DE3702782A1 - Instrumentation transformer for high voltage (high tension) - Google Patents

Abstract

The instrumentation transformer for high voltages consists of a head part, of a bushing part and of a base part. The active part (1, 2, 3, 4, 21) is accommodated in the head part and/or in the base part. The entire high-voltage insulation (7, 24, 25), which surrounds the bushing part and at least a portion of the active part (1, 2, 3, 4, 21), is elastic like rubber and has a Shore-A hardness of between 25 and 98. The load-bearing skeleton of the instrumentation transformer is formed from a rigid shell (10, 22) around the active part (1, 2, 3, 4, 21) and from a tube (11, 23) which is rigidly connected to this shell (10, 22) and passes through the bushing part. The high-voltage insulation (7, 25) may consist of silicone rubber. It is possible for the high-voltage insulation to be composed of an inner insulation element (24) having a high electrical breakdown strength (dielectric strength) and of an outer insulation element (25) which is resistant to leakage current and weather. <IMAGE>

Description

The present invention relates to a transducer for high voltage a head part, a base part and an intermediate bushing part, with at least one penetrating part at least through an active part housed in the head and / or base part of the transducer connected electrically conductive connection and with at least one a cast and hardened mass consisting of at least part of the Active part and the connection immediate high-voltage insulation.

A transducer of the type mentioned at the outset is from CH-PS 4 00 345 known. In this publication, a cast resin voltage converter in Pot construction and a cast resin current transformer described in head construction, the due to the opposite conicity of the cast resin insulator tight can be placed side by side. A big disadvantage of this with one brittle high-voltage insulation made of hardened cast resin Transducer is that between the active part of the transducer and the cast resin insulation requires padding, otherwise the Cast resin insulation can be split if the active part expands. Upholstery is not only economically disadvantageous connected, but also causes technical difficulties in the Production of a cavity-free binding of the casting resin on the surface potential-carrying parts. Cavities would be caused by glow discharges Destruction of the transducer. Another disadvantage of this transducer can be seen in the fact that in the event of an electrical breakdown in the High voltage insulation the solid, shattered parts of the casting resin isolation can be thrown explosively into the environment, causing men and neighboring parts of the system are at risk. In addition, the creep Resistance to current and the weather resistance of cast resin insulators is unconditional digend. The CH-PS 4 60 160 shows another cast resin insulated combination th transducer, which also has the aforementioned disadvantages. Around the tracking resistance and the weather resistance of an insulator made of casting To improve resin, you have the cast resin insulation according to CH-PS 4 68 060 a relatively thin outer layer of silicone rubber. The outer silicone rubber layer has a high tracking resistance and good weather resistance, with the inner rigid cast resin body thermal expansion of any metal part embedded in it can only endure with an intermediate padding without damage. The  The aforementioned disadvantages associated with upholstery therefore remain exist here too.

The object of the present invention is to provide a transducer at the beginning Specify mentioned genus, which is economically advantageous without a Upholstery between the embedded metal parts and the high voltage Isolation of the transducer is operational and even in the event of a possible electrical breakdown in the high voltage insulation no people and neighboring parts of the system are at risk.

The task is solved in that the entire high voltage isolation is rubber-like elastic and has a Shore A hardness between 25 and 98 and that the supporting skeleton of the transducer from a rigid Formwork around the active part and out of a rigid with this formwork connected the bushing penetrating the electrical connection receiving tube there. This measure makes the transducer very simple and therefore economically advantageous. The rubbery elas High-voltage insulation eliminates the need for upholstery between the beds metal parts and high-voltage insulation. The mechanically not stable High-voltage insulation is held by the supporting skeleton. The rubber like elastic high-voltage insulation with a possible electrical Breakdown in the high-voltage insulation only destroyed locally, does not explode and therefore endangers neither people nor the other parts of the system.

The high-voltage insulation can be at least partially made of silicone rubber stand. The rubber-like elasticity, the high tracking resistance and the good weather resistance of this material are beneficial.

The high voltage insulation can consist of at least one high electrical Internal partial insulation with dielectric strength and from thereon bound leakage current and weatherproof outer partial insulation. The inner partial insulation has a higher Shore A hardness than the outer Partial insulation. With this composite high voltage insulation it is possible, an economically more advantageous for the inner partial insulation rubber-like elastic material to choose. The fact that the inner part of the island tion has a higher Shore A hardness, the mechanical stability of the entire transducer can be increased.  

