DE2132418A1 - Splice connector for high voltage cables - Google Patents

Description

Dipl.-fng. Ludewi ^
Dipl.-Phys. Ruse
Dipl.-Phys. Mentzel

Patent attorneys 0 10 0 / 1O

Wuppertal-Barmen ^Z ' ^{ό lk} '

Unierdörneri 114 Tel. 553611/12

Password: "Spieissverbindungen II"

AMERACE ESNA CORPORATION, New York 10017, 245 Park Avenue

V.St.v.A.

Splice connector for high voltage cables

The present invention relates generally to electrical connectors, and more particularly to one electrical connector that creates a splice connection between armored high-voltage cables or between such a cable and other systems within a power grid.

In recent years, particular emphasis has been placed on the development of underground power supply networks, particularly in light industrial, commercial and residential areas. Various power supplies, including armored electrical cables, transformers and electrical connector has one developed for use in such networks.

109884/1173

The assemblies developed also include the armored electrical connectors, which are easily located in the Assemble outdoors at the end points of the power cables to facilitate the creation and installation of underτ to facilitate terrestrial power supply networks. The numerous advantages of these connectors have one Demand has led to connectors of the same type that are successful under even higher voltages than that already known connector can work.

According to the invention, an electrical connector is used whose components can be assembled outdoors at the end points of armored high-voltage cables in order to establish a connection between a first and a second cable of this type, said cables each consisting of a conductor surrounded by insulation which in turn is encased in a conductive armor, and wherein said electrical connector consists of:

two housing halves made of elastomer material, the each of an inner part made of electrically insulating elastomer and an outer part made of electrical There are conductive elastomer, the inner and outer part of each housing half along a generally continuous and void-free suture surface are connected;

these housing halves have on the opposite Ends corresponding parts that interlock watertight and consist of:

an axially extending plug at one end of the inner portion of one of said housing halves, the one root and one generally cylindrical surface

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whose outside diameter differs from the total diameter the outer surface of the remaining part of the called one half of the housing differs in such a way that that there is a generally laterally oriented surface between the root of the plug and the said External surface extends as well

an axially extending recess on the opposite end of the inner part of the other of the two mentioned housing halves, which consist of a open end and a generally cylindrical surface exists, the inside diameter of which corresponds to the outside diameter of the stopper, this inside diameter smaller than the total diameter of the outer surface of the remaining part of said other housing half is, in such a way that there is a generally laterally oriented surface between the end of the recess and said outer surface of said other housing half extends;

being the interface between the inner and outer parts of each housing half follow a continuous line which essentially extends up to the generally cylindrical surface of the plug or the recess extends in such a way that the course of the electrical stress between the opposite ends of the assembled housing halves is generally continuous and the stress gradient along the corresponding, laterally oriented surfaces of the housing halves on a Minimum dimension is reduced "

One or the other of the mentioned housing halves can be used to attach a cable to equipment

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within a power network except to connect to another cable by connecting a corresponding housing half of a suitable, matching one Arranges construction that corresponds to the construction of one or the other of said housing halves.

. By using the connector according to the invention a splice connection can be easily made outdoors without laborious work such as wrapping, having to pour, stew and the like.

The seam surface in an electrical connector according to the invention can be in a continuous Line, bypassing possible voids near the joined ends of the line assembled .Häusehälften a connector to to avoid harmful and concentrated electrical stresses in this area.

An electrical connector according to the invention can relatively easy and cheap to manufacture be.

The invention is illustrated as an example of an embodiment in the accompanying drawings, in which

Fig. 1-3 shows the assembly of a splice connection below Use of a splice according to the invention

prevent show; Fig. 4 is a longitudinal section of the adapter sleeve of a

The splice connector according to the invention shows} FIG. 5 a longitudinal section of the adapter sleeve according to FIG

Figure 4 shows after mounting on a cable; Fig. 6 is a cross section taken along line 6-6 in Fig. 5 shows;

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Jfig. 7 shows a longitudinal section in which the assembly one housing half can be seen on the adapter sleeve of FIG. 4;

8 shows a cross section of the fully assembled splice connector according to the invention;

Fig. 9 shows a plan view of a heat conductive housing half of a splice connector according to the invention, and

Figure 10 is an end view of the thermally conductive housing half according to Fig. 9 shows.

