IT202000029885A1 - METHOD FOR DETECTING THE CURRENT STATE OF STRESS OF A SPECIFIC POINT OF A CONCRETE STRUCTURE IN PLACE BEFORE TAKING THE SPECIFIC CORE TO BE TESTED IN THE LABORATORY FOR THE DETERMINATION OF THE BREAKING STRESS AND A DEVICE FOR ITS IMPLEMENTATION - Google Patents

Description

Title: A method for detecting the current state of stress of a specific point of a concrete structure in situ before taking the specific core to be tested in the laboratory for determining the breaking stress and a device for its implementation

The present invention refers to a method for detecting the current state of stress of a reinforced concrete bearing structure during the execution of a sampling core with, possibly, subsequent execution of the crushing test under press in the laboratory to determine the stress of failure, with a system using in this method according to the classifying part of claim 1 and a device for carrying out this method according to the invention.

Field of invention

The technical field in which the method and the device according to the invention is inserted refers to the verification of the current stress state of load-bearing structures in reinforced concrete, in particular pillars or beams of buildings or bridge piers or load-bearing structures functional to determine a specific capacity? resistant. During the life of a civil or industrial structure, in particular a concrete structure made up of load-bearing structural elements (pillars, beams, tie rods, walls, piers), ? necessary to determine the capacity? resistance of the material in order to verify its suitability? to respond positively to the stresses imposed by the ever greater loads foreseen by the standards, in particular in the seismic field, where the new prescriptions impose a re-evaluation of the capacities? resistant under the loads deriving from seismic accelerations indicated in the standards according to the geographical areas.

To achieve these objectives, the prior art and the standards themselves require the sampling of concrete cores, generally with a diameter of 100 mm and a length of 200 mm, which are subsequently taken to the authorized laboratories to determine, by crushing them to breaking under the press, the limit value of resistance and the elastic modulus.

The operation of taking the concrete core takes place using a?core drill? which consists of a steel cylinder with a cutting blade that cuts a cylindrical element by rotating it. The cropping is normally carried out using a tool with the use of water during the cut. The term carrot is not to be understood in a limiting sense in the present invention and in the attached claims can also be understood to be any specimen or test of material that is extracted from a structure. State of the art

Core drilling - UNI EN 12504-1/2009 standard

The evaluation of the mechanical resistance of a concrete in situ can? be evaluated with a coring test, extracting cylindrical specimens of the concrete using a core drill, allowing to carry out the laboratory compression test of the cylindrical specimens taken on site through the modalities? executive foreseen in the D.M. 14/01/2008 which indicates that during the sampling phase and before carrying out the axial compression test, as can also be seen from art. C.11.2.6 of the Circ. Min. Infra. and Transport 02/02/2009 n. 617, particular attention must be paid to:

- The diameter of the cores is greater than at least three times the maximum diameter of the aggregates (normally not less than 100 mm);

- the ratio between the length and the diameter of the specimens is equal to 2 or in any case higher than 1 and lower than 2;

- both during the withdrawal and in the subsequent phase of deposit awaiting breakage? it is important to avoid that the specimens are subjected to air drying;

- does the sample subjected to the compression test present perfect planarity? and orthogonality? of the supporting surfaces and, while cutting for this purpose, the specimen remains undisturbed.

university University of Naples Federico II Doctoral School in Industrial Engineering Doctoral course in Engineering of materials and structures coordinator: prof. eng.

XXI? PhD thesis cycle Combined methods for the evaluation of the compressive strength of concrete - June 2010

The specialist course describes the known methodology for assessing the strength of existing reinforced concrete buildings which ? become a problem that more and more? often the technicians in charge of the consolidation and/or restructuring are forced to face. Knowledge of the strength of concrete ? fundamental to obtain an evaluation as much as possible? possible accurate capacity? structural of a building. In situ test methods can be used for a quantitative estimation of the strength of the structure to be analyzed but, to do this, ? It is necessary to establish a representative correlation between destructive tests carried out on the building (which involve core drilling) and non-destructive tests. Does the current legislation currently leave discretion? technicians on the choice of measurement points, giving instead indications on the number of invasive tests necessary to carry out an adequate investigation plan. The attempt of this study ? aimed at verifying the? reliability? of the correlation formulas for the calculation of the compressive strength of the concrete starting from the rebound index and from the speed? ultrasound. To carry out this study ? A 14-storey building in Bari was examined, called Punta Perotti, destined for demolition on which it was possible to carry out a large number of core drillings.

Punta Perotti was also a reinforced concrete building exposed for several years. 10 years in particularly aggressive environmental conditions (near the sea and in a very windy area) and without infill walls. 494 cores (181 with a diameter of 100mm and 293 with a diameter of 32mm) were taken from pillars of the building at different floors (-1, 0, 1, 2, 3, 6) after having carried out the non-destructive tests (ultrasonics and sclerometrics) at the points where the carrots were taken. Were analyzed some correlation formulas between the measures of the indexes of rebound and speed? ultrasound for the evaluation of the compressive strength of concrete (SonReb method).

