RU2622007C1 - Segment method for enclosure structure strength determination - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: in the surveyed enclosure structure location, two cores are sampled at the entire masonry depth, the first core is taken in the middle of the outer brick row stretcher side, the second core is taken so that the grout layer was in the center of the core. Each obtained core is cut into cylinders, each cylinder undergoes strength testing by the shock pulse method, wherein the first core cylinder is struck only on the brick surface, and the second core cylinder is struck only on the grout surface. After testing, cylinders are laid in a place of their selection in the enclosure structure using a grout. Based on the measured strength values masonry structure compressive strength is calculated for in each layer corresponding to the cylinder arrangement.

EFFECT: improved accuracy of masonry enclosure structure strength characteristics calculation due to the possibility to determine the strength of all its layers along the structure cross-section by measuring the strength of samples taken at the entire masonry depth, and without loss of structural strength.

1 tbl, 1 dwg

Description

The invention relates to test equipment and can be used in construction to determine the estimated strength characteristics of building envelopes.

The strength of the supporting building envelope is the main characteristic in new construction and reconstruction of buildings. Brick walling occupies a significant place in buildings built more than half a century ago - at that time it was the main building material. Many of the constructed brick buildings are historically valuable buildings, others are used for repairs or reconstruction with a possible increase in number of storeys. Under these conditions, the determination of the strength characteristics of the bearing walls of a building requires maximum accuracy and reliability of the results.

Currently, there are two main standards that regulate the testing of masonry for compressive strength (GOST 32047-2012 “Masonry. Compression test method.” - M .: Standartinform, 2014 [1]; GOST 8462-85 “Wall materials Methods for determining the compressive and bending strength ". - M.: IPK Standards Publishing House, 2001 [2]). The current standards are mainly aimed at determining the strength of bricks when producing a batch at a factory. In addition, these methods do not allow investigating the strength of the building envelope in cross section, it is difficult to conduct tests with these methods to control the strength of the masonry when examining the structures built:

- sample preparation is a lengthy process, at least 3 days, and requires bulky equipment in the form of a press;

- the number of bricks required for testing is quite large: if in [2] two bricks were required for one batch, and the number of samples was not regulated by the standard, then [1] requires a minimum of three samples using at least 10 standard size bricks in each sample, which cannot to be selected from the load-bearing wall of the building without weakening it, and for historical buildings that have security requirements, it is generally impossible.

To solve the first question, which is the experimental technique, it is possible to use non-destructive testing methods. So, for example, the standard for monitoring the strength of concrete allows the use of such methods provided that a calibration curve is constructed for the compliance of this non-destructive testing method with the main one (GOST 10060-2012 “Concretes. Methods for determining frost resistance.” - M .: Standardartinform, 2014 [3]).

VSP 13-102-2003 "Rules for the inspection of load-bearing building structures of buildings and structures" (Gosstroy of Russia). - M .: Gosstroy of Russia, GUP TsPP, 2004 [4] it is said that it is advisable to preliminarily, using any operational (expert) method (a Fidzel hammer, ultrasonic surface sounding, etc.), examine concrete over its surface in design sections of structures and their elements in order to identify the possible presence of zones with varying concrete strengths.

The issue of weakening the bearing capacity of the building envelope when removing a significant number of bricks (moreover, intact, as prescribed [1, 2]) is solved in different ways. In [4] it is recommended that “the selection of bricks, stones and mortar from walls and foundations be made from non-supporting (under windows, in openings) or lightly loaded elements or structures to be dismantled and dismantled”. Although the same paragraph states that "strength is determined by testing samples and samples taken directly from the body of the test structure or nearby sites, if there is evidence of the identity of the materials used in these sites." Identical loaded and unloaded sections in the construction of the bearing wall are difficult to detect. Window sills, which are usually used for the selection of bricks, are in a different temperature and humidity mode, since batteries are usually installed behind them, and therefore, the wall can not be recognized as identical to the material.

