RU2140625C1 - Method determining physical condition of buildings and structures - Google Patents

Abstract

FIELD: construction and running of buildings and structures. SUBSTANCE: each building or structure has inherent individual complex of parameters of dynamic vibration as consequence of properties of bedrock and foundation of object, type and quality of connection of individual units, parts and members of object which changes are presented by corresponding changes of parameters of dynamic characteristics of vibrations of object as whole, of its individual units, parts and members. Vibrations are measured with use of three- component vibration transducers having frequency range 0.5-100.0 Hz which record values of vibrations by three coordinates X, Y and Z at same time. Vibrations are measured under action of microseismic background of natural and man-made origin under which conditions examined object stays constantly, frequencies and forms of inherent vibration of object as whole, its units and individual members of structure, spectra of values of displacement, speeds and accelerations of points of object with coordinates X, Y, Z, decrements of damping ( absorption ), transfer functions of ground-foundation of object are determined. On basis of these diagnostical indications there are established changes of properties of bedrock and defects in structure of object emerging in process of running as well as physical condition of object, evaluation of safety of its further running, possibility of repair, reconstruction or necessity of tear-down of examined building or structure. EFFECT: improved authenticity of method. 4 dwg, 1 tbl

Description

 The invention relates to the field of operation and construction of knowledge and structures and can be used to determine their physical condition.

 The proposed method of non-destructive instrumental engineering and seismological inspection of buildings and structures using seismic methods, apparatus and equipment allows for high accuracy measurement and registration of spatial micro-oscillations of buildings and structures arising under the influence of microseismic background of natural and technogenic origin (microseism), in which the examined building or structure is located and determine the set of parameters of dynamic x of characteristic spatial microvibrations buildings or structures that show their physical condition as a whole, and individual blocks and elements.

 Conducting systematic surveys of buildings and structures from the moment they are put into operation, it is possible to obtain instrumental data and determine, depending on the duration and operating conditions, their level of physical condition, degree of wear, the possibility and expediency of reconstruction or the need for demolition.

 A known method of dynamic testing of buildings (1) using explosive charges, with corresponding negative factors, in connection with the use of the latter.

 In another known method for determining building selections (2), vibration levels are simultaneously recorded on the ground near the building, as well as in its lower and other parts, which makes it possible to determine the transmission coefficients of vibrations from the ground to the lower part of the building and further on its parts, taking into account the technogenic background. The method is used to determine the possibility of installing precision equipment and to predict the level of vibration in newly constructed buildings of the same type.

 A significant disadvantage of this method is the one-dimensional measurement of the magnitude of the vibrations, which does not provide the necessary idea of the dynamic stress state of the object being examined.

 The closest analogue of the claimed image are experimental methods for studying the vibrations of structures, including testing structures and structures with special loads [3].

The study of vibration of structures is carried out with the aim of:
determining the permissibility of these vibrations;
determination of the diagnostic characteristics of the structure to predict its behavior in case of a possible change in dynamic loads due to reconstruction, equipment change, etc .;
research and clarification of the true nature of physical and mechanical processes in the structure for the development and improvement of methods for calculating and constructing structures taking into account dynamic phenomena [3].

To determine the dynamic characteristics (natural frequencies, decrements of vibrations) of the structure or its any element, the following types of vibrations are resorted to:
- harmonic oscillations, the frequency of which varies in a fairly wide range; as a result of the tests, the amplitude and phase-frequency characteristics of the structure are obtained for each investigated waveform;
- natural vibrations excited by impact or initial displacement of the structure; in this case, the dynamic characteristics of the structure are determined by known methods from the obtained record of natural vibrations;
- fluctuations in transition mode during start-up (stop) of equipment in the construction or a special harmonic oscillation pathogen; test results allow to approximately determine the values of natural frequencies [3].

 Mandatory conditions for these tests are the use of special effects to excite forced or free vibrations of the object and the exclusion of influence on the quality of recordings of microseismic background noise.

