RU2331737C2 - Method for strengthening and protection of old reinforced concrete foundations, piles and stands of electric installations from environmental impacts - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention is attributed to methods for repairing, strengthening and protection from environmental harmful impacts of in-service reinforced concrete foundations, stands and piles used for equipment of switching stations and for intermediate or angle-tension towers of power lines, or building structures of buildings. Method for strengthening and protection of old reinforced concrete foundations, piles and stands of electrical installations form environmental impact consists in that steel protective casing including two semicylinders is created around existing disrupted reinforced concrete structure for the rest lifetime. Semicylinders have designed protection length in overground and underground zones and wall thickness providing intended lifetime for reinforced concrete structure with regard to galvanic influence thereon of reinforcement in concrete. Semicylinders are sealed together by welding. Side inner cavity formed between protective casing and old reinforced concrete structure is filled with old structural concrete or other compound. In upper overground part, waterproof plug with atmospheric covering is installed, underground part of protective casing being used as natural earth lead for electric installation.

EFFECT: improvement of reinforced concrete structure fastness to environmental impacts.

Description

The invention relates to methods for repair, reinforcement and environmental protection of reinforced concrete foundations, racks and piles used for the equipment of electrical substations, as well as intermediate or anchor-angle supports of power lines, or building structures of buildings. The invention allows, along with the simplification and unification of the repair technology, to significantly increase the resistance of these reinforced concrete structures to external influences and to increase the resource for their work in soils and atmospheres of various aggressiveness for a given period.

For new foundations that have not yet been destroyed, there is a way to protect reinforced concrete foundations and building structures installed on them from the harmful effects of the environment according to copyright certificate No. 1314743 [1], which consists in stabilizing the temperature and humidity conditions in the soil around the foundations by creating an airtight screen on the soil surface.

For old foundations, this method is not acceptable, since it does not allow to strengthen the mechanical properties of the foundations.

The existing practice of repairing with strengthening the mechanical properties of foundations by concreting their upper part (installing concrete bandages with a height of 0.2-0.5 m) ensures the durability of the protected part for a period of not more than 2-5 years. This is due to the fact that the density of the concrete produced at the picket is usually low, the adhesion of the new concrete to the old is weak due to the difficult cleaning in the field of the old foundation from destroyed concrete particles, and the length of the protection zone is insufficient to stop the destructive processes in concrete. The massive use for such repairs of foundations of special concrete of the EMACO series [2], which have important properties for repair: quick curing, high initial density and low water absorption, is too expensive. For example, the calculations show that the average cost of repairing the foundation of the intermediate support of 500 kV overhead lines in a section 0.5 m long from its top using this material will be about 10 thousand rubles. Considering that the required protection zone for the foundation can be 0.9-1.5 m, then, accordingly, the cost of repair can increase by 2-3 times.

In addition, the foundation repair shell (concrete band) in the absence of concrete reinforcement does not work well in tension, even with the use of special concrete. The use of reinforced concrete bandage for repairing the foundation, with the installation of metal corners at its four corners and welding horizontal metal rods to them in the form of a lattice, strengthens the mechanical characteristics of the foundations, but makes repair more expensive and complicates, making it inefficient. The concrete used in this case for the repair shell (over the crate) performs only the function of protecting this reinforcement from corrosion. Such repairs do not protect the old foundation and the new repair composition from destruction under the influence of the environment, as it does not limit the contact of concrete with the external environment.

Closest to the claimed one is a method of reinforcing in-service reinforced concrete centrifuged racks used for equipping electrical substations and VL supports by installing metal bandages [3] (see the Standard Instructions for the operation of overhead power transmission lines with a voltage of 35-800 kV RD 34.20.504- 94).

To implement this method, a metal bandage consisting of two half-cylinders having bend planes along the generatrices of the cylinder in which the required number of holes has been drilled is installed on the object being repaired, a cylindrical or conical reinforced concrete centrifuged stand in the place of greatest cracking. Bolts are inserted into the holes, with the help of which the half-cylinders, after installing them on the rack, are pulled together. Bolted joints are not sealed. That is, the specified bandage is intended mainly for the perception of part of the mechanical load of the rack and to keep the concrete from further cracking. The lack of sealing of the protection zone of the bandage does not allow to stop the destructive processes occurring under it as a result of the interaction of the reinforced concrete structure and the environment and, therefore, protect the object from further destruction. The absence of a tight fit of the bandage to the reinforced concrete structure does not help to limit the evaporation of moisture from the protected surface of the structure and, therefore, does not prevent fresh aggressive reagents from sucking into this area. That is, the metal bandages currently used, along with the mechanical reinforcement of the reinforced concrete structure, do not protect this structure from the harmful effects of the environment.

