second switching position, if at least one of the two Separators is in its second position. Overvoltage protection device (1) after Claim 1 characterized in that the connecting element (12) is connected at its two ends (13a, 13b) respectively to a separating device, and that the center of the connecting element (12) contacts the switch (7) directly or via an actuating element (14), such that the switch (7) is held in its first switching position counter to a spring force (F) when the two separating devices are in their first position, while the switch (7) can be brought into a second switching position by the spring force (F), when at least one of the two separating devices is in its second position. Overvoltage protection device (1) according to one of Claims 1 to 3 , characterized in that the separating devices each comprise a conductive connecting element (8) and an insulating separating element (9a, 9b), that in the normal state of the first overvoltage limiting component (6a) a connection (10) of the first overvoltage limiting device (6a) via a first thermally disconnecting connection is electrically conductively connected to a first end of the first conductive connecting element (8) and wherein the first separating element (9a) is held in a first position by the first conductive connecting element (8) against a force (F) acting on it; in that, in the normal state of the second overvoltage limiting component (6b), one terminal of the second overvoltage limiting component (6b) is electrically conductively connected to a first end of the second conductive connecting element via a second thermally disconnecting connection, and wherein the second separating element (9b) is connected through the second leitfä hige connecting element is held against a force acting on it in a first position, that when exceeding a predetermined limit temperature of the first overvoltage limiting component (6a) separates the first thermal connection and the first separating element (9a) by the force acting on it in a second position in which a separation section of the first separation element (9a) is arranged between the first connection (10) of the first overvoltage-limiting component (6a) and the first end of the first conductive connection element (8), that exceeds a predetermined limit temperature of the second overvoltage-limiting element Component (6b) separates the second thermal connection and the second separating element (9b) is moved by the force acting on it in a second position in which a separating portion of the second separating element (9b) between the first terminal of the second overvoltage limiting Bauelem ents (6b) and the first end of the second conductive connecting element is arranged, and that the switch (7) via the connecting element (12) with the two separating elements (9a, 9b) is in operative connection. Overvoltage protection device (1) after Claim 3 and 4 , characterized in that in each case an opening (15a, 15b) is formed in both separating elements (9a, 9b), and in that in each case one end (13a, 13b) of the connecting element (12) is arranged in an opening (15a, 15b) in that upon movement of a separating element (9a, 9b) from its first position to its second position, the corresponding end (13a, 13b) of the connecting element (12) is moved along. Overvoltage protection device (1) after Claim 3 and 4 , characterized in that the connecting element (12) is integrally connected to the two separating elements (9a, 9b), wherein the connecting element (12) is at least partially flexible and / or the connections between the two separating elements (9a, 9b) and the Connecting element (12) are made flexible. Overvoltage protection device (1) according to one of Claims 4 to 6 , characterized in that the separating elements (9a, 9b) are each arranged linearly displaceable or rotatable in the housing (4). Overvoltage protection device (1) according to one of Claims 4 to 7 , characterized in that the conductive connecting elements (8) are each formed resiliently and deflected in its first position from its rest position, so that the connecting elements (8) feather respectively in a separated thermal connection due to their spring force from its first position to its second position , Overvoltage protection device (1) according to one of Claims 4 to 8th , characterized in that the separating elements (9a, 9b) each have a marking portion (19a, 19b) as an optical status indicator, and that in the housing (4) a viewing window (20) is formed, which is dimensioned such that, depending on the position of the Separating elements (9a, 9b) of the marking portion (19a, 19b) of at least one separating element (9a, 9b) through the viewing window (20) is visible from the outside or not. Overvoltage protection element (1) after Claim 9 , characterized in that the marking portions (19a, 19b) of the two separating elements (9a, 9b) are offset from one another such that one marking portion (19a) covers the other marking portion (19b) when both separating elements (9a, 9b) engage in their second position. Overvoltage protection device (1) after Claim 9 or 10 , characterized in that the marking sections (19a, 19b) are each connected via a film hinge with a separating element (9a, 9b) or formed as a film hinge. Overvoltage protection device (1) according to one of Claims 1 to 11 , characterized in that the overvoltage protection device (1) consists of a plug part (2) and a device lower part (3), and in that in the plug part (2) the overvoltage limiting components (6a, 6b) and the separating device and in the device lower part (3) the switch (7) and terminals are arranged.

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