UA139361U - POLYMER INSULATOR - Google Patents

Abstract

The polymeric insulator contains a power unit having a fiberglass electrical insulating rod, the ends of which are connected to metal terminals and on which a protective shell is applied. Part of the protective shell from 0.1 to 0.5 or from 0.5 to 1.0 is made of a material having a nonlinear characteristic and highlighted in green - the dependence of current on the applied voltage and the nonlinear dependence of the dielectric constant on the electric field strength.

Description

The utility model belongs to the field of electrical engineering, in particular to high-voltage insulators, and can be used in the production of rod polymer insulators intended for sheathing and fastening wires of substation power lines to grounded support structures.

Electrical insulators containing terminators - an element of attachment to a supporting structure and an element of wire attachment - are widely used for attaching wires of power transmission lines (LEP) to supporting (main) structures in the form of columns or pillars, bridges, tunnels or overpasses.

The specifics of the construction and operation of high-voltage transmission lines and substations are determined by very heterogeneous electric fields along the insulating suspensions of wires and busbars of substations, despite the measures taken to equalize the electric field using various screen systems.

Depending on the voltage on the wire, the insulators can have a screen armature, which equalizes the electric field intensity and protects the insulator from the occurrence of corona discharges during operation in normal weather conditions.

Considering the fact that most electrical insulating materials wear out faster when exposed to a strong electric field, the presence of surface erosion of the insulator leads to a significant reduction in its service life.

For insulators of high voltage classes (110-1250 kV), the screen armature cannot fully provide a reduction in the intensity of the electric field affecting the insulating materials. Acceptable levels of electric field strength should be at least 4.0 kV/cm for polymer materials used in high-voltage insulators today.

The part of the insulator that is located in the area of the greatest intensity of the electric field turns out to be the most electrically loaded.

The unevenness of the field is especially strongly felt as a result of natural contamination and wetting of insulators, when due to the uneven distribution of the contamination layer, numerous local places with high electric field intensity appear, partial breakdowns occur on the surface and so-called partial electric arcs ignite along the surface of the insulator.

З At the support point of each arc there is a zone with increased current density, which also worsens the operating conditions of the insulator, in connection with which there is a need for an even greater reduction of the electric field strength along the surface of the insulator. An increase in surface conductivity leads to an equalization of the electric field strength and a decrease in the field strength, in connection with which the initial voltage of the corona discharge increases, which significantly complicates the formation of an alternating discharge and improves the operating conditions of the insulator.

Improvement of the operating conditions of the insulator can be achieved by using semiconductor coatings on the surface of the fiberglass rod of the insulator, which complicate the conditions for the formation of zones of increased tension and the occurrence of corona discharge, and therefore the occurrence of partial electric arcs along the surface of the insulator. In the case of the use of semiconductor coatings on the surface of the fiberglass rod of the insulator, the magnitude of the electric field intensity along its surface is reduced, which leads to the impossibility of the development of ionization processes and erosion of the insulator surface due to the absence of most of the surface discharges, and the practical absence of corona discharge prevents accelerated aging of the body of the polymer insulator. This extends the service life of the body of the polymer insulator itself as a whole to at least 60 years, which is confirmed by research in the laboratory and computer simulation.

A polymer high-voltage insulator containing a power unit is known, which has a fiberglass insulating rod, the ends of which are connected to metal terminations, a protective shell with ribs, made of synthetic rubber and covering the power unit. The protective shell is made of solid or liquid synthetic rubber, the radius of rounding of the terminator K is within 0.2О0«К«0.50, where О is the thickness of the wall of the terminator, the upper and lower surfaces of the ribs have a conical shape and the angle a between the base of the cone and its axis is in the range from 90" to 45", the ratio of the distance between the ribs of different diameters is in the range of 16.5 mm"e5" 21 mm, and one diameter - 33 mm"e51"550 mm, the ratio of the length of the generating line of the protective sheath of the insulator and the length of the protective sheath is within 2-4, and the part of the protective sheath inside the metal terminator is crimped and treated with a neutral silicone sealant or part of the protective sheath covers the metal terminator (ША Mo44368), НО1В 17/00, 20091.

Making a protective shell from hard synthetic rubber does not sufficiently reduce the intensity of the electric field acting on polymer materials.

The basis of a useful model is the task of creating a design of such a polymer insulator, in which the reduction of the electric field strength acting on polymer materials is achieved by changing the dielectric properties of the materials themselves, in particular, by increasing the dielectric permeability and conductivity of the material in the area of increased electric field strength .

The problem is solved by the fact that in a polymer insulator containing a power unit having a fiberglass insulating rod, the ends of which are connected to metal terminations and on which a protective sheath is applied, according to a useful model, part of the protective sheath is made of a material having nonlinear characteristic - the dependence of the current on the applied voltage and the nonlinear dependence of the dielectric constant on the strength of the electric field.

The protective shell is made of organosilicon rubber from solid or liquid silicone rubber, which contains dimethylmethylvinylsiloxane rubber, aerosil and aluminum hydroxide - up to 60 95 by mass of the composition, and the part that has a nonlinear characteristic - the dependence of the current on the applied voltage and the nonlinear dependence of the dielectric constant on the voltage of an electric field is made of solid or liquid organosilicon rubber, in which part of the aluminum hydroxide is replaced by finely dispersed material based on zinc oxide. The portion of aluminum hydroxide that is replaced by zinc oxide fine material is 1095 to 6095. The length of the zinc oxide fine material portion of the protective shell may be 0.1 to 0.5 or 0.5 to 1.0 of the entire the length of the electrical insulating rod, while it is highlighted in green.

