RU2381470C2 - Method of monitoring and predicting technical state of buildings and structures and system for monitoring and predicing technical state of buildings and structures (versions) - Google Patents

Abstract

FIELD: physics; control.

SUBSTANCE: group of inventions relates to automated systems for monitoring technical state of buildings and structures and can be used in designing, construction and use of buildings and structures, including in accordance with programs for designing and constructing tall buildings, unique structures and high-risk objects. The method of monitoring and predicting technical state of buildings and structures involves installing a sensor unit and automated monitoring system equipment on a building or structure, determining technical state parametres of the object from measurements of these sensors and/or equipment, filtering technical state parametres of the object into two parametre groups: a group of technical state parametres of the lower part and a group of technical state parametres of the upper part of the object, determining design parametres of structural units of the upper part of the object based on technical state parametres of the lower part of the object, comparing design parametres of structural units of the upper part of the object with similar parametres of structural units of the upper part of the objects determined from in-situ measurements of the monitoring system sensors, correcting parametres of the mathematical model of the object under the condition that, design parametres of structural units of the upper part determined from in-situ measurements are greater than a given threshold, determining the trend of technical state parametres of the lower part of the object from the measured technical state parametres of the lower part, extrapolating trend values of technical state parametres of the lower part of the object on given time interval, determining predicted design technical state parametres of structural units of the upper part of the object based on extrapolation data of technical state parametres of the lower part of the object, recording for the user the predicted assessment of the future technical state of the object based on comparative analysis of the predicted design parametres of the technical state of structural units of the upper part of the object with admissible limit values. The system for monitoring and predicting technical state of buildings and structures which realises the method given above includes an impact action device, a sensor unit and automated monitoring system equipment, a unit for calculating technical state parametres of the object, a unit for filtering technical state parametres of the object, a unit for determining trends and extrapolation of technical state parametres of the lower part of the object, a comparator unit, a threshold device, a unit for mathematical modeling and calculating technical state parametres of the upper part, a unit for correcting parametres of the mathematical model of the object, an electronic switch, a unit for displaying prediction and monitoring information, a processing and output information unit and an output information grading unit. In another version the system for monitoring technical state of buildings and structures can be made with possibility of reacting to impact action in form of a microseismic background and/or technogenic character.

EFFECT: design of a method of monitoring and predicting technical state of an objct and a system for realising the method, which could enable at an early stage of development of adverse seismic and/or hydrogeological processes to predict the technical state of the superstructure of an object for a long period of time, thereby implementing a range of measures to prevent destruction of the object if necessary.

54 cl, 3 dwg

Description

1. The technical field to which the invention relates.

The invention relates to the field of automated systems for monitoring the technical condition of buildings and structures and can be used in the design, construction and operation of buildings and structures, including in accordance with programs for the design and construction of high-rise buildings, unique structures and high-risk facilities, in particular in accordance with the city complex investment program “New Ring of Moscow”.

2. The level of technology

There is a method and system for determining the stability of buildings and structures (RF patent No. 2245531 dated 2.04.2003) used to determine the stability of objects (buildings and structures), while the system for determining the stability of buildings and structures contains a shock device block, an electric formation block a clock pulse, a unit for converting oscillations into an electrical signal, an analog-to-digital unit for converting an electrical signal, a digital storage unit and a digital storage control unit, bl ok input experimental and / or calculated values of surface strength and / or bulk strength, and / or reinforcement parameters of structural elements of the object, and / or precipitation, and / or shear, and / or roll of the object, and / or the depth of the foundation, and / or its surface strength, and / or its bulk strength, and / or the period of natural vibrations of the soil under the object, and / or around it, measured at least by the first tone of the vibrations and / or groundwater level, experimental data comparison unit with normalized data read for the data of the structures and materials of the test object and the composition of the soil under it and / or around it and the playback unit for the received data, connected via control buses and data between themselves and with the rest of the functional blocks of the system.

Also known is the prototype monitoring system for the technical condition of buildings and structures (utility model patent No. 66525 dated 12/12/2006), which contains a shock device block, a vibration sensor block, a processing and output information block, an object vibration acceleration measuring unit and / or a block measuring an object’s vibration velocity and / or an object oscillation amplitude measuring unit and / or a slope measuring unit and / or a deflection measuring unit and / or a voltage measuring unit and / or a load measuring unit and / or an absolute and numbered precipitation and / or a unit for monitoring cracks, joints and seams and / or a unit for measuring geodetic parameters, a unit for gradation of output information, wherein the output of the unit for vibration sensors and / or the output for the unit for measuring acceleration of vibrations of the object and / or the output for the unit for measuring vibration rates of an object and / or the output of the unit for measuring the amplitudes of oscillations of the object and / or the output of the unit for measuring the slopes and / or the output of the unit for measuring deflections and / or the output of the unit for measuring stresses and / or the output of the unit for measuring loads and / or the output of the unit for measuring absolute and uneven the thrust and / or the output of the control unit for cracks, joints and seams and / or the output of the measuring unit for geodetic parameters are connected to the input of the processing unit and output information, the output of which is connected to the input of the output information gradation block

