RU2699918C1 - Diagnostic method of technical state of buildings and structures - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction and can be used for expert assessment and diagnostics of buildings and structures. Method is characterized by creating a spatial multiparameter digital model of an object, for which a geometric model of the object is constructed, which determines its contours and features of the geometry of its constituent parts. On the basis of instrumental studies parameters of materials of elements of the object are determined taking into account their damages and defects. Also, based on instrumental studies, physical and mechanical characteristics of bearing elements of structures, foundation and soil base are determined. Then presence and characteristics of interrelations of building-foundation-ground base system are determined. Temperature and humidity conditions of buildings or building structures are monitored, areas of a building or structure are determined with maximum and minimum temperature and/or humidity; thermal imaging of all internal walls is carried out in all rooms of building or structure, areas for installation of thermal detectors are determined and their location is fixed, after that automated monitoring of temperature readings is performed in selected areas. Each cycle of temperature and/or humidity fixation is set. Ground base parameters are determined taking into account of its damages and defects. Thereafter, a dynamic three-dimensional multi-parameter digital model is formed, which reflects the predicted change in time of each characteristic of the building-foundation-ground base system as a whole. Method comprises forming a finite-element model of a building or structure, based on which the calculation is carried out based on the time variation of the stress-strain state of the building or building structure, determining the degree of change of state and degree of durability of the building or structure in a given period of time.

EFFECT: technical result consists in improvement of accuracy of diagnostics and prediction of technical condition of building or building structure and its durability.

6 cl, 2 dwg

Description

The invention relates to construction and can be used for expert assessment and diagnostics of the technical condition of buildings and building structures, for predicting changes in the state of an object as a result of repairs and reinforcements, and also to calculate the durability taking into account the predicted changes in the stress-strain state of buildings and building structures.

There is a method of conducting surveys of building structures and assessing the technical condition of building structures (A. Gindoyan. A manual for the examination of building building structures. AO TsNIIPromzdaniy, M., 1997, pp. 7-11).

However, this method is complicated and time-consuming, the measurements made by this method are not accurate enough, and the analysis of the results is not reliable.

A technical solution is known for assessing the technical condition of metal structures of building structures (patent N RU N 2086741), which includes analysis of design and regulatory documents for metal structures, determining cross-section parameters for instrumental examination, establishing suitability criteria and their permissible values, making measurements and other instrumental examination , comparing the obtained values with acceptable values and establishing the suitability of the design for further safe operation luatatsii.

However, in this method is not achieved sufficient measurement accuracy with the least complexity.

The closest solution adopted as a prototype is "The method of constructing multi-parameter digital models of building objects, analysis and modeling of their condition (options)" according to patent No. 2177144, IPC G01C 15/00, publ. 12/20/2001.

The known solution discloses a method for constructing multi-parameter digital models of building objects, analyzing and modeling their condition, which consists in calculating the spatial coordinates of the points of the structural elements of the object and the points that determine the contour and the geometry of its component parts, conduct a detailed instrumental examination of the elements of the building object, determine actual parameters and characteristics of materials of elements of a building object and actual parameters of the basis and characteristics of the soil base, determine the actual values of the parameters of damage, defects and relationships of the individual components of the structural elements of the building object, based on these data, the spatial multi-parameter digital models of the object and its loading schemes are constructed, then the suitability of the elements of the building object and structure is determined by calculation General for further safe operation, lack of bearing capacity or necessary types of repair.

A disadvantage of the known solution is the lack of the ability to predict changes in the state of an object, taking into account changes in time of the stress-strain state of a building or building under the influence of temperature and humidity conditions.

The technical result from the use of this invention is to increase the accuracy of diagnosis and prediction of the technical condition of a building or construction and its durability.

The claimed technical result is achieved as follows.

