CN1163018A - Electrical interconnections - Google Patents
Electrical interconnections Download PDFInfo
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- CN1163018A CN1163018A CN 95194862 CN95194862A CN1163018A CN 1163018 A CN1163018 A CN 1163018A CN 95194862 CN95194862 CN 95194862 CN 95194862 A CN95194862 A CN 95194862A CN 1163018 A CN1163018 A CN 1163018A
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Abstract
A 15 kv cable joint is enclosed within two half shells (38, 40) filled with sealant material (46). Displacement or thermal expansion of the sealant is accommodated by various configurations of stress cones that have apertures or surfaces that are flexible and arranged to maintain pressure on the sealant material (46) during thermal cycling of the joint.
Description
The present invention relates to electrical connector is protected.Said connector can be between two or many cables (promptly being series connection or branch joint), can be between two or more other electric equipments such as transformer and power distribution equipment, above-mentioned connector also can comprise another cable or cable and include cable adaptor and the equipment of termination between.Above-mentioned connector usually needs protect in order to avoid moisture enters in the lead of interconnection and need provide electric insulation on every side at this connector.In addition, when voltage surpasses about 10KV, there is also a desire for the electric stress control of certain form usually.The present invention generally is applicable to the electrical connector that is about usually under 1 to 10KV the low pressure, is about the electrical connector depressed in 10 to 36KV usually and usually greater than the electrical connector under the high pressure of 36KV.
Have the multiple technologies that are used to protect above-mentioned connector; wherein some technology more is applicable to certain voltage range and is not suitable for other voltage range; and some technology for example is applicable to the cable that a kind of material such as polymer is made and is not suitable for for example other cable of papery cable and so on.Include the hot charging shrinkage system of polymer, elastomeric propelling pierced billet system, elastomeric maintenance system, winding system, heated bitumen fill system and resin cast cold system in the above-mentioned technology.The U.S. Patent application that its content has been published in the unsettled Reychem of international application file WO95/11543 number discloses a kind of power cable connector No. 08/138360, and this joint is filled with and has found that the very compressible seal material of superperformance such as gel.
The present invention is specifically related to the connector between cable and other electric equipment, wherein, used polymeric seal material compressible and that preferably can oil expand, so that around this connector, form sealing and electric insulation be provided, and, one conductive component is arranged on around the above-mentioned connector in the mode of a faraday cell.
Therefore, according to one aspect of the present invention, a kind of encapsulation piece is provided, it is arranged to seal two connectors between the conductive component, above-mentioned encapsulation piece comprises that an outer rigid cap and is arranged on the conductive component in this outer cover, this conductive component is arranged to and can is in use done to electrically contact and seal this connector in the mode of sealing with described connector, wherein, basically filled up compressible encapsulant in the space between above-mentioned conductive component and the outer cover in use, and, above-mentioned conductive component is flexible, thereby can prevent basically in use that the hole is formed within the outer cover in the described conductive component outside.
Above-mentioned resilient, conductive member can be arranged to and can exert pressure to described encapsulant, forms the hole so that prevent basically in the sealing material or between the other parts of above-mentioned encapsulant and aforementioned connector.
At least one hole or gas hold back part be formed entirely between the aforementioned conductive component and/or the connector of this conductive component and said two conductive components between.
Above-mentioned encapsulation piece can be sealed the connector between a power cable and another electric equipment, and the lead of described power cable has constituted one of conductive component of the present invention, and described electric equipment itself can be another power cable.After this, said conductive component plays a faraday cell (Faraday Cage) and for example can seal a pair of lead that has connected that is positioned at a cable joint place.
Encapsulation piece of the present invention can comprise that also a stress eliminates awl, it be arranged on a cable around, said cable has then for example constituted an assembly in the aforementioned conductive component.Described stress cone preferably includes the elastic opening device, and it is arranged to change according to the change in volume of encapsulant the volume of self.
Above-mentioned encapsulation piece also can comprise an outer cover, and at least a portion wall of this outer cover is flexible, thereby can adapt with the change in volume of encapsulant.
Said connector can comprise positioner, and it is arranged to support said conductive component and keeps the position of these parts in encapsulant.
Said encapsulation piece can comprise and for example play the seal member that stress is eliminated the awl effect that the sealing parts preferably include: (a) assembly that rigidity arranged relatively; And (b) a resilient relatively assembly has at least one opening on this assembly.Above-mentioned have the assembly of rigidity to be arranged to resilient relatively assembly to be pushed fully be fitted in aforementioned sealing around the object basically relatively, therefore, above-mentioned seal member can hold different size, the multiple object of different-diameter normally, this object for example is a power cable, can keep this object that the sealing in good and essentially no hole is arranged simultaneously on every side.
Used in the present invention preferably by two be bonded with each other split the outer cover that shell constitutes, preferably make by conducting polymer materials with about 103 ohm-cm specific insulations.Its material preferably is mixed with the polypropylene of carbon.In addition, described outer cover can have the intraware of an insulation and the external module of a conduction, so that necessary function of shielding is provided.As for other possibility of outer cover, the push structure of on connector, extending or as No. 4868967 disclosed rotating casings of United States Patent (USP) in addition.The outer cover of sealing electrical connector preferably has the such wall of at least a portion, and it is subjected to the pressure of flexible seal material and bending, thereby can adapt to the change in volume of sealing material.Above-mentioned elastic wall face portion can be bonded in a non-resilient wall portions so that between limits a displacement cavity from the outside, can include elastic device in this cavity.Can also imagine most of outer cover surface (promptly>50%), preferably be that to seal the whole outer cover surface of encapsulant from outer rim all flexible basically.Said outer cover can be out of shape, and therefore, it can become the cross section that can seal the another kind of shape of larger volume from a kind of cross section of shape.For example, this outer cover can be arranged to become from the ordinary elliptical cross section cross section that is essentially circular.
Specifically, although be not exclusive, but when encapsulant is material such as the polymer that oil expands, if encapsulant seal by for example two split outer cover that shell constitutes around the time be under pressure, then in order to comprise the sealing material, thereby the closure edge of outer cover is preferably in and is having significant displacement and pressure to coincide before affacting above-mentioned encapsulant before finally closing up.For example, with regard to splitting with regard to the shell of two longitudinal extensions, can embed along the groove at other casing half edge along the flange on the vertical limit of casing half.Therefore, thus above-mentioned encapsulant can be included in the outer cover of sealing by circumference before it is laterally extruded outer cover there being enough pressure to act on the sealing material.
Also provide to be used to limit outer cover relatively it seals that object rotates and/or the device of lengthwise movement, the said object of sealing then for example is an electrical connector.
The flex section of closed cover or the flex section of other assembly that is positioned at the pressure that is subjected to encapsulant and includes the joint of sealing material are provided with in such a way, that is: this flex section can make encapsulant at random shrink, to avoid forming any air pocket.
