RU232323U1 - Foundation of a reinforced concrete support for an overhead power line - Google Patents

Abstract

The utility model relates to the field of electric power engineering, namely to types of fastening in the ground of reinforced concrete supports of overhead power transmission lines (OPT), in particular during the operation of overhead power transmission lines in flooded areas and in areas with increased wind speed pressure on wires and supports. A foundation for a reinforced concrete support for an overhead power transmission line, consisting of a rectangular reinforced concrete support slab, in the center of which a foundation post in the form of a hollow semi-cylinder is located, the inner part of the foundation post is the support post location zone, perpendicular to the reinforced concrete support slab, along its short side, symmetrically to each other on both sides of the foundation post, two flat ribs are located along the height of the foundation post with a bevel in their upper part, characterized in that a blind support cup is located in the foundation post, the support post is fastened to the foundation post by one fastening belt consisting of a clamp that fits around the support post along its outer surface and presses it to the foundation post with bolts with washers, nuts and locknuts that enter the holes in the flat ribs symmetrically on both sides of the foundation post, at the points of contact of the bolt heads with the surface of the flat ribs and lugs The clamps are provided with steel plates, wherein the steel plates are part of the reinforced concrete reinforcement of the foundation and are manufactured during its reinforcement. The total height of the foundation is equal to the depth of the dug pit. The technical task of the proposed utility model is to increase the stability of supports in waterlogged soils and in areas of increased wind load. 2 s.p. f-ly, 4 ill.

Description

The utility model relates to the field of electric power engineering, namely to types of fastening in the ground of reinforced concrete supports of overhead power transmission lines (OPT), in particular during the operation of overhead power transmission lines in flooded areas and in areas with increased wind speed pressure on wires and supports.

The closest analogue to the proposed utility model is a reinforced concrete foundation [1] 3 m high, consisting of a rectangular support plate with side dimensions of 3.5 x 2.7 m, in the middle part of this plate there is a post in the form of a semi-cylinder, in the lower part of the post at its base at the junction with the support plate there is a cylindrical recess with a diameter equal to the internal diameter of the post and a height equal to the thickness of the foundation at the base of the post, this recess is a lower through support glass, where the lower part of the support post is installed during its installation in the foundation, the inner surface of the foundation post is the contact zone with the outer surface of the support post, perpendicular to the foundation support plate and symmetrically to each other along the short side of the support plate there are two flat ribs with bevels in their upper part, with a height equal to the height of the foundation post, the thickness of the ribs is the same along their entire height. The support post is fastened to the foundation post by two fastening belts at the bottom and top of the foundation post; each fastening belt consists of a clamp that fits around the outer surface of the support post and is attached to the foundation ribs by fastening bolts with nuts and locknuts; the bolts enter the holes in the foundation ribs.

The disadvantage of this technical solution is the presence of a through support cup, allowing the heel of the support post to rest on the ground. Such a position of the support post creates the possibility of its vertical movement and an increase in the angle of rotation of the support in case of significant waterlogging of the soil or weakening of the support post fastening to the foundation post due to the support vibration under the action of alternating wind load. The presence of such a position forces the manufacture of a lower fastening belt in addition to the upper one. This increases the weight of the support, which is undesirable when operating power transmission lines on waterlogged sections of routes, since it increases the specific pressure of the support on the ground, which contributes to the "subsidence" of the support and its additional rotation.

The technical objective of the proposed utility model is to increase the stability of supports in waterlogged soils and in areas of increased wind load.

The technical result of the proposed utility model is an increase in the efficiency of the operation of overhead power transmission lines when operating on flooded sections of routes and in areas with increased wind speed pressure due to a reduction in the duration of emergency shutdowns of these lines due to the violation of the stability of reinforced concrete supports, and in the duration of operations when replacing their damaged posts.

This is achieved by a foundation of a reinforced concrete support of an overhead power transmission line, consisting of a rectangular reinforced concrete support slab, in the center of which a foundation post is located in the form of a hollow semi-cylinder, the inner part of the foundation post is the support post location zone, perpendicular to the reinforced concrete support slab, along its short side, symmetrically to each other on both sides of the foundation post there are two flat ribs along the height of the foundation post with a bevel in their upper part, characterized in that a blind support glass is located in the foundation post, the support post is fastened to the foundation post by one fastening belt consisting of a clamp that fits around the support post along its outer surface and presses it to the foundation post with bolts with washers, nuts and locknuts that enter the holes in the flat ribs symmetrically on both sides of the foundation post, at the points of contact of the bolt heads with the surface of the flat ribs and lugs The clamps are provided with steel plates.

