RU115556U1 - TRANSFORMER - Google Patents

Abstract

A transformer containing an active part placed in a housing, made in the form of a magnetic circuit and separated from each other by means of interwinding insulation made of thermoplastic material, primary and secondary windings, while the housing is made of at least two layers, the first of which is inner - made of elastic electrical insulating elastic material, and the second - the outer layer, which is also electrical insulating and protective against mechanical and atmospheric influences, - made of thermoplastic material, characterized in that the body contains a third, additional, electrical insulating layer placed between the inner and outer layers made of silicone rubber, while the thickness of the additional layer hd is selected from the ratio:! hд≤hн≤hв, where hв - thickness of the inner insulating layer; ! hн - thickness of the outer insulating layer; ! hd is the thickness of the additional intermediate electrical insulating layer.

Description

The utility model relates to electrical engineering, in particular, to high-voltage apparatus engineering, and can find application in high-voltage transformers with cast epoxy insulation.

A known voltage transformer containing an active part located in the housing, made in the form of a magnetic circuit and separated from each other by means of inter-winding insulation in the form of an epoxy compound of the primary and secondary windings, the housing is made of two layers, the first of which is internal, which is electrical insulation, made from an epoxy compound, and the second is external, which is also electrical insulating and protective against mechanical influences, made of casting compound [L. one].

Such a transformer having a housing in the form of two layers of insulation is characterized by a certain electric strength, however, the implementation of the outer insulation layer of the housing from an epoxy compound, which, after hardening of the compound, has high rigidity, leads to insufficiently high operational reliability and durability, which, in turn, result in long atmospheric influences to the appearance of cracks on the surface of the body, and in the inner hard layer when heating the windings and the magnetic circuit under the influence of anicheskih stress cracks occur, leading to loss of electrical properties and mechanical strength. In addition, the transformer described in [L. 1] design is characterized by increased mass-dimensional characteristics.

Also known is a transformer containing an active part located in the housing, made in the form of a magnetic circuit and separated from each other by means of winding insulation of the primary and secondary windings, while the housing is made of two layers, the first of which is internal - it is electrical insulating and made of elastic material and the second - external - is also electrically insulating and protective against mechanical and atmospheric influences and is made together with winding insulation made of thermoplastic material and [L. 2].

The transformer described in [L. 2], characterized by smaller compared with the transformer according to [L. 1] by the mass-dimensional characteristics, however, the presence of two layers of insulation does not provide the electric strength required for the transformer, designed for 6 ÷ 10 and more kV, and, consequently, operational reliability, without a significant increase in mass and dimensions.

A useful model solves the problem of creating a transformer characterized by high electric strength, and, consequently, high operational reliability, in particular, when the voltage is increased to 6 ÷ 10 and more kV while maintaining the mass-dimensional characteristics practically unchanged due to a significant reduction in the insulation thickness of the additional layer .

To solve the problem in a transformer containing the active part located in the housing, made in the form of a magnetic wire and separated from each other by means of winding insulation made of thermoplastic material, primary and secondary windings, while the housing is made of at least two layers, the first of which - the inner - is made of elastic insulating elastic material, and the second is the outer layer - which is also electrical insulating and protective from mechanical and atmospheric influences minutes, made of thermoplastic material, it is proposed according to the present utility model, to introduce into the casing a third, optional, electrically insulating layer made of silicone rubber, and placing it between the inner and outer layers, the thickness of an additional, intermediate, layer h _e selected from ratios: h _d ≤h _n <h _in , where h _in - the thickness of the inner insulating layer; h _n - the thickness of the outer insulating layer; h _d - the thickness of the additional intermediate electrical insulating layer.

The utility model is illustrated by the example of the drawing, (figure 1) which shows the inventive transformer, its longitudinal section.

The transformer contains a magnetic circuit 1, on which the primary winding 2 and the secondary winding 3 are placed. Between the primary winding 2 and the secondary winding 3 an inter-winding insulation 4 is placed. In this case, the inter-winding insulation 4 is made of thermoplastic material, for example polycarbonate.