Faraday cell (Faraday Cage) parts preferably are made of the thermoplastic material of conduction, and this material has the resistivity similar to conductive outer shield, but above-mentioned parts also can be made of metal or the plastic material that plates with metal.The faraday cell parts of above-mentioned conduction are preferably flexible so that encapsulant is exerted pressure, thereby can stop the outside that is positioned at the above-mentioned conductive component that is included in this outer cover in above-mentioned outer cover to form the hole substantially.Above-mentioned conductive component is preferably with at least one and is completely contained in these parts and the hole or the gas that are subjected to encapsulant pressure is held back part.The support that is used for faraday cell preferably is made of the thermoplastic material of insulation.Above-mentioned support unit can suitably link to each other with outer cover in case the faraday cell positioning parts that can positively make above-mentioned conduction within the encapsulant of plastically deformable.
The stress cone that uses among the present invention can be made of conductive rubber or elastomeric material, is 10 by common specific insulation for example
3The EPDM of ohm-cm constitutes.
Described encapsulation piece can comprise electric stress awl, this electric stress awl comprises the elastic opening device, it is arranged to change according to the change in volume of seal material the volume of self, thereby, can in use keep filling up fully basically the outer cover around the above-mentioned electrical connector and can not form the hole therein.
Should be realized that the material of the above-mentioned various compositions that use among the present invention all should be chosen to anyly become phase-splitting compatible and particularly not have the reaction that is harmful to this composition in the long time with contacted with it.
Usually need said sealing passing through with blocks air, moisture or other fluid.
Encapsulant of the present invention generally comprises any compressible encapsulant for example resin or grease (the particularly grease of suitable thickness such as silicone grease).But described encapsulant preferably includes hard gel.
Said gel for example comprises silicon gel, urea gel, SEBS, SBS, diblock and triblock copolymer and their mixture, urethane gel or any suitable gel or colloidal state encapsulant.The copolymer synthetic that best gel pack oil scraper expands.As use this base of a fruit Vincent-Wo Lande structural analysis instrument (Stevens-Voland Texture Analyser) is determined, described gel at room temperature preferably has certain rigidity, and this hardness is greater than 48g, specifically greater than 14g, particularly greater than 18g, for example between 18g and 29g.The testing setup value of above-mentioned analyzer should be: speed=0.2 mm/second; Penetration depth=4 millimeter; Sphere diameter=0.25 inch.Preferably have certain stress relaxation, this stress relaxation is less than 60%, specifically less than 50%, particularly less than 40% and more preferably greater than 10%.As determined according to ASTM D638, the critical elongation under the room temperature is more preferably greater than 100%, particularly greater than 200%, specifically greater than 400%.Drawing coefficient during 100% distortion is to be at least 1.8MPa preferably, is to be at least 2.2MPa better.In general, compression set should be less than 25%, particularly less than 15%.Best is, said gel has the cone penetration of being measured as ASTM D217, and this cone penetration is at least 50 (10
-1Mm), be preferably at least 100 (10
-1Mm), more preferably at least 200 (10
-1Mm) and preferably be not more than 400 (10
-1Mm), particularly be not more than 350 (10
-1Mm).With regard to other gel parameter, can be with reference to No. 4852646, United States Patent (USP), particularly with reference to Fig. 3 of this patent, it is illustrated in the relation between Wo Lande hardness (Voland Hardness) and cone penetration (Cone Penetration) value, and this paper has quoted the full content of above-mentioned patent.In addition, also can be with reference to No. 5079300 disclosed suitable materials of United States Patent (USP), this paper has quoted the full content of this patent.
In addition, the copolymer synthetic that is made of gel can for example comprise synthetic rubber or block copolymer, and this block copolymer has harder relatively block and relative softer elastomeric block.The example of above-mentioned copolymer comprises for example styrene-diene block copolymer such as styrene-butadiene or styrene-isoprene two blocks or triblock copolymer, perhaps comprises as international patent document WO88/00603 number disclosed styrene-ethylene-butadiene-styrene triblock copolymer.But said copolymer synthetic preferably includes one or more styrene-ethylenes-propylene-styrene block copolymer, for example comprises the copolymer that the Japanese Kuraray usefulness Septon of company trade mark is sold.Specifically, Septon 2006 is brands of a kind of the best.Employed swelling agent liquid preferably includes the oil that is generally used for making the elastomeric material expansion in the gel.Said oil can be as the hydrocarbon oil of alkane family or naphthenic oil and so on, as the artificial oil of polybutene or polypropylene oils and so on and the mixture of above-mentioned hydrocarbon oil and artificial oil.The best aromatic alkane of oily right and wrong and the mixture of cycloalkanes hydrocarbon oil.Said gel pack contains the known additive such as dehumidizer (for example benzyl chloride), antioxidant, colouring agent and bactericide.
Gel used in the present invention preferably has certain insulation disruptive strength, and this intensity is at least 18KV/mm, and more preferably greater than 24KV/mm, optimum range even can be up to 100KV/mm within 24 to 50KV/mm.Above-mentioned numerical value is not only applicable to into the gel of piece itself, and is applicable to gel and any composition surface between contacted with it other material of described connector inner gel.Best gel rubber material comprises the silicon gel, and it is a kind of silicon polymer that is mixed with inertia silicone oil.
According to presents, should be realized that " compressible " this term of encapsulant is meant such material in the literary composition, this material is compressible when being subjected to external pressure, thereby can be in plastic deformation around the object of being sealed.Said pressure comes from the outer cover that includes encapsulant, and encapsulant then for example acts on electrical connector in the mode of sealing around, and perhaps, above-mentioned pressure comes from the thermal expansion of encapsulant.At the optimal seal material is under the situation of gel, and described pressure can cause basically with the on all four distortion of aforementioned object and/or move, even also can keep this consistency under the situation of property heat cycle variation.
Said connector has the cylindrical configuration of being essentially usually.The present invention is specially adapted to such connector, and in this connector, outer cover comprises two or more assemblies that are bonded with each other, and for example comprises that two are split shell.In this structure, stress cone also preferably is made of a plurality of assemblies, and for example the awl of splitting by two phase amalgamations when outer cover closes up constitutes, therefore, said connector can with around mode suitably to be formed on for example be around the finished product electrical connector of connector presser.Suitable is, gel sealing material is provided as the filler that is included in the outer cover various piece, and the sealing material is sealed the composition surface between the various piece of outer cover then.The U.S. Patent application 08/138360 (WO95/11543) of unsettled Raychem discloses the particularly advantage of this structure when gel is used as encapsulant, and this paper has quoted the full content of above-mentioned patent.Specifically, the very high dielectric strength at the place, composition surface of two parts gel and gel can prevent from air pocket to occur and a kind of cable joint is provided between them to the good bonding force of the connector assembly such as cable material (normally polyethylene or polyvinylidene chloride) basically, and it for example has than the short a lot of length of first front connector.The joint of shorter length needs less cable preliminary treatment, thereby needs less process time, cable system is embedded in when underground particularly like this.