In 1988, TSNIISK them. Kucherenko developed Recommendations (Recommendations for the inspection and assessment of the technical condition of large-panel and stone buildings. M: TsNIISK named after V.A. Kucherenko, 1988. 36 pp. [5], in which it was allowed (Sec. 3.12) “strength (grade) of natural stones of regular and irregular shape, as well as small and large blocks of heavy, silicate, cellular concrete and concrete on porous aggregates, shall be determined by compression testing of cubic samples or cylinders cut or drilled from stones, whole products or monoliths. ”Strength of natural ka mines and small and large blocks of these concretes are calculated by multiplying the test results of cubic samples or cylinders by scale factors, while it was separately noted that the coefficients can be used to determine the ultimate strength of ordinary clay and silicate bricks according to tests of cubes and cylinders with a rib height or a diameter of 40-80 mm. This method of determining the strength of building products is taken as a prototype of the invention.

The disadvantage of this method is that it does not allow to determine and take into account the strength of the brickwork in all its layers along the section of the masonry.

Studies have shown that the strength of old brickwork over its cross section is heterogeneous. The presence of the zone of maximum wetting of the masonry in the zone of negative temperatures, as well as a different number of freezing and thawing cycles inside the building envelope and on its surface, leads to an uneven decrease in the strength of the external building envelope over the cross section. The question arises about the need to determine and take into account the cross-sectional strength when examining and designing reconstructed buildings.

The aim of the invention is to develop a method for studying the strength of the load-bearing enclosing structure, which allows you to clarify the strength characteristics of the building envelope by determining its strength with sufficient accuracy anywhere in the load-bearing wall throughout its section without loss of structural strength.

The purpose of the invention is solved by the method of determining the strength of the building envelope from masonry, which consists in the fact that two cores are taken to the entire depth of the masonry in the studied place of the building, the first core is taken in the center of the spoon side of the outer row of bricks, the second core is taken so that the mortar layer was in the center of the core, each of the obtained cores is cut into cylinders, each of the cylinders is tested for strength by the pulse-shock method, and for the cylinders of the first core, impacts are made they are drilled only on the surface of the brick, and for the cylinders of the second core, impacts are made only on the surface of the mortar, the strength of the brick and mortar in the cylinders is measured, after testing the cylinders are connected with the mortar and the obtained cores are laid in the places of their selection in the enclosing structure, and according to the measured values Strengths calculate the compressive strength of the brickwork in each layer of the structure corresponding to the location of the cylinders.

The technical result achieved by the proposed method is to increase the accuracy of determining the strength characteristics of a brickwork enclosing structure by providing the ability to determine the strength in all its layers throughout the structural section by measuring the strength of samples taken to the entire depth of the masonry, and without loss of structural strength for due to the fact that the taken samples are fastened with a solution and are installed after testing in the same place.

In FIG. 1 shows a coring scheme from masonry.

The proposed method for determining the strength of the building envelope was carried out as follows.

Two cores 4 and 5 were selected using a drill 2 with a core sampler 3 at each designated place for monitoring the strength of the bearing wall 1 to the entire depth of the brickwork. It is recommended to use core samplers 3 with a core diameter of 50 or 80 mm. One core 4 was selected in the center of the spoon side of the outer row of bricks, the second core 5 was selected so that the solution layer was at the center of core 5. The first core 4 was used to determine the strength of the brick, the second core 5 - to determine the strength of the solution.

If core sampling is not possible on one side (with a large thickness of the outer wall), the core sampling procedure is as follows: to center the core sampling, first a drill with a diameter of 12-20 mm is drilled through with the formation of a through guide hole 6. Next, a guide is mounted on the drill 2 with core sample 3 in the form of reinforcement AI or AIII with a length of 1.5 times the wall thickness and a diameter of 10-12 mm. Using guide rod 7 allows with high accuracy to perform core sampling 4 and 5 towards each other.