109884/1173

In the figures, and in particular in FIGS a splice connection can be made between a pair of shielded high voltage electrical cables Io and 12 in a power distribution system. Each of the cables Io and 12 has a central conductor 14, which is surrounded by an insulating jacket 16, which itself is in an external seal 18 · In order to achieve a splice connection between the connection ends of the cables, a first housing or Plug member 2o pushed onto the end 22 of the cable Io and moved the length of the cable away from its end. One such Moving the housing member 2o along the cable Io is achieved with little or no resistance, since the housing member has an axially extending inner bore 24 (see Fig. 7) is provided, which has an inner diameter which is considerably larger than the overall outer diameter of the cable «Zn in a similar manner, a second housing or socket member 26 is pushed onto the end 23 of the cable 12 and moved along the cable in the direction away from its end

A portion 3o of each shield 18 is removed to form a portion 31 of the insulating jacket 16 between each cable end and expose the end 32 of the shield. Although the Part 3o of the shield 13 either before or after being pushed of the housing members 2o and 26 on the cables Io and 12 ent can be removed, the shielding section 3o_vor-_

preferably removed after sliding the housing members onto the cables, as shown in FIG.

As best seen in Figure 2, then a pair of sleeves 34 pushed onto the terminal ends of the cables, one sleeve 34 on each cable, and each Sleeve is moved along its respective cable in the direction of

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moved away to its end. The sleeves 34 are preferably made of an elastomeric material and have a first sleeve section 36 made of an electrically insulating elastomer and a second sleeve section 38, axially related to the first sleeve section 36 and fixed to it, made of an electrically conductive elastomer. The sleeve sections 36 and 38 are preferably cast so that they adjoin one another and are connected to form a single unit (see also FIG. 4). The sleeve sections lie directly against one another at the connection point Ao and have no gap. The connections of the sleeve sections are preferably built up on the same polymer in order to ensure a strong bond. An ethylene-propylene terpolymer available under Du Pont's trademark "NORDEL" is an example of a polymer which has been used successfully for this purpose. Insulating "NORDEL" is used for the first sleeve section 36 and conductive "NORDEL" is used for the second sleeve section 38.

At least parts of the second sleeve element 38 can be carried out in the form of a conductive coating, especially in places with relatively thin Cross section applied to the first sleeve element 36 will. In the context of the present description, the term "elastomer" is also intended to include such coatings include.

Each sleeve 34 has an inner bore 42 (see FIG. 4) which extends axially from the end 44 to the end 46 of the sleeve 34 through the first and second sleeve section extends, the bore 42 due to the resilient nature of the sleeve material is resiliently expandable, the inner bore 42 has a first inner surface 5o with a first diameter at the end 44 the sleeve, which is through the first Hülsenabschnitt 36 and

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part of the second sleeve portion 38 to a shoulder 52 runs, which lies between the first inner surface 5o and a second inner surface 54 at the other end 46 of a sleeve and which has a diameter that is slightly larger than the diameter of the first inner surface 50. The relative Dimensions of the first inner surface 5o and the diameter of the outer surface of the insulating jacket 16 are chosen so that the insulating jacket 16 can be inserted into the sleeve 34 by hand, the resilient nature of the sleeve their radial expansion and thereby a slight expansion of the inner bore 42 for the insertion of the insulating jacket enabled (see also Fig. 5). The inner bore thus engages the exposed one along its first surface 5o Length 31 of the insulating jacket 16 with a tight fit. The tight fit along the exposed length of the insulating jacket increases the dielectric strength of the creepage path along the outer surface of the insulating jacket 16 between the End 44 of the sleeve and end 32 of the shield 18. This it is ensured that no current flows between the conductor 14 and the shield 18 along the insulating jacket. The sleeve 34 continues to slide on the cable until the shoulder 52 rests against the end 32 of the shield 18 (as in 5 is shown} · In this position of the sleeve, the inner bore 42 expands along the second inner surface 54 resiliently to grip the shield 18 in electrical contact therewith. Each sleeve has two sections 36 and 38 common outer surface 56.