In this case, steel plates are part of the reinforced concrete reinforcement of the foundation and are manufactured during its reinforcement.

In this case, the total height of the foundation is equal to the depth of the excavated pit.

The essence of the utility model is explained by drawings.

Fig. 1 shows a diagram of the foundation for a reinforced concrete support of an overhead power line, front view.

Fig. 2 shows a diagram of the foundation for a reinforced concrete support of an overhead power line, top view.

Fig. 3 shows a diagram of the fastening of the support post to the foundation post using the upper fastening belt.

Fig. 4 shows a general view of the foundation.

1 – support plate;

2 – foundation post;

3 – blind support cup;

4 – flat edge;

5 – support stand;

6 – clamp;

7 – bolt;

8 – washer;

9 – nut;

10 – lock nut;

11 – steel plate (on the outer side of the flat rib);

12 – steel plate (on the inside between the flat edge and the clamp);

13 – steel plate (on the outside of the clamp);

14 – gap;

δ – gap size;

D _support – nominal diameter of the support post;

D _support + Δ – nominal internal diameter of the foundation post.

The foundation of a reinforced concrete support of an overhead power transmission line consisting of a rectangular reinforced concrete support slab 1 with the dimensions of its sides, for example, 3.5 × 2.7 m, intended for placement in the ground with its long side parallel to the support crossarm, in the center of which a foundation post 2 is located in the form of a hollow semi-cylinder, the inner part of the foundation post 2 is the area where the support post 5 is located, perpendicular to the reinforced concrete support slab 1, along its short side, symmetrically to each other on both sides of the foundation post 2 there are two flat ribs 4 along the height of the foundation post 2, acting as a crossbar, with a bevel in their upper part, in the foundation post 2 there is a blind support cup 3 with a diameter equal to the inner diameter of the support post and a height equal to the thickness of the foundation support slab 1, for example, 250 mm, to prevent horizontal shift and "subsidence" of the support post 5. At in this case, the support post 5 is fastened to the foundation post 2 by one fastening belt consisting of a clamp 6, which fits around the support post 5 along its outer surface and presses it to the foundation post 2 with bolts 7, for example, M24, with washers 8, nuts 9 and locknuts 10, which enter the holes of the flat ribs 4 symmetrically on both sides of the foundation post 2. To prevent cracks from appearing at the points of contact between the heads of the bolts 7 and the surface of the flat ribs 4 and the eyes of the clamp 6, a steel plate 11 is provided, which is located on the outer side of the flat rib 4, a steel plate 12, which is located on the inner side between the flat rib 4 and the clamp 6, and a steel plate 13, which is located on the outer side of the clamp 6; steel plates 11, 12 and 13 are part of the reinforced concrete reinforcement foundation and are made during its reinforcement.

The total height of the foundation is, for example, 3.2 m, which corresponds to the depth of the excavated pit.

The foundation of a reinforced concrete support for an overhead power line works as follows.

The proposed foundation for a reinforced concrete support for an overhead power transmission line (Fig. 1, Fig. 2) includes a support plate 1, in which a cylindrical recess is provided, called a blind support cup 3, where the heel of the support post 5 is installed during installation in the foundation. D _{of the support} is the nominal size of the diameter of the support post 5, which is equal, for example, to the diameter of the base of a typical centrifuged post SK22.1-1.1 of the reinforced concrete support PB 35-3.1t or other similar supports from this size range [2]. The size of the internal diameter of foundation post 2 is increased by the value Δ, compared to the external diameter of support post 5, so that support post 5 easily enters foundation post 2 during installation, while the nominal internal diameter of foundation post 2 will be equal to D _support + Δ, while the angle of rotation of support post 5 from its vertical position should not exceed the maximum permissible value according to technical standards of 0.02 rad [3]. The inner surface of the blind support cup 3 is the contact zone of the outer surface of the base of the support post 5 and serves to prevent horizontal displacement of the support post 5 in the foundation, as well as to center the support post 5 when installed in the foundation post 2. The support of the heel of the support post 5 on the bottom of the blind support cup 3 prevents the "subsidence" of the support post 5 in the soil when it is flooded or when the fastening of the support post 5 to the foundation post 2 is loosened. The thickness of the wall of the foundation post 2 is taken equal to the thickness of a typical centrifuged post SK22.1-1.1.

Perpendicular to the support plate 1 of the foundation along the short side of its side are flat ribs 4, acting as a beam, provide an obstacle to the movement of the foundation due to the resistance of the backfill soil under the action of a horizontal shear force on the surface of the ground level [4]. Flat ribs 4 also act as beams increasing the resistance to the movement of the foundation in the soil under the action of horizontal shear forces and also serve to attach the support post 5 to the foundation post 2. Unlike the beam AR-6, the ribs are made of the same thickness along their entire width and height. This ensures a margin of safety for bending stresses in the vertical and horizontal planes during the operation of the foundation.

