CZ20728U1 - Sealed cable grommet for medium and high voltages and biological protection thereof - Google Patents

Description

Hermetic cable gland for medium and high voltage and its biological protection

Technical field

The technical solution relates to a hermetic cable gland used in cable systems. The solution belongs to the field of electrical engineering, specifically to the group dealing with the construction of cables, conductors and insulators.

BACKGROUND OF THE INVENTION

Until now, the issue of reducing the level of partial discharges of hermetic medium cable glands has not been addressed. Low partial discharge level for this group of grommets (if required) - the usual solution is to fill the space between the electric field elements with a suitable oil - eg transformer oil. However, this solution usually did not meet other requirements - eg fire separation of the space between which the hermetic bushing is installed. With increasing requirements for fire safety and operational reliability even in extreme conditions (eg in a fire in one of the rooms), it is essential that the hermetic separation of the room separation is not compromised and the fire temperature does not cause the hermetic cable gland components to ignite. Another disadvantage of the solution without reducing the level of partial discharges in the hermetic cable glands is the lower lifetime until the insulation resistance values decrease and the substantially higher failure rate of such hermetic medium and high voltage cable glands.

The requirement for suppression of partial discharges was not applied in the construction of hermetic cable glands. It was not possible to simulate and model the distribution of electric charge and electric field inside the bushing structure. It was also assumed that voltage levels of around 10 kV are not risky in terms of partial discharges. However, the long-term operation of these bushings in nuclear power plant units has shown the need to reduce the value of partial discharges to a low value, which will not cause gradual destruction of the bushings' insulating materials, while not generating electromagnetic smog which increases the level of interfering fields for EMC operation.

Another requirement - ensuring the protection of persons in the vicinity of the hermetic cable gland against the penetration of ionizing radiation was not usually addressed in the cross-section of the hermetic cable gland. The most frequently used was the additional covering of the outer faces of the grommets, which by their composition and used materials ensure the shielding effect of radiation. In some cases, lead shot and lead wool were used. However, shielding shields make it difficult to access equipment controls and lead wave or shot did not respect the requirements to prevent partial discharges (coronary effects) in the electric field.

The above-mentioned disadvantages are solved by a hermetic cable gland according to the invention, which ensures a reduction of the values of partial discharges in the electric field between the electric conductor and the metal elements of the structure. The biological protection assembly in the hermetic cable gland provides protection against the penetration of harmful ionizing radiation through the hermetic cable gland,

The essence of the technical solution

The aforementioned disadvantages of the prior art are overcome by the arrangement of the inner insulating layers of the hermetic medium and high voltage cable gland. Biological protection against the penetration of ionizing radiation through the bushing consists of a composition (layering) of more suitable materials. These materials are typically lead and a mixture of polyethylene and boron. These materials are usually formed into plate-like bodies located directly in the body of the bushing. Some bodies made of a mixture of polyethylene and boron are provided with pads that serve as insulation between the individual electrically conductive elements within the bushing. The recess on the outer perimeter of the electric conductor is shaped so that the other assemblies are threaded on it. The shoulder adjacent to the inner perimeter of the bushing body is shaped so that the other internals are fitted inside

-1 CZ 20728 U1 of this shoulder. The internal conduits of the grommet formed by these bodies are shaped equivalent to the shape and size of the internal cross-section of the grommet and have at least one opening for the passage of the at least one electrical conductor. The internal fittings fill up the maximum cross-sectional area of the inner space of the hermetic cable gland. Only slight mounting gaps remain between the internal fittings, one or more conductors, the bushing body, or other components inside the bushing. At the same time, all electrically conductive elements contained in the bushing have a radius of curvature of the edges and surface finish to ensure anti-corona behavior at rated operating voltages. The radius of curvature of the edges is r = 3 to 15 mm. The maximum value of surface treatment of electrically conductive elements contained in the bushing is 8, according to the standard ČSN ISO 468, based on ČSN ENISO 4287, ČSN 013144.

The boron content of polyethylene is inversely proportional to the thickness of the inner liner formed by the mixture of polyethylene and boron. The less boron is present in the polyethylene, the thicker the layer must be to ensure sufficient shielding of the ionizing radiation.

Alternatively, the interior fittings may be secured within the body of the grommet by at least one mounting bolt of electrically non-conductive material. The material must have good electrical insulation properties and be tough. This mounting bolt secures the internals to each other and / or to the faces of the grommet.