3. Disclosure of invention

A common drawback of the technical solutions noted above is that they determine the technical condition of a building and structure (hereinafter referred to as the object) only at the time the sensors took various characteristics (periods of natural vibrations, inclinations, etc.), which does not allow a predictive assessment of the future technical condition of the object on long time interval. This is especially important when monitoring the technical condition of an object located in areas with complex seismic and / or hydrogeological conditions (the presence of karst and landslide phenomena, the level of groundwater close to the earth's surface, etc.). Under these conditions, as practice shows, an adverse change in time of the state of seismic and / or hydrogeological conditions in the initial stage of development of these processes under the object (growth of karst formations, slow landslide shifts, increase in groundwater level, etc.) practically does not affect the early stage on the technical condition of building structures of the ground part of the facility, and as a consequence of this, it is not possible to carry out a predictive assessment of the future technical condition at an early stage the ground part of the object for a long time interval.

The present invention is aimed at solving the technical problem of eliminating the aforementioned drawback and creating a method for monitoring and predicting the technical condition of the object and system for its implementation, which would allow at an early stage of development of adverse seismic and / or hydrogeological processes to carry out a predictive assessment of the future technical condition of the ground part facility for a long time interval and thereby would allow, if necessary, to implement a set of preventive measures to preventing the destruction of the object.

The specified technical result is achieved by the fact that at the facility:

install a block of sensors and equipment of an automated monitoring system (inclination measurement sensors and / or object vibration acceleration sensors and / or object vibration velocity measurement sensors and / or object vibration amplitude measurement sensors and / or load measurement sensors (including ground pressure sensors ) and / or strain gauges and / or geodetic equipment for measuring spatial parameters and / or navigation instruments for determining coordinates and / or temperature sensors s and / or humidity sensors and / or deflection sensors and / or absolute and non-uniform settlement sensors and / or sensors for monitoring cracks, joints and joints and controllers (electronic units) of sensors and / or equipment that convert and store the measurements into digital form for further processing and analysis);

in the unit for calculating the parameters of the technical state of the object according to the measurement data of these sensors (equipment), the parameters of the technical state of the object (for example, natural vibration frequencies, transfer functions calculated by the ratios of the power spectrum of the vibration measurements at two points of the object, slopes, deformations, pressure under the foundation plate and etc.). The parameters of the technical condition of the object can be values measured by sensors at a certain point in time (for example, deformation) and / or can be determined by performing mathematical operations on the measurement data of sensors and / or equipment (for example, calculating the average over a given period of time, integration, determination of derivatives , Fourier transform and determination of natural frequencies, determination of correlation dependencies, determination of maximum and minimum values in a given period of time Yeni and other mathematical operations);

filter the parameters of the technical condition of the object in the block filtering the parameters of the technical condition of the object according to two groups of parameters. The first group of parameters - the parameters of the technical condition of the lower part of the object, the second group of parameters - the parameters of the technical state of the upper part of the object. The separation of the object into the lower and upper parts is carried out depending on the design features and the specific implementation scheme of the automated monitoring system. For example, one of the types of such separation can be a division into a group of parameters of the technical condition of the underground part of the object and a group of parameters of the technical condition of the ground part of the object. For the underground part of the object, parameters of the technical condition of the object can be determined, such as: slopes and / or unevenness of settlement, and / or absolute settlement, and / or deformation in the foundation plate and / or piles, and / or pressure under the foundation plate and / or under fifth pile, and / or deformation in the "wall in the ground", and / or deformation in the supporting structures of the underground floors, and / or temperature, and / or humidity, and / or horizontal and / or vertical displacement of the structures of the underground part, etc. Technical the state of the underground part of the object affects Beginning of a group of parameters that evaluate the technical condition of the ground part of the object. These parameters include the following parameters: deformations in the supporting structures, and / or transfer functions, and / or periods (frequencies) of natural vibrations, and / or forms of natural vibrations, and / or slopes, and / or deflections, and / or absolute precipitation, and / or uneven precipitation, and / or crack sizes, and / or the opening size of joints, joints, and / or geodetic parameters, and / or vertical and / or horizontal movements, etc .;

Another example of dividing into the upper and lower parts is the example of dividing the supporting frame of the object and its cover, which is a complex structural scheme characteristic of unique objects (Ice sports palaces, stadiums, etc.);

using parameters of the technical condition of the lower part of the object, using mathematical (computer) modeling of the object, the calculated parameters of the building structures of the upper part of the object (deformations in the supporting structures, and / or transfer functions and / or periods (frequencies) of natural vibrations, and / or forms of natural vibrations are determined , and / or slopes, and / or deflections, and / or absolute precipitation, and / or uneven precipitation, and / or crack sizes, and / or the size of the opening of joints, joints, and / or geodetic parameters, and / or vertical linen and / or horizontal movements, etc.);

comparing the calculated parameters of the building structures of the upper part of the object with the same parameters of building structures of the upper part of the object, determined by the results of field measurements by sensors of the monitoring system;

adjust the parameters of the mathematical model of the object, provided that the calculated parameters of building structures of the upper part of the object, determined by the results of mathematical modeling, differ from similar parameters of building structures of the upper part of the object, determined by the results of field measurements by an amount greater than a predetermined threshold;