According to another aspect of the present invention, a kind of connector between cable and other electric equipment is provided, this connector is encapsulated in the encapsulation piece of first aspect of the present invention.
Said other electric equipment can for example be an another kind of cable or such as distributor that links to each other with above-mentioned cable or the equipment the transformer, or the miscellaneous equipment of above-mentioned cable institute termination.
Hereinafter will with reference to the Fig. 1 to Fig. 3 in the accompanying drawing encapsulation piece and connector be described especially, but, can imagine that the feature that the feature of other accompanying drawing is for example relevant with stress cone (Fig. 1 to Fig. 6 and Fig. 8), faraday cell (Fig. 1 and Fig. 3) and support unit (Fig. 1, Figure 21 and Figure 22) thereof and outer cover (Fig. 1, Fig. 6, Figure 14 to Figure 20 and Figure 23 to Figure 25) is also included within the connector that is used for above-mentioned encapsulation piece.The theme of the patent application that to be us submit to simultaneously with list of references RK502, RK505 and RK506 of some feature in these features, this paper has quoted the full content of above-mentioned list of references.
Followingly embodiments of the invention are described by way of example with reference to accompanying drawing, in the accompanying drawings:
Fig. 1 has roughly shown the profile of the tandem joint between the 15KV of two shieldings power cable connector, and it is used to show General Principle of the present invention;
Fig. 2, Fig. 2 A have roughly shown the first embodiment of the present invention, and wherein, the stress of joint shown in Figure 1 is eliminated the expansion that awl is arranged to adapt to the encapsulant of this joint;
Fig. 3 has shown that stress is eliminated the another kind of form of boring among Fig. 2;
Fig. 4, Fig. 4 A have shown another form of stress cone respectively in the mode of profile and isometrical drawing;
Fig. 5, Fig. 5 A have shown the another kind of form of cable connectors among Fig. 1 in the mode of profile and isometrical drawing respectively, wherein, can adapt to the expansion of encapsulant;
Fig. 6 has shown a kind of half part section of Improved connector;
Fig. 7 has shown another form of the stress cone that uses for Fig. 1 center tap;
Fig. 7 A has shown the cutaway view of stress cone among Fig. 7;
Fig. 7 B has shown the isometrical drawing of putting upside down of stress cone among Fig. 7;
Fig. 8 has shown another improved form that is used to adapt to the stress cone that encapsulant expands in Fig. 1 joint;
Fig. 9 has shown among Fig. 1 that employed outer cover and stress in the ordinary couplings structure eliminate half exploded view of the improvement structure of awl;
Figure 10 has shown the profile of the joint of Lian Haohou, and this joint has used stress cone shown in Figure 9;
Figure 11 and Figure 12 are half the isometrical drawings of rear end of a modified model roll adjustment stress cone;
Figure 13 A, Figure 13 B and Figure 13 C have roughly illustrated the device of the faraday cell that can be applicable to Fig. 1 center tap, and this device is used to adapt to the expansion of the encapsulant of described joint;
Figure 14 has roughly shown a kind of improved form of the outer cover of Fig. 1 joint, and it is used to adapt to the expansion of encapsulant;
Figure 15 has shown the another kind of improved form of Fig. 1 outer cover;
Figure 16 has shown half isometrical drawing of another improved form, and wherein, a complete insert has guaranteed the expansion of gel and comprised stress cone;
Figure 17 and Figure 18 have shown respectively the section along B-B line among Figure 16 and A-A line;
Figure 19 and Figure 20 have roughly shown a kind of improved form of the outer cover of above-mentioned joint, and it is made up of three assemblies;
Figure 21 has roughly shown a kind of like this structure, in this structure, when sealing the faraday cell of cable joint with nonrigid material, can support this faraday cell;
Figure 22 has shown another embodiment of the supporting member that is used for faraday cell;
Figure 22 A has shown a kind of profile of a part of joint, and this joint has used the supporting member among Figure 22;
Figure 23 and Figure 23 A have shown that with the form of profile one splits the embodiment of seal of the longitudinal edge of shell along two of the outer cover of above-mentioned joint;
Figure 23 B has shown the profile of an Improved connector, and it shows a vertical containment device;
Figure 24 is the isometrical drawing of an embodiment of the joint after connecting; And
Figure 25 is the end view of another embodiment of outer cover.
With reference to Fig. 1, said tandem joint is formed between two substantially the same polymer cables 2,4.Prune corresponding external jacket 6,8, shielding conductor 10,12, screen (semiconductive or conduction) 14,16, main insulating layer 18,20 and lead 22,24 successively in the mode of standard, shielding conductor 10,12 is folded on the corresponding sheath 6,8 so that carry out subsequently cross-over connection in the (not shown) that interconnects at above-mentioned joint two ends, thereby keeps the continuity of ground connection.Although can use the connector of any other suitable type, used a crimp connector to implement the electrical connection of lead 22,24.With comprising that two are generally the semi-cylindrical parts of shell 28,30 of splitting to the control of formed lead connection carrying out electric stress, said split that shell is made of the polymeric material of conduction and the housing 26 between above-mentioned two cables around be incorporated into together, and the above-mentioned shell of splitting longitudinally extends a bit of distance on cable insulation 18,20.Each is split shell 28,30 and all has three inside flanges 32, they and crimping connector 26 done to electrically contact, thereby guaranteed describedly to split shell 28,30 and be encapsulated in this and split the interior conductive component of shell and have identical current potential that the current potential of above-mentioned cable conductor is promptly arranged.Therefore, split shell 28,30 and can around crimp 26 and the lead that exposes 22,24, provide the faraday cell effect.Should be noted that splitting shell 28,30 is not sealed on the cable insulation 18,20.
Eliminate awl 34,36 for corresponding cable 2,4 provides stress, they are positioned to and can provide conical surface in common mode, and this surface deviates from the cutting end of corresponding shield parts 14,16. Stress cone 34,36 is made by conductive rubber, and each stress cone all is arranged to a pair of awl of splitting, so as after the electrical connection that has formed between the cable 2,4, to be assembled into cable 2,4 around.
The electric insulation support that forms by two half- cylindrical assemblies 42,44 links to each other with the outer surface of faraday cell 28,30 and links to each other with the inner surface of outer cover 38,40, thereby can make faraday cell 28,30 vertically and directly upwards being positioned within the described joint really, be electrically insulated from the said external outer cover so that guarantee faraday cell.
Be in the outer cover 38,40 around support 42,44 and the faraday cell 28,30 and within, and the space that links to each other with stress cone 34,36 in the vertical filled up the silicon gel 46 of electric insulation.
