DE102008045816B4 - Electrical feedthrough with elastic seal - Google Patents

Abstract

Electrical bushing (1), comprising at least one conductor (2, 2.1, 2.2) passed through an insulator (3), the conductor (2, 2.1, 2.2) protruding from the insulator (3) and on at least one exit side (F3, F4) is embedded in an elastic seal (4, 4.1, 4.2) from the insulator (3) at least in the area in which the conductor (2, 2.1, 2.2) protrudes from the insulator (3), the conductor ( 2) a sheathing (5) which is arranged at least in sections between the conductor (2) and the elastic seal (4, 4.1, 4.2), the sheathing (5) starting from the outlet side (F3, F4) of the Insulator or with the formation of a joint between an end face of the sheath (5) and the exit side (F3, F4) of the insulator extends along the conductor, the insulating sheath being arranged in such a way that the sheath (5) consists of the elastic seal (4, 4.1, 4.2) protrudes and a contact surface of the casing (5) with. ..

Description

The present invention relates to an electrical feedthrough, in particular the insulation of an electrical conductor of such an electrical feedthrough for use in a safety container and to a method for producing an electrical feedthrough.

Background of the invention

Electrical feedthroughs are used, inter alia, as components or attachments of hermetically sealed or enclosed spaces to conduct electrical signals in a gastight manner through the container wall and / or to provide corresponding devices with power and / or voltage. By way of example, mention may be made of a vacuum measuring cell placed in a vacuum chamber, which must be operated and read out accordingly.

Electrical feedthroughs generally include one or more conductors disposed in an insulator. Known insulators are made of plastic or glass, for example. In particular, high demands are placed on electrical feedthroughs with regard to permeability, temperature, pressure, radiation and long-term stability, which are used in or on walls of safety-relevant rooms or containers, such as dangerous goods containers, pressure vessels or containment, to ensure safe operation in the normal - and to ensure accident operation and to prevent penetration or escape of hazardous substances. Also, the operability of an electrical implementation in a humid environment, especially a heavily polluted, steam atmosphere should be guaranteed.

That's how it shows GB 2 115 238 A a device for guiding insulated conductors through the wall of a pressurized boiler. The device comprises a tubular casing leading through the wall and a sealing body having stepped holes through which partially stripped conductors are inserted. Another seal is achieved by hardening material, a pressure plate, a polyurethane-filled pressure ring and ceramic.

The GB 1 259 047 shows a device for zone melting of a crystalline body, in particular a rod of semiconductor material. The smelting kettle has electrical heating means comprising two conductors. These conductors are guided in a gastight manner through an opening in the vessel wall and are insulated from one another by insulating material which fills the opening. The insulating material has a Shore hardness of 10 to 100 and a ductility of at least 20%. Between this insulating material, the wall of the opening and the surface of the conductor forms an adhesive connection.

The US 4,960,391 shows a hermetically sealed electrical conductor feedthrough. The housing for this passage is made of a metal element to obtain a perfectly flat, abutting surface of a mounting area. This area extends peripherally around a contact receiving area disposed within a coverage area through an opening of the wall. Furthermore, the housing has a precisely planar surface of a contact receiving area to facilitate the assembly of exactly concentric mounted contacts which are mounted in passages through the receiving area and held therein by means of glass seals.

The US 5,017,740 shows a hermetically sealed connection device for a housing. This has a fuse-like area in the outer pin segment of a connection pin. The latter extends sealed through the body of the connection device. In this case, the body can be sealed against the housing wall. The fuse-like region is covered with a thermally decomposable coating which, in the case of decomposition, contains a rollover-suppressing agent. To protect the outer pin portion and to attach the end connection of the wire, a corresponding device is provided.