However, some of the harmful ionizing radiation may penetrate through openings in the internal installations along the electrical conductors. The solution is to offset the openings through which the current conductors pass, in the individual bodies constituting the internal installation and in the faces of the bushing so that the openings are offset relative to each other by at least the diameter of the opening in the length of the bushing. As a result, the holes get out of one axis along which the radiation moves in a straight line. Thus, if radiation penetrates through the apertures in some of the body forming the inner lining and / or through the aperture in the front of the grommet, the radiation is captured by the body forming the interior lining and / or the front of the grommet 25 with the bore displaced. In practice, the displacement of the holes is accomplished by rotating the grommet faces with the eccentrically located opening and the inner assemblies with the centrically and / or eccentrically positioned openings during the manufacture of the grommet.

Substantial shielding of the penetrating ionizing radiation is thus achieved by fitting internal fittings of suitable shapes and dimensions from materials that effectively prevent the penetration of ionizing radiation 30 through the grommet. This creates an effective biological protection that can remove harmful ionizing radiation in a space beyond the grommet to a virtually unmeasurable value.

Inside the grommet, at least at the smallest distance between the electrical conductor and any conductive (metal) element, the free space of the mounting gaps is completely filled with a potting curing insulating material which is homogeneous in volume. In practice, however, all the loose mounting gaps between the electrical conductor, all biological protection materials, and the bushing body are filled with 35 homogeneous encapsulating curing insulating material. This material is usually composed of a mixture based on polyurethanes with fillers, possibly supplemented with fire extinguishing agents. Fire extinguishing agents reduce the flammability of the encapsulant and serve to slow down the spread of fire. Replacing the gas in the mounting gaps with a sealant prevents partial discharges between the 40 conductive elements inside the grommet.

The advantage of this solution is that the smallest distances of the conductive components are insulated from each other (filled) with a homogeneous mass, which has adequate electrical strength and volume and mechanical stability during operation in all designed operating modes. The choice of very small distances between the electrically stressed components within the 45 hermetic cable gland results from the requirement for a medium and high voltage gland to shield possible ionizing radiation from the nuclear reactor shielding. The grommet is located in an aperture of limited cross-section in the grommet wall of the nuclear reactor containment. At the same time, the encapsulating hardening insulating material fixes the individual internal components of the hermetic cable gland and protects them from shocks and vibrations.

-2GB 20728 U1

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side and front diagram of a stepped biological protection assembly; FIG. 2 is a side and front diagram of a three-conductor biological control assembly; FIG. 3 is a practical hermetic lead-through with body and wire removed; 4 is a side and front diagram of a grommet with rotated holes in the fronts.

Examples

Example 1

In this case, the hermetic medium and high voltage cable gland is designed as a single conductor, and thus is provided with one conductor 1 of electric current. The conductor 1 is provided with insulators 2 at both end faces 6 of the leadthrough. The leadthrough is made of stainless steel tubes and is equipped with a biological protection assembly 4. In this case, the biological protection 4 consists of two disks of blend 4a of polyethylene boron. in which one disk of lead 4b is placed. The biological protection 4 is mounted on the electric conductor 1. All free spaces, respectively. the mounting gaps 5 between the elements of the polyethylene-boron mixture 4a and the lead 4b. forming the biological protection 4, the electric conductor 1 and the bushing body 3 are homogeneously filled with the encapsulating curing insulating material 2. In this case, the encapsulating curing insulating material 7 consists of a fire extinguishing mixture. All electrically conductive elements contained in the bushing have a diameter and / or edge radius such that their anti-corona behavior at rated operating voltage, which in this case is 8 kV, is ensured. In this case, all electrically conductive elements contained in the bushing have a radius of r = 3 and r - 15, the surface treatment value is 3.2 and 0.8 according to ČSN ISO 468, based on ČSN EN ISO 4287, ČSN 013144.

The described solution is evident from Fig. 1.