By being placed into corresponding outer cover, corresponding support 42,44, faraday cell 28,30 and stress cone 34,36 split in the shell 38,40, pour liquid, the gel 46 that do not solidify form into each and split the edge of shell until this shell, gel is solidified, just the assembled of aforementioned joint can be got up.Then, handle cable 2,4, lead 22,24 connected together with crimp 26 by cutting, after this, by ready outer cover is split shell 38,40 be clamped to cable 2,4 around insulation is provided, reduce stress and form shielding.Link the surface combination that can make each several part gel 46 be generally the plane together to together with splitting shell 38,40, this just can not only provide the composition surface of gel to the high insulation resistance of gel in half-open shell intersection, and the composition surface of high insulation resistance can be provided on the assembly that is encapsulated such as insulator 18,20 of cable 2,4.
When above-mentioned two were split shell 38,40 and connecting good cable 2,4 periphery seals and get up, gel 46 will be under pressure, thus can be around above-mentioned all component plastic deformation and fit with these assemblies.Therefore, can squeeze away connecting good cable ambient air, the gel 46 that has been out of shape can occupy the position of above-mentioned air.Should be noted that gel 46 can fill out the edge of splitting shell 38,40 basically before sealing.So, in case around connecting good cable, seal, just having a certain amount of gel 46 and produce displacement, the structure of said joint must can adapt to this situation.In addition, the variation heat cycle of power cable 2,4 also can cause gel to expand, and also must can adapt to this situation.Hereinafter the embodiment of disclosed joint has solved the problems referred to above.
The unsettled U.S. Patent application 08/138360 (WO95/11543) of Raychem company number has provided the general structure of above-mentioned joint and the details and the feature of assembly, and this paper has quoted the full content of this patent.
Following Fig. 2 to Figure 25 illustrates in greater detail each the version according to different aspect of the present invention in the concrete feature of cable joint among Fig. 1 and these devices.Should be realized that all combinations of two or more features as herein described all are considered to embodiments of the invention, unless this combination obviously can not be operated.
With reference to Fig. 2 and Fig. 2 A, being two stress cone 34A that are generally the semicolumn component form is the improved forms that have the stress cone 34 of basic structure among Fig. 1.Thereby this stress cone is formed in the outer cover 40 and defines an annular cavity with this outer cover.Awl 34A extends to the direction of leaving interlayer 14 edges, and the leading edge 53 of awl 34A then is sealed on the outer cover 40.
As can be seen, gel 46 has filled up volume in the outer cover 40 around the insulator 18 of cable.Shown in Figure 2ly gone out cable joint structure when mounted, wherein, cable is not powered and cools off.In use, the lead of cable can reach the working temperature up to 95 ℃, in some cases even can reach higher temperature.In this case, can expand at the volume of about 200 grams usually in the joint up to 20% to the gel between about 300 grams.Under the situation that outer rigid cap 40 is arranged, this expansion must can be inclusive within the structure of joint.In the present embodiment, the expansion that gel 46 acts on the soft relatively rubber of stress cone 34A can be pushed hole 50, shown in Fig. 2 A.When gel 46 shrank because of cooling, the elasticity of awl 34A, the elasticity of its leading edge 52 specifically can keep the sealing load of gel around each assembly of joint thereby can act on gel.Therefore, owing to all can maintain enough pressure on the gel 46 in all cases, so, can stop formation hole in the zone that is subjected to higher electric stress around the adapter assembly, the described zone that is subjected to higher electric stress then is positioned between two stress cone 34A and 36A (latter is not shown) that are arranged at the joint two ends symmetrically.Should be noted that by hole 50 is suitably located, can make the certain radial distance of leading edge 52 of stress cone 34A produce distortion, therefore, can not reduce the control of the electric field that the cutting end of screen 14 is located at least in any significant mode in cable 2 outsides.
Fig. 3 shows the another kind of modified model stress cone 34B that is positioned at outer cover 40, wherein, is made the opening 60 at place, the radially outer end of this stress cone near the inlet of gels 46 by the piston 62 of spring 64 outside bias voltages.Therefore, when gel 46 expands, the pressure that puts on the piston 62 can make this piston enter opening 60 against the elastic force of spring 64, when gelinite 46 relaxes, the restoring force of spring 64 can keep the pressure to gelinite 46, thus can stop joint be subject to electrical interference the zone in formation any undesirable hole.
Fig. 4 and Fig. 4 A show the another embodiment that stress is eliminated awl, and this stress is eliminated the expansion that awl is arranged to adapt to the gel in the joint that has Fig. 1 structure usually.Elasticity awl 34C among the figure is installed in the outer cover 40 and has an opening 70, and the inwall of this opening and this awl is adjacent.Opening 70 is open, so as to receive gel 46 and allow the gel turnover in rear end promptly in the inside that is bonded in the stress cone of wall portions 72 away from the place, end in coupling compression joint zone, wall portions 72 then plays the interlayer of an expanding chamber 74.So in use, the volume increase meeting of gel 46 is applied to pressure on the interlayer 72 by opening 70, therefore interlayer 72 can be expanded, and when gel was lax, 72 of interlayers can return to the not state of expansion of its nature.
The Improved connector structure of Fig. 5 and Fig. 5 A shows a stress cone 34D, is equipped with a columniform atubular extension portion 80 on the front end of this stress cone, and this extension ends at a flange 82, and this flange then is fixed on the inwall of outer cover 40D.Outer cover 40D is in that thereby some is arch and has formed a cavity 84 near the circumference of the awl extension 80, and extension 80 then is mounted to the flexible interlayer of this cavity of leap.Therefore, the volume increase meeting of joint inner gel 46 is pushed extension 80 become and is partly put in the cavity 84.So, when variations in temperature causes gel volume to increase or reduces, can maintain continuous pressure on the gel 46.Shown in Fig. 5 A, cavity 84 communicates to prevent to form vacuum with the zone that is positioned at awl 34D rear portion by a passage 86.As can be seen, inflation cavities 84 is only extended around circumferential section ground that each of outer cover split shell 38D, 40D from Fig. 5 A, thereby makes and be included in splitting gel in the shell and can sealing this on the edge and split shell of joint.Be the whole extension of stress cone 34D as shown in the figure but also can be that the part 80 of a stand-alone assembly directly is bonded in outer cover 38D, 40D along the longitudinal edge of outer cover 38D, 40D two positions of splitting the amalgamation of shell phase, be trapped between part 80 and the outer cover to stop air.
In a kind of improved form with Fig. 5 and Fig. 5 A principle, outer cover 38,40 is not the arch of cavity qualification such as the label 84, but extends on interlayer part 80 and contact with this part as a right circular cylinder.In this structure, can be to be independent of the extension 80 of assembly of stress cone 34,36 except that along aforementioned longitudinal edge, not being bonded in equitant outer cover.Therefore, when gel 46 shrank, part 80 can be under via the action of air pressure of through hole 86 moves apart the inwall of outer cover actually with gel towards the motion at joint center.Can imagine that assembly 80 comprises a part along the complete linear extension of joint longitudinal direction.In the present embodiment, assembly 80 also can be bonded in outer cover 38,40 in the zone that surrounds faraday cell 28,30, so that keep the electric geometry of joint in this zone.