Since electrical voltages tend to move along the connection point 4o between the first and second Focus on sleeve section 36 and 38, and although the relative dimensions of the inner bore 42 and the outer surface of the insulating jacket seek to prevent gaps between the sleeve and the insulating jacket 16, the possibility exists that there are gaps between the sleeve 34 and the insulating jacket 16 once the sleeve is installed

1.0 988 _{4/11 7 3 ωοθΜΑ}

(due to irregularities in the outer surface of the insulating jacket), the inner bore 42 of each sleeve is provided with a section 50 which has a reduced inner diameter along the connection point 6o of the inner bore with the connection point 4o (see FIG. 4). The section 58 with the normally reduced diameter ensures that when the inner bore of the sleeve expands resiliently, the inner bore engages the insulating jacket in close, essentially seamless contact at least at the connection point 6o. The increased pressure of the sleeve on the insulating jacket created by the reduced diameter at the connection point has been found to be effective in substantially eliminating minor imperfections which would otherwise affect the ionization height of the interface between the jacket and the insulating jacket. Although the reduced diameter at the connection point 6o increases the resistance to movement of the sleeve 34 along the insulating jacket 16, this resistance is reduced by the fact that the portion 56 with the reduced diameter is restricted to the area of the connection point. In order to further facilitate displacement of the sleeve on the insulating jacket, while at the same time ensuring that air is expelled from the vicinity of the connection point 6o, so that a close, essentially gapless contact results, the section 58 with the reduced inner diameter is with a Provided a profile contour which is conical to both ends 62 of the section 58 by gradually increasing the diameter from the connection point 6o itself. The profile outline is preferably curved. This controls electrical voltages at connection point 6o.

Once the sleeves 34 are in their correct position on their respective cables, a retainer 66, shown in the form of a snap ring, is attached to the end of each cable

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slipped as seen in Pig, 2 and attached to the insulating jacket 16 in abutment with the end 44 of each sleeve as shown in FIG. Each snap ring 66 is fixed on the insulating jacket 16, preferably with fastening means shown in the form of clamping screws 63 (see FIGS. 5 and 6) which engage the insulating jacket 16 in a force-locking manner in order to clamp the ring 66. The clamping screws 68 are screwed radially through each ring 66 to radially penetrate the dumbbell and may, but need not necessarily, contact the conductor 14 of the cable. Each sleeve 34 is therefore held in a force-locking manner against movement towards the cable end by a snap ring 66 . Movement in the opposite direction is prevented by the shoulder 52 resting against the end 32 of a shield 18. Each sleeve 34 thus has an outer surface 56 with a predetermined outer diameter, which is common to the first and second Hülsanabschnitts, and the end 32 of the shield 18 is encased and protected by the second Hülsenabohnitt 38, the shield 18 with the outer surface 56 predetermined diameter * electrically connected is"

A portion 70 of the insulating jacket 16 at the end of each cable is removed to allow a length 72 of conductor 14 between each End 22 and 23 and dome end 74 of the insulating jacket to expose (see Figures 3 and 5). Although these sections 7o either before or after installation of the sleeves 34 and the Circlips 66 can be removed, the ablation takes place preferably after installation of the snap rings, so that they act as guides for the arrangement at the end 74 of the Isolierraantels 16 can serve «

The bare ends 76 of the conductors / are then connected by means of a / 14 electrically connected in the form of a tubular metallic contact 8ο electrical connector member shown

ORIGINAL

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This has a LKngadurehbruch 82, which is of a Transverse wall 34 is divided to form a pair of ferrules 86 Each conductor 14 is inserted into its associated ferrule 86, and the contact So is depressed at 88 and 89 (see Fig. 5) to the contact 8o on the conductors 14 in a known manner Way to attach