The objective of the present invention is to provide a method for repairing old reinforced concrete structures using a steel hermetic shell, which, along with improving the mechanical characteristics of repaired objects, can significantly increase their resistance to external influences.

Other materials suitable for creating a tight connection between several parts by welding or gluing and having the required mechanical characteristics to strengthen the repaired reinforced concrete structure, as well as the necessary durability and linear expansion coefficient close to steel or concrete, can be used as a shell .

In accordance with clause 6.25 of SNiP 2.03.01-84 * for the purpose of reinforcing reinforced concrete structures in operation, the strength or cross-section of the remaining old concrete or reinforcement damaged due to corrosion can be ignored when they are reduced by 50% or more. It follows that a decrease in the cross-section of the elements of the reinforced concrete structure or the strength of concrete by 2 times can be considered a limiting case bordering on an emergency.

In accordance with clause 6.12 of the same SNiP, a decrease in strength by 20% already requires reinforcement of the reinforced concrete structure. However, since during operation not only the entire stand or foundation is exposed to active destruction under the influence of climatic factors, but only a small part of them in the transition zone “atmosphere - soil”, in the absence of corrosion hazard the longitudinal reinforcement can provide stable operation of the foundation for a long time.

The problem is solved due to the fact that using ultrasonic and vibration measurements on reinforced concrete structures in operation, the degree of defectiveness is determined according to the SNiP 2.03.01-84 * criteria specified above, and the necessary protection zone. The protection zone can also be determined without digging the foundation according to empirical expression:

R = 0.487 · H-3.28 [MPa]

where R is the average strength of the concrete foundation at a depth of H, MPa.

By known methods [4], the electrical resistivity of the soil ρ and the electrode potential φ of the steel sample relative to the copper-sulfate reference electrode are measured near the object to be repaired. Further, according to the Tarasov formula: K = 6.166-0.833 · ln ((φ-125) / ρ), the degree of danger of steel (K) corrosion under given ground conditions is determined. For this degree of corrosion hazard and Demin's curves [5], the average depth of steel corrosion (b) is found for the required service life of the object to be repaired. Based on the calculated corrosion depth, d = A + b expresses the thickness of the steel repair shell, where A is the minimum thickness of the steel repair shell selected according to the known conditions of the required mechanical strength of the repair for a particular protected object. According to the Uliga formula [6], the coefficient of corrosion rate of steel (m) is found, which is in galvanic contact with the reinforcement of the reinforced concrete structure, and then the maximum depth of steel corrosion is determined to be (b · m).

The method of repair and protection of reinforced concrete structures is as follows.

Half-cylinders with a radius of the circumference described above are sufficient for grasping this reinforced concrete structure over the entire length of its protection zone plus 3-5 cm at the prefabricated production of metal structures from steel sheet. The length of the forming half-cylinders should be at least calculated or empirically determined length of the protection zone of the reinforced concrete structure, and wall thickness - not less than calculated (d). A steel tread half-cylinder of the same radius as the main half-cylinder, but with a generatrix 10-15 cm long, is welded along the lower part of each half-cylinder. The tread half-cylinder is designed to perceive the corrosion current of the macropairs, in which the reinforcement of the reinforced concrete structure is cathode, and should have a wall thickness (m b).

At the preparatory production of dry concrete mixes and coatings, dry components are prepared for the manufacture of repair concrete, concrete waterproofing cork and materials for protective weather-resistant and anti-corrosion coatings.

As a repair composition, ordinary construction concrete of class B10-B30 or another composite can be used.

As a concrete for waterproofing cork, special mixes of the EMACO series or a mixture of non-shrink expanding McFlow cement and sand can be used, which can be laid directly on uncured building concrete with a layer of 2-3 cm.

Prepared building materials and information on the geometry of the repair go to the repair team to perform the repair of the reinforced concrete structure. Repair is as follows.