 While the vibrations of a building or structure under the influence of a microseismic background of natural and technogenic origin, in the conditions of which they are constantly located, the proposed method uses instead of a special source to determine their individual set of parameters of dynamic characteristics.

 At the same time, there is no indication of the use of the obtained dynamic characteristics of the natural vibrations of the test object for assessing its physical condition for testing, whereas in the proposed method, the numerical values of the parameters of the dynamic characteristics of the vibrations of a building or structure are used as diagnostic signs of their physical condition.

 The technical result of the invention is to obtain numerical values of physical parameters that reflect the actual physical state of a building or structure, as well as the change in this state over time during operation.

 The technical result is achieved by the fact that in the method for determining the physical condition of buildings and structures, according to the invention, they measure their spatial vibrations under the influence of a microseismic background of natural and man-made origin (microseism), in the conditions of which the object under investigation is constantly located, by means of three-component vibration sensors providing simultaneous registration oscillation values along the coordinates X, Y and Z.

 Based on the data obtained, an individual set of parameters of the dynamic characteristics of vibrations inherent in each building or structure is determined, as a result of the properties of the underlying soil (base) and the foundation of the building or structure, mass and elastic characteristics of the structure of the building or structure, type and quality of connections of individual blocks, parts and elements buildings or structures.

 The change in the operation process of these properties is displayed, respectively, by changes in the numerical parameters of the dynamic characteristics of the spatial vibrations of the building or structure as a whole or their individual blocks, parts and elements.

 As a result, the frequencies and forms of the natural vibrations of the object as a whole, its blocks and individual structural elements, the spectra of displacement values, the displacement velocities and the accelerations of the object points with the coordinates X, Y, Z, the attenuation (absorption) decrements, the transfer functions of the soil - the foundation of the object are determined the foundation of the object - the floors and parts of the object in height, the components of dynamic deformations and stresses that occur in the structure of the object.

 Based on the obtained numerical information, the presence of changes in the properties of the underlying soil and the weakening of elastic ties in the structure of the object that arise during operation are determined, the physical condition of the object is determined and the safety of its further operation is assessed, and the possibility of repair, the need for reconstruction or demolition of the examined building or structure.

 The essence of the method is as follows.

The basis of the engineering-seismological survey method is two physical phenomena:
- each building or structure is characterized by an individual set of parameters of the dynamic characteristics of spatial vibrations, reflecting the properties of the underlying soil (base), foundation, building materials and structural features of the object, as well as their changes in time and violation of the integrity of the building structure of the object during operation;
- microseismic background of natural and technogenic origin, under the constant influence of which there are buildings and structures, forced to make spatial microoscillations at frequencies of the forms of natural vibrations.

 The microseismic background of natural and technogenic origin is a wave field, the energy parameters of microoscillations and the nature of the impact of which can vary widely from white and “colored” noise to the presence of a narrow-band polyharmonic and irregular pulsed effect in its continuous frequency spectrum from 0 to 100 Hz.

Actually white noise is characterized by a continuous spectrum of frequencies and constant amplitudes of displacements in the frequency range from 0 to 10 Hz and constant amplitudes of accelerations in the frequency range from 10 to 100 Hz. Moreover, the magnitudes of the amplitudes, depending on the region of the time of day, are in the first case of the order of 0.1-1.0 μm, and in the second case of the order of 0.1-3.0 mm / s ² .

 The influence of the wave field of the microseismic background excites forced spatial micro-oscillations of the building or structure as a whole, and in case of violation of the integrity of the building structure of the object, its individual parts and elements at frequencies of natural vibration modes, since an energy source such as white noise provides their micro-oscillations in the bands of natural resonant frequencies.

 As a result, the object as a whole and each weakened element of the object carry out forced spatial microoscillations at the frequencies of their own forms, which allows us to determine at the measurement points the numerical values of the parameters of the dynamic characteristics of the microscillations of the object and weakened elements, reflecting its current physical state.