Variation of in situ concrete strength by European Standard and American Code? October 2017

Describe the methods operational and interpretative ones for the execution of the concrete core on site and subsequent tests in the laboratory to determine the compressive strength of the specimen and its way of being processed.

All previous publications do not teach how to determine, measure, the stress to which ? subject the point of withdrawal of the carrot.

The purpose of the present invention ? to create a method for measuring the current stress state of a structure, in particular pillars and beams of buildings or bridge piers or functional load-bearing structures to determine a specific capacity? resistant by extracting a core while, at the same time, the core is cut and the deformations, and therefore the stresses, deriving from the existing loads are detected.

This object is achieved by the present method for detecting the current state and monitoring the relative deformation during the formation of the core according to the characterizing part of claim 1.

A method is therefore proposed which includes the following steps:

a) preparation of a surface of a structure on which you intend to carry out the core,

b) placement of at least one strain gauge on the prepared surface of the structure,

In a preferred embodiment of the method according to the invention, two strain gauges are positioned parallel to each other or three strain gauges in which the second strain gauge ? rotated 45? compared to the first strain gauge and the third strain gauge by 90? than the first strain gauge.

c) connection of the strain gauges with an instrumentation for saving and/or sending the data detected by the strain gauge(s), the instrumentation ? arranged in a container preferably in the shape of a glass,

d) activation of data acquisition from the strain gauge(s) with prior setting of the scan and the technical parameters relating to the strain gauges connected via cable with plug and/or wireless system connected to a unit? data storage and processing,

e) fastening of the glass container to the surface of the structure around the strain gauges,

in an advantageous way the fixing takes place by means of the screws and/or plugs, the container preferably has a gasket on the contact surface with the surface of the structure, by means of the screws and/or plugs a pressure is generated which guarantees a watertight seal of the container ,

f) execution of the core using a tool around the container, data collection of the values generated by the strain gauges during the execution of the core formation,

In this case the tool that forms the carrot makes a circular cut, for example around the container. This type of tool normally uses water to lubricate and/or cool the core drill therefore? the watertightness of the container? particularly important.

In a subsequent phase, the core is taken to the laboratory to carry out tests, for example to carry out a core compression test.

Furthermore, a device according to the invention for carrying out the method according to the invention is disclosed.

The device according to the invention? formed by a body which has an opening on the side with which a glass-shaped container which can be placed on a structure is preferably placed on the side. be contained within the tool that performs the core.

Inside the body of the device according to the invention ? arranged a unit? of memory and/or sending data that ? directly connected with at least one extensometer, in which the extensometer adapted to be positioned on a surface of a structure to detect the relative strain data during the execution of the core and a battery or the like to power unit? memory and/or data transmission and/or at least one strain gauge.

So preferred the device ? directly connected with at least two strain gauges which are parallel to each other or with at least three strain gauges in which the first strain gauge is arranged substantially horizontally, the second ? disposed inclined at 45 ? compared to the first strain gauge and the third strain gauge ? willing 90? compared to the first strain gauge. This allows the measurement of the relative deformation during the execution of the core cut. The strain gauges are then connected to an acquisition and storage instrumentation with, where necessary, remote data transmission.

The device according to the invention has an opening on the surface of the body which is suitable to be opposed to the surface of the structure with a gasket and the device is fixed on the structure in a preferred way by means of plugs and/or screws.

In this way the instrumentation inside? protected since? a watertight body is formed between the surface of the structure and the device.

According to the invention in the method, in the first phase of one or more? strain gauges preferably three in the horizontal direction at 45? and 90? which allow the measurement of the relative deformation. The strain gauges are then connected to an acquisition and storage instrumentation with, where necessary, remote data transmission. The acquisition system has the advantage of being installed in a very small container, generally a preferably cylindrical or square element of about 50 mm in diameter, with battery power supply and data storage and/or remote data transmission system. This tool, fixed through two or more? screws with dowel to the concrete element to be cored, above the strain gauges, suitably watertight through a gasket placed on the contact edge.

The coring operation takes place after activating, either through a cable or wireless transmission connection to the computer, the acquisition of the data deriving from the strain gauges. Beforehand, the data scanning (the number of acquisitions per second) and the recognition parameters relating to the type of connected strain gauges are set. As the core drill advances, the strain gauges detect a deformation of the opposite sign, but of the same absolute value, to that impressed by the stresses present at the sampling point. Extracted the carrot this will result? completely released pre-existing tensions thus highlighting? the state of stress to which that portion of material was subjected.

The carrot what? extracted, and of which the state of stress of the sampling point is now known, it is compressed in the laboratory until it breaks.

