BE1026863A1 - Holding element for holding an electrode of a spark gap and spark gap with at least one holding element - Google Patents

Abstract

The invention relates to a holding element (10; 10 ') for holding an electrode (80) of a spark gap, the holding element (10; 10') having a recess (70) for introducing the electrode (80). The holding element (10; 10 ') is designed to be resilient at least at one point in the circumferential direction of the recess (70), as a result of which the electrode (80) can be clamped in the recess (70). The invention also relates to a spark gap with at least one such holding element (10; 10 ') which holds an electrode (80).

Description

Holding element for holding an electrode of a spark gap and spark gap with at least one holding element

The invention relates to a holding element for holding an electrode of a spark gap according to the preamble of claim 1. The invention further relates to a spark gap with at least one such holding element for holding a

Spark gap electrode.

In the area of overvoltage protection of electrical devices or systems, overvoltage protection elements are used which respond to a certain overvoltage, which would otherwise lead to faults and / or damage in a circuit in the event of an overvoltage event. Surge arresters based on spark gaps, for example, can be used as such surge protection elements. Spark gaps have proven their worth, particularly for the derivation of so-called transient overvoltages with very high amplitudes. As soon as a spark gap has ignited, a conductive connection is established via the arc gap of the spark gap, via which the overvoltage event is then derived.

Multiple spark gaps, in which several individual spark gaps are connected in series, have proven to be particularly advantageous. To form a multiple spark gap from several individual spark gaps, in certain embodiments, several disk-shaped or ring-shaped electrodes are joined to form a stack, these electrodes being made of graphite, for example. Zwi2

BE2018 / 5886 between the individual electrodes, a thin film or disk made of an insulating material is arranged. This results in several individual spark gaps between the electrodes, which can be ignited using a suitably designed voltage control.

EP 2 630 707 B1 also discloses a multiple spark gap consisting of a stack arrangement with a sequence of disk-shaped electrodes and insulation rings, the electrodes each being held in a frame-shaped insulation body. A recess is provided in the insulation body for receiving and centering the electrodes, the inner contour of which is complementary to the outer contour of the respective electrodes. The recess has at least one resilient, resilient centering projection on the inner circumference side, by means of which the electrode is held in the recess by a radial spring force.

The invention is based on the object of providing a further developed holding element for holding an electrode of a spark gap, which enables several individual components of the spark gap to be aligned with one another in a simple, safe and fault-resistant manner in order to ensure fault-free functioning of the spark gap.

This object is achieved by a holding element with the features of claim 1. Advantageous further developments of the

Holding element result from subclaims 2-12. Furthermore, the object is achieved by a spark gap according to claim 13, advantageous developments of this spark gap arising from claims 14-18.

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The holding element according to the invention is designed to hold an electrode of a spark gap by using a

Has recess for insertion of the electrode. According to the invention, the holding element is designed to be resilient at least at one point in the circumferential direction of this recess, as a result of which the electrode can be clamped in the recess.

It is therefore a self-resilient holding element in which the circumference of a recess for an electrode can be resiliently widened at at least one point. The shape and contour of the recess are preferably complementary to the outer contour of the electrode, although they can also differ slightly. For example, flat, disc-shaped electrodes with a circular or polygonal, in particular with a square (e.g. square) outer contour are used. This relates to the shape of the disk-shaped electrode in its plane of extension.

The holding element is also preferably a flat, disk-shaped or plate-shaped element in which a flat electrode can be received in a respective recess. In one embodiment of the invention, the holding element is therefore plate-shaped and the recess for receiving a disk-shaped electrode extends in the plate plane of the holding element. The holding element is preferably designed in the form of a frame, it being able to enclose an electrode completely or only partially. A frame can therefore also be designed to be open on one side, for example. Furthermore, there is

Holding element made of an insulating material, for example made of PTFE (polytetrafluoroethylene) or another suitable material.

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Such a holding element enables an electrode to be easily accommodated in a defined centered position within the holding element. In this position the

Electrode secure but not rigid. During assembly, an electrode is pressed into a recess of a holding element with slight pressure, the recess being slightly widened by the resilient design of the holding element. The electrode is then held by the restoring spring force of the holding element. If a higher clamping force is to be achieved, it can also be provided that the holding element is first attached to at least one

Spring is pulled apart to create a

Insert the electrode into the recess. In this way, in particular several holding elements can be equipped with electrodes and then combined to form a spark gap. The electrodes do not slip, but remain in the desired position, which ensures fault-resistant manufacture of the spark gap.