determine from the measured parameters of the technical condition of the lower part of the trend the parameters of the technical condition of the lower part of the object (slopes and / or unevenness of settlement, and / or absolute settlement, and / or deformation in the foundation plate and / or piles, and / or pressure under the foundation plate and / or under the fifth pile, and / or deformation in the "wall in the ground", and / or deformation in the supporting structures of the underground floors, and / or temperature, and / or humidity, and / or horizontal and / or vertical displacement of the structures of the underground part, etc. .),

extrapolating the trend values of the technical parameters of the state of the lower part of the object (slopes and / or unevenness of settlement, and / or absolute settlement, and / or deformation in the foundation plate and / or piles, and / or pressure under the foundation plate and / or under the fifth pile, and / or deformation in the "wall in the ground", and / or deformation in the supporting structures of the underground floors, and / or temperature, and / or humidity, and / or horizontal and / or vertical displacement of the structures of the lower part, etc.) for a given time interval ,

determine, based on the extrapolation of the parameters of the technical condition of the lower part of the object, the predicted design parameters of the building structures of the upper part of the object (deformations in the supporting structures, and / or transfer functions and / or periods (frequencies) of natural vibrations, and / or the form of natural vibrations, and / or slopes, and / or deflections, and / or absolute precipitation, and / or uneven precipitation, and / or crack sizes, and / or the opening size of joints, joints, and / or geodetic parameters, and / or vertical and / or horizontal displacement Niya and others.).

fix for the consumer a predictive assessment of the future technical condition of the facility based on a comparative analysis of the predicted design parameters of the technical condition of building structures of the lower and / or upper part of the facility with maximum permissible values.

The specified technical result in the invention, a system for monitoring and predicting the technical condition of an object, is achieved by the fact that in a system comprising a percussion device, a processing and output information unit, a output information gradation unit, and / or vibration sensors, and / or object vibration acceleration sensors, and / or sensors for measuring the speed of oscillation of the object and / or sensors for measuring the amplitudes of the oscillations of the object, and / or sensors for measuring slopes, and / or sensors for measuring deflections, and / or sensors for measuring stresses, and / whether the load measurement sensors, and / or the absolute and non-uniform draft measurement sensors, and / or the sensors for monitoring cracks, joints and seams, and / or the sensors for measuring geodetic parameters, pressure sensors are additionally included (object pressure on the ground and / or soil pressure on the object) , and / or strain gauges, and / or temperature sensors, and / or humidity sensors, (all of the above sensors are combined in one block - a block of sensors and equipment of an automated monitoring system), calculation block parameters of the technical state of the object, a block for filtering the parameters of the technical state of the object, a comparison unit, a threshold device, a block for mathematical modeling and calculation of parameters of the technical state of the upper part of the object, a block for adjusting the parameters of the mathematical model of the object, an electronic key, a block for determining trends and extrapolation of parameters of the technical state of the lower part facility, a display unit of predictive and monitoring information, and the output of the sensor unit and automation equipment This monitoring system is connected to the input of the unit for calculating the parameters of the technical condition of the object, the first output of which is connected to the input of the filtering unit for the parameters of the technical state of the object, and the second output is connected to the input of the processing unit and output information, the output of which is connected to the input of the gradation block of output information, the first output block filtering the parameters of the technical condition of the object is connected to the first input of the block of mathematical modeling and calculation of the parameters of the technical condition of the upper part of object, the second output of the filtering unit of the parameters of the technical state of the object is connected to the input of the comparison unit, the output of the comparison unit is connected to the input of the threshold device, the first output of which is connected to the input of the block for adjusting the parameters of the mathematical model of the object and the first control input of the electronic key, and the second output is connected to the second the control input of the electronic key, the output of the block adjusting the parameters of the mathematical model of the object is connected to the second input of the block of mathematical modeling of the object and calculating the parameters of the technical condition of the upper part of the object, the first output of which is connected to the input of the comparison unit, and the second output is connected to the first input of the display unit of forecast and monitoring information, the third input of the mathematical modeling block of the object and calculating the parameters of the technical condition of the upper part of the object is connected to the output of the block determining trends and extrapolating the parameters of the technical condition of the lower part of the object, the input of which is connected to the output of the electronic key.

These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

In the particular case of the execution of the present invention, the underground part of the object is used as the lower part, and the ground part of the object is used as the upper part.

In the particular case, the value of the time interval for which the trend values of the technical parameters of the state of the lower part of the object are extrapolated is selected based on the design features of the object, seismic and / or hydrogeological conditions of the object.

In the particular case of the implementation of the present invention for mathematical modeling of the object using software packages of finite element analysis (ANSYS, NASTRAN, MicroFe, LIRA, SCAD, MONOMAX, etc.)

In the particular case of the execution of the present invention, the value of the threshold level set in the threshold device is selected depending on the used design scheme of the object, mathematical modeling methods and accuracy characteristics of the sensors.

In a particular embodiment of the present invention, the impact device may be a mechanical device and / or an electrical device and / or an electromechanical device and / or a magnetic device and / or an electromagnetic device and / or a hydraulic device and / or an explosive device , and / or harmonic and / or special oscillation excitation device.

