The object of this invention is a method for measuring the utilization of the load carrying capacity of the building structural element subjected to variable actions, for example loaded with snow. The method can be used in systems for monitoring the utilization of the load carrying capacity (the level of safety risk) of roof structures of buildings, especially large-area buildings.
Monitoring the structure of buildings, in particular roof structural elements, leads to improvement of the safety of using these buildings. The basic group of methods used for this purpose includes methods for monitoring changes in the position of structural elements of a building using optical devices.
The specification of the Polish application P.381578 presents a method for detecting the achievement of predetermined utilization of the load carrying capacity based on directing a light beam below the beams of a roof structure. By excessive bending of at least one beam beyond a permitted, assumed value, the light beam is interrupted and then audible and visual alarms are activated.
The Polish patent description PL183116 discloses a method for measuring the twisting and deflection of a beam in static and dynamic systems, wherein at least one mirror is attached to the test element to which a laser beam is directed, which, after reflection, is read in a screen.
The applicants of the subject invention have developed a method for monitoring the vertical displacement component and vertical deflection component of structural elements of buildings using measurements made by laser rangefinders, disclosed in the U.S. Pat. No. 8,788,240 B2. The distance measurements performed in this method are made in relation to fixed elements, such as the floor.
The description of the patent FI118701B discloses a method for monitoring the load of the roof structure using inclinometers, i.e. instruments measuring the inclination of the measurement axis of the inclinometer from a plane perpendicular to the direction of the gravity vector, wherein they are placed on the structural elements of buildings freely, e.g. on one side of the structure of a roof or a building. The disadvantage of such a system is the possibility of the occurrence of large errors when measuring the utilization of the load carrying capacity of the structure in the case of an asymmetrical load on the roof.
The applicants of the present invention have developed a method for monitoring the variable actions on the roof structure with the use of inclinometers, which has been disclosed in the Polish patent description PL230522. This patent uses the measurements of rotation angles of cross-sections, caused by the variable action, by means of two inclinometers mounted on the monitored structural element in two points, symmetrically relative to its transverse axis of symmetry. Subsequently, the sum of absolute values of these angles is used as the measure of its load carrying capacity utilization. This sum represents well the utilization of the load carrying capacity in the case of some building structural elements, e.g. in the case of a single-span frame-based structure, in a situation when the maximum value of the utilization of the load carrying capacity occurs in the corner of the frame, where the value of the bending moment is usually the highest. In other cases, the error of determining the utilization of the load carrying capacity by means of said sum can be unacceptably high.
Known methods for monitoring the deflection of structural elements using laser rangefinders have limited applicability in cases when the ambient temperature is too low or too high, when the ground is uneven and soiled, or when there is high dustiness, which occurs, e.g. in the wood industry.
Known methods for monitoring the variable action on the roof structure using inclinometers are characterised by large measurement errors for a non-uniformly distributed load.
The object of the invention is a method for measuring the utilization of the load carrying capacity of the building structural element, used to reliably determine the level of risk to the safety of use of a building caused by temporary external factors, e.g. atmospheric. This method should be insensitive to the asymmetry of the load of the building structural element and harsh environmental conditions, such as very low temperatures (lower than −20° C.), frost, very high temperatures (higher than +50° C.), high humidity, high dustiness, contamination of the ground (e.g. snow or mud in open canopies), etc.
The object of the invention is a method for measuring the utilization of the load carrying capacity of a building structural element subject to variable action, comprising measurements of the rotation angles of cross-sections of this building structural element, wherein the rotation is caused by this variable action, characterised in that the rotation angles α1 and α2 of the cross-sections of the building structural element around the axis Z perpendicular to the longitudinal section of this building structural element are measured in two points A and B of this element, located symmetrically relative to its transverse axis of symmetry, and subsequently the higher of the measured values of the angles α1 and α2 is used as the measure of the utilization of the load carrying capacity of said element.
Also, it is preferable when the values of rotation angles γ1 and γ2 of cross-sections of the building structural element around axes perpendicular to these sections are also measured in points A and B of the building structural element, and subsequently the values of angles γ1 and γ2 are used as an indicator of a stability loss of the given building structural element.
Also, it is preferable when the measurements of the angles are performed periodically and/or synchronously.
The measurement of rotation angles is performed by means of inclinometers or other known devices or methods, such as geodetic methods.
The utilization of the load carrying capacity of a building structural element subject to variable action, determined based on the measured values of rotation angles α1 and α2 of the cross-sections around the axis Z, or its loss of stability, determined based on the measured values of rotation angles γ1 and γ2 of its cross-sections around an axis perpendicular to these sections, means exceeding the limit states of the utilization of the load carrying capacity, meaning that the structure has reached a state threatening the safety of the building and its users. Here, stability of the structure is understood as the ability of the structure to retain its unchanged position and shape under the load.
It is a common assumption that the deflection of a structural element is a good measure of the utilization of the load carrying capacity of this element, wherein said deflection is preferably measured in the middle of its span. In a case when the load is distributed uniformly across the entire span of the element, the deflection measured in the middle of its span is a good measure of the utilization of the load carrying capacity. In the case of an asymmetrical load, deflection measured in the middle of its span can be a considerably worse representation of the utilization of the load carrying capacity of this element. Similar or much larger errors in determining the utilization of the load carrying capacity of the element can result from using a single measurement of the rotation angle of the cross-section at one of the ends of this element.
The proposed method is free of the above mentioned disadvantages, and both in the case of symmetrical and asymmetrical loads it represents the utilization of the load carrying capacity of the building structural element with sufficient accuracy.