The obtained cores were cut into cylinders 50 mm high. Each cylinder from two flat surfaces was tested for strength by a non-destructive shock-pulse method with a number of strokes of at least 5. The planes of the first and last cylinders, which are the outer and inner surfaces of the enclosing structure under study, were controlled by 10 strokes. When determining the strength of the planes of the cylinders of the first core, impacts were made only on the surface of the brick; for the second core, impacts were made only on the surface of the mortar. Thus, the section strength every 50 mm was the arithmetic mean of 10 strokes. Other statistical processing is carried out if necessary.

To test the cylinders for strength by the shock-pulse method, the ONPRIS-2.5 strength meter was used (http://www.geobrand.ru/nerazrush-control/proch/interpribor/oniks.html#tabCertificates), User Manual (instruction) on the strength meter Interpribor ONIX-2.5 (http://www.geobrand.ru/images/pnk/beton%20hammers/manual-interpribor-Oniks-25.pdf). Other known methods for determining strength by non-destructive methods can be used.

After the study, a brand grade solution was prepared not lower than the maximum brick strength obtained during the study, and the cores were laid in the wall in the same place. At the same time, the outer wall of the building does not lose its strength and retains its appearance.

Calculation of the strength characteristics of a brick wall as a whole when conducting a survey using the developed technique was carried out in accordance with SNiPP-22-81 * “Stone and stone-stone structures” (Gosstroy of Russia). - M .: FSUE TsPP, 2004 [6]. Knowing the strength of the brick and mortar in each section of the masonry, the calculated resistance R to the compression of the masonry was determined according to tables 2-9.

Thus, the strength of the masonry in each individual layer of the multilayer wall was determined.

When calculating the strength characteristics, the enclosing structure is considered as a multilayer wall with rigid bonds, in which rigid bonds provide load distribution between the structural layers. When calculating multilayer walls, the different strength and elastic properties of the layers, as well as the incomplete use of their strength when working together in the wall, should be taken into account by reducing the cross-sectional area to the material of the main bearing layer (layer with maximum strength). In this case, the layer with the greatest strength should be taken as the main bearing layer in solving our problem. The eccentricities of all efforts must be determined with respect to the axis of the reduced section.

In accordance with [6], when reducing the wall cross section to one material, the layer thickness should be taken as actual, and the layer width (along the wall length) should be changed in proportion to the ratio of the design resistances and the utilization factors of the layer strength according to the formula

where b _red is the reduced layer width, m;

b is the actual width of the layer, m;

R, m is the calculated compression resistance, kgf / cm ² and the coefficient of utilization of the strength of the layer to which the cross section is given (maximum value);

R _i ; m _i is the calculated compression resistance, kgf / cm ² and the coefficient of utilization of the strength of any other layer of the wall.

The coefficients of using the strength of the layers m and m _i , due to the fact that the multilayer structure considered by us consists of one material, it is advisable to take equal to 1.

The table shows the results of measuring the strength of the cylinders and calculating their strength characteristics: the compressive strength of the masonry in the section R _i , the reduced layer width b _red , the reduced layer area F _i .

The proposed segmented method for studying the strength of the building envelope allows you to determine the strength of the load-bearing wall of the building in cross section at any point in the structure and not violate the strength and historical appearance of the building.

Claims (1)

A segmented method for determining the strength of a brickwork made of masonry, characterized in that two cores are taken to the entire depth of the masonry in the studied place of the building, the first core is taken in the center of the spoon side of the outer row of bricks, the second core is taken so that the solution layer is in the center core, each of the obtained cores is cut into cylinders, each of the cylinders is tested for strength by the shock-pulse method, while for the cylinders of the first core, impacts are made only on top brick, and for the cylinders of the second core, impacts are made only on the surface of the mortar, after testing the cylinders with the mortar are laid in their places of selection in the building envelope, the compressive strength of the brickwork in each construction layer corresponding to the location of the cylinders is calculated from the measured strength values.

Images