The criteria for assessing the physical condition of buildings and structures, their individual blocks, nodes and elements are changes in time and space of the numerical values of the parameters of the dynamic characteristics of the object’s vibrations:
- frequencies and forms of natural vibrations;
- values of the amplitude of displacements, displacement velocities and accelerations at the measurement points;
- attenuation parameters;
- transfer functions soil - foundation, foundation - floors;
- component of dynamic deformations, stresses, etc.

 Aging of a building or structure is accompanied by a decrease in the strength properties of building materials and the structure as a whole, which is displayed as a change in the parameters of dynamic characteristics. The latter are determined during a detailed engineering-seismological examination of an object under the influence of a microseismic background of natural and technogenic origin, in the conditions of which the object is constantly located, by recording several tens, hundreds or thousands of measurement points of spatial micro-vibrations of its structure at frequencies of its own forms in the range from 0.5 up to 100 Hz with amplitudes from fractions to tens of microns.

 Local defects causing a change in the values of the absorption coefficients and elastic-inertial parameters, respectively, change the numerical values of the frequencies and deform the calculated or initially obtained configuration of the modes of natural vibrations of the building structure. Moreover, the nature and degree of deformation determine the interaction of the building structure and the defect, which allows, taking into account the design features, to identify anomalous absorption zones - zones of partial destruction and zones of violation of the properties of elastic bonds.

 Comparison of the values of the parameters of dynamic characteristics obtained during the examination of the object with the initial or previous values (during repeated examinations) allows us to assess the degree of change in the physical condition of the building or structure.

 The method is as follows.

 Using three-component vibration sensors and recording equipment, measurements and recording in the frequency range from 0.5 to 100 Hz of spatial micro-oscillations of the soil (base) and the building or structure occurring under the influence of a microseismic background of natural and technogenic origin are carried out.

 The upper level of the frequency range is established based on the requirements of sanitary standards for residential premises and possible frequencies of natural vibrations of individual elements of buildings and structures.

 The spatial microoscillations are measured using the three components X, Y, and Z according to the observation scheme, which determines the purpose and detail of the object survey.

 The observation scheme is implemented on a grid with a certain step in three mutually perpendicular planes passing along the width (X-component), length (Y-component) and height (Z-component) of the object, which allows one to reliably describe its spatial vibrations.

 Microscillations are measured by three-component vibration sensors at all points of the grid and the corresponding multichannel equipment when recording is performed simultaneously, or by a group of three-component vibration sensors in series.

 In the latter case, a similar three-component vibration sensor is installed on the ground near the object or inside it - a control (reference) point, the position of which remains unchanged during the measurement process.

 At each arrangement according to the observation scheme of a group of vibration sensors, their signals and the signal of the vibration sensor at the reference point are recorded simultaneously.

 Registration records at the reference point allow, according to the known method [2], to bring the registration records of the group of vibration sensors to a single signal level at the reference point, which is similar to the simultaneous recording of vibration amplitudes at all measurement points on the object.

 Since the measurement of the object's microoscillations is carried out under the influence of a microseismic background, the recording is carried out for several (up to tens) minutes, which allows you to accumulate and highlight a useful signal.

Then, based on the registration records U (t, X _i , Y _i , Z _i ), the spectra of amplitudes and phases (the latter in the case of simultaneous recording) A (ω, x _i , y _i , z _i ) and φ (ω, x _i , y _i , z _i ). By way of example, the spectra of amplitudes of micro-vibrations of a building are shown in FIG. 2.

The spectra of amplitudes and phases make it possible, by filtering (“cutting out”) the frequencies corresponding to the forms of the object’s own microoscillations, to obtain numerical values of the amplitudes A (ω _j , x _i , y _i , z _i ) and phases (while recording) φ (ω _j , x _i , y _i , z _i ) displacements, displacement and acceleration rates for each measurement point at the frequency of the natural vibration form.

 The data obtained make it possible to construct appropriate maps of the distribution of displacement amplitudes and phase maps (for simultaneous recording) in the observation planes at frequencies of natural vibration modes, which reflect the physical state of the object as a whole and its individual elements (Fig. 3).

