EP2154698A2 - Method for manufacturing a tear-proof resin transformer and tear-proof resin transformer - Google Patents

Abstract

The method involves using a cast resin e.g. epoxy resin, for electrical isolation of a coil body of a cast resin transformer. A tenacity modifier such as an acrylonitrile copolymer and/or a silicone rubber, is added to a liquid cast resin, where a composite liquid cast resin serves for grouting the coil body. The poured coil body is warmed up for hardening at increasing temperature. A catalyst such as tertiary amine and/or a quaternary ammonium composite, is added to the liquid compound cast resin. An amorphous quartz powder acting as filler is added to the liquid cast resin. An independent claim is also included for a cast resin transformer with an electrical isolation of a coil body.

Description

The invention relates to a method for producing a crack-resistant cast-resin transformer, wherein a casting resin for electrical insulation of a winding body of the cast-resin transformer is used. Furthermore, the invention relates to a cast-resin transformer with an existing of cast resin electrical insulation of a winding body of the cast resin transformer.

The use of casting resins, in particular epoxy resins, for the electrical insulation of electrical components, in particular high-voltage transformers, has been state of the art for years. In transformer construction, casting resins have the advantage that casting resins on the one hand have high electrical strengths and on the other hand are mechanically very stable in the cured state. However, the problem with the use of casting resins is that the casting resin is liquid and thus difficult to process only in the heated state. Due to the sometimes high temperatures during the cooling process but locally different temperature gradients formed in the casting resin or at the material transitions, such as between the casting resin and embedded in the casting resin aluminum windings, which can lead to mechanical stresses and thus cracks in the casting resin or in the material transitions , Therefore, so far, the thermal stresses are reduced by a targeted and time-consuming cooling of the previously thermally cured Gießharzkörpers (tempering).

To increase the crack resistance of a cast-resin transformer, further additives and / or fillers are likewise added to the casting resin in the prior art. The incorporation of further components in the liquid casting resin supports the matrix structure arising during the curing of the liquid casting resin or enhances it by incorporating the components into the matrix.

For example, describes the DE 43 43 121 A1 a method for producing a cast ceramic. Foundry ceramics are made of water glass and a silicon and aluminum containing powder, which reduces the open porosity of the epoxy resin. Casting ceramics are mainly used as electrical insulators.

Furthermore, the DE 44 32 188 A1 an epoxy resin molding compound, which in addition to a phosphorus-modified epoxy resin further additives and inorganic fillers. According to the DE 44 32 188 A1 the epoxy resin molding composition is technically simpler and thus cheaper to produce and should have a lower water absorption and higher thermal shock resistance compared to known epoxy molding compounds.

Also discloses the DE 102 24 587 A1 a potting compound, in particular for producing molded parts with embedded therein inserts, consisting of a base component and at least one additive, wherein the base component is a casting resin and the base component at least two additives, in particular quartz powder and a mineral fiber material having.

A problem with the casting resin transformers produced hitherto in the state of the art is that they have a high electrical output Load or, in the case of a cold shock test prescribed in accordance with standard IEC600 76 - 11, cracks, especially at the material transitions. The risk of cracking is greater, the faster the curing of the casting resin during manufacture takes place. For this reason, very long curing times have hitherto been chosen in the prior art, so that a virtually uniform cooling of all components of the entire cast-resin transformer is ensured. The curing process until removal of the final casting mold from the cast-resin transformer therefore takes in part more than 30 hours.

Object of the present invention is therefore to shorten the curing process during the production of a cast-resin transformer.

With regard to the solution of the above-mentioned object, a method for producing a crack-resistant cast-resin transformer according to claim 1 is provided. Advantageous embodiments are embodied in the subclaims related thereto.

With regard to the casting resin transformer, the object is achieved by the features of claim 7. Advantageous embodiments are the subject of the dependent claims.

According to the invention, according to the method for producing a crack-resistant cast resin transformer, a toughening modifier of up to 20 phr is added to the liquid casting resin in comparison with the base component of the casting resin. The term phr ("parts per hundred resin") known to the person skilled in the art indicates how many parts by weight of a component in the Cast resin based on 100 parts by weight of the casting resin are present.

To this first component, an accelerator is added in such a concentration that gives a gel time of less than 15 minutes at 140 ° C, wherein the enriched with these two components liquid casting resin for casting of the winding body and the thus-cast winding body for curing a linear or stepped rising temperature profile is exposed. An example of this is the following temperature profile, in which within 4 hours, the composite liquid casting resin is continuously increased from a temperature of 80 ° C to 100 ° C. Subsequently, the temperature is continuously increased to 130 ° C and then finally cured for several hours at this temperature. An otherwise slow cooling in the cooling area for reducing the internal thermal stresses (annealing) is not necessary according to the present method.