A method for diagnosing the technical condition of buildings and construction structures is characterized in that they create a spatial multi-parameter digital model of the object, for which they build a geometric model of the object, which determines its contours and features of the geometry of its constituent parts. Based on instrumental studies, the parameters of the materials of the elements of the object are determined taking into account their damage and defects. And also, based on instrumental studies, the physicomechanical characteristics of the load-bearing structural elements, foundation and soil base are determined. Then determine the presence and characteristics of the relationship of the building-foundation-soil foundation system. The temperature and humidity conditions of buildings or structures are monitored, in which the areas of a building or structure with maximum and minimum temperature and / or humidity are determined in the following order: the existing weather conditions are recorded when they are relatively stabilized, characterized by a wind force of not more than 2 m / s , the absence of precipitation, the absence of temperature changes - not more than 5 ° C and humidity - not more than 10% during the day; conduct thermal imaging of all internal walls in all rooms of a building or structure, based on the obtained maximum and minimum temperature values on thermograms, determine abnormal areas for installing thermo-moisture recorders and fix their location, after which automated temperature monitoring is carried out in selected areas. Then carry out automated monitoring of temperature readings as follows. Set each cycle of fixing temperature and / or humidity with a frequency of not more than once per second for a period of at least 24 hours, record the maximum and minimum values and maximum daily fluctuations in temperature and humidity, when changing weather conditions and stabilize them, repeat the cycle of determining the temperature and / or humidity. The parameters of the soil base are determined taking into account its damage and defects. After that, a dynamic three-dimensional multi-parameter digital model is formed, which reflects the predicted change in time of each characteristic of the building-foundation-soil base system as a whole. Based on the obtained digital model, the finite element model of the building or structure is formed, on the basis of which a static calculation of the structure is carried out with the formation of the stiffness matrix of the finite element model and the vector of external influences, a dynamic calculation is carried out with the formation of the mass matrix, taking into account changes in time the deformed state of the building or construction, determine the degree of change in the state and the degree of durability of the building or structure in a given period of time change me.

At the same time, determining the parameters of the materials of the elements of the object, taking into account their damage and defects, includes carrying out mycological and environmental studies to obtain data on the relevant characteristics that affect the state of the materials of the building or construction.

In addition, determining the parameters of the soil base, taking into account its damage and defects, includes lithological studies, as well as mycological and environmental studies, to obtain data on the relevant characteristics that affect the state of the soil foundation.

Modeling of changes in time of the stress-strain state of a building or structure is carried out taking into account power and / or kinematic and / or temperature and / or dynamic and / or seismic loads.

The obtained and processed monitoring data of temperature and humidity fluctuations are processed using tabular and / or graphical construction of the maximum, minimum values of temperature and humidity in the rooms, temperature and humidity amplitudes, as well as the values of the temperature and humidity scatter at various points of the premises with the imposition of humidity and outdoor temperature. As a result of monitoring and processing the data obtained during the year, the created data array is used in conjunction with other diagnostic characteristics of the building and structure in order to predict its condition.

Example 1

The results of monitoring temperature and humidity fluctuations at an unheated Object No. 1 (ground floor) are shown in Table No. 1.

Table 1

In FIG. 1 shows the dynamics of changes in humidity of Object No. 1 (ground floor) for 12 cycles (August 4 decade - December 2 decade).

In FIG. 2 presents the dynamics of temperature changes over 12 cycles (August 4 decade-December 2 decade)

When creating a multi-parameter digital model of building objects (an exact geometric copy of a building or structure, which also includes a set of structural defects and physico-mechanical properties of materials identified during the examination and laboratory tests - “CLONE”), the design and regulatory documentation of the object is preliminarily analyzed, suitability criteria are established and their permissible values, create a geodetic substantiation of the object with respect to at least two base points while simultaneously equalizing iem errors. After that, the linear dimensions of the structural elements and the distances between the points of the contours of these structural elements are determined with respect to the spatial-spatial justification with simultaneous coding of the object description and identification of the structural elements of the object. A detailed instrumental examination of the elements of the construction object is carried out, the actual parameters and characteristics of the materials of the elements of the construction object and the actual parameters of the state and characteristics of the soil base are determined. The actual values of the parameters of damage, defects and relationships of the individual components of the structural elements of the construction object, the presence of sediments, corrosion, etc. are determined. and on the basis of these data, a spatial multi-parameter digital model of the object, its exact copy of the structure - “CLONE” and its loading schemes are built.

Based on the geometric copy of the CLONE structure, which is an exact copy of the object, which includes a set of structural defects and physico-mechanical properties of materials identified during the examination and laboratory tests, as well as including the foundation (at the time of the examination) and the soil foundation, its calculated course is created elemental model (FE model).