For applications under such extreme conditions in particular glass has proven itself as an insulator material. In order to reduce, or in some cases even avoid, possible insulation attenuation of the current-carrying metallic conductors, in particular in a moist environment, the regions of the conductor projecting from the insulator are coated with an insulating sheathing. It usually shrinks, preferably made of polyolefin or silicone or insulating hoses made of plastic or mineral fiber fabric, etc. are used, which are pulled over the head and by heat shrink or fit the head firmly and if necessary waterproof enclosing the sheath can serve as a creepage distance.

However, proves to be problematic, the area in which the head protrudes from the insulator and rests the jacket with its end face on the insulator. It turns out to be expensive or even impossible to seal this contact surface of the jacket to the insulator tight. With an imprecise sheathing of the conductor can be in This area even form a gap between the insulator and the sheath. The conductor is correspondingly open in this area and is exposed to possible corrosion.

Another serious downside is that moisture can condense on the surface of an electrical feedthrough, especially in the case of vapor development inside or outside such a space, for example a safety container. This allows the creation of unwanted leakage currents between the exposed areas of separate conductors or between a lying for example on high voltage conductor and a grounded jacket of the implementation. This can ultimately result in influencing the signal transmission or even in dangerous electrical short circuits, which may jeopardize the operation of a safety-relevant system.

General description of the invention:

Against this background, it is an object of the present invention to provide an electrical feedthrough and a method for the production thereof, which at least reduce the disadvantages of the prior art mentioned above. The electrical feedthroughs should be simple and economical to produce.

This object is achieved by an electrical implementation according to claim 1 and by a method according to claim 24. Advantageous developments are the subject of the respective subclaims.

In a first embodiment, the present invention comprises an electrical feedthrough comprising at least one conductor passed through an insulator, the conductor protruding from the insulator and at least one exit side from the insulator at least in the region in which the conductor protrudes from the insulator , embedded in an elastic seal.

In this case, the conductor has a casing, which is arranged at least in sections between the conductor and the elastic seal, wherein the casing extends from the outlet side of the insulator or forming a gap between an end face of the casing and the outlet side of the insulator along the conductor , The insulating jacket is arranged such that the jacket protrudes from the elastic seal and a contact surface of the jacket with the outlet side of the insulator or between the end face of the shell and the outlet side of the insulator existing gap is hermetically sealed by the elastic seal.

The resilient seal has a Shore Hardness of less than about 40 Shore A, preferably less than about 35 Shore A. In a particularly preferred embodiment, the Shore Hardness of the resilient seal is about 13 Shore A to about 35 Shore A.

Said range of Shore hardness is chosen so as to prevent on the one hand a detachment of the elastic seal from the insulator and / or the conductor by temperature changes due to different expansion coefficients of the individual materials. On the other hand, the aforesaid Shore hardnesses of the elastic seal enable a firm bond and hermetic closure of the elastic seal with both the insulator and the conductor. As a result, in particular a rupture of the elastic seal or a tearing of the adhesive bond of the elastic seal of the insulator at high temperature fluctuations, in particular in contrast to harder seals avoided.

According to the invention, the elastic seal comprises at least one elastomer. In a preferred form, the elastomer is or is silicone. Silicone preferably has the properties such. Wacker RT (xxx) (Wacker RT 745, 602 etc.). The name (xxx) stands as a collective term for the individual subgroups of the substance. Silicone is distinguished from simple plastics by increased long-term stability, is permanently elastic, UV-resistant, water-repellent, temperature-stable from -60 ° C to about 200 ° C and compatible with glass, metals or plastics.

The insulator comprises or is at least one of the following materials: glass, ceramic, glass-ceramic, plastic, PTFE, PEEK, fiber-reinforced epoxies or epoxy resins and / or similar electrical insulating materials or a combination of said materials. The plastics are, for example, PTFE, PEEK and / or fiber-reinforced epoxy resins, etc.

The conductor comprises or is at least one of the following materials, copper, copper alloys, iron, nickel iron, nickel cobalt iron, cobalt iron alloys, and / or thermocouple materials, or a combination of said materials.