The high-voltage insulation is advantageously subjected to mechanical stress, in which the ratio of the amount of Shore A hardness to the magnitude of the mechanical stress, expressed in N / mm ² , is at least 100. By adhering to this limit it can be achieved that the high-voltage insulation maintains its shape with a permissible tolerance.

The high voltage insulation in the headboard can be one of the formwork spaced electrode serving as a measuring electrode of a capacitive divider exhibit. If the limit of the mechanical stress of the High voltage insulation can be embedded in the high voltage insulation ten measuring electrode formed a capacitive divider of sufficient accuracy will.

The high-voltage insulation can at least on the head part and / or on the base part partially with a rubber-like elastic electrically conductive layer be drawn. This electrically conductive layer can in turn be covered with a rubber well covered elastic protective layer. The on the head or base The required potential coverings can be easily produced in this way. They adhere to the surface of the high-voltage insulation and follow it Movements. An elastic protective layer protects the conductive layer against mechanical influences.

The supporting skeleton of the Transducer advantageously has on its electrically conductive surface one consisting of an electrically at least semiconducting material on the High voltage insulation adhesive layer. With this measure, a any detachment of the high-voltage insulation associated with the formation of cavities be rendered ineffective by the formwork and the tube of the skeleton.

A measuring transformer in the form of a top current transformer is advantageously included a mechanically relieved high-voltage insulation, the High-voltage potential primary conductors of the current transformer from mechanically supported skeleton of the transducer supported on the base part independently and carried by adjacent parts of a high-voltage system is. The mechanical relief of the high-voltage insulation also ensures relatively soft insulation material the dimensional stability of the high voltage isolation and allows the use relatively heavy, at high current necessary primary conductors.  

The present invention overcomes one prevailing in the art Prejudice regarding the use of an exclusively rubber-like elastic material existing high voltage insulation for a transducer. Although a rubber-like elastic high-voltage insulation for flexible Cable ends in the form of an end sleeve that can be pushed onto the cable end without one mechanically supporting rigid skeleton, for example from DE-PS 29 44 120 was previously known, was only a rigid, mostly for high-voltage transducers high-voltage insulation made of cast resin applied, or at a a porcelain insulator as a mechanically unsustainable high voltage insulation Carrying element used.

In the following, two examples are given with reference to the accompanying drawings games of the invention described in more detail. Show it:

Fig. 1 shows the elevation section and

Fig. 2 is a side elevational sectional view of a head current transformer for high voltage,

Fig. 3 shows the elevation section and

Fig. 4 shows the side elevation section of a voltage converter for high voltage.

In Fig. 1, a current transformer is shown in a head design. The active part of this overhead current transformer housed in the head part consists of the two ring-shaped iron cores 3 , 4 wound with the secondary windings 1 , 2 . The primary conductor 5 penetrates the active part. The electrically conductive connected to the secondary windings 1 , 2 of the current transformer, not shown in FIGS. 1 and 2, lead through the lead-through part to the base part 6 of the current transformer, where they are accessible from the outside at corresponding terminals.

The entire high-voltage insulation 7 of the current transformer consists of a rubber-like elastic material whose Shore A hardness can generally be between 25 and 98. Such materials belong to the group of elastomers. In the example shown in Figs. 1 and 2, a current transformer made of kaltvernetzendem silicone rubber having a Shore A hardness of 50 high-voltage insulation 7 is inserted. The mechanical stress of this high-voltage insulation 7 does not exceed a certain limit, whereby the dimensional stability and a constant electrical stress remains ge guaranteed. The permissible limit of the mechanical load is where the ratio of the amount of Shore A hardness to the amount of the mechanical load expressed in N / mm ² is at least 100. After the high-voltage insulation 7 shown in FIGS. 1 and 2 has a Shore A hardness of 50, the mechanical stress on the high-voltage insulation should not exceed the value of 0.5 N / mm ² . With this stress, it is possible to install a measuring electrode 8 in the high-voltage insulation 7 in the head part of the current transformer. This measuring electrode 8 is the measuring tap of a capacitive divider, which is arranged between the high-voltage, electrically conductive layer 9 around the head part on the one hand and the electrically conductive inner casing 10 around the active part on the other. The measuring accuracy of the capacitive divider remains within the permissible limits if the mechanical stress does not exceed the previously mentioned limit.