As shown in Figure 7, there is the first walking limb from oiner made of an elastomeric material to set structure. The composite structure has an inner portion 9o made of an electrically isolating * the elastomer and an outer portion 92 made of an electrically conductive elastomer. Inside and outside section

9o and 92 are preferably potted together, for example by first pouring the inner section and then the outer portion is molded around the inner portion to form the composite housing member so that the housing member 2o a solid structure with adjacent one another Forms inner and outer sections 9o and 92 which are connected into a single assembly, wherein Inner and outer section 9ο and 92 at the connection point 94 lie against one another and do not form a gap, so that electrical voltages are below the length of the housing member Control can be kept. Both housing members 2o and 26 are preferably made of the same Ilatorialien, how they are used in the manufacture of the sleeves 34 «

The inner bore 24 of the first housing member 2o has a common to the inner and outer sections 9o and 92, axially extending through this first portion 96 at one end 98 of the housing member. The relative Dimensions of the first section 96 of the inner bore 24 and the outer surface 56 of the corresponding sleeve 34 are chosen so that when moving the GehSusogliedes towards the end of the cable 22 and over the sleeve 34, the section

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the inner bore resiliently expands to watertightly engage the outer surface of the sleeve 34 therewith.

As best seen in Figure 8, is the second housing member 26 is also a composite structure and has an inner portion loo and an outer portion Io2 on. Its inner bore Io4 is also common to both the inner section loo and the outer section Io2. sam, and the relative dimensions of the first section Io6 the inner bore Io4 and its corresponding sleeve 34 have the same relationship as above in connection with FIG the first housing member 2o and its corresponding sleeve 34 has been described «The housing members 2o and 26 are provided with corresponding sections that interact in a waterproof manner and in the form of a plug attachment Io7 des first housing member 2o and a corresponding socket Io8 in the second housing member 26 are shown. When both housing members are pulled to their respective cable ends 22 and 28 and thus approach one another, the connector Io7 penetrates into the socket Io8 to form a watertight seal between the housing members as well as a electrical contact between the outer portions 92 and Io2 of the housing members by engagement of the plug portion Ho with the socket section 112. Due to the tight fit between the housing members 2o and 26 and their respective sleeves 34 it is ensured that the outer sections 92 and Io2 the respective second sleeve sections 38 engage to make electrical contact in order to 'override the electrical continuity of the shield 18 Ensure the assembled splice connection 114 · At the same time, the tight fit increases dielectric strength of the creepage distance along the portion 116 of the outer surface 56 of the sleeve 34, which is attached to the inner portion of each Housing members · adjoin.

109884/1173

The inner bores 24 and Io4 of the housing members 2o and 26 each have a second bore section 12o and 122, which are used when the housing members are assembled a fixed housing assembly 118 on the sleeves 34, as shown in Fig. 3, form a closed chamber 124, in which the contact 8o is arranged and sealed. An electrically and thermally conductive metal tube 126 (see Fig. 7 and 8) is arranged in the second bore section 12o of the first housing member 2o and is used during assembly of the Housing members inserted into the second bore section 122 of the second housing member 26. The pipe 126 1st relatively rigid and forms an internal support for the connector Io7 to create a tight seal between the To ensure the connector approach Io7 and the socket Io8, and is preferably made of aluminum * The first housing member 2o is with a bridging portion made of electrically conductive elastomeric material between one end 132 of the metal tube 126 and a part 138 of the first bore section Io6 of the inner bore Io4 of this housing member runs «If so the housing members, as shown in FIG. 8, are assembled into a fixed housing assembly 118 is the closed chamber 124 surrounded by a wall made of electrically conductive and thermally conductive material, which runs coaxially to the contact 8o and the conductors 14 and is radially spaced from the outer surface I4o of the contact. Although it has been considered that the Housing assembly 118 may be provided in the form of a housing unit, it has been found to be preferable is to field assemble the housing from a pair of housing members as previously described.