Fig. 6 shows half a part of joint 600, and said joint combines the principle of Fig. 3 and Fig. 4 embodiment.Sealing with splitting the passage 604 that shell 602 has a longitudinal extension of joint 600, this passage is positioned at this outer wall of splitting shell and extends along above-mentioned almost whole length of splitting shell at a circumferential location.(only show this passage half) all is fixed with a spring 606 and piston 608 in each of fixed length passage 604 half.One basically the stress cone 610 of splitting of rigidity be positioned at and split shell 602 and have a passage 612, upper channel is positioned on the outer surface of above-mentioned stress cone and extends to the rear portion of awl 610 and interlink with outer cover passage 604 from boring 610 front ends towards the gel-filled body 614 of joint.Therefore, gel 614 can flow through between awl 610 and outer cover 602 passage 612 and enter outer cover passage 604, thereby act on or acted on the piston 608 of spring bias voltage so that hold moving or expansion of gelinite.
Another modified model stress cone 34E among Fig. 7, Fig. 7 A and Fig. 7 B is equipped with as above with reference to Fig. 5 and Fig. 5 A described modified model interlayer device and certain roll-setting gear.Therefore, awl 34E front end promptly has an opening 90 (Fig. 7 A and Fig. 7 B) on the conical surface of gel, and specifically shown in Fig. 7 A, Fig. 7 A shows the section of above-mentioned stress cone.Gel 46 (not shown) enter opening 90 and power are applied on the outer surface that stress cone plays interlayer 92 effect, thereby extend into one with in the described similar mode of reference Fig. 5 and Fig. 5 A is formed on displacement cavity on the outer cover (not shown), said cavity is formed on outer cover and seals and bore on 34E main body that part of.In addition, the rear surface of opening 90 is to play an interlayer to the described similar mode of reference Fig. 4 and Fig. 4 A.
Stress cone 34E also has roll-setting gear, and roll-setting gear can make above-mentioned stress cone be used for the cables with different diameters in the given range.Therefore, have three openings 96,98,100 in the stress cone 34E, these openings lead to the rear surface (Fig. 7 and Fig. 7 A) of stress cone and define two path 10s 2,104 between these openings, and these two passages laterally extend in the said stress cone and partly extend into above-mentioned stress cone from aforementioned rear surface in mode longitudinally.Hereinafter with reference to Fig. 9 and Figure 10 illustrate stress cone 34E roll adjustment ability operation and with the cooperating of outer cover.
When gel 46 rose to some extent because of the temperature rising in use of the cable after sealing and/or because of the rising of the ambient temperature around the outer cover 40 temperature, previous embodiment allowed gel 46 volumetric expansions in the joint.But, owing under the common state of joint, also be the butt joint most of the time in useful life, gel 46 always is in heating status and therefore expands, so, can imagine the contraction in the time of for example should be able to adapting under some situation the power breakdown via cable.Above-mentioned gelinite moving structure depends on the motion of an elastomeric element, this moving structure can be arranged in to be in relaxed state when gel expands and to spread apart when gel cooling and volume reduce, so that keep pressure on the gel.Fig. 8 shows an embodiment of said structure, and wherein, stress is eliminated awl 34F and had an opening 110, and this opening portion ground is positioned at above-mentioned stress to be eliminated on the awl excircle adjacent with outer cover wall 60F.Outer cover 60F has a kerf part 112, and this notch portion and opening 110 are adjacent but separate mutually with aforementioned opening by the flexible diaphragm 114 that is fixed on the described notch portion.Notch portion 112 is led to the rear portion of stress cone 34F.With barrier film 114 and be arranged to make gel 46 after expanding under the normal operating state of joint can fill up opening 110 being connected of outer cover 60F and barrier film 114 is in relaxed state.When thereby cooling gel 46 shrank, barrier film 114 will be subjected to the extruding from the excess air pressure of air chamber (not shown), thereby expanded, extends into opening 110 and be in the position shown in the dotted line, therefore can keep the pressure on the gel 46.
Should be noted that with reference to the described principle of Fig. 8 also to be applicable to other structure, for example be applicable to reference to Fig. 5 and the described structure of Fig. 5 A.
Fig. 9 and Figure 10 eliminate awl with the stress that is applied to use for for example Fig. 1 center tap and show the embodiment of a roll adjustment structure as example, and said roll adjustment structure is used for forming sealing elongated the sealing on of object with different-diameter.Outer cover 160 is that polypropylene material constitutes and is two and is generally columniform form (only showing one of them) of splitting shell by the conducting polymer that relative stiffness is arranged.All be equipped with two substantially parallel and plain-straight-face flange inwardly or fins 162 on each end of outer cover 160, they are used for and corresponding stress elimination awl 164 engages, and each stress is eliminated awl and also formed two cones of splitting.Stress cone 164 is by having flexible relatively conductive rubber material to constitute and having groove 166, and these grooves are used to receive corresponding flange 162.As can be seen from Figure 10, when described two structures of reference Fig. 9 are incorporated into a time-out around cable 168, the soft material of the stress cone 164 that has been shaped can extend on the external diameter of cable 168 and can be separated along the composition surface 170 of the two halves of joint encapsulation piece.But the rigidity that extends into the fin 162 of the stress cone 164 that is positioned at cable 168 both sides can stop stress cone 164, and 170 places move apart cable 168 on the composition surface.
In Fig. 9 and example shown in Figure 10, have opening 172 in the flexible material of stress cone 164, the rear portion that these openings lead to conical surface promptly is in away from the surface in coupling compression joint zone and be located at the next door of the groove of being strengthened by fin 162 in the structure that assembles 166.Opening 172 can impel the inner surface of stress cone 164 to expand on cable 168 so that hold the cable of large-size, and 170 places keep cable excellent sealing on every side on the composition surface simultaneously.Central opening 172 specifically defines an inner semi-cylindrical barrier film, and it can stretch around cable 168, and the reinforcement flange 162 of rigidity then is consistent the cable 168 that the two halves of cone 164 are pushed Yu 170 places are encapsulated on the composition surface.
The reinforcement that is bonded with each other that should be noted that Fig. 9 and Figure 10 not applied stress is eliminated awl and just can be consistent with the elongated object of sealing.This principle can for example be used for providing sealing or as a sleeve pipe, in this sleeve pipe, have cable penetration one guard shield of a kind of diameter in the multiple diameter around a rotating shaft.