Toughness modifiers are known for improving the temperature resistance of casting resins (for example DE 601 04 449 T2 ). The use of cure accelerators (for example DE 42 06 733 C2 ), the polymerization or polyaddition accelerates conversion to a crosslinked composite matrix of the thermosetting molding resin. The sole or non-coordinated addition of accelerators to a liquid casting resin leads just to a rapid curing with high mechanical stresses, which forms in case of frequent temperature changes of the cast resin transformer during operation, the cracks to be avoided.

Through the use of defined toughness modifiers and a corresponding increase in the accelerator concentration the crack resistance of the casting resin can be increased in such a way that mechanical stresses just do not arise during the curing process and thus at the same time the curing times can be reduced. In particular, the combination of the toughness modifier with adjusted accelerator concentrations and a co-ordinated curing process reduces or eliminates the cracking of a cast resin transformer thus produced.

This results in the one hand, the advantage of shorter curing times with a correspondingly reduced energy consumption in the production of Gießharztransformators. At the same time, the life of a cast resin transformer thus produced is prolonged, since the temperature variations arising during operation do not generate cracks within the cast resin transformer.

In an advantageous embodiment of the method is provided that the liquid casting resin as an accelerator, in particular a tertiary amine and / or a quaternary ammonium compound is added.

Advantageously, the temperature profile is controlled during the curing process of the liquid casting resin by means of a temperature distribution in a furnace surrounding the winding body.

Advantageously, a filler is added to the liquid casting resin, in particular a mineral quartz powder. Furthermore, up to 5 percent by weight, in particular 3 percent by weight, of glass short fibers based on the filler is added to the liquid casting resin, in order in addition to increase the composite matrix of the hardening casting resin by the glass short fibers to reinforce. This has the advantage that an otherwise usual reinforcement in the form of a glass fiber mat or a fleece on the inside and / or outside of the cast resin body is not necessary.

According to the invention, a toughening modifier of up to 20 phr is added to the casting resin of the cast-resin transformer. Furthermore, advantageously, a filler is added to the casting resin, wherein based on the weight percent of the filler of up to 5 percent by weight glass short fibers are added to the casting resin. In an advantageous embodiment of the cast-resin transformer, the filler is a mineral filler, in particular an amorphous quartz powder.

In an advantageous embodiment of the cast resin transformer, the accelerator is in particular a tert. Amine and / or a quaternary ammonium compound and the toughness modifier, a copolymer, in particular an acrylonitrile or a silicone rubber.

Claims (12)

Method for producing a crack-resistant cast-resin transformer, wherein a casting resin is used for electrical insulation of a winding body of the cast-resin transformer,
characterized in that
a toughening modifier of up to 20 phr is added to the liquid casting resin and the liquid casting resin thus composed serves to encase the winding body, the thus-cast winding body being heated to harden with increasing temperature. Method according to claim 1,
characterized in that
a copolymer, in particular an acrylonitrile copolymer or silicone rubber, is added to the liquid casting resin as toughness modifier. Method according to one of claims 1 or 2,
characterized in that
the temperature in the form of a defined temperature profile is increased linearly and / or stepwise during the curing of the composite liquid casting resin. Method according to claim 3,
characterized in that
the temperature profile during the curing process of the composite liquid casting resin is controlled by means of a temperature distribution in a furnace surrounding the winding body. Process according to claims 1 to 4,
characterized in that
an accelerator, in particular a tertiary amine and / or a quaternary ammonium compound, is added to the liquid composite casting resin. Method according to claim 5,
characterized in that the concentration of the accelerator leads to a gelling time of less than 15 minutes at 140 ° C and is thus adapted to the curing process. Method according to one of claims 1 to 6,
characterized in that
a filler is added to the liquid casting resin, wherein based on the weight percent of the filler up to 5 percent by weight of short glass fibers are added. Method according to claim 7,
characterized in that
a mineral filler, in particular an amorphous quartz powder, is added to the liquid casting resin as filler. Casting resin transformer with an electrical insulation of a winding body of the cast-resin transformer consisting of cast resin,
characterized in that
the liquid casting resin contains a toughness modifier of up to 20 phr, and the composite casting resin thus obtained can be heated by means of a defined linear and / or step-shaped rising temperature profile and thus hardens crack-resistant. Cast resin transformer according to claim 9,
characterized in that
a filler is added to the casting resin, wherein based on the weight percent of the filler of up to 5 percent by weight glass short fibers are added to the casting resin. Cast resin transformer according to one of claims 9 or 10,
characterized in that
the filler is a mineral filler, especially an amorphous silica flour. Cast resin transformer according to one of claims 9 to 11,
characterized in that
the composite liquid casting resin comprises an accelerator, in particular a tertiary amine and / or a quaternary ammonium compound, and the toughness modifier is a copolymer, in particular an acrylonitrile or silicone rubber.