Before the assembly of the two housing members 2o and 26 and the resulting closure of the chamber 124

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a member of thermally conductive material, which is shown in Fig. to Io is shown in the form of a metal member 142, arranged on the outer surface I4o of the contact 80 so that the conductive member 142 when assembling the housing members and terminating the chamber both the electrical contact So as well as the metal tube 126 to provide a path for heat conduction across the space between the contacts and tube 126, thereby allowing excessive heat to be dissipated from contact 80 and increasing the useful power of splice connection 114. At the same time, conductive member 142 is electrically conductive and thus switches any adverse voltage difference between the wall of the chamber 124 and the contact 80 and The bridging section 136 of the second housing member 26 also runs along the floor of socket I08 at 144 to remove adverse electrical voltages across any space between the end of the Plug Io7 and the bottom of socket I08 « The bridging sections 13o and 136 are preferred firmly cast with the inner sections 3o and loo of the respective housing members 2o and 26 to form a coherent and gapless connection 146 between each bridging section and to achieve its respective inner section.

As best seen in Figures 8, 9 and Io, the conductive member 142 is preferably provided in the form of a resilient arched metal band I5o, the Radius is normally greater than the radius of the cylindrical outer surface I4o of the contact 80 and greater as the inner cylindrical surface of the metal tube 126 "a plurality of resilient fingers 152 stand out from both Ends 154 of the metal strip I5o and form with this a unit with each finger 152 axially from the end of the Ribbon and ends in a free tip 156 *

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The free tips 156 of the fingers 152 lie on an arc with a circumferential length which is smaller than that Circumferential length of the dogens of the band I5o, and extend axially parallel to each other such that the metal link be wrapped around the outer surface I4o of the contact 8o may, with tips 156 of fingers 152 touching the outer surface of contact 8o and tape 15o so positioned is that it contacts the metal pipe 126. The fingertips are preferably frictionally connected to the contact 8o a relatively short length of wire or tape wrapped around the fingertips at 158, as in FIG Fig. 8 is shown. When the housing members 2o and 26 are assembled on the conductive member I4o, an effective earner heat conduction path between the contact 8o and the pipe 126 is created in the assembled housing 118. This way, heat from the contact 8o can go directly to the pipe guided and thereby diverted to the surrounding housing,

The combination of the housing 118 with the corresponding sleeves 34 enables easy assembly in the field, since the sleeves 34, which contain thin wall parts relative to the corresponding wall parts of the housing, easily in the correct position on the cables by hand without damaging the cable and especially the shielding can. The greater forces required to pull the housing or housing members over the sleeves, are easy to apply to the housing or the larger diameter housing members. The sleeves 34 against Movement in accordance with such tensile forces are secured by means of the snap rings 66, can withstand such tensile forces, and the tensile forces need not have been applied directly to the more delicate shield 18. About that In addition, cables of different diameters can be

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Changes in the size or design of the housing can be accommodated simply in that sleeves 34 with internal bores different diameters are provided, the outer surfaces 56 of the sleeves having the same diameter maintained. In some cases it may be desirable for the cable Io to vary in size from the cable 12, and such a difference can easily be accounted for by the use of sleeves 34 with internal bores different diameter. By choosing the correct sleeves 34, the splice connector thus adapted to accommodate a wide variety of cable sizes.

SAD ORIGINAL 109884/1173

—F7-

To ensure that the connection made by assembling the housing halves 20 and 26 is resistant to the high voltage applied between the conductor 22 and the armor 3.8 of the spliced cables, the electrical stresses inside the splice connector must be controlled, and every concentration electrical stress at a certain point must be avoided. A place where can easily concentrate electrical stresses is in the vicinity of the connection surface l60 between the housing halves 20 and 26. This tendency exists at the point mentioned, since the two housing halves have laterally extending surfaces through which the opposite end faces of the assembled Housing halves are defined. '

For example, as best seen in FIGS. 7 and 8, a laterally oriented surface extends between the root 164 of the axially extending plug 107 and the outer surface 166 of the remaining part of the housing half 20, since the substantially cylindrical surface of the Plug 107 has a smaller diameter than the total diameter of the outer surface. Correspondingly, a laterally oriented surface I70 extends between the end I72 of the axially extending recess I08 and the outer surface 174 of the remaining part of the housing half 26, since the essentially cylindrical surface of the recess IO8 has a smaller diameter than the total diameter of the outer surface 174. Since there is a tendency for air to become trapped in voids between these laterally extending surfaces I62 and I70 when the housing halves 20 and 26 are assembled

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from these cavities potential sites for stress concentrations that eventually lead to the breakdown of the insulation at these points and as a result can lead to failure of the splice connector.