The reinforced concrete structure is excavated to the estimated repair depth in compliance with the necessary safety measures. The surface of the reinforced concrete structure is cleaned with metal brushes or using mechanization. Around the reinforced concrete structure, half-cylinders are installed and welded together, forming a repair shell. If the reinforced concrete structure being repaired is intended to operate as a natural ground electrode system for an electrical installation, then the metal structures installed on this reinforced concrete structure or its reinforcing frame are welded by means of a steel conductor to the repair shell. The space between the welded half-cylinders and the old reinforced concrete structure is filled with construction concrete prepared in a concrete mixer or in another way 2-3 cm below the upper edge of the metal shell. In the process of laying building concrete, it is vibrated by available means. Immediately after laying construction concrete, the remaining space in the upper part of the repair cup is filled with a waterproofing composition so that after hardening there is a slope for rainwater to drain from the surface of the waterproofing plug and water does not accumulate on the repair surface. If the reinforced concrete structure being repaired is intended to work as a natural ground electrode system for an electrical installation, then a polymer anticorrosion coating on the outer surface of the steel repair cup is applied only in the aboveground part and 15-20 cm below the ground level. Otherwise, it is completely covered with a waterproofing anticorrosive coating. After drying, the coating is backfilled with a layer-by-layer tamper. And after hardening (setting) of the concrete waterproofing plug in the upper part of the repair cup, it is covered with weather-resistant paint.

Using the proposed method of repair will allow with high efficiency and specified durability to strengthen and protect against the harmful effects of the environment of defective and emergency reinforced concrete structures. The use of the invention helps to prevent emergency situations and ensures the stable operation of old building structures in various soil, climatic and industrial conditions. The practically described repair method was carried out on 10 foundations of intermediate supports on guy wires of 500 kV overhead lines Zarya-Barnaul. The performance of the proposed method for the repair of reinforced concrete structures under various mechanical stresses and frost resistance was tested laboratory-based on the basis of the Siberian Research Institute of Energy.

Information sources

1. A method of protecting reinforced concrete foundations and building structures installed on them from the harmful effects of the environment. Author's certificate No. 1314743 of the USSR, H01R 4/66 Demin Yu.V., Dobzhinsky M.S., Tarasov A.G., Repyakh L.N., Romanov P.I., Zinkin A.A. Application No. 3828996. priority of the invention 04.24.87. Registered in the State. the register of inventions of the USSR 1.02.1987

2. Zakrzhevsky M.V. Repair of power line structures with special concretes of the EMASO ^® series. Second Russian scientific-practical conference with international participation: Power lines 2006: design, construction, operating experience and scientific and technological progress. Novosibirsk, June 5-9, 2006

3. Typical operating instructions for overhead power lines with a voltage of 35-800 kV, RD 34.20.504-94. - M.: Publishing House NTs ENAS, 2003 .-- 200 p .: ill.

4. A method for determining the corrosion state of metal elements of the anchor assembly of guy wires of supports. Application No. 2005119527/28 (022117) dated 06/16/2005

5. Guidelines for monitoring the state of the grounding devices of electrical installations RD 153-34.0-20.525-00. Developed by NSTU, MPEI, NPF ELNAP, ORGRES OJSC. Approved by the Department of Development Strategy and Scientific and Technical Policy of RAO UES of Russia on 05/07/2000. M .: ORGRES Service of Excellence, 2000. 64 p.

6. Ulig G.G., Revi R.U. Corrosion and the fight against it. L .: Chemistry, 1989.

Claims (1)

A method of reinforcing and protecting old reinforced concrete foundations, piles and racks of electrical installations from environmental influences, in which around the existing destroyed reinforced concrete structure for the remaining life period a steel protective shell is created, consisting of two half-cylinders, characterized in that the half-cylinders have an estimated length of protection (in aboveground and underground zones) and wall thickness, providing a given service life of the reinforced concrete structure, taking into account the galvanic effect of reinforcement in concrete on it, seal they are connected to each other by welding; The lateral internal cavity formed between the protective shell and the old reinforced concrete structure is filled with building concrete or another composite, and a waterproofing plug with weatherproof coating is installed in the upper above-ground part, while the underground part of the protective shell is used as a natural grounding system for the electrical installation.