Advantageously, the elastic seal can be applied for example by means of spraying, dispensing and / or pouring. The elastic seal forms with the insulator at least in sections a cohesive connection. If necessary, liability is supported by primers.

In order to ensure sufficient long-term stability and sealing, the mean height of the elastic seal is about 0.1 mm to about 50 mm, preferably about 0.5 mm to about 20 mm. More preferably, the height is about 1 mm to about 15 mm.

In order to reduce possible embrittlement or aging of the elastic seal, in one embodiment at least one first plasticizer, preferably in the form of at least one intermediate layer, can be arranged between the insulator and the elastic seal. This intermediate layer constitutes a reservoir from which the plasticizer can enter the elastic seal by diffusion processes. In addition, the mentioned intermediate layer may contain alone or additionally an adhesion promoter.

In one embodiment, the top of the elastic seal is formed substantially flat. The elastic seal is applied, essentially no longer post-processed and therefore easy to manufacture.

In order to ensure improved adhesion of the elastic seal to the insulator, the upper side of the insulator, in particular for enlarging the adhesive surface, if necessary, at least partially structuring.

In a preferred embodiment, the elastic seal substantially corresponds to the shape of a disc. In an alternative embodiment, the elastic seal substantially corresponds to the shape of a hollow rivet or a cylindrical men's hat open on both sides.

In one embodiment, the conductor has a jacket, which is arranged at least in sections between the conductor and the elastic seal.

The sheath comprises or is an insulation or an insulation tube and comprises as material at least silicone or consists of silicone. This sheath is slipped over the conductor or over at least a portion of the surface of the exposed conductor prior to the application of the elastic seal, i. H. over a portion of the surface of the conductor, which is not enclosed by the insulator, pushed.

If the sheath is arranged around the conductor such that it already surrounds or encloses the conductor in the section in which it exits or protrudes directly from the insulator, the elastic seal seals the region or section in which the sheath bears with its end face the insulator is tightly sealed or encapsulated. Ie. the joint, which is or is formed between the end face of the casing and the surface of the insulator or is closed accordingly. The joint at the contact surface sheathing insulator is encapsulated. The conductor is accordingly not exposed to corrosion in this section. Potential short-circuit currents between individual conductors and / or a housing are also prevented. According to the invention, the elastic seal with the conductor and / or with the sheath at least partially a cohesive connection.

To increase a possible short-circuit path between the outer terminal end of a conductor to an adjacent conductor or the housing of the electrical feedthrough, the sheath in a preferred embodiment also protrudes from the elastic layer.

The sheath has a thickness of from about 0.1 mm to about 5 mm, preferably from about 0.1 mm to about 3 mm, and / or a height greater than about 5 mm, preferably greater than about 10 mm. In one embodiment, the elastic layer has a height which is smaller than the length of the sheath.

In an alternative embodiment, the upper side of the elastic seal is structured at least in sections. This is particularly advantageous when a further layer is deposited on the elastic seal.

In order to reduce a functional impairment of the elastic seal by extreme environmental influences or by the surrounding atmosphere, such as high temperatures, intense radiation, high pressures or vapors, at least a first layer is arranged in a further embodiment on the free upper side of the elastic seal. The second layer comprises or is a protective layer. Said first layer is characterized in that it has a Shore hardness greater than about 40 Shore A, preferably greater than about 45 Shore A. The height of the first layer is about 0.1 mm to about 20 mm, preferably about 1 mm to about 10 mm, more preferably about 3 mm to about 5 mm. In a preferred embodiment, the first layer comprises or is an elastomer, preferably silicone, such as. B. Dow Corning Sylgard (xxx). The name (xxx) stands as a collective term for the individual subgroups of the substance.

In order to ensure long-term stability and improved adhesion, an at least second plasticizer and / or at least one second adhesion promoter is on the underside of the first layer, preferably arranged in at least one intermediate layer arranged.