In order to avoid such a concentration of electrical stresses, the connecting surface 9 ^ between the inner part 90 and the outer part 92 of the housing half 20 follows a continuous line which extends essentially to the surface of the plug 107 immediately at its root iGk . Correspondingly, a connecting surface I76 between the inner part 100 and the outer part 102 of the housing half 26 follows a continuous line which extends essentially to the surface of the recess IO8, immediately at its end I72. This has the effect that the electrical stresses within the insulating parts 90 and 100 of the housing halves 20 and 26, respectively, are distributed in a substantially continuous manner without abrupt changes occurring which can lead to a harmful concentration of stresses. The term "continuous" in connection with the lines of the connecting surfaces 9 ^ and I76 and in connection with the distribution of the electrical stresses is used here in a mathematical sense; ie the changes in direction are smooth and gradual instead of abrupt and sharp-edged.

Thus, the lines of the connecting surfaces 94 and I76 in the area of the laterally extending surfaces 162 and 170 not only achieve an advantageous distribution of the electrical stresses in the connection between the housing halves 20 and 26, but also reduce the stress gradient along them

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-49-

laterally extending surfaces to a minimum, so that the formation of corona effects in voids between these surfaces and the adverse effects such corona effects can be largely avoided.

Although such undesirable effects can be reduced or substantially eliminated by using the Connection surfaces 94 and I76 practically to the surface of the plug 107 or the recess IO8 has extended it has proven advantageous to use the connecting surface 9 ^ to extend into the plug 107 so that the connection surface with the surface of the The plug intersects at point 178, which is a short distance from the root 164 of the plug. on in this way the outer part 92 will overlap with the surface of the recess I08 when the housing halves 20 and 26 are put together, ensuring that all voids are between the opposing laterally extending surfaces 162 and 170 bounded by electrically conductive material will. Accordingly, the connection surface I76 preferably made so that they the surface of the recess IO8 at a short distance from its open end I72 intersects so that the outer part 102 is aligned with the Plug IO7 overlaps directly at its root 164.

Accordingly, you can all possibly occurring cavities along the pipe 126 between the pipe 126 and the inner part of the housing half 20 with a conductive Surround material by making the bridging part I30 in the form of a thin layer I80 of conductive material, so that the cavity-free connecting surface l46 extends to the end I82 of the housing half 20.

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The foregoing detailed description of a preferred embodiment of the invention is given by way of example only. Various details of construction and manufacture can be changed without departing from the invention as set out in the following claims.

1 0 98 8V 1 173

Claims (1)

