DE202014103262U1 - Snubber - Google Patents

Abstract

Surge protection element for use between a neutral conductor N and an equipotential bonding PE in the power supply of a low-voltage network, with a housing (2), with an overvoltage-limiting component (3) arranged in the housing (2), with two connection contacts (4, 5) for electrical connection of the overvoltage protection element (1) to the current path to be protected, with an electrically conductive connecting element (6), with an insulating separating element (7) and with at least one spring element, a gas-filled surge arrester (3) being used as the overvoltage-limiting component, the insulating separating element (7) is arranged displaceably on the housing (2) and can be brought from a first position into a second position by the force of the at least one spring element, the first connection contact (4) being electrically conductive with the first electrode (9) of the surge arrester (3) connected, the second connection contact ( 5) is electrically conductively connected to the first end (10) of the electrically conductive connecting element (6), with the second end (11) of the electrically conductive connecting element (6) via a thermally separating connection (12) in the normal state of the overvoltage protection element (1) is electrically conductively connected to the second electrode (13) of the surge arrester (3) and the insulating separating element (7) is held in its first position, and when a predetermined limit temperature of the surge arrester (3) is exceeded, the thermal connection (12) between the the second end (11) of the electrically conductive connecting element (6) and the second electrode (13) of the surge arrester (3) and the insulating separating element (7) is moved into its second position by the force of the at least one spring element, in which a section of the separating element (7) between the second end (11) of the electrically conductive connecting element (6) and de r second electrode (13) of the surge arrester (3) is arranged.

Description

The invention relates to an overvoltage protection element for use between a neutral conductor N and an equipotential bonding PE in the power supply of a low-voltage network, with a housing, arranged in a housing overvoltage limiting component, with two connection contacts for electrical connection of the overvoltage protection element to be protected current path, with a electrically conductive connection element and with a thermally disconnecting connection.

From the DE 42 41 311 C2 is an overvoltage protection element is known, which has a thermal separation device for monitoring the state of a varistor. In this overvoltage protection element, the first connection contact is connected via a flexible conductor to a conductive connection element whose end remote from the flexible conductor is connected via a solder joint to a connection lug provided on the varistor. The other terminal contact is connected via a flexible conductor fixed to the varistor or a terminal lug on the varistor. The conductive connecting element is acted upon by a spring system with a force that causes the connecting element is linearly moved away during the separation of the solder joint from the terminal lug, so that the varistor is electrically disconnected under thermal overload. By using the flexible conductors for connecting the varistor, the height of the maximum permissible pulse current which can be derived from the overvoltage protection element is limited.

The DE 695 03 743 T2 discloses an overvoltage protection element with two varistors, which has two conductive connecting elements, by means of which the varistors can each be separated individually at the end of their life. The connecting elements are each designed as resilient separating tongues, the first end of the separating tongue being fixedly connected to the first connecting contact and the second end of the separating tongue being fastened in the normal state of the overvoltage protection element via a soldering point to a connecting tongue on the varistor. If there is an inadmissible heating of the varistor, this leads to a melting of the solder joint. Since the separation tongue is deflected in the soldered state (normal state of the overvoltage protection element) from its rest position and thus biased, the free end of the separation tongue springs in softening the solder joint of the terminal tongue of the varistor, whereby the varistor is electrically disconnected. In order to ensure the required insulation and tracking resistance, and to erase an emerging when opening the separation point arc, it is necessary that the largest possible distance between the second end of the separation tongue and the connection tongue of the varistor is achieved when pivoting the separation tongue. In addition, the cross-section of the separation tongue must not be too large, so that this has a sufficient spring property. However, this also leads to a limitation of the maximum permissible pulse current.

The known overvoltage protection elements are generally designed as a "protective plug", which together with a device lower part form an overvoltage protection device. In order to install such a surge protection device which is intended to protect individual current paths or lines of a low-voltage network, corresponding connection terminals for the individual conductors L1, L2, L3 and the neutral conductor N and the ground conductor PE are provided in the known surge protection devices on the device base. For simple mechanical and electrical contacting of the device lower part with the respective overvoltage protection element, the connection contacts are designed as plug pins to the overvoltage protection element, which are arranged in the lower part of the device corresponding, connected to the terminals sockets, so that the overvoltage protection element can be easily attached to the device base.