The conductors of the invention find their use in walls of hermetically sealed or enclosed spaces, to pass electrical signals through the wall and / or to provide corresponding devices with power and / or voltage. In particular, their use is provided in walls of rooms, which have an increased or decreased pressure, increased or reduced temperature, increased radiation, altered composition of the atmosphere, in particular moisture relative to the environment. Possible examples are hazardous goods containers, pressure vessels, security containers, vacuum containers and / or reaction vessels.

Furthermore, the present invention comprises a method for producing an electrical feedthrough, in particular for producing the electrical feedthrough described above. The inventive method comprises the following steps, first fixing at least one conductor in an insulator so that the conductor protrudes from the insulator, then placing an insulating sheath over at least a portion of a surface of the protruding from the insulator conductor, then applying a Sealing material on at least one exit side of the insulator at least in the region in which the conductor protrudes from the insulator and the sheath is arranged, wherein the sheath, starting from the outlet side of the insulator or to form a joint between an end face of the sheath and the outlet side extends the insulator along the conductor, wherein the application of the sealing material takes place such that the casing protrudes from the elastic seal and a contact surface of the casing with the outlet side of the insulator or between the end face of the casing and the Outlet of the insulator existing hermetically sealed by the elastic seal and the curing of the sealing material, so that an elastic seal with a Shore hardness of less than about 40 Shore A, preferably less than about 35 Shore A forms. In a particularly preferred embodiment, the elastic seal is cured so that it has a Shore hardness of about 13 Shore A to about 35 Shore A. At least one elastomer, preferably silicone, is provided as the material for the elastic seal.

In a further embodiment, at least one first layer is applied to the elastic seal, which takes over the function of a protective layer for the elastic seal. The first layer is provided with a Shore Hardness greater than about 40 Shore A.

According to the invention, the elastic seal and / or the first layer is sprayed, spotted or cast in one embodiment, the elastic seal, preferably by means of a punch, if necessary, in sections or at least in sections, structured.

Furthermore, the present invention comprises a flange which comprises at least one of the electrical feedthroughs described above.

The present invention will be described in detail below with reference to exemplary embodiments, wherein the features of the different embodiments can be combined with one another. For this purpose, reference is made to the accompanying drawings. For this purpose, the same reference numerals refer to the same parts in the individual drawings.

1 shows the technical drawing of the cross section of an electrical feedthrough according to the invention.

2 shows by way of example a simplified schematic plan view of an electrical feedthrough.

3 shows a schematic detail view of the detail Z from 1 in a symmetrical embodiment.

4 shows a schematic detail view of the detail Z from 1 in an asymmetrical embodiment.

5 shows a schematic detail view of the detail Z from 1 in a one-sided embodiment.

6 shows a schematic detail view of the detail Z from 1 in a one-sided embodiment with sections of sheathing.

7 shows a schematic detail view of the detail Z from 1 in a one-sided embodiment with structured top of the insulator.

8th shows a schematic detail view of the detail Z from 1 in the execution of a hollow rivet mold.

9 shows a schematic detail view of the detail Z from 1 with an additional protective layer.

10 shows a schematic detail view of the detail Z from 1 with structured Top of the elastic seal and an additional applied protective layer.

1 shows the technical drawing of an embodiment of the invention the electrical feedthrough 1 in cross section. The electrical implementation 1 is shown to scale with an outer diameter L1 = 10.5 cm and a total length L2 = 19.6 cm.

The electrical implementation 1 has a plurality of ladders 2 on which is in an isolator 3 , here in the embodiment of a molten glass. The individual ladder 2 are on the two exit sides 2.1 . 2.2 from the insulator 3 in the area where the single conductor 2 from the insulator 3 protrudes, each with a sheath 5 . 5.1 . 5.2 provided as well as each in an elastic seal 4.1 . 4.2 embedded. According to their position in the insulator 3 and the illustrated cross section are the conductors 2 and the sheathing 5 . 5a . 5s both in a cross section 5s as well as in a supervision 5a to recognize. The ladder 2 are made of copper, copper alloys, iron, iron, nickel alloy and / or other conductive materials and their sheath 5 made of silicone or other insulating material.

