RU2636606C1 - Method of installing support of power transmission lines for various climatic areas - Google Patents

Abstract

FIELD: construction.SUBSTANCE: method of installing power transmission lines for various climatic areas, consisting in that climatic areas differing from one another by parameters of wind pressure and the glazed frost wall thickness and lined up in the ascending order of these parameters, are divided at least into two groups, each of which comprises at least two climatic areas differing from each other by these parameters, and a support is used for the transmission lines in the same group of climate areas, the design of which is different from the support design in the other group of climatic areas. Wherein for each climatic area in the same group, the same support design is used, whose mechanical indices are calculated according to the working conditions in a climatic area with the greatest sequence number in the group, and for each climatic area in this group with smaller sequence numbers, for installing a support of a specific structure, a stand is used; the greater is the stand height, the smaller is the sequence number of a climatic area in the group, wherein the supports on the stands along a power transmission line are arranged at a distance increasing in accordance with the descending of the sequence number of a climatic area.EFFECT: increasing the effectiveness of the use of strength properties of supports of the same type for voltage lines in various climatic areas due to equalizing the load on the support in each climatic area by adjusting the height of the supports and the distance between them.4 dwg

Description

The invention relates to the construction, in particular, to methods of calculation and installation on power lines of lengthy load-bearing structures such as a rack of a support of a power line.

When developing supports for overhead power lines (OHL), it is necessary to calculate their mechanical strength for using supports in various icy and wind areas, because icy and wind areas determine the loads transferred to the support from the wires.

The rules of the Electrical Installation Devices PUE, approved by Order of the Ministry of Energy of Russia dated 08.07.2002 No. 204 (hereinafter referred to as the Rules ...) distinguish eight climatic regions in wind and ice, from the first to the special (table 2.5.1. "Standard wind pressure W0 at a height of 10 m above the surface of the earth "and table 2.5.3." The normative wall thickness of ice glare ve for a height of 10 m above the surface of the earth "from the Rules ...).

When calculating the overhead line and their elements, climatic conditions should be taken into account - wind pressure, ice wall thickness, air temperature, degree of aggressive environmental impact, lightning activity intensity, dancing of wires and cables, vibration. Determination of design conditions for wind and ice is carried out on the basis of appropriate maps of the climatic zoning of the territory of the Russian Federation with the refinement, if necessary, of their parameters in the direction of increasing or decreasing according to regional maps and materials of long-term observations of hydrometeorological stations and weather stations for wind speed, mass, size and type of icy-frosty deposits. The basis for regionalization by wind pressure are the values of maximum wind speeds with a 10-minute interval of averaging speeds at a height of 10 m with a repeatability of once every 25 years. Zoning on ice is carried out according to the maximum wall thickness of the ice accumulation of cylindrical shape at a density of 0.9 g / cm ³ on a wire with a diameter of 10 mm, located at a height of 10 m above the earth's surface, repeatable once every 25 years.

Thus, requirements for the design parameters of overhead lines have been developed for each climatic region, since it is impossible to create one universal support that could be used in all climatic regions (see Rules ... "Section 2. Sewerage of electricity", Chapter 2.4. Overhead power transmission lines with voltage up to 1 kV), since the loads transferred to the support increase with the district number, and, as a result, if you create support for the loads of the maximum area, it will be underused by its mechanical strength in areas with less stress. Such underutilization leads to an unreasonable rise in the cost of construction of overhead lines in areas with lower loads, because in these areas the support will be overweight and therefore overpriced. The overestimated weight of the supports also causes excessive costs for its installation. It is possible to develop its own support for each region, but this will cause a sharp increase in the product range at manufacturers, pickers and designers, which will also affect the cost of overhead lines (see JSC Federal Grid Company of a Unified Energy System. Organization Standard 35-750 kV overhead power transmission lines "SO 153-34.20.121-2006, approved by Order of JSC FGC UES dated 06.16.06 No. 187).