The resilient widening of the recess takes place in the circumferential direction of the recess at this point. This distinguishes the invention, for example, from that from EP 2

630 707 B1 known embodiment of a frame in which a recess widens radially by pressing one or more centering projections or centering lugs radially outwards when an electrode is inserted. The restoring spring force of the centering projections or

Centering lugs then act essentially radially inwards.

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According to the invention, the restoring spring force of the self-resilient holding element does not act in the radial direction, but essentially in the direction of the circumference of the recess at the resiliently designed location, i.e.

transverse to the radial direction. If, for example, a circular electrode is chosen which is introduced into a circular recess in a frame, the circumferential direction runs in an arc to the right and left of the spring-mounted point. If a polygonal electrode is selected which is introduced into a corresponding polygonal recess in a frame, several straight sides result on the inner circumference of the recess. Will be straight on one of these

Provided a resilient point on both sides, the circumferential direction runs along this straight side.

In one embodiment of the invention, a holding element each has a plurality of holding element sides, and at least one holding element side is designed to be resilient in its longitudinal direction. For example, these holding element sides form a polygonal recess for receiving a polygonal one

Electrode, and at least one of these holding element sides is resilient in its longitudinal direction. The longitudinal direction of a holding element side runs along the greatest extent of the holding element side. In particular, a square (e.g. square) recess is used for a square (e.g. square) electrode and the

The outer contour of the holding element is also essentially square (e.g. square). The longitudinal direction of a holding element side then runs in each case between the two adjacent holding element sides.

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In one embodiment of the invention, a holding element is designed to be resilient at two opposite points in the circumferential direction of the respective recess. More than two resilient points can also be provided, these preferably being uniform over the circumference of the

Recess for the electrode are arranged. This results in holding element sides with and without suspension, with resilient holding element sides also being referred to below as spring sides and rigid holding element sides without spring action as rigid sides.

The self-resilient effect of a holding element can be realized in different ways. For example, a suspension can be produced by a specific shaping of the material of the holding element. In alternative embodiments, additional spring elements are in the

Inserted material of the holding element. Combinations of both variants are also possible. In one embodiment of the invention, it is provided, for example, that at least one location is formed from the material of the holding element in each case at least one location that is elastically deformable in the circumferential direction of the respective recess, the at least one structure

Forms spring section. For example, a spring section is formed at least by a plurality of spring legs that can be folded elastically toward one another.

In addition to a spring action, an elastically deformable

Structure in the material of the holding element perform other functions. For example, it can optionally have at least one

Form the contact section against which the electrode rests. This helps to position the electrode as precisely as possible within the recess and prevents it

BE2018 / 5886 a slipping of the electrode in a direction transverse to the circumferential direction of the recess.

In a further embodiment of the invention, a

Holding element each at least at one point on a radial separation, which is bridged by a spring element. The holding element is resilient in the area of the separation. A spring element can be formed, for example, by a rubber element or various types of springs made of metal or plastic.

In addition to holding an electrode, a holding element is preferably also advantageous for contacting a control element and / or a control device

Voltage distribution across a spark gap. For example, a capacitance is used as the control element. A holding element can thus advantageously be used for several purposes. For example, a holding element has a receptacle into which a control element for controlling an electrode can be inserted. This receptacle for a control element is at least one passage in the material of the holding element with the recess for the

Electrode connected. In particular, one embodiment of the invention provides for a first one of the receptacles for the control element in the material of the holding element

Go out slot and a second slot, from which the first slot opens to the recess for the electrode.

The first slot can be used to make contacting of the control element up to the electrode.

The second slot can be used to contact the control element from the outside with a control device,

BE2018 / 5886 which is designed to control the voltage distribution over a spark gap.

The position of the control element is precisely defined by the inclusion in the holding element and the control element can be preassembled together with an electrode in a holding element. The contact between the control element and the electrode can also optionally be established before several holding elements with electrodes are joined to form a spark gap.