Fig. 2 shows the fastening, which is carried out by one upper fastening belt. Bolts 7 enter the holes in the eyes of clamp 6 and flat ribs 4. To prevent the occurrence of cracks in the places of contact of the heads and rods of bolts 7 with the surface of flat ribs 4 and eyes of clamp 6, steel plates 11, 12 and 13 are provided. Steel plates 11, 12 have a thickness of, for example, 10 mm, steel plate 13 has a thickness of, for example, 5 mm. Steel plates 11, 12 and 13 are made when reinforcing the foundation with steel reinforcement, being part of the foundation reinforcement. Lock nut 10 is needed to prevent loosening of the fastening of support post 5 to foundation post 2 when rocking support post 5 under the action of alternating wind load.

The clamp 6 can be made, for example, from reinforced concrete or from steel, by analogy with the details of fastening the beam AR-6 to the support post 5 during installation in the ground in a cylindrical pit or in pits with a disturbed soil structure [5]. The upper part of the rectangular support plate 1 of the foundation is made in the form of a trapezoid (Fig. 4) to obtain a lower blind support cup 3. The trapezoidal shape of the upper part of the support plate 1 also provides a large contact surface of the support plate 1 with the backfill soil in the pit, improving the stability of the foundation. The gap 14 between the clamp 6 and the flat rib 4 serves to ensure the possibility of tightening the fastener for the purpose of better fitting the surfaces of the support post 5 and the foundation post 2. The gap 14 is equal to the value δ, as indicated in Fig. 3.

The foundation with a blind support glass 3 has one upper fastening belt for fastening the support post 5 to the foundation post 2, which is sufficient for reliable fastening. If it is necessary to replace the support post 5, its dismantling is carried out in the reverse order. The presence of one fastening belt reduces the mass of the foundation, which has a positive effect on the operation of the power transmission line in waterlogged soils.

Thus, the use of the proposed foundation of a reinforced concrete support of an overhead power transmission line by using a blind support cup 3 in the foundation structure under the lower part of the support post 5 will increase the stability of reinforced concrete supports on flooded sections of routes and in areas with increased wind speed, reduce the duration of emergency shutdowns of overhead power transmission lines when replacing damaged posts of reinforced concrete supports, which in general will contribute to increasing the efficiency of the operation of overhead power transmission lines in extreme conditions of their operation.

Literature

1. Innovative patent No. 30810 Foundation for transmission line supports. Application No. 2014/1926.1 Registered in the state register of inventions of the Republic of Kazakhstan dated 24.12.2015. Bulletin No. 12.

2. GOST 22,687.3 Centrifuged reinforced concrete pillars for high-voltage power transmission lines. Designs of embedded parts and bearings. – 1986.

3. North-West Branch of the Institute "Energosetproekt" Standard design solutions 407-03-252. Anchoring in the soil of standardized reinforced concrete supports of 35-110 kV overhead lines - USSR Ministry of Energy. - 1981.

4. Reut M.A. Handbook of designing power transmission lines 2nd edition.

5. Vinogradov D.E. Securing supports for 35-750 kV power transmission lines – M.: Energy, 1980.-269 p.

Claims (3)

1. A foundation for a reinforced concrete support for an overhead power transmission line, consisting of a rectangular reinforced concrete support slab, in the center of which a foundation post in the form of a hollow semi-cylinder is located, the inner part of the foundation post is the support post location zone, perpendicular to the reinforced concrete support slab, along its short side, symmetrically to each other on both sides of the foundation post, two flat ribs are located along the height of the foundation post with a bevel in their upper part, characterized in that a blind support cup is located in the foundation post, the support post is fastened to the foundation post by one fastening belt consisting of a clamp that fits around the support post along its outer surface and presses it to the foundation post with bolts with washers, nuts and locknuts that enter the holes in the flat ribs symmetrically on both sides of the foundation post, at the points of contact of the bolt heads with the surface of the flat ribs and lugs The clamps are provided with steel plates. 2. A foundation for a reinforced concrete support of an overhead power transmission line according to paragraph 1, characterized in that the steel plates are part of the reinforced concrete reinforcement of the foundation and are manufactured during its reinforcement. 3. A foundation for a reinforced concrete support of an overhead power transmission line according to paragraph 1, characterized in that the total height of the foundation is equal to the depth of the excavated pit.