Claims ; 1. Electrical connector, its components in the open air at the terminals of armored high-voltage cables Can be put together to form a connection between a first and a second cable of this type, said cables each consisting of a Consist of conductors surrounded by insulation which in turn is encased in a conductive armor, and wherein said electrical connector consists of: two housing halves made of elastomer material, the each of an inner part made of electrically insulating elastomer and an outer part made of electrical conductive elastomer, said inner (90,100) and outer (92, 102) part of each Housing half (20,26) along a substantially continuous and cavity-free seam surface (94,1? 6) are connected; these housing halves (3 ^) have on the opposite Ends corresponding parts that interlock watertight and consist of: an axially extending plug (107) an end of the inner portion of one (20) of said housing halves having a root (164) and an im has a substantially cylindrical surface, the outer 109884/1173 -12- diameter differs from the total diameter of the outer surface (166) of the remaining part of said one housing half differs in that a substantially laterally oriented surface (162) between the root (164) of the plug and the aforesaid External surface (166) extends, as well an axially extending recess (108) at the opposite end of the inner part (100) of the other (26) of the two mentioned housing halves, consisting of an open end (172) and a substantially cylindrical surface, the inner diameter of which corresponds to the outside diameter of the stopper (107), this inside diameter being smaller than the Geasrat diameter the outer surface (174) of the remaining part the other half of the housing mentioned, in such a way that that one, essentially oriented laterally Surface (170) between the end (172) of the recess (108) and the named outer surface (174) of the named other Housing half extends; wherein the connecting surface (94,176) between the inner (90,100) and outer (92,102) parts of each housing half (20,26) of a continuous line follows, which extends essentially up to the generally cylindrical surface of the plug (107) or. the Recess (108) extends in such a way that the distribution of electrical stresses between the opposite ends of the assembled housing halves is substantially continuous and the Stress gradient along the corresponding, laterally oriented surfaces (162,170) of the housing halves is reduced to a minimum. 109884/1173 2. Electrical connector according to claim 1, characterized in that the lines of the Connection surface (9 ^) in said one (20) Housing half has a part whose diameter is smaller than the outside diameter of the plug (107) and its Is root (164) and which extends axially along part of the plug (107) to a point that it cuts the surface of the plug at a short distance (at point 178) from its root, in such a way that that the outer part (92) of said one (20) of the two housing halves is connected to a corresponding part the recess (IO8) directly at its open end (172) overlaps. 3. Electrical connector according to claims 1 or 2, characterized in that the lines the connection surface (I76) in the other (26) mentioned of the two housing halves the surface of the recess (IO8) at a short distance from their open end (172) intersects, in such a way that the outer part (102) of the said other (26) of the two housing halves also coincides the corresponding part of the plug (IO7) directly touches and overlaps at its root (164). k. Electrical connector, the components of which can be assembled outdoors at the end of an armored high-voltage cable consisting of a conductor surrounded by an insulating sheath, which in turn has a conductive armor, the electrical connector being composed of: a housing half made of elastomer material, which from an inner part made of electrically insulating elastomer and an outer part made of electrically conductive 109884/1173 Elastomer, characterized in that said inner (90) and outer (92) parts along a substantially continuous and void-free seam surface (9 ^) are connected, as well as an axially extending plug (107) one end of the inner part (90), which has a root (164) and a substantially cylindrical surface whose outside diameter differs from the total diameter of the Outer surface (166) of the remaining part the said housing half differs in such a way that one is essentially laterally oriented Surface (162) extends between the root (164) of the plug (I07) and said outer surface (166); wherein the connecting surface (9 ^) between the inner (90) and outer (92) parts of the housing half (20) follow a continuous line that extends in the substantially down to the generally cylindrical surface of the plug (IO7) extends. 5. Electrical connector according to claim 4, characterized in that the lines of the connecting surface (yk) have a part whose ψ diameter is smaller than the outside diameter of the plug (IO7) and its root (164) and which extends axially along a part of the plug (IO7) extends and its surface intersects a short distance (at point I78) from its root (l64). 6. Electrical connector, the components of which can be assembled in the price at the end of an armored high-voltage cable, consisting of a conductor surrounded by an insulating sleeve, which in turn has a conductive armor, the electrical connector consisting of: 10 9884/1173 a housing half made of elastomer material, which from an inner part made of electrically insulating elastomer and an outer part made of electrically conductive Elastomer, characterized in that said inner (100) and outer (102) parts along a substantially continuous and void-free suture surface (I76) are connected, as well as an axially extending recess (IO8) one end of the inner part (100) of the housing half (26) which has an open end (172) and a substantially cylindrical surface whose inner diameter smaller than the total diameter of the outer surface (17 ^) of the remaining part of the housing half (26) is such that a substantially lateral oriented surface (I70) between the end (172) of the recess (I08) and the named outer surface (17 ^) the housing half (26) extends; wherein the connecting surface (I76) between the inner (100) and outer (102) parts of the housing half (26) follows a continuous line extending substantially to the generally cylindrical surface the recess, (IO8) extends. 7. Electrical connector according to claim 6, characterized in that the line of the connection surface (176) intersects the surface of the recess (I08) at a short distance from its open end (172). 10988W1 173