Example 2

In this case, the hermetic medium and high voltage cable gland is designed as a three-conductor cable and is therefore provided with three electric conductors 1. Each electrical conductor 1 is provided with insulators 2 at the point of passage of the lead-through 6 of the bushing. The basic embodiment of the construction of Example 1 is adapted here in such a way that the electric conductors 1 are displaced uniformly by 120 ° with respect to the cross-sectional plane. Thus, the biological protection 4 and the front 6 of the feedthrough are provided with three openings, which are aligned with the conductors 1 of the electric current. All the free spaces between the elements of the polyethylene-boron mixture 4a and the lead 4b forming the biological protection 4, the conductors 1 and the lead body 3 are homogeneously filled with the potting curing insulating material 7. All electrically conductive elements contained in the lead have such a diameter and / or edge radius that their anti-coronary behavior is assured at the rated operating voltage, which in this case is 8/12 kV. In this case, all electrically conductive elements contained in the bushing have a radius of r = 3 and r = 15, the surface treatment value is 3.2 and 0.8 according to ČSN ISO 468, based on ČSN EN ISO 4287, ČSN 013144.

The advantage of the three-conductor design of the bushing is the reduction of short-circuit current losses around the phase conductors in the three-phase distribution system.

The solution described is evident from Fig. 2.

Example 3

In this case, the hermetic medium and high voltage cable gland is designed as a three-conductor cable and is therefore provided with three electric conductors 1. Each electric current conductor 1 is provided with insulators 2 at the point of passage through the face 6 of the bushing. This embodiment differs from Example 2 by rotating the faces 6 of the bushing and the elements of the mixture 4a of polyethylene with boron and of the lead 4b forming the biological protection 4 relative to each other. The faces 6 must be rotated in such a way that

-3GB 20728 The slots in the fronts 6 are pivoted relative to each other. offset by at least the diameter of the holes. This design change achieves a further reduction in penetration (penetration) of the linearly propagating ionizing radiation from the nuclear reactor's protective envelope into the secondary (non-biologically loaded) spaces.

The described solution is evident from Fig. 4.

Industrial applicability

The hermetic medium and high voltage cable gland is particularly suitable for supplying power to the main circulation pumps of nuclear power plants. The embodiment of the present invention provides all design operational and emergency modes. The grommet according to the invention is also suitable for high voltage outlets from various devices (transformers, electric motors, switchboards, etc.) where a low Partial Discharge value is required.

Claims (6)

1. A hermetic medium and high voltage cable gland forming part of the penetration walls of a nuclear reactor protective sleeve containing all electrical, measuring, output and supply conductors, and having a reduced insulation capacity of the body bushing (3), in comprising at least one electrical conductor (1) provided with insulators (2) at the ends of the grommet body (3) at the ends of the grommets (6), the distance of the individual electrical conductors (1) and / or other electrically conductive The gaps in the feedthrough are variable, characterized in that the mounting gaps (5) between the conductors (1) of the electric current and / or other electrically conductive and / or non-conductive materials are filled with a potting curing insulating material (7) whose structure is homogeneous. Hermetic medium and high voltage cable gland according to claim 1, characterized in that the homogeneous encapsulating hardening insulating material (7) consists of a fire extinguishing mixture. Biological protection of a hermetic cable gland, according to claim 1, which is part of the penetration walls of a nuclear reactor protective sleeve containing all electrical, measurement, output and supply conductors, and in which the insulating capability of the gland wall of the protective of a nuclear reactor package against ionizing radiation, characterized in that in the longitudinal axis of the grommet it comprises at least one inner lining of a lead layer (4b) and at least one inner lining of a homogeneous mixture of polyethylene and boron, at least one opening for the passage of the electric conductor (1), the at least one internal assembly comprising a mixture (4a) of polyethylene with boron has bushings on the inner circumference of the body (3) and / or on the outer circumference of the electric conductor (1) and all electrically conductive elements contained in the hermetic bushing have a radius of curvature of the edges r ranging from 3 to 15 mm and at the same time the maximum surface treatment of these electrically conductive elements is 8. -4GB 20728 U1 Biological protection of a hermetic cable gland according to claim 3, characterized in that the boron content of the polyethylene is inversely proportional to the layer thickness of the polyethylene-boron mixture. Biological protection of a hermetic cable gland, according to claims 3 and 4, characterized in that the internal assemblies are fastened to the gland faces (6) and / or to each other by at least one mounting bolt (9) of electrically non-conductive material. Biological protection of a hermetic cable gland according to claims 3 to 5, characterized in that the position of each hole in the lead-in (6) of the lead-through is offset from the position of the same hole in the opposite and at the lead-in (6) by at least the diameter of the hole.