With reference to Figure 11 and Figure 12, half cone 800 of being made by conductive rubber material is improved forms of half cone 164 among Fig. 9 and Figure 10.Should note, similar to half cone 164, half cone 800 has the front end of sealing, and, above-mentioned cone will be placed on each end of splitting shell, and the said shell of splitting has then constituted cable joint encapsulation piece (Fig. 1 and Figure 12 only show a part of splitting shell) on every side.One bigger opening 802 locate in the rear end (as shown in the figure) of half cone 800 to extend to this cone sealing front surface and sealed by half housing 804 diametrically.Opening 802 is divided into three parts by a pair of fin 806.This to fin then roughly radially to extend with inner surface that half cone 160 of fin 162 relative outer covers shown in Fig. 9 embodiment is extended similar relative half housing 804 of mode.Fin 806 is arranged in the both sides that are positioned at the joint inner cable in the use.Half cone 800 inboard relatively thin wall portions of locating 808 is arch, thereby can in use fit in the internal freedom end of entrapped cable and reception and guiding fin 806.As shown in figure 11, fin is positioned comparison near the position of the joint longitudinal axis, thereby makes the length of arcuate part of inwall 808 of half cone 800 for minimum.In the above-mentioned position of fin 806, half cone 800 can be consistent with the cable (not shown) that minimum diameter is arranged.As can be seen from Figure 12, fin 806 has certain flexible, and this flexible outward-dipping and feasible one section bigger arcuate walls face portion 808 of fin that makes is extended between above-mentioned fin.In this state, half cone 800 can cause mutually with the cable of maximum gauge.Should be noted that with the embodiment of Fig. 9 and Figure 10 differently, the inner surface 808 of half cone can not extend in the present embodiment.But the existence of fin 806 still can not have air pocket to appear at the complete basically stickiness that has around the cable of cone in multiple size of guaranteeing under the situation at place, composition surface that near the cable surface two split awl altogether.The flexible meeting that should be noted that fin 806 makes fin outward-dipping but can make fin 800 comparatively soft resilient material has relative rigidity with respect to splitting cone around larger-diameter cable.
Figure 13 A and Figure 13 B and Figure 13 C show in order to the another kind of method that guarantees that gel 46 expands in Fig. 1 center tap, and above-mentioned each accompanying drawing has not all gone out according to faraday box shown in the label among Fig. 1 28,30 to improve the faraday cell that forms.With reference to Figure 13 A, split shell 28A, 30A for two and constitute by flexible conducting polymer materials and include three openings 120.When gel 46 expands, have the pressure that has increased and act on shell 28A, the 38A that splits, above-mentioned shell then can be out of shape because of the extruding of opening 120.Thereby the cooling of gel can cause the volumetric expansion of opening 120 can keep pressure on the gel 46.
Figure 13 B and Figure 13 C show a kind of improved form of structure among Figure 13 A, wherein, the end of splitting shell 28B and 30B all is sealed on the insulator 18,20 of cable, thereby defines two openings 122, and these two openings are positioned within faraday cell 28B, the 30B of lead after the crimping.Shown in Figure 13 C, when gel 46 expanded, opening 122 was split shell 28B, 30B and is curved inwardly and adapt to the increase of gel pressure by making.
Figure 14 and Figure 15 disclose two embodiment with Fig. 1 center tap principle, and wherein, a kind of improved form of outer cover 40 structures can adapt to the change in volume of encapsulant 46.
In the embodiment of Figure 14, the outer cover 40C that is generally rigidity is equipped with flexible wall 130 as its surperficial part, and above-mentioned flexible wall will be subjected to being included in the pressure of gel 46 (not shown) in the described outer cover.In use can to have rigidity by buried whole outer cover 40C in order making, the cover cap 132 of a rigidity to be arranged to be enclosed within on the flexible wall 130 so that limit a cavity with this wall.The elastomer block 134 that is made of rubber is placed within the said cavity.Therefore, when gel 46 expanded, flexible wall 130 can make have pressure to remove elasticity of compression piece 134 against the resistance of outer rigid cap 40C, and when gel 46 shrank, then wall 130 can keep the pressure on the gel to form the hole to stop around joint.
The embodiment of Figure 15 is arranged to obtain the effect identical with the embodiment of Figure 14, but, in order to reach this purpose, per half outer cover 40D constitutes by elastomeric material and have a circumferential section 140 that has than thin cross section near stress cone 142, thereby adapts to any increase of gel volume and gel is applied restoring force so that can expand in the mode of the best.
With reference to Figure 16, Figure 17 and Figure 18, one elongated half-cylindrical whole rubber module 1000 has thin wall mid portion 1002 (Figure 17) and an a pair of thicker wall end sections 1004, is formed with on this inboard to end sections and splits stress cone 1006 (Figure 18).Module 1000 is arranged to imbed in the plastic outer housing 1008 of a rigidity, and this housing is separated along at least a portion and the module 1000 of mid portion 1002.Mobile or the expansion of the gel-filled material in the module 1000 can make mid portion 1002 bendings that the expanding chamber that is provided by the said external housing is provided, and said housing then preferably is made of a pair of shell of splitting of the joint after engaging.
The inner rigid supporting member 150,160 that is illustrated with reference to Figure 21, Figure 22 and Figure 22 A hereinafter can be merged into rubber module 1000 and embed by the mode that cooperates with clamping in the external shell of above-mentioned plastics and locate.
With reference to Figure 19 and Figure 20, be shown schematically in two cables 1140 and 1142 and linked together at label 1144 places.Have finger 1148 on the end of one elastic insulator 114 of reeling, these finger are tapered so that consistent with the diameter that has reduced of the cable 1140,1142 of connector area 1114 both sides.One columniform encapsulation piece 1150 when beginning scroll to each cable 1140,1142.Encapsulation piece 1150 is made of the rubber of conduction.
Figure 20 shows the joint that part engages.The insulator 1146 of splitting shell rather than being made of winding-structure like that as shown in the figure that can comprise a pair of phase amalgamation has been sealed the gel rubber material 1152 of insulation and can have been included the solid insulating material of sealing this gel sealing material.Insulator 1146 is encapsulated in around the joint 1144, and finger 1148 then is retracted on the cable 1140,1142.There is shown encapsulation piece 1150 its stop place stretching, extension on cable 1140 relatively already of a conduction, thereby extend into the more than half part of just crossing over insulator 1146.After this, rest on still that another encapsulation piece 1150 on the cable 1142 also can stretch in case with above-mentioned first encapsulation piece overlaid.In this way, including the insulator 1146 of finger-like end 1148 and whole cable joint district all can be encapsulated within the external component 1150 of two conductions.
Figure 21, Figure 22 and Figure 22 A disclose the embodiment of cable joint, wherein, conductive component such as faraday cell can be supported within the described joint when being sealed by nonrigid material, and specifically, above-mentioned conductive component can be with the relative conductive outer shield of the mode of determining location.