 Close to the theoretical configurations of the distribution maps of the magnitudes of the displacements and phase maps of the modes of natural vibrations indicate a satisfactory physical condition of the building or structure.

 Deviations or distortions in the configuration of these maps arise as a result of changes in the physical state of an object, including a decrease in its spatial stiffness as a whole or of individual blocks and elements due to weakening of elastic bonds or violation of the integrity of the structure.

Registration records U (t, x _i , y _i , z _i ) at each measurement point allow calculating the parameters of the dynamic characteristics of the object’s micro-oscillations, which together in the form of a series of numerical values reflect the physical state of the building or structure at the time of the examination:
- the frequency and shape of the natural vibrations of the object as a whole, its blocks and individual structural elements;
- values of displacements, displacement velocities and accelerations at each measurement point on the object with coordinates X, Y, Z;
- logarithmic decrements of attenuation (absorption);
- transfer functions soil - the foundation of the facility, the foundation of the facility - floors and parts of the facility in height;
- components of dynamic deformations and stresses arising in the object, etc.

 The obtained parameters of the dynamic characteristics of microoscillations reflect the initial state and quality of the construction of the facility, or the actual physical state of the operated facility as a whole, its blocks and individual structural elements.

One of the known methods is determined from the amplitude spectra A (ω, x _i , y _i , z _i ) by the corresponding components the logarithmic attenuation decrement (attenuation parameter) at each measurement point at the frequencies of the forms of natural transverse, longitudinal and vertical vibrations.

 Based on the data obtained, maps of the distribution of the attenuation decrement in the observation planes are constructed and its average value is determined by the corresponding components for the object as a whole.

 Next, determine the values of the frequencies of the modes of natural vibrations at each measurement point and the average frequencies of the modes of natural vibrations for the object as a whole for the corresponding components.

 They plot the deviation of the frequencies of the modes of natural oscillations relative to the average frequency for each observation plane.

 The constructed maps and graphs of the parameters of dynamic characteristics and their average values reflect the actual physical condition of the examined object.

 In this case, the average values of the frequencies, damping decrements, the number and configuration of the modes of natural vibrations characterize the physical condition of the examined building or structure integrally (as a whole).

The initial registration records U (t, x _i , y _i , z _i ) allow us to calculate other parameters of the dynamic characteristics of the microoscillations of the examined object, reflecting its physical state.

The physical state of the object being examined is estimated based on the values of the parameters of dynamic characteristics calculated for each measurement point by comparing the obtained instrumental data:
- with design or regulatory;
- with the parameters of the dynamic characteristics of the reference object of the same type;
- with the previously obtained parameters of the dynamic characteristics of the object.

 The second of these methods is used in mechanical engineering for the diagnosis of the physical condition of machines [4]. A similar approach is promising in assessing the physical condition of typical buildings and structures based on a set of parameters of the dynamic characteristics of their vibrations.

 In addition, according to well-known physical laws, combinations and relationships between the values of the parameters of dynamic characteristics — amplitudes of displacements, decrements of attenuation, and changes in the frequencies of the modes of natural vibrations — distinguish places of weakening of elastic ties of the object’s structure.

 The combination of a higher value of the amplitude of the form of natural vibrations with a simultaneous decrease in their frequency indicates a weakening of the elastic bonds of the structural elements (in particular, the presence of a crack), is a diagnostic sign related to the last (fourth) method.

 Changes in the properties of the soil that arise during the operation on which the object under study relies, the properties of the foundation or the structure of the object, respectively, are displayed on the parameters of the dynamic characteristics of the micro-oscillations of the object.

 The nature of the defects in the detected abnormally fluctuating blocks, parts and elements of the object is established by methods accepted in repair-operational and construction practice.

 In some cases, when examining objects in operation or prolonged inactivity, re-examination may be undertaken, shifted by a reasonable time, in order to determine the dynamics of the development of established defects and to identify newly arising.

