RU66525U1 - SYSTEM FOR MONITORING THE TECHNICAL CONDITION OF BUILDINGS AND STRUCTURES - Google Patents

Abstract

The utility model relates to the field of automated systems for monitoring the technical condition of buildings and structures and can be used in the design 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 city integrated investment program "New Ring of Moscow". A system for monitoring the technical condition of buildings and structures, comprising a shock device unit, a vibration sensor unit, and a processing and output information unit, characterized in that it further includes a unit for measuring acceleration of vibrations of the object and / or a unit for measuring vibration velocities of the object and / or a unit for measuring amplitudes of vibration of the object and / or a slope measuring unit and / or a deflection measuring unit and / or a stress measuring unit and / or a load measuring unit and / or an absolute and non-uniform draft measurement unit and / or a control unit For cracks, joints and seams, and / or a block for measuring geodetic parameters, a block for gradation of output information, the output of the block for vibration sensors and / or the output for the block for measuring accelerations of the object’s vibrations and / or the output for the block for measuring the velocities of the object’s vibrations and / or the output of the block for measuring the object’s oscillation amplitudes and / or the output of the slope measuring unit and / or the output of the deflection measuring unit and / or the output of the stress measuring unit and / or the output of the load measuring unit and / or the output of the absolute and non-uniform draft measurement unit and / or the output of the counter A crack joints and seams and / or output unit geodetic measuring parameters connected to the input of the processing unit and output information, the output of which is connected to the input of the output gradation information. 19 dependent points of f-ly, 2 ill.

Description

The utility model relates to the field of automated systems for monitoring the technical condition of buildings and structures and can be used in the design 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 city complex investment program "New Ring of Moscow".

BACKGROUND OF THE INVENTION

A device for implementing the method of testing buildings and structures (Nazin VV "The latest earthquake-resistant structures and reinforced concrete mechanisms for the seismic isolation of buildings and structures" - M .: Stroyizdat, 1993, p. 95-96), containing a device for exciting the tested object and installed at the facility, at least one unit for converting vibration into an electrical signal, connected in series with the recorder of the electrical signal. In this device, the vibration of the test object is excited by means of a hydraulic jack equipped with a special system of instant release from horizontal force.

Also known is the prototype 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 unit devices, a unit for generating an electric clock, a unit for converting oscillations into an electrical signal, an analog-

digital conversion of the electrical signal, a digital storage unit and a digital storage control unit, an input unit for experimental and / or calculated values of surface strength and / or volumetric strength and / or reinforcement parameters of the structural elements of the object and / or precipitation, and / or shifts and / or rolls 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, measure at least for the first tone of vibrations and / or the level of groundwater, a unit for comparing experimental data with normalized data calculated for structural data and materials of the test object and soil composition beneath and / or around it, and a unit for reproducing the obtained data related on control and data buses between themselves and with other functional blocks of the system. This system provides information on the sustainability of buildings and structures.

The disadvantage of this technical solution is the lack of gradation of the output information on the levels of the technical condition of the object.

DISCLOSURE OF A USEFUL MODEL

The claimed utility model eliminates the above drawback and implements an automated monitoring system for the technical condition of buildings and structures in the form of a device - a functional system represented in the form of spatially distributed functional blocks interconnected by functional links. Thus, this functional

the system satisfies the features inherent in devices as technical solutions.

The technical result obtained by grading the output information by the levels of the technical condition of the object is achieved by the fact that in the system for determining the stability of buildings and structures, comprising, a shock device unit, a vibration sensor unit and a processing and output information unit, an additional unit for measuring accelerations of object vibrations and / or an object vibration velocity measuring unit and / or an object vibration amplitude measuring unit and / or an inclination measuring unit and / or a deflection measuring unit and / or a voltage measuring unit minutes and / or load measurement unit and / or a unit measure absolute and differential settlement and / or block crack control joints and seams and / or geodetic measuring unit parameters and gradation output information block, coupled with the above functional blocks communication lines.

In the stated decision, the object is understood as a building, structure, structure or their structural part.

In the claimed solution, the output information gradation unit is the information output unit, divided by the levels of the technical condition of the object.

The output information gradation unit may produce, for example, visual signaling information divided by colors, for example, red color, characterizing the dangerous technical condition of the object, yellow color, characterizing increased attention to the technical condition of the object, green color, characterizing the normal technical condition of the object,

for example, sound information divided by acoustic parameters, for example, frequencies, tones, melodies, etc.

In addition, the output information gradation unit can provide information about changes in the technical condition of an object and its individual parts and elements.

In the claimed technical solution, the unit for measuring the acceleration of an object’s vibration is technical devices (for example, accelerometers) for measuring the acceleration of the object’s vibrations with the issuance of measurement results, including in digital form.

In the claimed technical solution, the unit for measuring the object’s oscillation velocities is technical devices (for example, velocimeters) for measuring the object’s oscillation velocity with the issuance of measurement results, incl. in digital form.