In Figure 21, the faraday cell 280 of arch is made by the polymeric material of conduction, and be arranged on as described above in the silicon gel sealing material 46, above-mentioned faraday cell (by unshowned device) radially is interval in the crimping lead (not shown) that is encapsulated and axially is positioned between stress cone 34G and the 36G.Said these assemblies all are encapsulated within the outer cover 40, and outer cover 40 then is made of the polypropylene that has added conductive filler.In some cases, particularly when the temperature of gel 46 increased, will have such possibility promptly: the faraday cell 28C of conduction laterally shifted in gel 46 and is in earthy outer cover 40, thereby the high pressure of cable conductor has formed a short circuit relatively.In this enforcement, utilize the polymeric support or the separator 150 of an insulation can stop faraday cell 28C to move.Support 150 be arch and be installed in faraday cell 28C and outer cover 40 between the annular gap in, and similar to aforementioned components, be to constitute with two forms of splitting shell.All be equipped with series of flanges on each of separator 150 half, these flanges are positioned on the curved surface of separator, thereby separator 150 and faraday cell 28C and outer cover 40 are separated, so that gel 46 fills up this separator space on every side basically fully.Separator 150 is arranged to can be for example make good physical engagement by interlocking flange and opening and/or a clamping adapting device with faraday cell 28C and outer cover 40, thereby all the faraday cell 28C of conduction is firmly held in the appropriate position in the joint diametrically and vertically.
Figure 22 and Figure 22 A show the another kind of version of the supporting member that uses for faraday cell.With reference to these two accompanying drawings, the polymeric support elements 160 of insulation has local half cylindrical structure and has flange at the place, end, so as to provide when in use being used to support faraday cell 28 one be positioned at supporting member 160 and outer cover 60 circular passage 162.Shown in Figure 22 A, this figure is one the section in the casing assembly split of joint, and it is half-cylindrical completely that faraday cell 28 and outer cover 60 all are, therefore, when their around lead (not shown) of crimping with accordingly to and shell when lumping together, their cylindrical surface will close up.But, two of above-mentioned supporting member split shell (only show one of them 160) and extend less than 180 degree, and zone and passage 162 between these two shells are filled by gel 46, thereby the radial engagement face of gel to gel can be provided between faraday cell 28 and outer cover 60 when splitting shell enclosure to crimp region with these two.Supporting member 160 can the mechanically faraday cell 28 of its corresponding casing half and outer cover 40 phase interlockings as the embodiment of reference Figure 21 is illustrated, thereby faraday cell 28 is positioned within the joint securely.
But, support dividers 150,160 needn't with the conterminal mode longitudinal extension of relevant faraday cell.
In another embodiment, can imagine that described supporting member can be molded as integral body with faraday cell and/or outer cover.In this structure, the molded operation of supporting member can be discharged air the molded surface of this supporting member, thereby has avoided making gel 46 can pass in and out any composition surface between supporting member and faraday cell and/or the outer cover.
Figure 23 shows two kinds of different structures with Figure 23 A, utilizes this two kinds of structures, and two longitudinal edges of splitting shell of the outer cover of cable joint are interlocked together.In above-mentioned two kinds of situations, edge 180, a 180A all are equipped with groove 182, the 182A along its extension, and they have the keyhole formula cross section shown in trapezoid cross section shown in Figure 23 and Figure 23 A.Be full of gel in groove 182, the 182A, said gel is preferably identical with the sort of gelinite of the one-tenth piece insulator that can constitute joint.Flange 186, the 186A of respective shapes be equipped with on the opposed edges 184 of outer cover, the 184A.Two of outer cover are being split shell enclosure around the described electrical connector time, flange 186,186A will engage with relevant groove 182,182A, and said gel then can form sealing between them.
With reference to Figure 23 B, it is shown schematically in the cross section of a cable that connects at label 200 places, is embedded in the gel 202 above-mentioned cable section, and gel 202 then is included in a pair of various piece of splitting shell 204,206.Split shell 204,206 and be half-cylindrical and hinged at label 208 places basically along pair of longitudinal edges.Split the cylindrical jacket that has been hinged together that shell constitutes by above-mentioned two and be encapsulated in around the described cable that has connected, Figure 23 B represents the just situation before closing up outer cover.Split shell 204,206 relative with articulated elements 208 to longitudinal edge on joint tongue 210 and the groove 212 that matches be equipped with along most of length of outer cover, outer cover then include to be pushed be extruded into fit in be encapsulated connect gel 202 around the good cable.Joint tongue 210 along the circumferential direction has such length promptly: when splitting shell 204,206 when closing two, this joint tongue engages with groove 212 before will being enough at the pressure on the gel 202 gel laterally extruded outer cover.In this way, all gels 202 all can fully be included within the outer cover that closes up with circular, fashion, thereby have avoided any may cutting of gel cut, and this shearing can cause having in the outer cover hole to form afterwards.
Utilization can be split shell 204,206 with two along a plurality of discrete flanges 214 of joint tongue 210 outer surfaces and positively be locked onto together, and said flange then is stuck in the opening that matches 216 on groove 212 outer walls.
By a convex ridge 218 is provided around the whole edge of casing half 206, can seal up outer cover, in case moisture, air, dust or other impurity around should outer shroud rim invades at two places, composition surfaces of splitting shell 204,206, above-mentioned convex ridge then engages with the marginal trough portion 220 of the pairing usefulness on the mode that seals and the casing half 204.
At last, can or can split outer cover with above-mentioned two at outer cover outside other the suitable fastener that uses that has closed up with crank pincers is secured together.
With reference to Figure 24, the joint between two shielded type cables 1160,1162 is encapsulated in a pair of assembly outer cover 1164.Each end place at outer cover 1164 all axially cuts out a slit 1166 in the mode of vertical alignment, and the shielding conductor 1168,1170 of cable 1160,1162 exposes via slit 166 respectively and is crimped on together in label 1172 places on the surface of outer cover.By the way shielding conductor 1168,117 is linked together and they is embedded in the slit 1166, can stop outer cover 1164 in rotary manner or in mode longitudinally with respect to connecting good cable movement.
With reference to Figure 25, outer cover 1180 is made of two semi-cylindrical shells of splitting, and splits shell joint tongue and groove structure hinged in label 1182 places along the core of outer cover and that be positioned at around the amalgamation edge of these two shells for these two and seals.Towards the outside of the tapering part of outer cover 1180 ends, have a cylindrical part 1186 to be formed between a pair of rib 1188, said this to rib then round the circumferential extension of outer cover.Maybe can be wrapped in cylindrical jacket part 1186 similar device on every side with adhesive tape, package strip, wind spring outer cover 1180 is fixed to connecting on the good cable of being encapsulated.In order to be sealed to outer cover on the cable and to help outer cover is fixed on the cable, is placed with resin or other encapsulant between cover part 1186 and the beneath cable cover(ing).Said encapsulant can be used as covering and is applied to cable, perhaps by outer cover 1180 clampings.
Claims (14)
1. encapsulation piece, it is arranged to seal two connectors between the conductive component, above-mentioned encapsulation piece comprises that an outer rigid cap and is arranged on the conductive component in this outer cover, this conductive component is arranged to and can is in use done to electrically contact and seal this connector in the mode of sealing with described connector, wherein, basically filled up compressible encapsulant in the space between above-mentioned conductive component and the outer cover in use, and, above-mentioned conductive component is flexible, thereby can prevent basically in use that the hole is formed within the outer cover in the described conductive component outside.