The introduction of finely dispersed material based on zinc oxide into the material of the protective shell - organosilicon rubber - helps to equalize the electric field in the zone where the electric field intensity exceeds the critical level.

Varistors, which have a non-linear dependence of the dielectric constant on the electric field strength and a sharply non-linear characteristic - the dependence of the current on the applied voltage, due to which they change their conductivity in a very wide range, are usually made from a finely dispersed material based on zinc oxide. This property allows you to avoid the appearance of local jumps in the electric field strength and the appearance of partial brackets on

From the surface of both a wetted and a dry insulator due to the fact that the time of operation of the varistor is about 10-20 nanoseconds, and the time of development and formation of the partial arc and corona discharge is about 0.2 microseconds, which is about 10-20 times longer . This facilitates the working conditions of the polymer insulator, increases its reliability, improves operational characteristics and extends its service life.

To determine the place of inclusion of finely dispersed material based on zinc oxide, a neutral dye is included, in the invention - green.

In the composition, according to a useful model, at least part of the aluminum hydroxide (from 10 95 to 60 95) is replaced by a material based on zinc oxide, from which varistors are made and which performs the role of a varistor and a sharply nonlinear characteristic - the dependence of the current on the applied voltage, due to which changes its conductivity in a very wide range, and also has a non-linear dependence of the dielectric constant on the strength of the electric field.

From the obtained composition, a protective sheath of the insulator or a part of the protective sheath placed in the zone where the electric field strength exceeds the critical level for this material is made by the methods used in the production of insulators (injection molding, transfer or direct pressing).

A useful model is explained by drawing a polymer insulator.

The polymer insulator has a power assembly containing a fiberglass electrical insulating rod 1, the ends of which are connected to metal terminations 2. A protective shell 3 is applied to the fiberglass electrical insulating rod 1, which is made of organosilicon rubber of solid or liquid silicone rubber and which contains dimethylmethylvinylsiloxane rubber, aerosil and aluminum hydroxide - up to 6095 from the weight of the composition. Part 4 of the protective shell 3, which has a non-linear characteristic - the dependence of the current on the applied voltage and the non-linear dependence of the dielectric constant on the strength of the electric field, is made of organosilicon rubber, in which part of the aluminum hydroxide (from 1095 to 60 95) is replaced by finely dispersed material based on zinc oxide. The length of the part 4 of the protective shell C with finely dispersed material based on zinc oxide can be from 0.1 to 0.5 or from 0.5 to 0.9 of the entire length of the fiberglass electrical insulating rod 1, while it is highlighted in green.

The protective shell of the polymer insulator is made from a composition containing dimethylmethylvinylsiloxane rubber, aerosil and aluminum hydroxide.

The composition is made by mixing the components in a mixer for 30-90 minutes.

Part of the aluminum hydroxide (from 10 95 to 60 95) is replaced with finely dispersed material based on zinc oxide by methods used in the production of insulators (injection molding, transfer or direct pressing).

The polymer insulator functions as follows.

On the protective shell C in the zone of increased electric field intensity, a significant electric charge accumulates, which cannot be redistributed along the protective shell C due to its low dielectric permeability. If the dielectric permittivity of the material increases, during the increase of the electric field, the conductivity of the material also increases, and the charge is redistributed along the protective shell C to the zone where the electric field strength in areas with low electric field conductivity, the insulating material does not change its dielectric properties and remains a dielectric with the previous properties, which performs the functions of a protective shell of a polymer insulator.

Claims (4)

USEFUL MODEL FORMULA 1. A polymer insulator containing a power assembly having a fiberglass insulating rod, the ends of which are connected to metal terminations and on which a protective sheath is applied, which is distinguished by the fact that part of the protective sheath is made of a material with a non-linear characteristic - current dependence from the applied voltage and the nonlinear dependence of the dielectric constant on the electric field strength. 2. Insulator according to claim 1, which is characterized by the fact that the protective shell is made of organosilicon rubber from solid or liquid silicone rubber, which contains dimethylmethylvinylsiloxane rubber, aerosol and aluminum hydroxide - up to 6095 by weight of the composition, and the part that has a non-linear characteristic - dependence current from the applied voltage and the non-linear dependence of the dielectric constant on the strength of the electric field, made of organic silicon rubber, in which part of the aluminum hydroxide is replaced by a finely dispersed material based on zinc oxide and is from 10 95 to 60 95. C. Insulator according to claim 1, characterized in that the length of the part of the protective shell made of a material having a non-linear characteristic is from 0.1 to 0.5 of the entire length of the electrically insulating rod, and it is highlighted in green. 4. The insulator according to claim 1, which is characterized in that the length of the part of the protective shell made of a material having a non-linear characteristic is from 0.5 to 1.0 of the entire length of the electrically insulating rod, and it is highlighted in green. Shi 4 I yo I I y Ne x Ж WHAT I xx i. eat | d; she shchi u I moh i i gYa