In the particular case of the execution of the present invention, the impact on the object can be carried out by exposure to a microseismic background and / or anthropogenic character.

In the particular case of the implementation of the present invention, sensors mounted on the lower and / or upper part of the object are made using optical fiber.

In the particular case of the execution of the present invention, the output information of the gradation block of the output information is represented by an information signal in the form of at least three gradations that differ from each other in different colors and / or sound.

In the particular case of the execution of the present invention, the geographic information systems are included in the processing and output information unit.

In the particular case of the execution of the present invention, the geographic information systems are included in the output information gradation block.

In the particular case of the implementation of the present invention, the communication lines of the functional blocks of the system are wired communication lines.

In the particular case of the implementation of the present invention, the communication lines of the functional blocks of the system are wireless communication lines.

In the particular case of the implementation of the present invention, the communication lines of the functional blocks of the system are combinations of wired and wireless communication lines.

In the frequent case of the execution of the present invention, accelerometers may be sensors for measuring accelerations of object vibrations.

In the particular case of the implementation of the present invention, the sensors for measuring the object’s vibrational velocities can be bicycle meters.

In the particular case of the implementation of the present invention, the sensors for measuring the amplitudes of the displacement of the object can be seismometers.

In the particular case of the implementation of the present invention, the sensors for measuring the inclination of the object can be tilt meters and / or inclinometers and / or clinometers.

In the particular case of the implementation of the present invention, the sensors for measuring the deflection of the object can be deflection meters.

In the particular case of the implementation of the present invention, the sensors for measuring the voltage of the object can be tensometers.

In the particular case of the implementation of the present invention, the sensors for measuring the loads on the object can be pressure sensors.

In the particular case of the implementation of the present invention, the sensors for monitoring cracks, joints and seams can be crack gauges.

In the particular case of the implementation of the present invention, the sensors for measuring the geodetic parameters of the object can be total stations and / or theodolites with auxiliary equipment.

4. Brief Description of the Drawings

The invention is illustrated by drawings.

Figure 1 shows a block diagram of a system for monitoring and forecasting the technical condition of buildings and structures, where 1 is a block of sensors and equipment of an automated system for monitoring an object, 2 is a block for calculating the parameters of the technical condition of the object, 3 is a block for filtering the parameters of the technical condition of the object, 4 - block for mathematical modeling of the object and calculation of parameters of the technical state of the upper part of the object, 5 - comparison block, 6 - block for adjusting the parameters of the mathematical model of the object, 7 - threshold device, 8 - an electronic key, 9 - a unit for determining trends and extrapolating the parameters of the technical condition of the lower part of the object, 10 - a unit for displaying forecast and monitoring information, 11 - a unit for processing and output information, 12 - a unit for gradation of output information.

Figure 2 shows a special case of the output image of the gradation block of the output information illustrating the current technical condition of the object in quasi-real time mode.

Figure 3 shows an example of the output image of the display unit of the forecast and monitoring information illustrating the future technical condition of the object.

5. The implementation of the invention

One of the most typical embodiments of the invention is as follows.