 A detailed examination, for example, of several typical panel residential buildings before their demolition will provide reliable information on the correlation of the established dynamic parameters of micro-vibrations and the anomalies detected with the general physical condition of building structures and defects actually detected during disassembly of both individual blocks and elements of objects, and their compounds.

Thus, the determination by the proposed method of the parameters of the dynamic characteristics of the micro-oscillations of buildings and structures, characterized in that the vibration measurements are carried out at the object under the influence of a microseismic background of natural and man-made origin by three-component vibration sensors, which allows:
- establish changes in the bearing capacity of the soil under the object and defects in the design of buildings and structures that arise during operation;
- assess the safety of further operation, the possibility of repair, the need for reconstruction or demolition of a building or structure;
- use the information obtained on the health of buildings and structures operating in various conditions to adjust the technical standards for the design, operation, repair and reconstruction of buildings and structures and obtain the corresponding economic effect.

 Example 1. The methodology of non-destructive instrumental engineering and seismological examination of the physical condition of buildings and structures by determining the parameters of the dynamic characteristics of the object’s micro-vibrations was tested during the examination of the laboratory and technological building (LTC) of the Institute of Semiconductor Physics of the Siberian Branch of the Russian Academy Sciences in the city of Novosibirsk.

 By the beginning of the survey work in 1993, the construction of the western extension to the LTK was underway, and by the time of the last stage of the survey in 1997, the eastern extension was commissioned (1996).

 Actually LTK is a five-story laboratory building, supported by a basement-basement floor and completed with a technical floor. These two floors house systems and engineering and technical support services for the functioning of the building.

 Structurally, the building and outbuildings are made with a reinforced concrete frame, strip foundations of concrete blocks and brick walls. The LTK frame consists of columns (6x6 m grid), crossbars, floor slabs and stiffness diaphragms. The total length of the building is 60 m, the width is 13.5 - 16.5 m, the height of the building is about 24 m.

 The western extension has a grid of columns 6x3x6 m and the adjoining of the walls to the LTK by embedding in shtrabs. The total extension is 40 m, the width is 16.5 m.

 The eastern extension has a grid of columns 6x3x6 m, a similar junction of walls to the LTK, a length of 25 m and a "G" -shaped plan.

 At the first stage, the survey was carried out under the influence of a monochromatic wave field with a frequency of 2.083 Hz, created by a working 3G-100/200 high-pressure piston compressor located at a distance of about 300 meters at an angle of 35 degrees to the longitudinal axis of the LTK.

 The measurements were carried out on the ground near the building and along the longitudinal axis of the building (component Y) on the floor in the middle of the corridors of six floors, starting from the basement-basement, at ten points on each floor. Component X was adopted directed perpendicular to the longitudinal axis of the building (Y-component), component Z-vertically from bottom to top.

 According to the data obtained, a map of isolines of the magnitudes of the amplitudes of the displacements of the building’s vibrations along the X, Y, Z-components in the vertical plane passing along the longitudinal axis of the building in the direction of the Y axis was constructed (Fig. 1).

 The presented contour map indicates that under the influence of a monochromatic wave field, the building oscillates in the transverse direction (component X) with a maximum displacement of about 24 μm on the fifth floor of the LTC on the adjoining side of the western extension. The values of the displacements of the transverse vibrations of the western end of the LTK building increase eight times from the basement-basement to the fifth floor. This is due to the rocking of the building in the transverse direction, since the frequency of the monochromatic field is close to the frequencies of the natural transverse vibrations of the building (2.12 - 2.4 Hz).

 At the second stage of the survey, measurements were made of the spatial micro-oscillations of the LTK building with extensions under the influence of a microseismic background of natural and technogenic origin. The measurements were carried out along the longitudinal axis of six floors of the building with a step of 3 m, with reference to the grid of columns.