Currently, this problem is being solved as follows: most of the manufacturers of supports create supports for several neighboring climatic regions, for example, one type of support is used for I-IV areas, and the other for V-VII areas. Moreover, the support mechanics with this approach is calculated optimal for some middle region, for example, for the first case for III, and for the second for VI (NTC Electric Power Industry OJSC) Manual on the design of overhead power lines with a voltage of 0.38-20 kV with self-supporting insulated and shielded wires ", book 4" System of shielded wires with a voltage of 6-20 kV ", volume 4" Single-circuit reinforced concrete supports VLZ 10 kV for climatic regions IV-VII ", St. Petersburg, 2011, p. 20, 21, part V , "Design of single-chain reinforced concrete supports according to the project code 29 .0008 "p. 68-75) (hereinafter - the Guide ...) (adopted as a prototype).

With this approach, it is optimal for the area for which the support is designed, for over-estimated areas it is heavy, and for areas above the estimated, in order to reduce the load on the support, the spans between the supports should be reduced, which again leads to an increase in the cost of construction of overhead lines (see. ... part IV "Design spans for 10 kV overhead towers according to PUE 7th edition", pp. 63-66).

The present invention is aimed at achieving a technical result, which consists in increasing the efficiency of using strength qualities of the same type of supports for overhead lines in different climatic regions by balancing the load on the support in each climatic region by adjusting the height of the supports and the distance between them.

The height of the stand, in turn, is calculated so that in areas with less wind and ice on the support, optimal loads are created for it due to an increase in the spans between the supports. With this approach, the problem of underutilization of the mechanical strength of the support is solved: in each region, the support is used optimally, i.e. it does not have excess weight and excess cost, and also does not lead to an involuntary reduction of spans.

The specified technical result is achieved by the fact that in the method of installing power lines for various climatic regions, namely, that climatic regions that differ from each other in terms of wind pressure and ice wall thickness and are arranged in order of increasing these parameters are divided at least into two groups, each of which contains at least two climatic regions that are different from each other in the indicated parameters, and for power lines in one group of climatic regions They use a support installed on a foundation, the design of which is different from a support installed on a foundation for a power line in another group of climatic regions, for each group of climatic regions one type of support is used, the mechanical indicators of which correspond to the working conditions in the last climatic region in the group according to the serial number and which are arranged along the power line with a given distance relative to each other, and for each other climatic region in this group with decreasing they use the indicated type of support, which is installed on the foundation through a stand, with their serial numbers, the higher the more, the lower the serial number of the climatic region in the group, while in each climatic region in this group, with decreasing serial numbers of the support, the supports on the stands are placed at a distance relative to each other, increasing in accordance with the decreasing serial number of the climatic region.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present invention is illustrated by a specific implementation example, which, however, is not the only possible, but clearly demonstrates the possibility of achieving the desired technical result.

In FIG. 1 shows a diagram of the support, for example, for the IV region in the wind and ice;

FIG. 2 shows a support diagram, for example, for region III in the wind and ice;

FIG. Figure 3 shows the support structure, for example, for district II in the wind and ice;

FIG. Figure 4 shows the support structure, for example, for the 1st district in the wind and ice.

According to the present invention, a new method for installing power lines for different climatic regions is considered, which consists in that climatic regions that differ from each other in wind pressure and ice wall thickness and are arranged in increasing order of these parameters are divided into at least two groups , each of which contains at least two climatic regions that are different from each other in the indicated parameters.

And for power lines in one group of climatic regions, a support installed on the foundation is used, the design of which is different from the support installed on the foundation for power lines in another group of climatic regions.

Moreover, for each group of climatic regions, one type of support is used, the mechanical indicators of which correspond to the working conditions in the last in the group according to the serial number of the climatic region and which are built along the power line with a given distance relative to each other.

And for each other climatic region in this group with decreasing serial numbers, the indicated type of support is used, which is installed on the foundation through a stand, the height of which is greater, the smaller the serial number of the climatic region in the group. Moreover, in each climatic region in this group, with decreasing serial numbers, the supports on the supports along the power line are placed at a distance relative to each other, increasing in accordance with the decreasing serial number of the climatic region.