The thermal separation devices used in the known overvoltage protection elements, which are based on the melting of a solder joint, have to fulfill several tasks. In the normal state of the overvoltage protection element, d. H. in the non-separated state, a secure and good electrical connection between the associated terminal contact and the overvoltage limiting component must be ensured. When a certain limit temperature is exceeded, the separation point must ensure a safe separation of the overvoltage limiting component as well as a permanent insulation resistance and tracking resistance. If the overvoltage protection elements moreover have the smallest possible dimensions so that the overvoltage protection devices do not exceed the dimensions specified for DIN rail devices, this leads to the fact that the known overvoltage protection devices can only be used in the lower and middle power classes. Therefore, the known overvoltage protection elements have hitherto been provided and designed primarily for use between a phase conductor L1, L2, L3 and the neutral conductor N.

The present invention is therefore based on the object to provide an initially described overvoltage protection element, in which the aforementioned disadvantages be avoided, so that the overvoltage protection element can also be used for use between a neutral conductor N and a potential equalization PE.

This object is achieved in the surge protection element described above with the features of claim 1 protection. In contrast to the known overvoltage protection elements, which likewise have a thermal cut-off device, the overvoltage protection element according to the invention initially has a gas-filled surge arrester instead of a varistor as a voltage-limiting component. As a result, larger pulse currents up to 100 kA can be derived.

The overvoltage protection element according to the invention also has an insulating separating element, which is arranged displaceably on the housing and can be moved by the force of at least one spring element from a first position to a second position. In the case of the overvoltage protection element, the first connection contact is permanently electrically connected to the first electrode of the surge arrester. The second connection contact is - also permanently - electrically conductively connected to the first end of the electrically conductive connection element.

In the normal state of the overvoltage protection element, i. If the surge arrester is not heated inadmissible, the second end of the electrically conductive connecting element is electrically conductively connected via a thermally disconnecting connection with the second electrode of the gas-filled surge arrester. In the normal state of the overvoltage protection element, moreover, the insulating separating element is held in its first position by the connection which is realized between the second end of the conductive connecting element and the second electrode of the surge arrester, which is preferably a solder connection.

If the surge arrester has become so hot due to a permanent overloading of the overvoltage protection element that a predetermined limit temperature is exceeded, the thermal connection between the second end of the electrically conductive connection element and the second electrode of the surge arrestor breaks down, the isolating isolating element passing through the force of the at least one spring element is moved to its second position. In the second position of the separating element, a portion of the separating element is arranged between the second end of the electrically conductive connecting element and the second electrode of the surge arrester, so that the overvoltage protection element is electrically disconnected.

In the normal state of the overvoltage protection element, the insulating separating element is held against the spring force of the at least one spring element in its first position by the existing at the thermally splitting connection soldered connection. If there is an inadmissible heating of the surge arrester, this also leads to a heating of the solder joint, which can no longer hold the separating element counter to the spring force in the first position above a certain limit temperature. Characterized in that then the separating element is moved to its second position, the electrically conductive connection between the conductive connecting element and the second electrode of the surge arrester is separated, wherein a possibly resulting when opening the separation point arc reliably deleted by the entering into the separation point insulating separating element becomes.

In addition, the second end of the conductive connecting element is securely isolated even after the opening of the separation point by the separating element with respect to the second electrode of the surge arrester, so that a permanent insulation resistance and tracking resistance is ensured. The electrical connection between the connecting element and the second electrode of the surge arrester is thereby interrupted primarily by the insulating separating retracting into the separation point and not (only) by a deflection of the connecting element. As a result, the connecting element can have a larger cross section, so that even large pulse currents can be conducted via the connecting element.

According to an advantageous embodiment, the insulating separating element has an opening through which the second end of the electrically conductive connecting element is electrically conductively connected via the thermally disconnecting connection to the second electrode of the surge arrester in the normal state of the overvoltage protection element. Preferably, the portion of the insulating separating element, which is arranged in the second position of the separating element between the second end of the connecting element and the second electrode of the surge arrester, adjacent to the opening and has a perpendicular to the direction of movement of the separating element separating portion and a direction parallel to the direction of movement Separating element extending isolation section. The vertically extending separating section ensures a safe separation of the heated solder joint, while the parallel to the direction of movement of the separating element extending insulation section, the insulation resistance and Creep resistance guaranteed. The insulation section is dimensioned such that even in the second position of the separating element, a sufficient insulation distance between the second end of the connecting element and the second electrode of the surge arrester is ensured.

According to a further preferred embodiment of the invention, the gas-filled surge arrester is disc-shaped and arranged in the housing such that the extent of the surge arrester runs from the first electrode to the second electrode perpendicular to the longitudinal extent of the overvoltage protection element. As a result, an overvoltage protection element is made possible with a very small width.