The data obtained were constructed spectra microvibrations building at 252 ^th measurement points, which are represented in FIG. 2, where the frequencies of the natural vibration modes of the LTC building are distinguished:
- transverse (X-component) - 2.12, 2.42, 2.7, 3.45 Hz;
- longitudinal (Y-component) - 2.65 Hz;
- vertical (Z-component) - 8 - 10 Hz.

 In FIG. Figure 3 presents maps of magnitudes of displacement amplitudes for the first two forms of natural transverse vibrations of the LTC building with extensions in the median plane of the building. At the same time, floors are indicated on the vertical axis, and the length of the building in meters on the horizontal axis.

In analyzing the maps of FIG. 3 should be considered:
- part of the building over: from 0 to 40 m - the western extension, from 40 to 100 m - the LTK building itself, from 100 to 125 m - the eastern extension;
- a rectangular grid shows at the intersections of the measurement points during the examination (252 points).

 The first form of the amplitudes of the displacements of the transverse vibrations is not symmetrical with respect to the middle of the length of the building, which is due to the greater rigidity and higher frequency of the first form of natural vibrations of the eastern extension ("G" -shaped building in plan).

 In the second form of the amplitudes of the displacements of transverse vibrations, the minimum value of the displacement amplitudes (node) for the same reason is not shifted to the left to the border of the adjoining western extension to the LTK building itself.

 Thus, a complex building structure consisting of a building and two different spatial stiffnesses of the extensions to it is accordingly displayed on the configurations of the forms of natural vibrations, which was established during the examination.

 At each point of the measurement grid for the established forms of natural vibrations, the logarithmic decrements of attenuation (absorption), natural vibration frequencies, stiffness values are determined and the corresponding distribution maps of these parameters along the length and height of the building are built.

 The logarithmic damping (absorption) decrement of transverse vibrations in the LTK building with extensions varies from 0.135 to 0.22, while its minimum value refers to the eastern extension.

 It is known (5) that the displacement field for three components determines the dynamic deformations and stresses that arise in a building or structure. To determine the nine components of the deformation field, the derivatives of the three displacement components in coordinates (X, Y, Z) are calculated and, accordingly, the grid is measured in at least two vertical planes passing along the longitudinal axis of the building and in two planes perpendicular to the longitudinal axis of the building.

By way of illustration in FIG. 4 shows the intensity of shear deformations e _xy in a vertical plane passing along the longitudinal axis of the LTC building. Deformations characterize the change in the transverse component of displacements along the longitudinal axis of the building (horizontal axis) and along the floors of the building (vertical axis). Deformations (module) were calculated at the frequency of the first form of natural transverse vibrations of the LTK building - 2.12 Hz.

 In FIG. 4b, alternating vertical areas of greater and lesser intensity of shear deformations are traced, which correlate with the structural structure of the frame building (Fig. 4a): the intensities of the natural transverse vibrations of the enclosing walls, the grid of columns and floor slabs of the building vary significantly.

Conclusions and recommendations:
- analysis of maps of their own forms and phases of micro-vibrations of LTK buildings and the resulting shear deformations makes it possible to assess the quality of the installation of supporting structures and the construction of enclosing walls as satisfactory;
- during the operation of buildings, the nodes and sections of the enclosing walls at the junction of the annex buildings to the LTK building itself require special attention, where shear deformations during microoscillations vary 30-50 times;
- when designing, greater attention should be paid to the design of the interfaces of buildings and the assessment of their mutual power and dynamic influence.

 Example 2. The table below presents the averaged values of the frequencies and attenuation decrements of the transverse and longitudinal vibrations of a number of buildings examined by the authors as a whole.

 Based on the results of an engineering-seismological survey of the buildings indicated in the table (items 2-6), recommendations are given on the nature, volume and sequence of restoration repair of the building part.

 It is recommended to evaluate the economic feasibility of reconstruction of the building pos. 6 compared to the construction of a new building.