The electrical implementation 1 has a rotationally symmetric hollow body 10 , with the openings 21 and 22 , on, in which the insulator 3 is fixed. In a preferred embodiment, the body is 10 a metal body. The body 10 or the housing of the electrical feedthrough 1 is in the present embodiment as a flange 20 educated. Rectangular casings are possible.

The one connection end 2.1 the leader 2 extends in the direction of the opening 21 the electrical implementation 1 , After mounting the electrical feedthrough 1 , For example, on the wall of a containment, the opening opens 21 preferably in the outside 1.1 or the surrounding side of a wall. In contrast, the opposite terminal end extends 2.2 the leader 2 in the direction of the opening 22 , The opening 22 preferably flows into the inside 1.2 or the interior of a containment or pressure vessel.

2 shows an example of a simplified schematic plan view of the opening 21 the in 1 illustrated electrical implementation 1 , To recognize are the body 10 or the housing, the connection ends 2.1 the leader 2 , the sheathing 5 and the elastic seal 4 . 4.1 on the outside 1.1 , The elastic seal is formed in one piece in this embodiment. It will be all leaders 2 the electrical implementation 1 in a continuous elastic layer 4 . 4.1 embedded. Alternatively, it is a discrete embedding or discreet enclosure of each individual conductor 2 and his sheath 5 by a respective elastic seal 4 . 4.1 possible.

3 shows a simplified schematic detail view of the detail Z from 1 , The leader 2 is in the insulator 3 , here a glass insulator, fixed and extends both towards the outside 1.1 as well as towards the inside 1.2 with its connection ends 2.1 . 2.2 from the insulator 3 out.

both sides 1.1 . 1.2 each is a sheath 5 around the conductor 2 arranged, with the sheath 5 starting from the top F3, F4 of the insulator 3 by a certain length along the conductor 2 extends. By using the sheath 5 becomes the total distance or short circuit distance along the surface of the insulator 3 and the sheath 5 from an exposed end of the conductor 2.1 . 2.2 extended to the exposed end of an adjacent conductor, not shown here. The jacket 5 is an insulation tube or is formed by a shrink tube or insulation tube, in particular made of silicone.

The leader 2 or with the sheath 5 provided ladder 2 is on both sides in an elastic seal 4.1 . 4.2 the height H1, H2 embedded. The elastic seal 4 . 4.1 . 4.2 is on the top F3, F4 of the insulator 3 placed and surrounds the in the sheath 5 arranged ladder 2 , The elastic seal 4 . 4.1 , 4.2 is made of silicone with a Shore hardness of 20 Shore A to 35 Shore A.

In essence, the contact surface 7 or seam of the sheath 5 with the top F3, F4 of the insulator 3 or one between the end face of the casing 5 and the top F3, F4 of the insulator 3 existing joint through the elastic seal 4 . 4.1 . 4.2 hermetically sealed or encapsulated and possible corrosion of the conductor 2 prevented.

In particular, in the case of vapor development inside or outside a containment vessel, moisture will be present on the surface of an electrical feedthrough 1 can condense, prevents the combination of sheathing 5 and elastic seal 4 the emergence of unwanted creepage currents between the exposed areas 2.1 . 2.2 separate conductor 2 or between a high-voltage conductor, for example 2 and a mantle at ground potential 10 or housing the implementation 1 ,

The arrangement of elastic seals 4.1 . 4.2 and the sheath 5 is bilateral and symmetrical, ie both on the inside 1.2 as well as on the outside 1.2 the electric execution 1 Show the elastic seals 4.1 . 4.2 and the sheathing 5 , in particular substantially, the same dimensions, in particular the same heights H1, H2, on. The height H1, H2 has a value of about 6 mm to 12 mm, preferably 6 mm to 10 mm, particularly preferably about 8 mm. This embodiment can thus be produced in a simplified manner since no process parameters have to be varied during production