In order to further facilitate the electrical connection of the two electrodes of the gas-filled surge arrester, it is advantageously provided that the two electrodes are each electrically conductively connected to a connection element. In the normal state of the overvoltage protection element, the second end of the electrically conductive connection element is then connected via the solder connection serving as a thermally disconnecting connection to the connection element connected to the second electrode of the surge arrester.

The construction and assembly of the overvoltage protection element can be further simplified in that the first electrode of the gas-filled surge arrester and the first connection element in one piece, d. H. are formed as a component. In order to enable a secure and at the same time space-saving contacting of the two electrodes of the gas-filled surge arrester, the first connection element has a section which, like the conductive connection elements, runs parallel to the longitudinal extension of the overvoltage protection element and perpendicular to the longitudinal extension of the two connection contacts. In addition, the first connection element has a second section which runs perpendicular to the longitudinal extent of the overvoltage protection element and parallel to the longitudinal extension of the two connection contacts, which are each arranged in the region of an end face of the overvoltage protection element and have a width which substantially corresponds to the width of the overvoltage protection element. The second section of the first connection element can be soldered or welded to the first connection contact in such a simple and large area, so that a good and lasting electrical contact between the first connection contact and the first electrode of the surge arrester is provided.

According to a further, particularly advantageous embodiment, it is provided that the connection element connected to the second electrode of the gas-filled surge arrester has a connection region which is slightly spaced from the surface of the surge arrester. In the normal state of the overvoltage protection element, the second end of the electrically conductive connection element can then be connected to the connection region of the connection element arranged inside the opening in the separation element via the soldering point, wherein the connection element is not or only slightly deflected out of its rest position.

The distance between the connection region of the connection element and the surface of the surge arrester is adapted to the material thickness of the insulating separation element, so that the separation element can be moved past the connection region of the connection element when the solder connection is interrupted. Since then the conductive connecting element does not have to have any special fault characteristics, but rather can be made relatively rigid, the cross-section of the conductive connecting element can be better adapted to the height of the maximum permissible pulse current. In addition, can be influenced by the choice of the distance of the connection region of the connection element of the surface of the surge arrester, the heat input from the surge arrester in the solder joint, so that on the choice of the distance, a defined heat coupling can be achieved.

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 protection claim 1 subordinate claims as well as the following description of a preferred embodiment in conjunction with the drawings. In the drawing show:

1 an embodiment of an overvoltage protection element according to the invention in the normal state,

2 the overvoltage protection element according to 1 with electrically isolated surge arrester,

3 an exploded view of the overvoltage protection element according to 1 .

4 an enlarged view of the surge arrester, and

5 the overvoltage protection element according to 1 with separate outer housing.

The figures show a preferred embodiment of an overvoltage protection element 1 with a housing 2 , wherein in the housing 2 a gas-filled surge arrester 3 is arranged as overvoltage limiting component. The trained as a protective plug surge protection element 1 has two terminal contacts designed as blade contacts 4 . 5 on, which can be inserted for connecting the overvoltage protection element to the current path to be protected in corresponding sockets of a device lower part, not shown here.

As in particular from the exploded view according to 2 it can be seen has the overvoltage protection element 1 an electrically conductive connecting element 6 and a sliding in the housing 2 arranged insulating separator 7 on, which is designed as a kind of isolation slide. In two on the case 2 trained guides 8th in each case a spring element is arranged, through which the insulating separating element 7 from a first position ( 1 ) into a second position ( 2 ) can be moved. By the spring elements is the separating element 7 thus subjected to a force which the separating element 7 parallel to the side surface of the housing 2 - in alignment according to 1 - Moves from right to left from the first position to the second position when the separator 7 not held in the first position.

From the exploded view according to 1 In addition, it can be seen that the first connection contact 4 via a first connection element 18 electrically conductive with the - in 3 rear - first electrode 9 the surge arrester 3 connected is. Here is the connection element 18 according to 4 integral with the first electrode 9 the surge arrester 3 educated. The other, the surge arrester 3 opposite end of the connecting element 18 is with the first connection contact 4 soldered or welded.

The second connection contact 5 is with the first end 10 the electrically conductive connection element 6 permanently electrically connected, namely in particular soldered or welded. In addition, according to 1 the second end 11 of the electrically conductive connecting element 6 in the normal state of the overvoltage protection element 1 over a solder joint 12 as a thermal disconnecting compound with the second electrode 13 the surge arrester 3 electrically connected. By the normal state of the overvoltage protection element 1 existing solder joint 12 becomes the insulating separator 7 held in its first position against the force of the spring elements.