In this way you can detect the relationship between stress in place and ability? resistant. Ratio which becomes fundamental for understanding the level of safety of the structural element in question.

Further characteristics and details result from the further claims and from the description of an embodiment of a device according to the invention, with reference to the Figures of the attached drawing, in which:

Figure 1 shows a front view of a structure on which to detect the current stress state,

Figure 2 shows a section of Figure 1 with the data acquisition tool applied, e

Figure 3 shows an enlargement of Figure 2 with a detail of the device according to the invention.

In figure 1 ? indicated with the reference number 100 a load-bearing structure in particular a beam, a pillar, a pier or in any case a concrete element of which, in one point, one wants to know both the state of stress and the capacity? resistant.

The supporting structure? formed by at least one reinforced concrete element 101 on which at least one strain gauge 102 is arranged, preferably at least two arranged parallel to each other or three strain gauges arranged at 0?, 45?, 90?.

After the strain gauges have been glued to the structure 100, these are preferably protected by a film, for example of butyl coated with aluminum.

In a subsequent step, the cables 105a of the strain gauges 102 are connected directly (by means of cables) with power supply and data acquisition and/or data storage, and/or data transmission means, for example remotely, 104. All elements are inserted into the hollow body having an opening on the side suitable for being opposed to the surface of the structure, for example a container 105, generally cylindrical, of reduced dimensions, substantially cup-shaped, which is fixed to the surface of the structure in a preferred way by means of screws and dowels 106 and which has a seal 107 on the edge of the opening for watertightness since? the? operation of coring ? carried out when the core drill is cooled with water and the electronic/electrical elements present in the device must be protected.

The coring operation takes place preferably after activating, either via a cable or wireless transmission connection to the computer, the acquisition of the data deriving from the strain gauges. Beforehand, the data scanning (the number of acquisitions per second) and the electrical parameters relating to the recognition of the type of strain gauge used are set.

We then proceed with the activation of the core drill until the core is taken and transported to the laboratory.

AND? finally, it is clear that additions, modifications or variations that are obvious to a person skilled in the art can be applied to the method described up to now without thereby departing from the scope of protection provided by the appended claims. In particular, the single steps of the method can be performed in different order.

List of reference numbers

100 structure to analyze

101 reinforced concrete element

102 strain gauges

103 carrot/specimen

104 power supply, storage and/or data transmission equipment

5 hollow body / glass container 6 fixing screws and dowels

07 gasket

Claims (8)

Claims 1. Method for detecting the current state of stress of a structure (100) preferably made of concrete wherein the method comprising the following steps: a) preparation of a surface of a structure (100) on which it is intended to carry out a core (103), b) placing at least one strain gauge (102) on the prepared surface of the structure, c) connection of the strain gauges with an instrumentation for powering and saving and/or sending the data detected by the strain gauge(s), d) activation of data acquisition from the strain gauge(s) e) fixing the hollow body (105) with an opening opposite the surface of the structure which occurs around the strain gauges, f) execution of the core (103) by means of a tool around the container, data collection from the strain gauges during the execution of the formation of the core (103). 2. Method according to claim 1, characterized in that there are two strain gauges (102) and arranged parallel to each other. 3. Method according to claim 1, characterized in that the strain gauges (102) are three strain gauges wherein the second strain gauge ? rotated 45? compared to the first strain gauge (102) and the third strain gauge by 90? than the first strain gauge (102). 4. Method according to one of the preceding claims, characterized in that in step d) the scanning of the data to be acquired and of the technical parameters relating to the strain gauges connected by cable and/or wireless system connected to a unit? of calculation. 5. Method according to one of the preceding claims, characterized in that the fixing of the hollow body (105) which is a container in the shape of a glass takes place by means of the screws and/or dowels (106), and that the container (105) has a gasket (107) on the contact surface with the surface of the structure, and that by means of the screws and/or dowels (106) a pressure is generated which guarantees a tight seal of the container (105). 6. Method according to one of the preceding claims, characterized in that the strain gauges (102) are powered by the instrumentation (104) which acquires and memorizes the data during the execution of the core (103) and, possibly, transmits them remotely. 7. Method according to one of the preceding claims, characterized in that the strain gauges (102) are protected by an aluminum film coated with butyl or a suitable material to prevent the infiltration of humidity. 8. Device for a method according to one of the preceding claims characterized in that ? formed by a body that has an opening on the side with which pu? be placed on a structure (100), preferably a glass-shaped container (105) which can be arranged inside a tool which performs the core (103), and which instrumentation (104) is arranged inside the body of the device, presenting a unit? of memory and/or a unit? sending data and a battery or similar to power the unit? of memory and/or data transmission and/or l?at least a strain gauge and that ? instrumentation (104) ? directly connected to at least one strain gauge (102) and that the opening has a seal (107).