A receptacle for a control element is preferably introduced into a holding element side, which is rigid without spring action. An electrode rests securely on such a rigid side, so that stable contact can be established between the electrode and the control element. In the case of a holding element with two opposite spring sides, a receptacle for a control element is therefore preferably provided in a rigid side between these two spring sides. When shooting, it can be a continuous

Act opening in the material of the frame or a recess in which the control element is inserted.

A holding element can have further features which serve in particular to align holding elements with one another or with other components of a spark gap. In particular, grooves or lugs can be provided for aligning the holding elements with respect to other components. Corresponding elements can be provided for an alignment of the holding elements with respect to one another, which interlock positively. These are, for example, on the outer edges or corners of a holding element 9

BE2018 / 5886 sorted. Furthermore, means for fixing holding elements in a stack arrangement can be provided. These are in particular through openings which are aligned with one another in a stack of holding elements, so that fixing rods or fixing screws can be guided through these through openings.

The invention also includes an arrangement of a

Holding element according to an embodiment of the invention, an electrode and a control element for controlling the

Electrode, the electrode in a recess and the

Control element are introduced into a receptacle of the holding element. The control element is, for example, a capacitance that is in contact with the electrode. This is done by contacting the

Control element is guided through a first slot to the electrode in the recess. This is preferably located

Contact with spring force on the electrode.

A second contact of the control element can lie in a second slot in the material of the holding element and can be contacted there with a control device. Such a control device is provided for influencing the voltage distribution over a spark gap in order to suitably ignite the spark gap. This control device can be designed in known or new ways in order to meet the requirements placed on the surge protection. The two contacts of the control element are preferably the contact pins of an electrical component which run at any angle to one another. For example, they run at an angle different from each other by 180 °. So they can

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Component legs are clamped into the two slots in the holding element in such a way that a leg can rest against the electrode under spring force.

The invention also encompasses a spark gap, having at least two electrodes, the electrodes each being held in a recess in a holding element. At least one holding element is designed according to one embodiment of the invention and is thus self-resilient. In particular, an arrangement is used in which a control element for controlling an electrode is also introduced into a receptacle of the holding element. In one embodiment of the invention, contacting of the control element is guided from the receptacle through a first slot and contacts the

Electrode under spring force. Furthermore, a control device for influencing the voltage distribution over the spark gap is provided, for example. In particular, an electrical connection is established between the control element and this control device.

In one embodiment of the invention, the electrodes are each flush in the recess of a respective holding element, so that the holding element and the electrode lie in a common extension plane. This creates several flat components that can be installed in a spark gap. The outer contour of the holding elements is particularly adapted to how they are to be arranged in the construction of the spark gap. For example, essentially rectangular outer contours of the holding elements have proven to be advantageous, but other outer contours can also be expedient.

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After a holding element equipped with an electrode has been installed in a spark gap, the electrode can continue to be clamped in a recess solely by a restoring spring force of the holding element. In one embodiment of the invention it is therefore provided that the electrode is clamped in a spark gap by the spring force of the holding element in the circumferential direction of the respective recess in the recess of the holding element. The self-resilient effect of a holding element can thus advantageously not only be used when installing a spark gap. Rather, it also serves for the safe positioning of the electrodes during the operation of the spark gap.

In an alternative embodiment of the invention it is provided that the electrode is clamped in a spark gap by a force in the recess of the holding element which is additionally applied to the self-resilient holding element. For example, the assembly of the plurality of holding elements with electrodes in a stack can cause a resilient location of a holding element to be compressed further, which increases the clamping force on the electrode. This is an advantage over the embodiment of EP 2 630 707 B1, in which the application of such an additional clamping force is not possible. The clamping force that can be applied is determined exclusively by the restoring spring force of the centering projections or

Centering lugs determined, which resetting spring force can decrease over time due to aging of the material of the centering projections or lugs. In contrast, the holding element according to the invention enables the langfris12

BE2018 / 5886 applied a precisely defined clamping force to the electrodes, which advantageously contributes to the fault-free functioning of a spark gap.

In one embodiment of the invention, the spark gap is a multiple spark gap with a plurality of individual spark gaps connected in series, which are arranged in a stack, the individual spark gaps each having two electrodes which are separated from one another by at least one insulating material element.

For example, the electrodes are ring-shaped or disk-shaped. The electrodes are each held in a recess of a holding element, the insulating material elements being arranged between the holding elements and being fixed by them. The electrodes are preferably made of graphite.