In order to achieve the desired mechanical stability of the current transformer in the case of rubber-like elastic high-voltage insulation 7 , the mechanically load-bearing skeleton of the current transformer consists of the rigid casing 10 around the active part of the current transformer and of a tube 11 rigidly connected to this casing 10 . The tube 11 is rigidly attached to the base part 6 of the current transformer. The base part 6 in turn is stationary.

In order to mechanically relieve the high-voltage insulation 7 , the primary conductor 5 is independently fastened to an adjacent part 12 of a high-voltage system by the supporting skeleton supported on the base part 6 . The adjoining part 12 can be the connection point of a circuit breaker, a disconnector, an overvoltage arrester, a post insulator, a fixed busbar or any part of the system carrying the primary conductor 5 .

The high-voltage insulation 7 of the current transformer is covered on the head part with a rubber-like, elastic, electrically conductive layer 9 . This layer 9 consists of an addition-crosslinked silicone rubber made electrically conductive by the addition of carbon black, has a Shore A hardness of 55 and is vulcanized onto the high-voltage insulation 7 at temperatures between 180 and 200 ° C. The layer 9 is closed in the transition area between the head part and the feed-through part with an electrically conductive ring 13 . The electrically conductive layer 9 is interrupted in the hole area of the head part in order to avoid a short circuit turn around the iron cores 3 and 4 . On both sides of the hole provided for the primary conductor 5 on the head part of the current transformer, two insulating plates 15 held together by means of electrically insulating tension bolts 14 are attached. The central opening on these insulating plates 15 is so large that the primary conductor 5 is not supported on it. Under one of the two insulating plates 15 is connected to the primary conductor 5 electrically connected in the figures, not shown connecting wire is clamped. This connecting wire establishes a potential connection between the primary conductor 5 and the electrically conductive layer 9 .

In high-voltage systems, arrangements can be made in which there are no mechanically load-bearing parts 12 in the immediate vicinity of the current transformer. For such arrangements, provision is made to adapt the central openings on the insulating material plates 15 to the diameter of the primary conductor 5 . The primary conductor 5 , which fits in the central openings of the insulating material plates 15 , is supported in this case by the skeleton formed from the tube 11 and the casing 10 and by the high-voltage insulation 7 lying between the casing 10 and the insulating material plates 15 . In this case, however, care must be taken to ensure that the connection lines of the high-voltage system are connected to the primary conductor 5 in a largely mechanically relieved manner. The current transformer should not have to perform any support functions. The primary conductor 5 can also form several turns around the iron cores 3 and 4 , as is already known from current transformer technology, for example from CH-PS 4 60 160. In this case, the insulating material plates 15 hold the connection bolts of the current transformer.

The supporting skeleton of the current transformer formed from the casing 10 and from the tube 11 is provided with an electrically semiconducting layer 16 on its electrically conductive surface. To make this layer 16 , a semiconductor paper tape is wound on the skeleton. This semiconducting layer 16 is penetrated by the cast material when the high-voltage insulation 7 is poured, as a result of which good adhesion is created between the semiconducting layer 16 and the high-voltage insulation 7 . Thanks to this good adhesion and the electrical connection between the electrically conductive skeleton and the semiconducting layer 16 , any undesired electrically stressed cavities on the surface of the skeleton can be avoided. On the other hand, the semiconducting layer 16 reduces the potential jump on the surface of the skeleton.

FIGS. 3 and 4 show a voltage converter in elevation-section and in side elevation cut. The active part of the voltage converter is housed in the base part. The iron core 17 is fastened to a base plate 19 by means of rods 18 . The secondary winding 20 and the primary winding 21 are supported on the iron core 17 . Around the primary winding 21 , a form 22 having the shape of a slit cylinder is attached. An electrically conductive tube 23 is rigidly attached to this formwork 22 . The tube 23 and the casing 22 rigidly connected to it form the mechanically load-bearing skeleton of the voltage converter.

