EA026225B1 - Method for conducting seismic tests of electricity transmission towers - Google Patents

Abstract

The invention is related to the field of construction of power transmission lines. The technical result is provision of seismic tests of electricity transmitting towers with simulation of real earthquake conditions and real conditions of a transmission tower securing in soil and loading. The method includes installation of at least one transmission tower in a soil tray of a seismic platform filled with soil or with a mixture imitating soil and having a density corresponding to density of the soil in which the tested transmission tower is planned to be installed, fastening of loads to one or several cross-arms of the transmission tower, weight of the loads corresponding to weight of wires and/or fibre-optic cable between the towers of the transmission line for construction of which the tested transmission tower is intended, setting the soil tray into oscillatory motion in one or several cosecutively used modes while meeting the following conditions: frequency not higher than 300 Hz, duration at least 1 s, acceleration in vertical and horizontal directions at least 0.2 g, velocity not lower than 0.1 m/s and shift not less than 0.01 m, withdrawal of the tested transmission tower from the soil tray as it stops, and inspection of integrity of the transmission tower components and/or joints thereof.

Description

The invention relates to the field of construction of power lines, and specifically to a method for conducting seismic testing of power line poles, which allows you to check the seismic resistance of towers of various designs for power lines with a voltage of 0.4-35 kV, constructed in areas with seismicity of up to 9 points. Testing of power transmission towers constructed on the basis of reinforced concrete, metal, wooden, composite and combined racks can be carried out.

State of the art

A known method of testing racks of supports of power lines, providing for fixing in a glass-shaped box with the end for installation in the ground of the rack of the support of power lines. The rack is fixed in a glass-like box using jacks installed between the walls of the glass-like box and the surfaces of the rack. The end of the rack rests on a soil backfill. The tests are carried out directly by moving the glass-like box on the trolley in one horizontal direction (8I 169271 A1, IPC S01M 19/00, 1965).

The oscillatory motion of the glass-like box in the known solution is not provided, as well as the movement in the vertical direction, which indicates the impossibility of simulating the load on the power line support arising from an earthquake. Also, in the known solution, it is not possible to simulate the actual installation of the rack in the soil with modeling soil or soil in a specific area of the construction of the power line, for which the test support is provided.

SUMMARY OF THE INVENTION

The technical result of the present invention is to provide seismic testing of the supports of power lines with modeling the conditions of a real earthquake and the real conditions of fixing in the ground and loading of the support of the power line.

The achievement of this technical result is realized by the method of conducting seismic testing of power line poles, which provides for the installation of at least one power line support in an earth tray of a seismic platform, filled with soil or simulating soil with a mixture with a density corresponding to the density of the soil for installation in which the power line test pole is intended ;

securing on one or more traverses the supports of the power transmission line of goods, the weight of which corresponds to the weight of the wires and / or fiber-optic cable between the supports of the power lines, for the construction of which the test transmission line support is intended;

bringing the soil tray into oscillatory motion with one or more sequentially executed modes in compliance with the following conditions: frequency of not more than 300 Hz, duration of not less than 1 s, acceleration in the vertical and horizontal directions of not less than 0.2 §, speed of not less than 0.1 m / s and offset not less than 0.01 m;

removing the test transmission line support from the soil tray after it is stopped and checking the integrity of its constituent elements and / or their connections.

Oscillating motion of the soil tray can be carried out with the following modes: duration 1 s, acceleration with a magnitude of 30 d in a vertical direction, speed 3 m / s and an offset of up to 0.5 m, horizontal acceleration of 40 §, a speed of 3 m / s and an offset up to 0.5 m.

The oscillatory motion of the soil tray can be carried out with the following modes: duration 5 s, vertical and horizontal directions acceleration 10 §, speed 2 m / s and displacement up to 0.5 m.

Oscillating motion of the soil tray can be carried out with the following modes: duration 30 s, acceleration 2 § in the vertical and horizontal directions, speed 1 m / s and displacement up to 1.0 m.

In the best embodiment, the number of weights is fixed, corresponding to the number of wires and / or fiber optic cables for fixing which the test transmission line support is intended.

On the suspended insulators fixed to the traverse, rods can be fixed with the ability to simulate wires fixed to the traverses. In this case, the goods are fixed on rods.

Cargoes can be secured to power line supports insulators installed on the traverse.

Cargoes can be fixed rigidly on the supporting structure of the beam.

Along with the installation of goods, the weight of which corresponds to the weight of the wires and / or fiber optic cable, suspension equipment or a load corresponding to it in weight can be fixed on the supports.