4 shows a schematic detail view of the detail Z from 1 in an asymmetrical embodiment. The electrical implementation 1 corresponds to the in 3 illustrated implementation, but with the difference that the elastic seal 4.1 on the outside 1.1 the electrical implementation 1 one opposite the height H2 of the elastic seal 4.2 reduced height has H1. The height H1 in this case has a value of about 3 mm to about 4 mm. This will allow the outside 1.1 the electrical implementation 1 only exposed to the conditions of the ambient atmosphere. In contrast, the inside is 1.2 the electrical implementation 1 the extreme conditions in terms of temperature, radiation, steam, for example, in a containment, exposed, whereby an improved encapsulation of the conductor 2 is required.

In a correspondingly dry atmosphere on the outside 1.1 or the environment may even be a waiver of the elastic seal possible. This possible one-sided embodiment is in 5 shown. In the 4 and 5 illustrated embodiments allow a saving of material used.

However, the use of the elastic seal 4 . 4.1 . 4.2 required, so, while using the sheath 5 , provided in one embodiment, that the sheath 5 not with the surface F3 of the insulator 3 must complete and essentially only towards the inside of the elastic seal 4 . 4.1 . 4.2 extends. This is a sheathing of the conductor 2 With low precision possible without having to accept a deterioration of the encapsulation properties. This embodiment of a one-sided embodiment with sections of sheathing is in 6 shown.

7 shows a schematic detail view of the detail Z from 1 in a one-sided embodiment with structured top F3 of the insulator 3 , The structuring leads inter alia to an improved adhesion of the elastic layer 4 . 4.2 on the insulator 3 , By structuring, a detachment of the elastic seal 4 . 4.2 from the insulator 3 can be reduced by shear forces occurring during temperature changes. According to the invention, the mechanical and / or chemical roughening of the upper side F3 of the insulator is also used for structuring 3 Understood.

8th shows a schematic detail view of the detail Z from 1 in the execution of a hollow rivet mold, the outside 1.1 the elastic seal 4.1 according to the in 3 shown outside 1.1 is trained. This embodiment of the one-piece elastic seal 4.2 the inside 1.2 combines the benefits of encapsulation while using a sheath 5 and an elastic flat seal 4.1 as it is on the outside for illustration 1.1 the electrical connection 1 is shown. The Hohlnietform or the shape of a top hat open in the cylinder of the elastic seal 4.2 is by applying the elastic seal 4.2 and a subsequent structuring of the elastic seal 4.2 generated. The structuring takes place, for example, by means of a stamp, which has the negative form of the hollow rivet shape shown.

9 shows a further embodiment with an additional on the top F1 of the elastic layer 4.2 applied first layer 6 , here a protective layer. The elastic layer 4.2 Bets the ladder 2 one or encloses the conductor 2 and also goes with the insulator 3 and the sheath 5 an intimate connection. The first shift 6 or protective layer has a relation to the elastic seal 4.2 higher Shore hardness of about 45-60 Shore A and has a height of about 3 mm to about 4 mm. It encapsulates the elastic layer 4.2 and protects them from premature aging, embrittlement or damage under extreme environmental conditions.

10 shows a schematic detail view according to the in 9 illustrated embodiment, however, with a structured top F1 of the elastic seal 4.2 , The structure on the top F1 of the elastic seal 4.2 allows for improved adhesion of the first layer 6 or the protective layer on the elastic layer 4.2 , According to the invention, the roughening of the upper side F1 of the elastic seal is also used for structuring 4.2 Understood.

It will be apparent to those skilled in the art that the embodiments described above are to be understood as exemplary. The invention is not limited to these, but can be varied in many ways without departing from the spirit of the invention. Features of individual embodiments and the features mentioned in the general part of the description can each be combined with each other and with each other.