With the development of unfavorable seismic and / or hydrogeological conditions at the initial stage (karst formation, slow landslide phenomena, soil liquefaction, etc.), the lower one (hereinafter, we consider a particular case of the invention when the underground part acts as the lower part and the upper parts - the ground part of the object) the part of the object begins to be affected by the corresponding external loads, which, upon reaching a certain level, lead to a change in the parameters of the technical condition ( slope, non-uniformity of precipitation, horizontal displacement, etc.) of the underground part of the object as a whole or of its individual structures (foundation slab, piles, columns and floors of underground floors, “wall in soil”). Moreover, as follows from practice, even a significant change in the parameters of the underground part of the object (for example, a decrease in ground pressure under one or more piles and / or a foundation slab) may practically not immediately affect the technical condition of the ground part of the object and not be recorded by appropriate sensors. To predict the stress-strain state of the object, information is recorded and removed from the block of sensors and equipment of the automated monitoring system, which enters the block for calculating the parameters of the technical condition of the object, where, based on measurements of sensors and equipment of the automated monitoring system, the parameters of the technical state are calculated by performing measurements mathematical operations (integration, differentiation, calculation of the average over a given period of time tim, Fourier transform, and others.). The calculated parameters are fed to the input of the filtration unit for the parameters of the technical condition of the object, where the parameters of the technical condition of the object are divided into two groups based on their belonging to the lower (in this example, underground) and upper (in this example, ground) part of the object. The parameters of the technical condition of the underground part of the object are input to the block of mathematical modeling of the object and the calculation of the parameters of the technical condition of the upper part of the object, where the calculation of the parameters of building structures of the ground part of buildings and structures (periods of natural vibrations, and / or slopes, and / or deflections, and / or displacements, and / or stresses, and / or absolute and / or uneven precipitation, and / or crack sizes, and / or opening sizes st Cove, seams, and / or geodetic parameters (including spatial coordinates)). The calculated data obtained are compared in the comparison unit with similar data obtained from the output of the filtering unit of the technical condition parameters of the object, which are determined by the data of field measurements of sensors located on the ground part of the object. If the compared data differ by an amount greater than a predetermined threshold, then in the block for correcting the parameters of the mathematical model of the object, the parameters of the mathematical model are corrected so that the difference between the calculated data of the parameters of building structures of the ground part of the object obtained from the output of the mathematical modeling block and similar data with the second output of the unit for filtering the parameters of the technical condition of the object according to field measurements from sensors installed on the Nazi parts of the object, have become less than a given threshold. Thus, the adequacy of the mathematical model of the object to its physical prototype is established. In the process of adjusting the mathematical model of the object, the information from the output of the block of mathematical modeling of the object does not go to the input of the display unit of the forecast and monitoring information, because the signal from the first output of the threshold device locks the electronic key at the first control input. After the correction of the mathematical model of the object is completed, the signal from the output of the comparison unit will become less than a predetermined threshold, the signal from the second output of the threshold device will open an electronic key at the second control input and the trends of the parameters will be determined in the unit for determining trends and extrapolating the parameters of the technical state of the lower part of the object the technical condition of the underground part of the object (slope, uneven precipitation, horizontal displacement, etc.) and data will be extrapolated trov for a given time interval. Using the extrapolated values of the parameters of the underground part of the object in the block of mathematical modeling of the object and calculation of the parameters of the technical condition of the upper part of the object, the forecast parameters of the technical state of the ground part are calculated, after which the predictive assessment of the future technical condition of the building and structure according to various parameters will be sent to the display unit of the forecast and monitoring information. This forecast information, as well as information from the unit for determining trends and extrapolating the parameters of the technical condition of the lower part of the object about the trends in the parameters of the technical condition of the underground part of the object (slope and / or uneven precipitation, and / or horizontal displacement, etc.) is displayed to the consumer (operating organization , the owner of the building and structures, etc.) in the display unit of the forecast and monitoring information. Based on the monitoring information received about the future technical condition of the facility, the consumer can take a set of preventive measures to prevent the destruction of the facility. The consumer can judge the effectiveness of the preventive measures taken by changing trends in the parameters of the technical condition of the underground part of the object (slope and / or uneven precipitation, and / or horizontal displacement, etc.), information about which is displayed in the display unit for forecast and monitoring information. In addition to predictive information about the future technical condition of the facility, it is also important for the consumer to have up-to-date information about the current state of the facility, especially after exposure to the facility of intense external loads of a natural and man-made nature (earthquake, floods, explosions, etc.). Such an opportunity in the present invention is provided by analogy with the technical solution taken as a prototype (utility model patent No. 66525 dated 12/12/2006). This is achieved by the fact that the signal from the output of the unit for calculating the parameters of the technical state of the object is fed to the input of the processing unit and the output information, where the parameters of the technical state of comparison are processed in accordance with the criteria (for example, the value of the parameter exceeds a predetermined threshold) used in the processing unit and the output information to determine I, in what technical condition is the object. Information from the output of the processing unit and the output information is fed to the input of the output information gradation unit, which generates an information signal of various colors depending on the state of the object, for example: a) normal (for example, green) b) serious defects are accumulated (for example, yellow) c) defects are accumulated that are hazardous to the safety of the object (for example, red). In this case, the number of gradations of the information signal at the output of the gradation block of the output information by color and / or sound should be at least three.

Thus, in the present invention, a technical problem is solved that allows, at an early stage of development of adverse seismic and / or hydrogeological processes, to carry out a predictive assessment of the future technical condition of the ground part of the object for a long time interval and thereby, if necessary, implement a set of preventive measures to prevent destruction of the object . In this case, the technical problem is also assessed to assess the current technical condition of the object.

Claims (54)