The installation of the power line support in the soil tray is preferably carried out at a distance of at least 0.2 m from its inner walls and bottom.

The implementation of the invention

In order to conduct seismic tests of power transmission towers in accordance with the invention, a seismic platform is used, the diagrams of which are shown in FIG. 1 (side view) and in FIG. 2 (top view), where the following elements of the seismic platform are indicated by digital positions:

- 1 026225 support structure of the seismic platform - 1; seismic platform - 2;

pneumatic elements of pillow type - 3;

soil tray - 4;

vibrator - 5;

structural partition - 6;

base - 7;

cement preparation - 8.

A seismic platform of a different design can be used, provided that it is possible to practically implement the test conditions and modes provided for by the present invention.

A method for conducting seismic testing of power line poles includes installing at least one power line support 9 in a soil tray 4 of a seismic platform 1 filled with soil or simulating soil with a mixture with a density corresponding to the density of the soil for installation in which the power line under test 9 is intended;

securing on one or more traverses (not shown in the diagrams) supports 9 of the power line, loads whose weight corresponds to the weight of wires and / or fiber optic cable between the supports of power lines, for the construction of which the test tower 9 of the power line is intended;

bringing the soil tray 4 into oscillatory motion with one or more sequentially executed modes in compliance with the following conditions: frequency of not more than 300 Hz, duration of not less than 1 s, acceleration in the vertical and horizontal directions of not less than 0.2 d, speed of not less than 0, 1 m / s and an offset of at least 0.01 m (d is the value of the acceleration of gravity);

removing the test tower 9 of the power line from the soil tray 4 after it is stopped and checking the integrity of its constituent elements and / or their connections.

The table shows the main test modes that correspond to several basic amplitude-time characteristics that simulate possible seismic loads on the power line poles during an earthquake.

Mode type loading Acceleration (§) on axes Speeds (m / s) on axes Displacement (m) by axles Duration loading, s ΟΖ OH (ΟΥ) ΟΖ Oh (ΟΥ) ΟΖ OH (ΟΥ) Shock seismic +30/10 40 + 3 / -1 3 + 0.5 / 0.2 0.5 up to 1.0 Hard- seismic 10 10 2 2 0.5 0.5 up to 5.0 Soft- seismic 2 2 one one 0.7 1,0 up to 30.0

The table shows: ΟΖ - vertical axis, ΟΧ (ΟΥ) - horizontal axis.

The modes given in the table can be implemented during testing, as noted above, individually or sequentially. The amplitude characteristics of the vibrations are taken at least with a seismicity of 6 or less points of the acceleration amplitude - ± 50 cm / s ² , speeds - ± 4 cm / s, displacement - ± 2.0 cm;

with a seismicity of 7 points, the acceleration amplitudes are ± 100 cm / s ² , velocities ± 8 cm / s, displacements ± 4.0 cm;

with a seismicity of 8 points, the acceleration amplitudes are ± 200 cm / s ² , velocities ± 16 m / s, displacements ± 8.0 cm;

with a seismicity of 9 points, the acceleration amplitudes are ± 400 cm / s ² , velocities ± 32 cm / s, displacements ± 16.0 cm.

The amplitudes of accelerations, velocities and displacements in the vertical direction are set, as a rule, equal to 0.7 values for horizontal directions.

Seismic platform 2 provides two- and / or three-component movement and provides a measuring and computing complex that provides measuring instruments at control points on seismic platform 2 for measuring accelerations and movements in the directions of test movements;

on the side walls of the soil chamber 4 for measuring accelerations in horizontal directions; on the bottom of the soil chamber 4 under the test support 9 for measuring acceleration in the vertical direction 2,026,225.

The sensors of the measuring and computing complex are installed to ensure contact with the test object. The fidelity of the required test modes is monitored. Deviations in movement amplitude ± 15%, acceleration amplitude ± 15%, frequent vibration ± 0.5 Hz at frequencies up to 35 Hz, exposure duration ± 10% are allowed.

The installation of the power line support 9 in the soil tray 4 is carried out at a distance from its inner walls and bottom of at least 0.2 m, usually 0.2-0.3 m. The support 9 is installed in the ground in the normal position provided for a particular design test support 9.