If there is an inadmissible heating of the surge arrester 3 , this leads to a softening of the solder joint 12 , which then causes the insulating separator 7 due to the spring force of the spring elements in his - in 2 shown - second position is moved. In the second position of the separating element 7 is the separator 7 between the second end 11 of the conductive connection element 6 and the second electrode 13 the surge arrester 3 so that the overvoltage protection element 1 is electrically disconnected, since the electrically conductive connection between the second terminal contact 5 and the second electrode 13 the surge arrester 3 is interrupted. A possibly resulting when opening the separation point arc is reliably by the entering into the separation point insulating separator 7 deleted.

Like from the 1 to 3 it can be seen has the insulating separator 7 a front end 14 on, which is an opening 15 followed. In addition, the insulating separator 7 one perpendicular to the direction of movement of the separating element 7 extending severing section 16 and a parallel to the direction of movement of the separating element 7 extending isolation section 17 on. The opening 15 is thus on one side of the front page 14 and on the other side of the severing section 16 limited. In the normal state of the overvoltage protection element 1 is the second end 11 of the electrically conductive connecting element 6 through the opening 15 in the separating element 7 with the solder connection 12 connected.

In the illustrated in the figures preferred embodiment of the overvoltage protection element according to the invention 1 is the solder connection 12 not immediately between the second end 11 of the connecting element 6 and the second electrode 13 of the gas-filled surge arrester 3 but between the second end 11 of the connection element 6 and the connection area 20 a second connection element 19 intended. The second connection element 19 is there, as in particular from the 3 and 4 it can be seen with the second electrode 13 of the gas-filled surge arrester 3 electrically connected, namely soldered or welded. In addition, the second connection element 19 one from the surface of the surge arrester 3 or from the electrode 13 spaced connection area 20 on, the normal state of the overvoltage protection element 1 inside the opening 15 in the insulating separator 7 is arranged.

By in the direction of the second end 11 of the connecting element 6 above connection area 20 may be the second end 11 of the connecting element 6 over the solder joint 12 With the connection element 19 and therefore also with the second electrode 13 the surge arrester 3 be electrically connected without the connecting element 6 has to be distracted from its rest position. The connecting element 6 must therefore have no special spring properties. The cross section of the conductive connecting element 6 can be chosen so that also relatively high pulse currents through the connecting element 6 can be derived. Nevertheless, it is advantageous if the connecting element 6 is resilient, so that it during the separation process something of the connection area 20 of the connection element 19 lifts or by moving to its second position insulating separating element 6 from the connection area 20 is pushed away.

When softening the solder joint 12 due to excessive temperature of the surge arrester 3 the separation of the connection between the second end takes place 11 of the connecting element 6 and the connection area 20 of the second connection element 19 thus primarily by the fact that the insulating separator 7 between the second end 11 of the connecting element 6 and the connection area 20 pushes and not by the fact that the second end 11 of the connecting element 6 from the connection area 20 wegfedert. The connecting element 6 However, it is sufficiently resilient, so that its second end 11 as far as the connection area 20 It can be moved away, that the movement of the separating element 7 is not obstructed from its first position to its second position, ie the separating element 7 will not be between the second end 12 of the connecting element 6 and the connection area 20 trapped.

Out 4 it can be seen that the gas-filled surge arrester 3 is disc-shaped, so that the overvoltage protection element 1 in the illustrated arrangement of the surge arrester 3 in the case 2 - Extension of the surge arrester 3 from the first electrode 9 to the second electrode 13 perpendicular to the longitudinal extent L of the overvoltage protection element 1 - Has a very small width. In addition, it can be seen that the one piece with the first electrode 9 trained first connection element 18 a first portion parallel to the electrode 9 runs. The first section is followed by a second section, which is bent vertically so that the second section - as shown in FIG 3 recognizable - simply with the first connection contact 4 can be soldered or welded.

For optical indication of the state of the overvoltage protection element 1 has the insulating separator 7 two adjacent markers 21 . 22 in different colors, for example green and red, which serve as an optical status indicator for the overvoltage protection element 1 serve. This is in the in 5 illustrated hood-like outer casing 23 of the overvoltage protection element 1 that with the case 2 latched, a viewing opening 24 formed, which is dimensioned such that, depending on the position of the insulating separating element 7 only one or the other colored marking 21 . 22 through the viewing aperture 24 is visible from the outside. The first, green mark 21 is in the first position of the separating element 7 through the viewing aperture 24 visible while the second, red mark 22 in the second position of the insulating separator 7 under the viewing aperture 24 is arranged.