1. A method for monitoring the technical condition of a building and construction (facility), including the excitation of vibrations of the object at natural frequencies, registration of vibrations and / or accelerations of vibrations, and / or vibration speeds, and / or vibration amplitudes, and / or inclinations, and / or deflections, and / or stresses, and / or loads, and / or measurements of absolute and uneven settlement, and / or geodetic parameters, and / or control of cracks, joints, seams, characterized in that they filter the technical conditions of buildings and structures on two groups pa ametres: a group of parameters of the technical condition of the lower part of the object and a group of parameters of the technical state of the upper part of the object, determined using the parameters of the technical condition of the lower part of the object by mathematical (computer) modeling of the object, the calculated parameters of the building structures of the upper part of the object, compare the calculated parameters of the building structures of the upper part of the object with similar parameters of building structures of the upper part of the object, determined by the results of measurements from sensors to monitor the technical condition of the upper part of the object, adjust the parameters of the mathematical model of the object, provided that the calculated parameters of the building structures of the upper part of the object, determined by the results of mathematical modeling, differ from similar parameters of building structures of the upper part of the object, determined by the results of field measurements an amount greater than a predetermined threshold, determined by the measured parameters of the technical condition of the lower part of The project trends the parameters of the technical condition of the lower part of the object, extrapolates the trend values of the parameters of the technical condition of the lower part of the object for a given time interval, determines, based on the data of extrapolation of the parameters of the technical condition of the lower part of the object, the predicted calculated parameters of the technical condition of the building structures of the upper part of the object, fixes the forecast estimate for the consumer future technical condition of the facility based on a comparative analysis of forecasted settlement pairs meters technical state of the top structures of the object with the maximum admissible values. 2. The method according to claim 1, characterized in that the underground part of the object is used as the lower part, and the ground part of the object is used as the upper part. 3. The method according to one of claims 1 and 2, characterized in that for the lower part of the object the following parameters of the technical condition are determined: slopes, and / or unevenness of settlement, and / or absolute settlement, and / or deformation in the foundation plate, and / or piles, and / or pressure under the foundation plate, and / or under the fifth pile, and / or deformation in the "wall in the ground", and / or deformation in the supporting structures of the underground floors, and / or temperature, and / or humidity, and / or horizontal and / or vertical displacement of the structures of the lower part of the object and / or soil near and / or one object. 4. The method according to one of claims 1 and 2, characterized in that according to the sensors installed on the lower part of the object, determine the trends of the following parameters of the technical condition of the lower part of the object: slope, uneven precipitation of the object and / or individual structures of the object, horizontal and / or the vertical displacement of the building structures of the object and / or soil, and / or vibrational parameters (for example, vibration amplitude, spectrum, spectral density and other characteristics of vibrational phenomena), and / or temperature, and / or humidity. 5. The method according to one of claims 1 and 2, characterized in that the registration of the parameters of the technical condition of the lower part of the object is carried out in certain places, including on the foundation plate, and / or in the foundation plate, and / or in piles, and / or under the fifth pile, and / or on the ground, and / or in the ground, and / or in the ground in a specially equipped room (for example, in a bunker), and / or on the supporting structures of the underground floors, and / or in the supporting structures of the underground floors , and / or in a “wall in the ground”, and / or in sheet piling, and / or supporting columns, and / or supporting st enah. 6. The method according to one of claims 1 and 2, characterized in that according to the extrapolation of the technical parameters of the state of the underground part of the building and structure, the following calculated parameters of the building structures of the upper part of the object are determined by mathematical modeling methods: deformations in load-bearing structures, and / or transfer functions , and / or periods (frequencies) of natural oscillations, and / or forms of natural oscillations, and / or inclinations, and / or deflections, and / or absolute precipitation, and / or uneven precipitation, and / or size of cracks, and / or size open ment of joints, seams, and / or geodetic parameters (including spatial coordinates) and / or vertical and / or horizontal movements. 7. The method according to one of claims 1 and 2, characterized in that according to the results of field measurements with sensors installed on the upper part of the object, the following parameters of the building structures of the upper part of buildings and structures are determined: deformations in the supporting structures, and / or transfer functions, and / or periods (frequencies) of natural vibrations, and / or forms of natural vibrations, and / or slopes, and / or deflections, and / or absolute precipitation, and / or uneven precipitation, and / or crack sizes, and / or joint opening size , seams, and / or geodetic parameters ( including spatial coordinates) and / or vertical and / or horizontal movements. 8. The method according to one of claims 1 and 2, characterized in that for mathematical modeling of the object using software packages of finite element analysis (ANSYS, NASTRAN, MicroFe, LIRA, SCAD, MONOMAX, etc.) 9. The method according to one of claims 1 and 2, characterized in that the value of the predetermined threshold set in the threshold device is selected depending on the used design scheme of the object, and / or methods of mathematical modeling, and / or accuracy characteristics of the sensors. 10. The method according to one of claims 1 and 2, characterized in that the impact device may be a mechanical device and / or an electrical device and / or an electromechanical device and / or a magnetic device and / or an electromagnetic device, and / or a hydraulic device and / or explosive device and / or harmonic and / or special oscillation excitation device. 11. The method according to one of claims 1 and 2, characterized in that the impact on the object can be effected by microseismic background and / or man-made character. 12. The method according to one of claims 1 and 2, characterized in that the sensors mounted on the lower and / or upper part of the object are made using optical fiber. 13. The method according to one of claims 1 and 2, characterized in that the value of the time interval over which the trend values of the technical parameters of the state of the lower part of the object are extrapolated is selected based on the design features of the object, seismic and / or hydrogeological conditions of the object. 