In other words, the essence of this approach is that, for example, for the range of regions I-IV, the mechanics of the support are calculated for the maximum IV region, and in areas below IV the same support is used, but installed on a support, the height of which is the higher, the lower climatic region number. For the range of regions V-VII, the support is calculated accordingly for the VII region, and in regions VI and V it is used with supports. The height of the stand, in turn, is calculated so that in areas with less wind and ice on the support, optimal loads are created for it due to an increase in the spans between the supports. With this approach, the problem of underutilization of the mechanical strength of the support is solved: in each region, the support is used optimally, i.e. It does not have excess weight and excess cost, and also does not lead to an involuntary reduction of spans. At the same time, the nomenclature of the supports does not grow, and only stands for the supports are added, which from a technical point of view are unified designs that differ only in length, which does not create any problems either in production or in assembly and design. The proposed approach can be implemented for supports made of various materials that are installed on the foundation, because for such supports it is possible to establish a supply between the foundation and the support.

The invention is illustrated by drawings, where in FIG. 1 shows a diagram of the support 1, calculated by mechanical indicators, for example, for the IV region in wind and ice (the most difficult climatic region in the group for the parameters of wind pressure and the wall thickness of ice), and in FIG. 2-4, respectively, supports 1 for regions III, II, and I in this group (that is, for climatic regions in the same group, where the parameters of wind pressure and ice wall thickness decrease, that is, less in relation to each other). In this case, the support 1 of each of the following climatic regions (Fig. 2-4) has a higher stand 2 compared with the above climatic region, and the distance between the supports with stands 2 is greater, the smaller the number of the region in the group. All supports are mounted on the foundation 3, properly fixed in the ground.

The claimed method includes not only a planning solution in terms of increasing distances and the breakdown of climatic regions into groups, but also design features of the technical design of the supports (supports without supports and supports with supports). In the field of creating power lines, the bulk of the metal consumption falls on the supports (vertically oriented long truss structures with braces and equipment for hanging wires). When all climatic regions are taken into account, the assortment of support structures increases sharply, which is not always fully in demand. When using the support unification algorithm for several climatic regions, the process of creating supports becomes effective and profitable. In addition, it becomes possible to use the same support in different climatic regions. This is beneficial both for the creation of typical power lines and for repair work, since it becomes possible to use poles from one district in another region (for places remote from the production of poles). Another important aspect is that it becomes possible to optimally use the same supports in different climatic regions for the bearing load. This is solved by increasing the distance between the supports in areas with decreasing numbers (where the parameters of wind pressure and ice wall thickness are lower than the mechanical capabilities of the support in their perception, resistance). With an increase in the distance between the supports, the load on them increases and becomes corresponding to the bearing capacity of the support (which was created constructively for the region with more serious wind pressure parameters and the ice wall thickness). And to compensate for the sag of wires, stands are used that raise the belt with braces 4 to a height at which the distance from the ground to the sag of the wires begins to comply with the standards.

Thus, a new way of organizing power lines eliminates the underutilization of the mechanical strength of the support: in each area the support is used optimally, i.e. It does not have excess weight and excess cost, and also does not lead to an involuntary reduction in spans and an increase in the number of supports. By design, the supports must comply with the standards adopted in the construction of supports for lines 0.4, 6, 10, 35, 110, 220, 330, 500, 750, 1150 kV. Structurally, such supports are not considered within the framework of this application, but we are talking about supports that are fixed to the foundation. It is this feature that allows the use of a stand, that is, an element of elongation of the support with respect to the line of the foundation.

The present invention is industrially applicable and can be manufactured under the conditions of production, adjusted for the release of supports for overhead lines.

Claims (1)

The method of installing power lines for different climatic regions, which consists in the fact that climatic regions that differ from each other in terms of wind pressure and ice wall thickness and are arranged in increasing order of these parameters are divided into at least two groups, each of which contains at least two climatic regions that are different from each other in the indicated parameters, and for transmission lines in one group of climatic regions a support is used whose design is different from the con structure of the support in another group of climatic regions, characterized in that for each climatic region in one group the same support structure is used, the mechanical indicators of which are calculated according to the working conditions in the climatic region with the highest serial number in the group, and for each climatic region in this group with smaller serial numbers for the installation of the support of the specified design use the stand, the height of which is greater, the smaller the serial number of the climatic region in the group, while Orae on supports power line positioned at increasing distances in accordance with decreasing atomic number climatic region.

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