Thin disks or foils made of a suitable insulating material can be used as the insulating material elements. The insulating material elements are ring-shaped, so that the required distance for a single spark gap is formed between two electrodes and leads through an opening in an insulating material element.

Further advantages, special features and expedient developments of the invention result from the subclaims and the following illustration of preferred exemplary embodiments with the aid of the figures.

Show it

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Fig. 1 a first embodiment of a holding element in a front view; Fig. 2nd a first side view of the holding element according to Fig. 1 from the right; Fig. 3rd a longitudinal section A-A through a holding element according to FIG. 1; Fig. 4th 1 in a top view with the section A-A; Fig. 5 a holding element according to Figure 3 with inserted control element (capacity) and contacting. Fig. 6 a holding element according to Figure 1 with inserted electrode and control element (capacity). Fig. 7 a second embodiment of a holding element in a front view;

Fig. 8th a Fig. first side view of the 7 from the right; Holding element according to Fig. 9 a longitudinal section B-B according to Fig. 7; a holding element Fig. 10th the With Holding element according to the sectional view B-B; 7 in a top view Fig. 11 a holding element according to FIG. Electrode and control 7 with inserted (capacity); and

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Fig. 12 is a schematic representation of a spark gap.

Figure 1 shows a first embodiment of a holding element 10 in a front view of the top of the holding element. The holding element 10 is frame-shaped, so that it is also referred to below as a frame. In the embodiment of Figure 1, a suspension of the frame 10 is realized by an elastically resilient structure in the material of the frame. The frame 10 has a

Essentially square outer contour with slightly beveled or rounded corners. The frame 10 is formed by four holding element sides or frame sides 20, 21, 30 and 40, which enclose a square recess 70. There are two opposite frame sides 20 and 21 as

Rigid sides are formed without a resilient effect, while two further opposite frame sides 30 and 40 are resilient in the circumferential direction of the recess 70.

FIG. 2 shows a side view of the frame according to FIG. It is a view of the right side of the frame 10. It can be seen from this side view that the frame 10 is a relatively flat plate with a thickness of the order of magnitude of, for example, 3 mm to 10 mm. In the corners of the frame 10 there are optional corner elevations, of which one corner elevation is identified by way of example with the reference number 51. Corresponding corner depressions 52 are then located on the opposite underside of the frame 10 (left in FIG. 2). When several frames are joined together to form a stack arrangement

BE2018 / 5886 the corner elevations 51 of a frame engage in the corner recesses 52 of an adjacent frame so that the frames can be aligned with one another.

The frame 10 also has a through opening in the corners, of which a through opening is also identified by way of example with the reference number 50. Fixing rods or fixing screws can be guided through these through openings 50 in a stack arrangement consisting of several frames. In addition, a groove 61 is provided on the outer edge of the rigid side 21, which can be used to align the frame with other components of a spark gap. This groove 61 is only to be understood as an example and further and / or other means can be provided for such an alignment.

The spring sides 30 and 40 of the frame 10 have resilient

Structures that are realized by a corresponding shaping of these frame sides 30, 40 at at least one point. In the embodiment of FIG. 1, an elastically resilient structure was selected, which consists of several legs that can be folded elastically toward one another. As a result, several spring sections are formed. The recess 70 can be widened in the direction of the double arrow by these two spring sides 30, 40.

The resilient structure of a spring side 30, 40 is described by way of example with reference to the frame side 30, the opposite frame side 40 being designed analogously. Only a further groove 35 is provided on the outside of the tongue side 40 in addition. The frame side 30 consists of a middle part 31, to the side of which two springs 16

BE2018 / 5886 adjoin sections 32 and 33, these spring sections

32, 33 adjoin the ends of the frame sides 20, 21. The

The middle part 34 can have a contact section 34 on the inside, which can optionally rest on an electrode attached in the recess 70. In the embodiment of FIG. 1, however, this section 34 is offset to the outside to such an extent that it does not come into contact with an electrode provided in the recess 70.

A spring section 32, 33 is formed by a plurality of legs, which are explained using the spring section 32. The spring section 32 is formed by two legs 32a and 32b which can be folded towards one another due to elastic connecting points. Such a spring section 32 can be compressed and pulled apart like an accordion. In the area of the rigid sides 20, 21 there remain lugs, one lug of which is identified by the reference number 22.