Using the FE model, taking into account the dynamics of changes in humidity and temperature of a real object, calculations of a building or building construction for given power, kinematic, temperature, dynamic, seismic, and other influences are performed. These calculations are made taking into account physical or geometric nonlinearity. By physical nonlinearity is meant, first of all, the nonlinear relationship between stresses and deformations of structural materials (plasticity, creep, viscoplasticity, etc.). In this case, the mechanical characteristics of the materials can be specified by the functions of deformations, their velocities, and time. Geometric non-linearity is understood as taking into account finite or large displacements and deformations, the presence of one-way bonds, etc.

In the static calculation of the structure, the stiffness matrix of the FE model and the vector of external influences are formed. In the dynamic calculation, in addition to these objects, a mass matrix is formed and, if necessary, a damping matrix.

The result of these calculations are the characteristics of the stress-strain state of a building or structure, on the basis of which a conclusion is made about its strength and rigidity. Analysis of the results makes it possible to diagnose the condition of the facility and classify the degree of its accident rate and maintainability.

Based on the calculation results, forecasts of the durability of the structure can be made.

This method allows the development of measures to restore the operational qualities of construction objects, as well as modeling behavior, analysis and prediction of their technical condition after the implementation of restoration operations, reconstruction or as a result of natural wear and tear.

This method allows to increase the accuracy of determining the actual load-bearing capacity of a building object, to speed up and simplify the analysis of documentation and the development of recommendations on the most effective solutions for strengthening and repairing building objects and their structural elements or issuing a conclusion on the further operation of the object as a whole. This method provides the possibility of using it for modeling and predicting the state of the object in the future.

Claims (6)

1. A method for diagnosing the technical condition of buildings and structures, characterized in that they create a spatial multi-parameter digital model of the object, for which they build a geometric model of the object, which determines its contours and features of the geometry of its constituent parts; on the basis of instrumental studies determine the parameters of the materials of the elements of the object, taking into account their damage and defects; determine the physico-mechanical characteristics of the load-bearing structural elements, foundation and soil base; determine the presence and characteristics of the relationship of the building - foundation - soil base system; they monitor the temperature and humidity conditions of buildings and structures, determine the parameters of the soil base taking into account its damage and defects, and then form a dynamic three-dimensional multi-parameter digital model that reflects the predicted time change of each characteristic of the building - foundation - soil base system based on the obtained digital model carry out the formation of a finite element model of a building or structure, on the basis of which a static calculation of the structure with the form By using the rigidity matrix of the finite element model and the vector of external influences, a dynamic calculation is carried out with the formation of the mass matrix taking into account the change in time of the stress-strain state of the building or structure, the degree of change in state and the degree of durability of the building or structure in a given period of time are determined. 2. The method according to claim 1, characterized in that the determination of the parameters of the materials of the elements of the object, taking into account their damage and defects, includes carrying out mycological and environmental studies to obtain data on the relevant characteristics that affect the state of the materials of the building or structure. 3. The method according to claim 1, characterized in that the determination of the parameters of the soil base, taking into account its damage and defects, includes lithological studies, as well as mycological and environmental studies to obtain data on the relevant characteristics that affect the state of the soil base. 4. The method according to claim 1, characterized in that the monitoring of the temperature and humidity conditions of buildings and structures includes determining the areas of a building or structure with maximum and minimum temperature and / or humidity in the following order: the existing weather conditions are recorded at their relative stabilization, characterized by force wind - no more than 2 m / s, no precipitation, no temperature changes - no more than 5 ^о С and humidity - no more than 10% during the day; conduct thermal imaging of all internal walls in all rooms of a building or structure, based on the obtained maximum and minimum temperature values on the thermograms, determine the areas for installing thermal moisture recorders and fix their location, after which automated temperature monitoring is carried out in selected areas. 5. The method according to claim 1, characterized in that monitoring the temperature and humidity conditions of buildings and structures includes automated monitoring of temperature readings, which is performed as follows: each cycle of fixing temperature and / or humidity is set at a frequency of not more than once per second per period not less than 24 hours; record the maximum and minimum values and maximum daily fluctuations in temperature and humidity; when weather conditions change and stabilize in established areas, data is re-collected. 6. The method according to claim 1, characterized in that the simulation of changes in time of the stress-strain state of a building or structure is carried out taking into account power, and / or kinematic, and / or temperature, and / or dynamic, and / or seismic loads.

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