The high-voltage insulation consists of an inner partial insulation 24 and an outer partial insulation 25 bonded to it. The inner partial insulation 24 is brought up on the supporting skeleton provided with a semiconducting layer 16 and has a high dielectric strength. For this inner partial insulation 24 , a plastic obtained from reactive polysiloxanes and organic thermoplastics by a special polymerization process is used, which is commercially available, for example, under the name "Wacker m-Polymers" from Wacker-Chemie GmbH, 8000 Munich 2. The outer partial insulation 25 can be coated on the outside by the ambient air and consists of a leakage-proof and weatherproof material, made of silicone rubber. The inner partial insulation 24 has a Shore A hardness of 70 and the outer partial insulation 25 one of 28. The harder inner partial insulation 24 ensures satisfactory mechanical stability of the voltage converter.

The inner partial insulation 24 is provided in the base part of the voltage converter with an electrically conductive, grounded layer 26 . This layer 26 is vulcanized onto the inner partial insulation 24 and has a Shore A hardness of 55. Layer 26 is closed with a ring 27 in the transition region between the base part and the lead-through part.

A rubber-like elastic protective layer 28 made of silicone rubber is applied to the electrically conductive, grounded layer 26 . This protective layer 28 has a Shore A hardness of 28 and protects the underlying electrically conductive layer 26 against mechanical and weather-related influences.

The head part 29 of the voltage converter carries the connecting bolt 30 .

The use of a rubber-like elastic high is particularly advantageous voltage isolation also with regard to explosion safety. With the be Written transducers arise in the event of an electrical through do not hit people flying around in the high-voltage insulation  neighboring fragments of the system or measuring transducer parts. The rubber like elastic high-voltage insulation is in the event of an electrical breakdown only locally destroyed and does not explode.

Claims (10)

1.Measuring transducer for high voltage with a head part, a base part and a lead-through part in between, with at least one electrically conductive connection which penetrates the lead-through part and is connected to at least one active part accommodated in the head and / or base part of the transducer and with at least one cast and hardened one Mass existing at least part of the active part and the connection bypassing high-voltage insulation, characterized in that the entire high-voltage insulation ( 7 , 24 , 25 ) is rubber-like elastic and has a Shore A hardness between 25 and 98 and that the load-bearing skeleton of the transducer is made of a rigid casing ( 10 , 22 ) around the active part ( 1 , 2 , 3 , 4 , 21 ) and from a pipe ( 11 , 23 ) penetrating the electrical connection and rigidly connected to this casing ( 10 , 22 ). 2. Transducer according to claim 1, characterized in that the high voltage insulation ( 7 , 25 ) is at least partially made of silicone rubber. 3. A measuring transducer according to claim 7 or 2, characterized in that the high-voltage insulation is composed of an inner partial insulation ( 24 ) which has at least a high dielectric strength and an attached partial insulation ( 25 ) which is bonded to the outside and which can be coated with the ambient air and is weatherproof . 4. Transducer according to claim 3, characterized in that the inner partial insulation ( 24 ) has a higher Shore A hardness than the outer partial insulation ( 25 ). 5. Transducer according to one of claims 1 to 4, characterized in that the high-voltage insulation ( 7 , 24 , 25 ) is exposed to mechanical stress, in which the ratio of the amount of Shore A hardness to the amount of in N / mm ² expressed mechanical stress is at least 100. 6. A measuring transducer according to claim 5, characterized in that the high-voltage insulation ( 7 ) in the head part has an electrode ( 8 ) which is spaced apart from the casing ( 10 ) and serves as the measuring electrode of a capacitive divider. 7. Transducer according to one of claims 1 to 6, characterized in that the high-voltage insulation ( 7 , 24 ) on the head part and / or on the base part is at least partially covered with a rubber-like, elastic, electrically conductive layer ( 9 , 26 ). 8. Transducer according to claim 7, characterized in that the electrically conductive layer ( 26 ) is covered with a rubber-like elastic protective layer ( 28 ). 9. Transducer according to one of claims 1 to 8, characterized in that the supporting skeleton of the transducer formed from a casing ( 10 , 22 ) and a tube ( 11 , 23 ) on its electrically conductive surface is made of an electrically at least semiconducting material existing layer ( 16 ) adhering to the high-voltage insulation ( 7 , 24 ). 10. Measuring transformer in the form of a head current transformer according to one of claims 1 to 9, characterized in that the high-voltage insulation ( 7 ) is mechanically relieved, the high-voltage potential primary conductor ( 5 ) of the head current transformer mechanically supported on the base part ( 6 ) of the supporting skeleton of the measuring transformer is carried independently and by adjacent parts ( 12 ) of a high-voltage system.