2. encapsulation piece, it is arranged to seal two connectors between the conductive component, above-mentioned encapsulation piece comprises that an outer rigid cap and is arranged on the conductive component in this outer cover, this conductive component is arranged to and can is in use done to electrically contact and seal this connector in the mode of sealing with described connector, wherein, basically filled up the polymeric seal material that can oil expands in the space between above-mentioned conductive component and the outer cover in use, and, above-mentioned conductive component is flexible, thereby can prevent basically in use that the hole is formed within the outer cover in the described conductive component outside.
3. encapsulation piece as claimed in claim 1 or 2 is characterized in that, said elastomeric element is arranged to and can be in use exerted pressure to aforementioned encapsulant.
4. the described encapsulation piece of any one claim as described above, it is characterized in that, said conductive component has at least one hole or gas is held back part, and it is completely contained within this conductive component and bears the pressure of described encapsulant by this resilient, conductive member.
5. as any one described encapsulation piece in the claim 1 to 3, it is characterized in that, having at least a hole or gas to hold back part in use is arranged to be included between aforementioned conductive component and the connector in the mode of sealing, this connector is then between said two conductive components, and above-mentioned hole or gas are held back part is born described encapsulant by aforementioned resilient, conductive member pressure.
6. the described encapsulation piece of any one claim as described above is characterized in that said encapsulant comprises gel.
7. the described encapsulation piece of any one claim as described above, it is characterized in that, this encapsulation piece comprises stress elimination awl, this awl be arranged in use one of conductive component in the described outer cover around, and, this stress cone comprises the elastic opening device, and it is arranged to change according to the change in volume of above-mentioned encapsulant the volume of self.
8. the described encapsulation piece of any one claim as described above is characterized in that, said outer cover comprises the outer surface of a conduction.
9. the described encapsulation piece of any one claim as described above is characterized in that, said outer cover comprises that an elastic part is with the change in volume that adapts to described encapsulant or move.
10. the described encapsulation piece of any one claim as described above is characterized in that said outer cover comprises at least two parts that are bonded with each other, and each part all can be sealed a part of living in to state conductive component and the part of encapsulant.
11. the described encapsulation piece of any one claim is characterized in that as described above, this encapsulation piece comprises positioner, and this device is arranged to support aforementioned conductive component and is kept the position of this conductive component in described encapsulant.
12. the described encapsulation piece of any one claim is characterized in that as described above, said stress cone comprises: (a) assembly of a relative stiffness; And, (b) resilient relatively assembly, and, described stiff member be arranged in use above-mentioned elastic parts to be pushed fully be fitted in basically described cable around.
13. an electrical connector, wherein, two conductive components that are electrically connected are being encapsulated near their junction within the described encapsulation piece of aforementioned any one claim.
14. encapsulation piece as claimed in claim 13 is characterized in that, at least one assembly in the described conductive component preferably two assemblies includes a power cable.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN 95194862 CN1163018A (en) | 1994-07-11 | 1995-07-10 | Electrical interconnections |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB9414038.1 | 1994-07-11 | ||
CN 95194862 CN1163018A (en) | 1994-07-11 | 1995-07-10 | Electrical interconnections |
Publications (1)
Publication Number | Publication Date |
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CN1163018A true CN1163018A (en) | 1997-10-22 |
Family
ID=5082866
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN 95194862 Pending CN1163018A (en) | 1994-07-11 | 1995-07-10 | Electrical interconnections |
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CN (1) | CN1163018A (en) |
Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
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CN101170247B (en) * | 2006-10-27 | 2010-05-19 | 3M新设资产公司 | Re-accessible connector enclosing cover |
CN101203992B (en) * | 2005-04-12 | 2010-12-01 | 赛尔派克有限公司 | Two- or multiple-piece insulating body system for producing medium high voltage cable fittings |
CN101467319B (en) * | 2006-06-07 | 2012-06-13 | 3M创新有限公司 | Method of making closure housing for sealing |
CN101467321B (en) * | 2006-06-07 | 2012-11-28 | 3M创新有限公司 | Sealing apparatus |
CN104620444A (en) * | 2012-04-18 | 2015-05-13 | 泰科电子有限公司 | Cable connector systems and methods including same |
CN104145388B (en) * | 2012-02-29 | 2017-03-15 | Abb Hv电缆瑞士有限责任公司 | The method of two sections of the joint and joining power cables including two sections of power cable |
CN110676783A (en) * | 2019-10-29 | 2020-01-10 | 威腾电气集团股份有限公司 | Resin casting bus expansion joint |
CN114256788A (en) * | 2021-12-27 | 2022-03-29 | 国网河南省电力公司汤阴县供电公司 | Fool type intelligent constant-temperature cable explosion-proof box and use method thereof |
CN115441290A (en) * | 2022-10-08 | 2022-12-06 | 郑州祥龙电力股份有限公司 | Manufacturing process of 35KV cable intermediate connector |
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1995
- 1995-07-10 CN CN 95194862 patent/CN1163018A/en active Pending
Cited By (12)
Publication number | Priority date | Publication date | Assignee | Title |
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CN101203992B (en) * | 2005-04-12 | 2010-12-01 | 赛尔派克有限公司 | Two- or multiple-piece insulating body system for producing medium high voltage cable fittings |
CN101467319B (en) * | 2006-06-07 | 2012-06-13 | 3M创新有限公司 | Method of making closure housing for sealing |
CN101467321B (en) * | 2006-06-07 | 2012-11-28 | 3M创新有限公司 | Sealing apparatus |
CN101170247B (en) * | 2006-10-27 | 2010-05-19 | 3M新设资产公司 | Re-accessible connector enclosing cover |
CN104145388B (en) * | 2012-02-29 | 2017-03-15 | Abb Hv电缆瑞士有限责任公司 | The method of two sections of the joint and joining power cables including two sections of power cable |
CN104620444A (en) * | 2012-04-18 | 2015-05-13 | 泰科电子有限公司 | Cable connector systems and methods including same |
CN104620444B (en) * | 2012-04-18 | 2017-09-12 | 泰科电子有限公司 | Wire and cable connector system and the method including it |
CN110676783A (en) * | 2019-10-29 | 2020-01-10 | 威腾电气集团股份有限公司 | Resin casting bus expansion joint |
CN114256788A (en) * | 2021-12-27 | 2022-03-29 | 国网河南省电力公司汤阴县供电公司 | Fool type intelligent constant-temperature cable explosion-proof box and use method thereof |
CN114256788B (en) * | 2021-12-27 | 2024-03-08 | 国网河南省电力公司汤阴县供电公司 | Fool type intelligent constant temperature cable explosion-proof box and use method thereof |
CN115441290A (en) * | 2022-10-08 | 2022-12-06 | 郑州祥龙电力股份有限公司 | Manufacturing process of 35KV cable intermediate connector |
CN115441290B (en) * | 2022-10-08 | 2024-09-24 | 郑州祥龙电力股份有限公司 | Manufacturing process of 35KV cable intermediate connector |
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