In the claimed technical solution, the displacement measurement unit are technical devices for measuring the amplitudes of the object’s vibration (for example, seismometers) with the issuance of measurement results, incl. in digital form.

In the claimed technical solution, the slope measurement unit is technical devices (for example, inclinometers, inclinometers, clinometers) for measuring the inclination of the object with the issuance of measurement results, including in digital form.

In the claimed technical solution, the deflection measuring unit is the technical device for measuring the deflection (for example, deflection) of the object with the issuance of measurement results, including in digital form.

In the claimed technical solution, the voltage measuring unit is technical devices (for example, strain gauges) for measuring the voltage of an object with the issuance of measurement results, including in digital form.

In the claimed technical solution, the load measuring unit is technical devices (for example, pressure sensors (loads)) for measuring pressure (loads) on (c) the object (e) and outside it with the issuance of measurement results, including in digital form.

In the claimed technical solution, the absolute and non-uniform precipitation measuring unit is technical devices (for example, absolute and non-uniform precipitation measuring sensors) for measuring object precipitation with the issuance of measurement results, including

in digital form.

In the claimed technical solution, the block control unit for cracks, joints and seams are technical devices (for example, crack gauges) for monitoring joints, cracks, seams with the issuance of measurement results, including in digital form.

In the claimed technical solution, the measuring unit for geodetic parameters is technical devices (for example, total stations and auxiliary equipment) for measuring the absolute and / or relative geodetic parameters of the object, including in real time with the issuance of measurement results, including in digital form.

The claimed combination of distinctive features has a stable relationship of functional blocks, not known to the applicant.

The claimed technical solution is industrially applicable because it does not use new technical devices not known to date, but is based on a new combination of functional blocks.

The block diagram of the utility model is shown in FIG. 1, where the shock block (1) excites object vibrations detected by the vibration sensor block (2) and / or the object vibration acceleration measurement unit (3) and / or the object vibration velocity measurement unit (4) and / or a unit for measuring the amplitudes of oscillations of the object (5), the outputs of blocks 2-5 are connected to the input of the processing unit and output information (6), the output of the slope measuring unit (7) and / or the output of the deflection measuring unit (8) and / or the output voltage measuring unit (9) and / or output of the load measuring unit (10) and / or the output of the absolute and non-uniform draft measurement unit (11), and / or the output of the unit for monitoring cracks, joints and seams (12) and / or the output of the unit for measuring geodetic parameters (13) are connected to the input of the processing unit and output information (6), the output of which is connected to the input of the output information gradation block (14).

The system operates as follows in accordance with figure 1.

Microseismic ground vibrations under the object or vibrations caused by the shock device block are transmitted to the object and then to the object vibration acceleration measurement unit and / or the object vibration velocity measurement unit and / or the object vibration amplitude measurement unit. The signals from the unit for measuring the acceleration of oscillations of the object and / or the unit for measuring the speeds of the oscillations of the object and / or the unit for measuring the amplitudes of the vibrations of the object are received in the processing unit and the output information. The same processing and output information block receives signals from the slope measuring unit about the object tilts and their changes and / or the deflection measuring unit about the object deflections and their changes and / or the voltage measuring unit about the stresses in the object and their changes and / or the measuring unit loads on the loads (pressures) on (in) the object (e) and outside it and their changes and / or the unit for measuring absolute and uneven precipitation on the degree of precipitation of the object and their changes in space and time and / or the control unit for cracks, joints and seams about the degree of disclosure Ia cracks, joints and seams and their changes and / or unit of measurement of the absolute and / or relative geodetic parameters object elements, including a real-time mode. The processing and output information block processes all incoming signals including the use of geoinformation systems that allow digital processing of spatially separated data with their coordinate reference and gives signals to the output information gradation block, from where the output information depending on the technical condition of the object can be represented in color, including using geographic information systems and / or sound, for various consumers, including for operating object services. If according to the processing data, in the processing unit and the output information of the measurement of various sensors it is established that the object is in a normal (safe) technical condition, then at the output of the output information gradation unit the information signal has one color (for example, green), if according to the processing data, it will be established that serious defects are accumulated in the object and increased attention is required, the information signal at the output of the output information gradation block will have a different color (for example, yellow), Finally, if, according to the processing data, it is established that defects that are hazardous to its safety have been accumulated in the object, the information signal at the output of the output information gradation block will have a third color (for example, red). Moreover, the number of gradations of the information signal at the output of the gradation block is output information on color and / or sound should be at least three.

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

Based on the results of processing the measurement data in the processing unit and the output information, local zones of the object can be determined in which the technical state of the individual elements of the object changes, information about this goes to the gradation block of output information, an information signal from which, depending on the technical condition of the local zones of the object , acquires one or another color (for example, green with the normal (safe) condition of the object, yellow with the accumulation of serious defects in the local area of the object, cr other, with a dangerous level of accumulation of defects in the local area of the object.