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 4241311 C2 [0002]
• DE 69503743 T2 [0003]

Claims (10)

Overvoltage protection element for use between a neutral conductor N and a potential equalization PE in the power supply of a low-voltage network, comprising a housing ( 2 ), with one in the housing ( 2 ) arranged overvoltage limiting component ( 3 ), with two connection contacts ( 4 . 5 ) for the electrical connection of the overvoltage protection element ( 1 ) to the current path to be protected, with an electrically conductive connecting element ( 6 ), with an insulating separating element ( 7 ) and with at least one spring element, wherein as overvoltage limiting component a gas-filled surge arrester ( 3 ) is used, wherein the insulating separating element ( 7 ) displaceable on the housing ( 2 ) and can be brought by the force of the at least one spring element from a first position to a second position, wherein the first terminal contact ( 4 ) with the first electrode ( 9 ) of the surge arrester ( 3 ) is electrically conductively connected, wherein the second terminal contact ( 5 ) with the first end ( 10 ) of the electrically conductive connecting element ( 6 ) is electrically conductively connected, wherein in the normal state of the overvoltage protection element ( 1 ) the second end ( 11 ) of the electrically conductive connecting element ( 6 ) via a thermally dissociating compound ( 12 ) with the second electrode ( 13 ) of the surge arrester ( 3 ) is electrically conductively connected and the insulating separating element ( 7 ) is held in its first position, and wherein when a predetermined limit temperature of the surge arrester is exceeded ( 3 ) the thermal compound ( 12 ) between the second end ( 11 ) of the electrically conductive connecting element ( 6 ) and the second electrode ( 13 ) of the surge arrester ( 3 ) and the insulating separating element ( 7 ) is moved by the force of the at least one spring element in its second position, in which a portion of the separating element ( 7 ) between the second end ( 11 ) of the electrically conductive connecting element ( 6 ) and the second electrode ( 13 ) of the surge arrester ( 3 ) is arranged. Overvoltage protection element according to claim 1, characterized in that the insulating separating element ( 7 ) an opening ( 15 ), in the normal state of the overvoltage protection element ( 1 ) the second end ( 11 ) of the electrically conductive connecting element ( 6 ) via the thermally splitting compound ( 12 ) with the second electrode ( 13 ) of the surge arrester ( 3 ) is electrically connected. Overvoltage protection element according to claim 2, characterized in that the insulating separating element ( 7 ) one perpendicular to the direction of movement of the separating element ( 7 ) extending separating section ( 16 ) and one parallel to the direction of movement of the separating element ( 7 ) extending isolation section ( 17 ) having. Overvoltage protection element according to one of claims 1 to 3, characterized in that the gas-filled surge arrester ( 3 ) disc-shaped and so in the housing ( 2 ) is arranged such that the extension of the surge arrester ( 3 ) from the first electrode ( 9 ) to the second electrode ( 13 ) perpendicular to the longitudinal extent (L) of the overvoltage protection element ( 1 ) runs. Overvoltage protection element according to one of Claims 1 to 4, characterized in that the two electrodes ( 9 . 13 ) of the gas-filled surge arrester ( 3 ) each with a connection element ( 18 . 19 ) are electrically connected. Overvoltage protection element according to claim 5, characterized in that the first electrode ( 9 ) of the gas-filled surge arrester ( 3 ) and the first connection element ( 18 ) are integrally formed. Overvoltage protection element according to claim 5 or 6, characterized in that the with the second electrode ( 13 ) of the gas-filled surge arrester ( 3 ) connected connection element ( 19 ) a connection area ( 20 ), which in such a way from the surface of the surge arrester ( 3 ) is spaced in the normal state of the overvoltage protection element ( 1 ) the second end ( 11 ) of the electrically conductive connecting element ( 6 ) via the thermally splitting compound ( 12 ) with the connection area ( 20 ) is connected without the connecting element ( 6 ) is substantially deflected from its rest position. Overvoltage protection element according to one of claims 1 to 7, characterized in that the insulating separating element ( 7 ) two juxtaposed markings ( 21 . 22 ) in different colors, which serves as an optical status indicator for the overvoltage protection element ( 1 ) serve. Overvoltage protection element according to one of claims 1 to 8, characterized in that a hood-like outer housing ( 23 ) provided with the housing ( 2 ) is locked. Overvoltage protection element according to claim 8 and 9, characterized in that in the outer housing ( 23 ) a viewing opening ( 24 ) is formed, which is dimensioned such that, depending on the position of the insulating separating element ( 7 ) only one or the other colored marking ( 21 . 22 ) through the viewing aperture ( 24 ) is visible from the outside.

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