In the soil chamber 4 form a soil environment with the desired characteristics. The characteristics of the soil environment during testing should meet the characteristics of the soil or soil of the region of construction of the object for which the use of this batch of supports is supposed. During loading, the soil is layer by layer (layer height no more than 30 cm) compacted to specified values. Monitoring the characteristics of the soil is carried out at each stage of backfill. The test support 9 is set in a predetermined manner (immersion, indentation, etc.), ensuring the reproduction of the standard unfastening of the test sample. It is not allowed to conduct seismic testing of supports 9 under conditions of full or partial hard termination.

Tests of supports 9 of the power line are carried out in their standard completeness. An amount of freight corresponding to the number of wires and / or fiber optic cables is secured to the power line support 9, for fixing which the test power line support is intended. A variant of a different number of cargoes, a different simulation of the loading of the support 9 of the power line is possible. The loads are fixed on the insulators installed on the crosshead of the support 9 of the power line, or the loads are fixed rigidly on the supporting structure of the beam. In the case when the power line support 9 provides suspension insulators, then rods are mounted on the suspension insulators with the possibility of simulating wires attached to the traverses, and the loads are fixed on rods. Along with the installation of weights, the weight of which corresponds to the weight of the wires and / or fiber-optic cable, suspension equipment provided for installation on a test transmission line support 9 or a weight corresponding to the weight of the suspension equipment can be fixed on the support 9.

When monitoring the condition of the test support in order to identify its damage, places of damage and destruction are identified. Those are recorded using photography. The power line support 9 is considered not to have passed seismic tests if the integrity of the structure of the support and / or any of its elements is violated; deformations and / or damage to the support and / or any of its elements are detected; the top of the support is deviated from the vertical axis by more than the following value for steel supports - by 1/200 of the height of the support, for reinforced concrete supports - by 1/150 height, for wooden supports - by 1/100 height.

Implementation of the invention in other aspects not mentioned above is carried out using known means and methods. The example embodiment of the invention is not exhaustive. Other embodiments of the invention are possible corresponding to the scope of patent claims.

Claims (10)

CLAIM 1. A method of conducting seismic testing of power line poles, including installing at least one power line support in an earth tray of a seismic platform filled with soil or simulating soil with a mixture with a density corresponding to the density of the soil, for installation in which the power line test pole is intended to be mounted on one or several traverses of the support of the power transmission line of goods, the weight of which corresponds to the weight of the wires and / or fiber-optic cable between the supports of the power lines a feeder, for the construction of which the tested power line support is intended, bringing the soil tray into oscillatory motion with one or more sequentially executed modes, subject to the following conditions: frequency of not more than 300 Hz, duration of at least 1 s, acceleration in the vertical and horizontal directions of at least 0.2 d, a speed of at least 0.1 m / s and a displacement of at least 0.01 m, the removal of the test transmission line support from the soil tray after it is stopped and the integrity check is checked of its components and / or their compounds. 2. The method according to claim 1, characterized in that the oscillatory movement of the soil tray is carried out with the following modes: duration 1 s, in the vertical direction acceleration with a value of 30 d, speed 3 m / s and an offset of up to 0.5 m in the horizontal direction acceleration of 40 d, speed 3 m / s and an offset of up to 0.5 m. 3. The method according to any one of claims 1 or 2, characterized in that the oscillating movement of the soil tray is carried out with the following modes: duration 5 s, in the vertical and horizontal directions, acceleration 10 d, speed 2 m / s and displacement up to 0.5 m 4. The method according to any one of claims 1 to 3, characterized in that the oscillating movement of the soil tray is carried out with the following modes: duration 30 s, acceleration 2 d in the vertical and horizontal directions, speed 1 m / s and offset up to 1.0 m . 5. The method according to any one of claims 1 to 4, characterized in that they fix the number of goods corresponding to the number of wires and / or fiber optic cables, for fixing which the test transmission line support is intended. 6. The method according to any one of claims 1 to 5, characterized in that the rods are mounted on pendant insulators fixed to the traverse with the ability to simulate wires secured to the traverses, and the loads are fixed on rods. 7. The method according to any one of claims 1 to 5, characterized in that the goods are secured to power line poles installed on the crosshead. 8. The method according to any one of claims 1 to 5, characterized in that the loads are fixed rigidly on the supporting structure of the beam. 9. The method according to any one of paragraphs.5-8, characterized in that, along with the installation of goods, the weight of which corresponds to the weight of the wires and / or fiber optic cable, suspension equipment or a load corresponding to it by weight is fixed on the supports. 10. The method according to any one of claims 1 to 9, characterized in that the installation of the power line support in the soil tray is carried out at a distance from its inner walls and bottom, which is at least