Moreover, the alternative used in this description and / or means all kinds of combinations of the joint functioning of all system blocks.

In the particular case of the implementation of the utility model, communication lines between functional blocks can be wired communication lines.

In the particular case of the implementation of the utility model, the communication lines of the functional blocks of the system can be wireless communication lines.

In the particular case of the implementation of the utility model, the communication lines of the functional blocks of the system can be combinations of wired and wireless communication lines.

In the particular case of the implementation of the utility model, that 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 sounds .. For example, with the number of gradations equal to three, the output information signal may have the following type of coloring: green color - safe technical condition of the object, yellow color - increased attention to the technical condition of the object, red color - dangerous technical condition of the object.

In the frequent case of the implementation of the utility model, the accelerometers may be the unit for measuring accelerations of object vibrations.

In the particular case of the implementation of the utility model, the unit for measuring the object’s oscillation velocities may be velocimeters.

In the particular case of the implementation of the utility model, the unit for measuring the amplitudes of the object’s vibrations can be displacement amplitude sensors or / and seismometers.

In the particular case of the implementation of the utility model, the unit for measuring the slopes of an object can be tilt meters and / or inclinometers and / or clinometers.

In the particular case of the implementation of the utility model, the unit of deflection of the deflection of the object may be deflection.

In the particular case of the implementation of the utility model, the unit may measure the voltage of the object tensometers.

In the particular case of the implementation of the utility model, the unit for measuring the loads on the object may be pressure sensors (loads).

In the particular case of the implementation of the utility model, the unit for measuring absolute and non-uniform precipitation of an object can be sensors for measuring absolute precipitation and sensors for measuring non-uniform precipitation.

In the particular case of the implementation of the utility model, the unit for monitoring cracks, joints and seams may be crack gauges.

In the particular case of the implementation of the utility model, the unit for measuring the geodetic parameters of an object can be total stations and auxiliary equipment.

In the particular case of the implementation of the utility model, the system for monitoring the technical condition of buildings and structures can be stationary and automated.

In the particular case of the implementation of the utility model, the system for monitoring the technical condition of buildings and structures can be mobile.

In the particular case of the implementation of the utility model, the functions of the block of the percussion device can carry out microseismic noise.

In the particular case of the implementation of the utility model, geographic information systems can be included in the processing and output information block.

In the particular case of the implementation of the utility model, geoinformation systems can be included in the output information gradation block.

Claims (20)

1. A system for monitoring the technical condition of buildings and structures, comprising a shock device unit, a vibration sensor unit, and a processing and output information unit, characterized in that an additional unit for measuring acceleration of vibrations of the object, and / or a unit for measuring velocities of vibration of the object, and / or measurement unit the oscillation amplitudes of the object, and / or the slope measuring unit, and / or the deflection measuring unit, and / or the stress measuring unit, and / or the load measuring unit, and / or the absolute and non-uniform draft measurement unit, and / or the unit warning light cracks, joints and seams, and / or block geodetic measuring parameters and gradation output information block. 2. The system according to claim 1, characterized in that the communication lines of the functional blocks of the system are wired communication lines. 3. The system according to claim 1, characterized in that the communication lines of the functional blocks of the system are wireless communication lines. 4. The system according to claim 1, characterized in that the communication lines of the functional blocks of the system are a combination of wired and wireless communication lines. 5. The system according to any one of claims 1 to 4, characterized in that 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, differing from each other in different colors and / or sound. 6. The system according to claim 5, characterized in that the unit for measuring acceleration of oscillations of objects are accelerometers. 7. The system according to claim 6, characterized in that the unit for measuring the speed of oscillation of the objects are cycle meters. 8. The system according to claim 7, characterized in that the unit for measuring the amplitudes of the oscillations of the object are sensors for measuring the amplitudes of displacement and / or seismometers. 9. The system of claim 8, characterized in that the unit for measuring the slopes of the object are tilt meters and / or inclinometers and / or clinometers. 10. The system according to claim 9, characterized in that the unit of deflection of the deflections of the object are deflection meters. 11. The system of claim 10, characterized in that the unit for measuring the voltage of the object are tensometers. 12. The system according to claim 11, characterized in that the unit for measuring the loads on the object are pressure sensors. 13. The system according to p. 12, characterized in that the unit for measuring the absolute and non-uniform precipitation of the object are the sensors for measuring absolute precipitation and the sensors for measuring non-uniform precipitation. 14. The system according to item 13, wherein the control unit for cracks, joints and joints can be crack gauges. 15. The system according to 14, characterized in that the unit for measuring the geodetic parameters of the object is a total station and auxiliary equipment. 16. The system of clause 15, wherein the system is stationary and automated. 17. The system according to clause 16, wherein the system is mobile. 18. The system according to 17, characterized in that the functions of the block of the percussion device can carry out microseismic noise. 19. The system of claim 18, wherein the geoinformation system is included in the processing and output information unit. 20. The system according to claim 19, characterized in that the geographic information systems are included in the output information gradation block.