Analysis of the presented data shows that as the building ages:
- the attenuation decrement increases, that is, the amount of energy absorbed by the structure (see pos. 2-6);
- as a rule, the average frequencies of the modes of natural vibrations decrease (see buildings of the same type, items 2-6, which are located in the table as their physical state decreases);
- additional frequencies of forms of natural vibrations are formed in the event of a significant change in the spatial rigidity of the building structure due to destruction (cracks) or an error in the selection of the sequence and measures of restoration repair - restoration of part of the foundation and strengthening of part of the walls (see pos. 4).

 Consequently, the physical state of a building or structure and its change in time characterizes a number of numerical values of physical parameters: the frequencies of the modes of natural vibrations and the number of forms, amplitudes of natural oscillations and decrements of attenuation.

 Thus, the parameters of the dynamic characteristics of the micro-oscillations of the object obtained as a result of an engineering-seismological survey in the form of their numerical values, distribution maps of the amplitudes of natural vibration modes, eigenfrequency graphs and distribution maps of attenuation decrements, etc., as well as their ratios make it possible to determine as diagnostic signs the physical condition of the building or structure as a whole, and their individual blocks and elements.

 The list of graphic illustrations of the application of the proposed method.

 FIG. 1 is a map of the absolute amplitudes of vibrations of the LTK building with a western extension at a frequency of 2.083 Hz (isolines in myrkons).

 FIG. 2 - spectra of micro-oscillations of the LTK building with extensions.

 FIG. 3 is a map of the absolute amplitudes of the first two forms of natural transverse vibrations of the LTK building with extensions along the longitudinal axis of the building (in microns).

 FIG. 4a is a vertical section of the LTK building with extensions along the longitudinal axis of the building.

 FIG. 4b is a map of shear deformations of the LTK building with extensions along the longitudinal axis of the building at a frequency of the first form - 2.12 Hz.

Literature
1. The method of dynamic testing of buildings and structures. RF patent N 2011174, cl. G 01 M 7/00, 1994.

 2. A method for determining vibration of a building. USSR author's certificate N 1777018, cl. G 01 M 7/00, 1992.

 3. M. F. Barstein, V.A. Ilyichev, B.G. Korenev et al. Dynamic calculation of buildings and structures. Designer reference. Ed. B.G. Koreneva, I.M. Rabinovich, M., Stroyizdat, 1984, p. 272 - 280.

 4.S. A. Dobrynin, M.S. Feldman, G.I. Firsov Methods of automated study of machine vibrations. Handbook, M, Mechanical Engineering, 1987, pp. 197 - 201.

 5. R. Klaf, J. Penzien Dynamics of structures. M. Stroyizdat, 1979.

Claims (1)

 The method for determining the physical state of buildings and structures, which consists in the fact that the dynamic characteristics of the vibrations of buildings and structures are determined by excitation by a special effect of forced or free vibrations of an object, characterized in that the measurements of spatial vibrations are carried out under the influence of a microseismic background of natural and technogenic origin, under which the object under investigation is constantly located, by means of three-component Densities, vibration sensors that record vibration values at the X, Y, Z coordinates at the same time, determine the individual set of parameters of the dynamic characteristics of their own spatial vibrations inherent in each building or structure, as a result of the properties of the underlying soil and the foundation of the building or structure, masses and elastic characteristics of the building structure or structures, type and quality of connections of individual blocks, parts and elements of a building or structure, the change of which over time during operation shows corresponding changes of the dynamic characteristics of the building or structure vibrations in general, they are separate units, parts and components, i.e. determine the frequencies and forms of the natural vibrations of the object as a whole, its blocks and individual structural elements, the spectra of displacement values, displacement velocities and accelerations of the object points with X, Y, Z coordinates, attenuation (absorption) decrements, transfer functions soil - the foundation of the object, the foundation of the object - floors and parts of the object in height, components of dynamic deformations and stresses that occur in the structure of the object, and establish on the basis of these diagnostic signs the presence of changes in the properties of the underlying soil and defect in the design of object arising in the course of its operation, as well as determine the physical condition of the facility and assess the safety of its further operation, the ability to repair, renovation or demolition of the need to object.

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