The method according to the invention is presented carried out in an embodiment in
As indicated above,
The points of attachment of the inclinometers Incl_1 and Incl_2 depend on the type of the structure, the type of the structural element and its span, indicated in
Table 1 lists the results of simulation calculations for the framework structure system with sample defined parameters presented in
A reference value determining the utilization of the load carrying capacity of the presented frame is the maximum value of the stress σmax (column f in Table 1) in the frame (in any place).
An analysis of the calculation results presented in Table 1 shows that the values of the deflection u in middle of the span (column c in Table 1) and the smaller of the two measured rotation angles, in this case α1 (column d in Table 1), behave completely differently as a function of the change in load distribution (cases 2-9 in Table 1) from the maximum stress σmax (column f in Table 1) occurring in the frame. The use of these values (u and α1) as a measure of the utilization of the load carrying capacity of the structural element for a non-uniform load could result in very large errors (column i in Table 1 for the deflection u and column j in Table 1 for the angle α1). The method for measuring the utilization of the load carrying capacity based on measuring any of the two possible rotation angles, thus also including α1, is used—without any reservations—to monitor the building structure according to the prior art, i.e. the specification of FI118701B.
Another method, disclosed in PL230522, is based on the measurement of the average value of the rotation angles αav (column h in Table 1). The use of this value as the measure of the utilization of the load carrying capacity results in errors (column I in Table 1) reaching even −166% for a highly uneven load. An error value of less than zero additionally means that the current utilization of the load carrying capacity will be higher than the measured one (determined based on the measured values of the angle αav).
It is quite the opposite in the case of using the greater of the rotation angles αmax (column g in Table 1), in this case αmax=α2, of two cross-sections as a value representing the utilization of the load carrying capacity of the frame. The ratio of the value of the greater of the rotation angles α1 and α2 of the cross-sections αmax (column g in Table 1) to the value of maximum stress σmax (column fin Table 1) is constant, with an error of no more than 20% for the presented frame (column k in Table 1), for changes in the unevenness of load within a wider range than what is observed in practice—from the uniformly distributed load across the entire length of the roof to one located only in ⅕ of the span. Such a value of the error is acceptable in the investigated application, especially since it is always higher than zero, which means that the current utilization of the load carrying capacity will be lower than the measured one (determined based on the measured value of the angle αmax). Such a situation is safe; it poses no risk of overloading the structure by excessive utilization of its load carrying capacity.
In the case of using the deflection u, measured in the middle of the span of the frame (column c in Table 1), for determining the utilization of its load carrying capacity, the error of such determination (column h in Table 1) reaches a value of approx. −50% for a load located only on one roof surface (L1=0.5 L), or even on the order of −330% for a load located in ⅕ of the span. In addition, this error has a value lower than zero, which means that the current utilization of the load carrying capacity in this case would be higher than the measured one. Therefore, such a situation would be dangerous and it could pose a risk of overloading the structure.
The measurement of the utilization of the load carrying capacity of the building structural element (based on the measurements of the rotation angles α1 and α2) is possible when the building structural element is stable. The loss of stability means reaching the limit state of the utilization of the load carrying capacity regardless of the measured value of the utilization of the load carrying capacity. A loss of stability of the building structural element can be detected by means of optionally measured rotation angles γ1 and γ2, where a considerable change in one or both rotation angles can indeed mean a loss of stability.
Therefore, in structural systems of the single-bay frame type, the value of the greater of the rotation angles of cross-sections around the axis Z perpendicular to its cross-section, measured in two points of the structural system, situated symmetrically relative to the transverse axis of symmetry of the building structural element, caused by a variable action, represents the utilization of the load carrying capacity of the structure with sufficient accuracy for practice, within a scope of load changes which is real from a practical point of view. Similar error values are also obtained as a result of calculations for other types of structures, such as beams or trusses. In addition, the values of the rotation angles of cross-sections around axes perpendicular to these sections may serve the detection of a loss of stability of this system.
A flowchart is shown in
The measuring of the rotation angle γ1 and the rotation angle γ2 of the structural element cross-sections around axes perpendicular to the cross-sections comprises also measuring at the two points (A, B) of the structural element, and subsequently using the value of angle γ1 and the value of angle γ2 as an indicator of stability loss of the structural element of the building.
It should be realized that the measuring of rotation angles may performed periodically as shown by the decision step after the step of using, thereby allowing for repeated steps of measuring, processing, and using again. The steps may be performed synchronously as well.
Number | Date | Country | Kind |
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433466 | Apr 2020 | PL | national |
Number | Name | Date | Kind |
---|---|---|---|
8788240 | Pioro | Jul 2014 | B2 |
20080030710 | Oshima | Feb 2008 | A1 |
20110029276 | Cabral Martin | Feb 2011 | A1 |
20120166136 | Pioro | Jun 2012 | A1 |
20170307467 | McCallen | Oct 2017 | A1 |
20180164093 | Westcott | Jun 2018 | A1 |
20190390955 | Pioro | Dec 2019 | A1 |
Number | Date | Country |
---|---|---|
206670571 | Nov 2017 | CN |
3312555 | Apr 2018 | EP |
3312555 | Apr 2018 | EP |
118701 | Feb 2008 | FI |
183116 | May 1997 | PL |
381578 | Apr 2008 | PL |
Entry |
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Polish search report for application No. P.433466, dated Apr. 8, 2021, 1 page. |
Machine translation of the abstract for PL379088A1, 1 page. |
Bibliographic data by DEPATISnet for PL379088A1, 1 page. |
Number | Date | Country | |
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20210310896 A1 | Oct 2021 | US |