LIST OF REFERENCE NUMBERS

1

Electrical implementation

1.1

outside

1.2

inside

2

ladder

2.1

Outer terminal end

2.2

Inner connection end

3

insulator

4

Elastic seal

4.1

Elastic seal of the outside

4.2

Elastic seal on the inside

5 / 5a / 5s

jacket

6

First shift

7

Contact surface of sheath insulator

10

Body or metal body

20

flange

21

External opening of electrical feedthrough

22

Inside opening of the electrical outlet

H1

Height of elastic density on the outside

H2

Height of elastic density on the inside

L1

Diameter of electrical feedthrough

L2

Total length of electrical feedthrough

Z

Enlarged cutout area of the carrier substrate

F1

Top of the elastic seal

F2

Bottom of the elastic seal

F3

Inner top of the insulator

F4

Outer top of the insulator

Claims (32)

Electrical implementation ( 1 ), comprising at least one by an isolator ( 3 ) ( 2 . 2.1 . 2.2 ), the leader ( 2 . 2.1 . 2.2 ) from the isolator ( 3 protrudes and on at least one outlet side (F3, F4) from the insulator ( 3 ) at least in the area in which the conductor ( 2 . 2.1 . 2.2 ) from the isolator ( 3 protruding in an elastic seal ( 4 . 4.1 . 4.2 ), the leader ( 2 ) a sheath ( 5 ), which at least partially between the conductor ( 2 ) and the elastic seal ( 4 . 4.1 . 4.2 ), wherein the sheath ( 5 ) starting from the outlet side (F3, F4) of the insulator or forming a joint between an end face of the casing ( 5 ) and the exit side (F3, F4) of the insulator extends along the conductor, wherein the insulating sheath is arranged such that the sheath ( 5 ) from the elastic seal ( 4 . 4.1 . 4.2 protrudes) and a contact surface of the sheath ( 5 ) with the exit side (F3, F4) of the insulator ( 3 ) or between the end face of the casing ( 5 ) and the exit side (F3, F4) of the insulator ( 3 ) existing joint through the elastic seal ( 4 . 4.1 . 4.2 ) is hermetically sealed, and wherein the elastic seal ( 4 . 4.1 . 4.2 ) has a Shore hardness of less than 40 Shore A. Electrical feedthrough according to claim 1, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) has a Shore hardness of less than 35 Shore A. Electrical feedthrough according to claim 1 or 2, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) comprises at least one elastomer. Electrical feedthrough according to claim 3, characterized in that the elastomer comprises silicone. Electrical feedthrough according to one of the preceding claims, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) is applied. Electrical feedthrough according to one of the preceding claims, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) with the insulator ( 3 ) is connected at least partially cohesively. Electrical feedthrough according to one of the preceding claims, characterized in that the height (H1, H2) of the elastic seal ( 4 4.1 , 0.1 mm to 50 mm, preferably 0.5 mm to 20 mm, particularly preferably 1 mm to 15 mm. Electrical feedthrough according to one of the preceding claims, characterized in that between the insulator ( 3 ) and the elastic seal ( 4 . 4.1 . 4.2 ) at least a first plasticizer and / or at least one adhesion promoter is arranged. Electrical feedthrough according to one of the preceding claims, characterized in that an upper side (F1) of the elastic seal ( 4 . 4.1 . 4.2 ) is substantially flat. Electrical feedthrough according to one of the preceding claims, characterized in that at least one upper side (F1) of the elastic seal ( 4 . 4.1 4.2 ) is structured at least in sections. Electrical feedthrough according to one of the preceding claims, characterized in that at least one upper side (F3, F4) of the insulator ( 3 ) is structured at least in sections. Electrical feedthrough according to one of the preceding claims, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) substantially corresponds to the shape of a disc. Electrical feedthrough according to one of Claims 1 to 11, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) substantially corresponds to the shape of a hollow rivet. Electrical feedthrough according to one of the preceding claims, characterized in that the sheath ( 5 ) as insulation, which in particular comprises silicone, is formed. Electrical feedthrough according to one of the preceding claims, characterized in that that the elastic seal ( 4 . 