14. A system for monitoring the technical condition of buildings and structures, comprising a shock impact device, a processing and output information unit, an output information gradation unit, and / or object vibration measuring sensors, and / or object vibration acceleration measuring sensors, and / or vibration velocity measuring sensors object, and / or sensors for measuring the amplitudes of oscillations of the object, and / or sensors for measuring slopes, and / or sensors for measuring deflections, and / or sensors for measuring stresses, and / or sensors for measuring loads, and / or sensors for measuring absolute and uneven settlement, and / or sensors for monitoring cracks, joints and seams, and / or sensors for measuring geodetic parameters, characterized in that it additionally includes pressure sensors (including for monitoring the object’s pressure on the ground and / or soil pressure per object), and / or strain gauges, and / or temperature sensors, and / or humidity sensors (all of the above sensors are combined in one block - a block of sensors and equipment of an automated monitoring system), calculation unit parameters of the technical state of the object, a block for filtering the parameters of the technical state of the object, a block for determining trends and extrapolation of parameters for the technical condition of the lower part of the object, a comparison unit, a threshold device, a block for mathematical modeling and calculation of parameters for the technical condition of the upper part of the object, an adjustment block for the parameters of the mathematical model of the object, electronic a key, a unit for displaying forecast and monitoring information, the output of a block of sensors and automation equipment This monitoring system is connected to the input of the unit for calculating the parameters of the technical condition of the object, the first output of which is connected to the input of the filtering unit for the parameters of the technical state of the object, and the second output is connected to the input of the processing unit and output information, the output of which is connected to the input of the gradation block of output information, the first output block filtering the parameters of the technical condition of the object is connected to the first input of the block of mathematical modeling and calculation of the parameters of the technical condition of the upper part of object, the second output of the filtering unit of the parameters of the technical state of the object is connected to the input of the comparison unit, the output of the comparison unit is connected to the input of the threshold device, the first output of which is connected to the input of the block for adjusting the parameters of the mathematical model of the object and the first control input of the electronic key, and the second output is connected to the second the control input of the electronic key, the output of the block adjusting the parameters of the mathematical model of the object is connected to the second input of the block of mathematical modeling of the object and calculating the parameters of the technical condition of the upper part of the object, the first output of which is connected to the input of the comparison unit, and the second output is connected to the first input of the display unit of forecast and monitoring information, the third input of the mathematical modeling block of the object and calculating the parameters of the technical condition of the upper part of the object is connected to the output of the block determining trends and extrapolating the parameters of the technical condition of the lower part of the object, the input of which is connected to the output of the electronic key. 15. The system of claim 14, wherein the output information of the gradation block of the output information is represented by an information signal in the form of at least three gradations that differ from each other in different colors and / or sound. 16. The system of claim 14, wherein the geoinformation system is included in the processing and output information unit. 17. The system of claim 14, wherein the geoinformation system is included in the output information gradation block. 18. The system of claim 14, wherein the sensors installed on the lower and / or upper part of the object are made using optical fiber. 19. The system according to 14, characterized in that the communication lines of the functional blocks of the system are wired communication lines. 20. The system according to 14, characterized in that the communication lines of the functional blocks of the system are wireless communication lines. 21. The system according to 14, characterized in that the communication lines of the functional blocks of the system are a combination of wired and wireless communication lines. 22. The system of claim 14, wherein the impact device may be a mechanical device and / or an electrical device and / or an electromechanical device and / or a magnetic device and / or an electromagnetic device and / or a hydraulic device , and / or explosive device, and / or harmonic and / or special oscillation excitation device. 23. The system of claim 14, characterized in that the accelerometers may be sensors for measuring accelerations of object vibrations. 24. The system according to 14, characterized in that the sensors for measuring the speed of oscillation of the object can be a bicycle. 25. The system according to 14, characterized in that the sensors for measuring the amplitudes of the displacement of the object can be seismometers. 26. The system according to 14, characterized in that the sensors for measuring the slopes of the object can be tilt and / or inclinometers and / or clinometers. 27. The system of claim 14, characterized in that the deflection sensors of the object can be deflection meters. 28. The system according to 14, characterized in that the sensors can measure stress and / or deformation of the object can be tensometers. 29. The system of claim 14, wherein the sensors for measuring the loads on the object can be pressure sensors. 30. The system according to 14, characterized in that the sensors for monitoring cracks, joints and seams can be crack gauges. 31. The system according to 14, characterized in that the sensors for measuring the geodetic parameters of the object can be total stations and / or theodolites with auxiliary equipment. 32. The system according to 14, characterized in that the sensors mounted on the lower and / or upper part of the object are made using optical fiber. 33. The system according to 14, characterized in that the sensors that record the parameters of the technical condition of the lower (underground) part of the object are tilt measurement sensors and / or vibration measurement sensors, and / or load and / or pressure sensors (in including on the ground), and / or strain gauges, and / or equipment for measuring geodetic parameters, and / or navigation instruments for measuring spatial coordinates, and / or temperature sensors, and / or humidity sensors, and / or device at gift effect. 34. The system according to 14, characterized in that the sensors that record the parameters of the technical condition of the upper (ground) part of the building and structure are sensors for measuring vibration, and / or sensors for measuring vibration accelerations, and / or sensors for measuring vibration speeds, and / or sensors for measuring oscillation amplitudes, and / or sensors for measuring slopes, and / or sensors for measuring deflections, and / or sensors for measuring stresses and / or deformations, and / or sensors for measuring loads, and / or sensors for measuring absolute draft, and / or sensor and measurement of uneven settlement, and / or sensors for monitoring cracks, joints and seams, and / or sensors for measuring geodetic parameters, and / or navigation devices for measuring spatial coordinates, and / or sensors for measuring temperature, and / or sensors for measuring humidity, and / or impact device. 