A receptacle 60 for a control element and a contact opening 64 for contacting the control element are provided on a rigid side 21. A capacity is used in particular as a control element. Figure 3 shows one

Longitudinal section A-A through a frame according to Figure 1, the section of Figure 4 can be seen. FIG. 4 shows a top view of the frame 10 according to FIG. 1.

The longitudinal section in FIG. 3 shows that of the

Take 60 receptacle for a control two slots 62 and 63. A first slot 63 runs from the receptacle 60 to the recess 70 and opens towards the latter. A second slot 62 runs along the frame side 21. The contact opening 64 adjoins this second slot 62.

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In Figure 5 it is shown how a control element 81 in the

Recording 60 is introduced. The control element 81 has two contacts 82, 83 which lie in the two slots 62, 63. The contacts 82, 83 are the component legs of the control element 81 which protrude from the latter. The two contacts 82, 83 are clamped in the two slots 62, 63 such that the contact 82 rests in the first slot 63 under spring force on an electrode when it is introduced into the recess 70. This is not the case in FIG. 5, but FIG. 6 shows a front view of the frame 10 according to FIG

Figure 1, wherein an electrode 80 is introduced into the recess 70. The electrode 80 lies against the inner sides of the rigid sides 20, 21 and is clamped in the frame 10 by the restoring spring force of the two spring sides 30, 40. Furthermore, it bears from the inside on the lugs and optionally on the spring sections of the spring sides 30. If a contact section 34 is designed accordingly, the electrode 80 could also abut this section.

Through the contact opening 64, the contact 83 of the control element 81 can be connected to a control device (not shown). The control element 81 was introduced from the rear of the frame into the receptacle 60 and the two slots 62, 63, so that these are not visible in the front view of FIG. 6 of the frame 10.

FIG. 7 shows a second embodiment of a frame 10 ″, the structure of the frame 10 ″ essentially corresponding to the frame 10 of the first embodiment. The Be18

BE2018 / 5886 description of the same features therefore applies analogously to this embodiment of the frame. However, the two opposite spring sides 30, 40 are not formed by a resilient structure of the frame material, but a radial separation is provided in each of these frame sides 30, 40, which is bridged by an additionally inserted spring element 36, 41. Springs are used here as an example, but it can also be elastic rubber elements or other suitable spring elements.

The structure of such a spring side is explained by way of example with reference to the frame side 30 and applies analogously to the opposite frame side 40. The radial separation does not extend over the entire width of the frame side 30, but there remain projections 37 and 38, between which a spring element 36 is stretched is.

FIG. 8 shows analogously to the first embodiment of the

Frame 10 is a side view of the frame according to Figure 7 from the right side. FIG. 9 shows a longitudinal section B-B through a frame according to FIG. 7, the section of the section being shown in the top view of FIG. 10. A control element 81 like a capacitance will be analogous to the first

Embodiment introduced and Figure 11 shows a frame

10 'according to the second embodiment with inserted electrode 80.

Further embodiments of frames are also possible which are designed to be resilient at least at one point in the circumferential direction of a recess for an electrode. Several frames are interposed with Isolierstoffele19

BE2018 / 5886 elements are combined, for example, to form a multiple spark gap in a stacked arrangement. Figure 12 shows schematically the structure of such a multiple spark gap 11. Several frames 10 each take one

Electrode 80. Thin insulating material elements 90 in the form of disks or foils with a central opening are fixed between the frames 10, so that a single spark gap is formed in each case between two electrodes.

Thus, the individual spark gaps each consist of two disk-shaped electrodes, which are spaced apart by an insulating material element. The electrodes are held in a frame made of insulating material and are each connected within this frame via a contact to an integrated control element such as a capacitance. The insulating material elements form the required distance between two electrodes for a corresponding partial spark gap by means of a central recess.

Each electrode 80 can be contacted via a described control contact 110 and controlled by a control device 100 in order to achieve the desired voltage distribution. The control of the multiple spark gap is only to be understood as an example, however, and other forms of contacting and / or control can also be provided.