4.1 . 4.2 ) has a height (H1, H2) which is smaller than the length of the sheath ( 5 ). Electrical feedthrough according to one of the preceding claims, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) with the ladder ( 2 ) and / or with the sheath ( 5 ) is connected at least partially cohesively. Electrical feedthrough according to one of the preceding claims, characterized in that on an upper side (F1) of the elastic seal ( 4 . 4.1 . 4.2 ) at least a first layer ( 6 ) is arranged. Electrical feedthrough according to the preceding claim, characterized in that the first layer ( 6 ) comprises a protective layer. Electrical feedthrough according to one of the two preceding claims, characterized in that the first layer ( 6 ) has a Shore hardness of greater than 40 Shore A, preferably greater than 45 Shore A. Electrical feedthrough according to one of Claims 17 to 19, characterized in that the height of the first layer ( 6 ) 0.1 mm to 20 mm, preferably 1 mm to 10 mm, particularly preferably 3 mm to 5 mm. Electrical feedthrough according to one of Claims 17 to 20, characterized in that an at least second plasticizer and / or at least one second adhesion promoter is arranged on a lower side of the first layer. Electrical feedthrough according to one of Claims 17 to 21, characterized in that the first layer ( 6 ) comprises an elastomer, preferably silicone. Electrical feedthrough according to one of the preceding claims, characterized in that the insulator ( 3 ) Glass, ceramic, plastic and / or glass ceramic. Method for producing an electrical feedthrough comprising - fixing at least one conductor ( 2 ) in an isolator ( 3 ), so that the conductor ( 2 ) from the isolator ( 3 protruding, - arranging an insulating sheath ( 5 ) over at least a portion of a surface of the insulator ( 3 ) outstanding conductor ( 2 ), - applying a sealing material on at least one outlet side (F3, F4) from the insulator ( 3 ) at least in the area in which the conductor ( 2 ) from the isolator ( 3 protruding and the sheath is arranged, wherein the sheath ( 5 ) starting from the outlet side (F3, F4) of the insulator or forming a joint between an end face of the casing ( 5 ) and the exit side (F3, F4) of the insulator extends along the conductor, wherein the application of the sealing material takes place in such a way that the sheath ( 5 ) from the elastic seal ( 4 . 4.1 . 4.2 protrudes) and a contact surface of the sheath ( 5 ) with the exit side (F3, F4) of the insulator ( 3 ) or between the end face of the casing ( 5 ) and the exit side (F3, F4) of the insulator ( 3 ) existing joint is hermetically sealed by the elastic seal, - hardening of the sealing material such that an elastic seal ( 4 . 4.1 . 4.2 ) with a Shore hardness of less than 40 Shore A. Method according to the preceding claim, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) with a Shore hardness of less than 35 Shore A. Method according to one of the two preceding claims, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) comprising an elastomer, preferably silicone. Method according to one of the preceding claims 24 to 26, characterized in that at least one first layer ( 6 ) on the elastic seal ( 4 . 4.1 . 4.2 ) is applied. Method according to the preceding claim, characterized in that the first layer ( 6 ) is provided with a Shore hardness greater than 40 Shore A. Method according to one of the preceding claims 27 to 28, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) and / or the first layer ( 6 ) is sprayed on, aufdispenst and / or poured. Method according to one of the preceding claims 25 to 29, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) is structured at least in sections. Method according to the preceding claim, characterized in that the elastic seal ( 4 . 4.1 . 4.2 ) is structured by means of a stamp. Flange, comprising at least one electrical feedthrough according to one of the preceding claims 1 to 23.

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