35. A system for monitoring the technical condition of buildings and structures configured to respond to impact in the form of a microseismic background of a natural and / or technogenic nature, comprising a processing unit and output information, a gradation block for output information and / or vibration sensors for measuring object vibrations, and / or sensors for measuring accelerations of oscillations of an object, and / or sensors for measuring velocities of oscillations of an object, and / or sensors for measuring amplitudes of oscillations of an object, and / or sensors for measuring inclination, and / or sensors for measuring deflections, and / or sensors for measuring stresses, and / or sensors for measuring loads, and / or sensors for measuring absolute and uneven settlement, and / or sensors for monitoring cracks, joints and seams, and / or sensors for measuring geodetic parameters, characterized in that it additionally includes pressure sensors (including for monitoring the pressure of the object on the ground and / or pressure on the object), and / or strain gauges, and / or temperature sensors, and / or humidity sensors (all of which are listed above sensors combined into one block - a block of sensors and equipment of an automated monitoring system), a block for calculating the parameters of the technical state of the object, a block for filtering the parameters of the technical state of the object, a block for determining trends and extrapolating the parameters of the technical state of the lower part of the object, a comparison unit, a threshold device, a block for mathematical modeling and calculation of parameters the technical condition of the upper part of the object, the block adjusting the parameters of the mathematical model of the object, an electronic key, a display unit fire and monitoring information, and the output of the sensor unit and the equipment of the automated monitoring system is connected to the input of the unit for calculating the parameters of the technical condition of the object, the first output of which is connected to the input of the filtering unit of the parameters of the technical condition of the object, and the second output is connected to the input of the processing unit and output information, output which is connected to the input of the gradation block of the output information, the first output of the filtering block of the parameters of the technical condition of the object is connected to the first input of the bl the eye of mathematical modeling and calculation of the parameters of the technical condition of the upper part of the object, the second output of the filtering block of the parameters of the technical state of the object is connected to the input of the comparison unit, the output of the comparison unit is connected to the input of the threshold device, the first output of which is connected to the input of the block for adjusting the parameters of the mathematical model of the object and the first control an electronic key input, and the second output is connected to the second control input of the electronic key, the output of the mate parameter adjustment block of the static model of the object is connected to the second input of the mathematical modeling unit of the object and calculation of the parameters of the technical condition of the upper part of the object, the first output of which is connected to the input of the comparison unit, and the second output is connected to the first input of the display unit of forecast and monitoring information, the third input of the mathematical modeling unit of the object and calculating the parameters of the technical condition of the upper part of the object is connected to the output of the trend determination unit and extrapolating the parameters of the technical condition the lower part of the object, the input of which is connected to the output of the electronic key. 36. The system of claim 35, wherein the output information of the gradation block of the output information is represented by an information signal in the form of at least three gradations that differ from each other in different colors and / or sound. 37. The system of claim 35, wherein the processing and output information unit includes geographic information systems. 38. The system of claim 35, wherein the geoinformation system is included in the output information gradation block. 39. The system according to clause 35, wherein the sensors mounted on the lower and / or upper part of the object are made using optical fiber. 40. The system according to clause 35, wherein the communication lines of the functional blocks of the system are wired communication lines. 41. The system according to clause 35, wherein the communication lines of the functional blocks of the system are wireless communication lines. 42. The system according to clause 35, wherein the communication lines of the functional blocks of the system are a combination of wired and wireless communication lines. 43. The system of claim 35, wherein the accelerometers may be sensors for measuring accelerations of object vibrations. 44. The system according to clause 35, wherein the sensors for measuring the velocity of oscillation of the object can be a bicycle. 45. The system according to clause 35, wherein the sensors for measuring the amplitude of the displacement of the object can be seismometers. 46. The system according to clause 35, wherein the sensors for measuring the slope of the object can be tilt and / or inclinometers and / or clinometers. 47. The system according to clause 35, wherein the sensors for measuring the deflection of the object may be deflection meters. 48. The system according to clause 35, wherein the sensors can measure stress and / or deformation of the object can be tensometers. 49. The system according to clause 35, wherein the sensors for measuring the loads on the object can be pressure sensors. 50. The system according to clause 35, wherein the sensors for monitoring cracks, joints and seams can be crack gauges. 51. The system of claim 35, wherein the sensors for measuring the geodetic parameters of the object can be total stations and / or theodolites with auxiliary equipment. 52. The system according to clause 35, wherein the sensors mounted on the lower and / or upper part of the object are made using optical fiber. 53. The system according to clause 35, wherein the sensors that record the parameters of the technical condition of the lower (underground) part of the object are tilt sensors and / or vibration sensors, and / or load and / or pressure sensors (in including on the ground), and / or strain gauges, and / or equipment for measuring geodetic parameters, and / or navigation instruments for measuring spatial coordinates, and / or temperature sensors, and / or humidity sensors. 54. The system according to clause 35, wherein the sensors that record the parameters of the technical condition of the upper (ground) part of the building and structure are sensors for measuring vibration, and / or sensors for measuring acceleration of vibrations, and / or sensors for measuring vibration speeds, and / or sensors for measuring oscillation amplitudes, and / or sensors for measuring slopes, and / or sensors for measuring deflections, and / or sensors for measuring stresses and / or deformations, and / or sensors for measuring loads, and / or sensors for measuring absolute draft, and / or sensor and measurement of uneven settlement, and / or sensors for monitoring cracks, joints and seams, and / or sensors for measuring geodetic parameters, and / or navigation devices for measuring spatial coordinates, and / or sensors for measuring temperature, and / or sensors for measuring humidity.

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