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Reference list

Holding element, frame 10, 10 ' Spark gap, multiple spark gap 11 Holding element side, frame side, rigid side 20 , 21 nose 22 Holding element side, frame side, spring side 30th Middle section 31 Spring section 32 , 33 Feather legs 32a, 32b Investment section 34 Groove 35 Spring element 36 head Start 37 , 38 Holding element side, frame side, spring side 40 Spring element 41 Through opening 50 Corner survey 51 Corner recess 52 Recording for control 60 Groove 61 slot 62 , 63 Contact opening 64 Recess for the electrode 70 electrode 80 Control, capacity 81 Contacting, component leg 82 , 83 Insulating element 90 Control device 100 Tax contacting 110

Claims (18)

Claims 1. Holding element (10; 10 ') for holding an electrode (80) of a spark gap, the holding element (10; 10') having a recess (70) for introducing the electrode (80), characterized in that the holding element (10 ; 10 ') is designed to be resilient at least at one point in the circumferential direction of the recess (70), as a result of which the electrode (80) can be clamped in the recess (70). 2. Holding element according to claim 1, wherein the holding element (10; 10 ″) is plate-shaped and the recess (70) for receiving a disk-shaped electrode (80) extends in the plate plane of the holding element (10; 10 ″). 3. Holding element according to claim 1 or 2, wherein the holding element (10; 10 ') is frame-shaped. 4. Holding element according to one of claims 1 to 3, wherein the holding element (10; 10 ') each has a plurality of holding element sides, and at least one holding element side (30) is resilient in its longitudinal direction. 5. Holding element according to one of claims 1 to 4, wherein the holding element (10; 10 ') is resilient at two opposite locations in the circumferential direction of the recess (70). BE2018 / 5886 6. Holding element according to one of claims 1 to 5, wherein from the material of the holding element (10; 10 ') in each case at least one location in the circumferential direction of the recess (70) is elastically deformable structure is formed, the at least one spring section (32; 33 ) trains. 7. Holding element according to claim 6, wherein a spring section (32; 33) is formed at least by a plurality of resiliently foldable spring legs (32a; 32b). 8. Holding element according to one of claims 1 to 7, wherein the holding element (10; 10 ') has at least one point a radially extending separation, which is bridged by a spring element (36; 41). 9. Holding element according to one of claims 1 to 8, wherein the holding element (10; 10 ') has a receptacle (60) into which a control element (81) for controlling an electrode (80) can be introduced. 10. Holding element according to claim 9, wherein the receptacle (60) for a control element (81) is connected to the recess (70) for the electrode (80) via at least one passage in the material of the holding element (10; 10 '). 11. Holding element according to claim 10, wherein from the receptacle (60) for the control element (81) in the material of the holding element (10; 10 ') a first slot (63) and a second slot (62), of which the first Slit (63) to the recess (70) for the electrode (80) opens. BE2018 / 5886 12. Holding element according to one of claims 1 to 11, wherein the holding element (10; 10 ') is formed from an insulating material, in particular from PTFE (polytetrafluoroethylene). 13. spark gap (11), having at least two electrodes (80), the electrodes (80) each being held in a recess (70) of a holding element (10; 10 '), characterized in that at least one holding element (10; 10 ') is designed according to one of claims 1 to 12. 14. spark gap according to claim 13, wherein a holding element (10; 10 ') is formed according to one of claims 9 to 12, and a control element (81) for controlling an electrode (80) in a receptacle (60) of the holding element (10; 10 ') is introduced. 15. Spark gap according to one of claims 13 and 14, wherein a control device (100) for influencing the voltage distribution over the spark gap (11) is provided. 16. spark gap according to claims 14 and 15, wherein an electrical connection between the control element (80) and the control device (100) is established. 17. spark gap according to one of claims 14 to 16, wherein a holding element (10; 10 ') is formed according to one of claims 11 to 12 and a contact (82) of the Control element (80) of the receptacle (60) by the BE2018 / 5886 first slot (63) is guided and contacted the electrode (80) under spring force. 18. Spark gap according to one of claims 13 to 17, wherein 5 is the spark gap to a multiple Spark gap (11) with a plurality of individual spark gaps connected in series, which are located in a stacked arrangement, the individual spark gaps each having two electrodes (80) which are separated by 10 at least one insulating material element (90) are separated from one another, and the electrodes (80) are each in one Recess (70) of a holding element (10; 10 '') are held, the insulating material elements (90) being arranged between the holding elements (10; 10 '') and being fixed by them.