The magnetic circuit 1 with the primary winding 2 and the secondary winding 3 form the active part, placed in a housing made of three layers, the first of which - the inner layer 5 - is insulating and made of elastic elastic insulating material, for example, “viscinte” compound, the second is the outer layer 6 - is also electrical insulating and protective against mechanical and atmospheric influences and is made of thermoplastic material, such as polycarbonate; the third additional layer 7 is also insulating, it is placed between the inner insulating layer 5 and the outer insulating layer 6 and is made of silicone rubber. The thickness of the additional, intermediate, insulating layer 7 is selected from the ratio:

Where

h _in - the thickness of the inner insulating layer;

h _n - the thickness of the outer insulating layer;

h _d - the thickness of the additional, intermediate, electrical insulating layer.

Therefore, the winding insulation 4 and the outer layer 6 are made of the same thermoplastic polycarbonate material, the inner insulating layer 5 is made of “viscinte” compound, and the intermediate insulating layer is made of silicone rubber.

In this case, the thickness of the additional intermediate layer 7 is selected from relation (1) and with the thickness of the inner layer 5 equal to 10 mm, and the thickness of the outer layer 6 equal to 4 mm, equal to 2 mm.

The transformer manufacturing process involves the following technological operations:

1) the manufacture of magnetic cores;

2) manufacture of windings;

3) manufacture on a molding machine of a cylinder of thermoplastic material for winding insulation;

4) the assembly of the windings, which consists in landing between the low voltage and high voltage windings of the thermoplastic cylinder winding insulation;

5) assembly of windings with magnetic cores;

6) the implementation of fasteners, embedded parts, lead ends, connections of the windings;

7) manufacture of an injection mold from a thermoplastic electrical insulating material on an injection molding machine, which is the outer layer of the transformer body;

8) applying an intermediate insulating layer;

9) installation and fastening in the casting form of the windings and the transformer;

10) filling the inner layer with an elastic insulating compound;

11) control tests.

The implementation of the outer layer of the casing and winding insulation of thermoplastic material, and the inner electrical insulating layer of the casing of elastic material allows due to the elasticity and elasticity of the outer surface of the casing to eliminate the appearance of cracks on its surface and thereby increase the operational reliability and durability of the entire transformer as a whole.

The implementation of the transformer with an additional intermediate layer of insulation made of silicone rubber will increase the electric strength and reliability of the transformer due to the uniform distribution of potentials between the insulation layers, and, therefore, will reduce the thickness of the inner layer, which ultimately leads to the preservation of mass overall indicators and expanding the functionality of the transformer due to its application to higher voltage classes.

The Scientific and Production Enterprise Elektromash LLC has developed technical documentation that implements the claimed solution and in accordance with which transformers of type OS-1.25 for primary winding voltage 6 are manufactured and tested; 10; 27.5; 35kV.

The test results confirmed the operability of the inventive transformer, as well as its technical advantages compared to known similar products and the wide range of practical applications in the future.

Literature:

1. A.M. Dymkov, V. M. Kibel, Y. V. Tishenin // Voltage transformers // Moscow, "Energy", 1975, her. 120 ÷ 128.

2. Utility Model Patent No. 65286, IPC H01F 27/32, 2007

Claims (1)

A transformer containing an active part located in the housing, made in the form of a magnetic circuit and separated from each other by means of winding insulation made of thermoplastic material, primary and secondary windings, while the housing is made of at least two layers, the first of which is internal - made of elastic insulating elastic material, and the second is the outer layer, which is also electrical insulating and protective from mechanical and atmospheric influences, - made of thermoplastic material Methods and material, characterized in that the housing comprises a third, optional, electrically insulating layer sandwiched between the inner and outer layers made of silicone rubber, the thickness of the additional layer is selected from h _d ratio: h _d ≤h _n ≤h _in , where h _in - the thickness of the inner insulating layer; h _n - the thickness of the outer insulating layer; h _d - the thickness of the additional intermediate electrical insulating layer.