KR101711449B1 - Compensation method for horizontal or vertical displacement of irregular tall building - Google Patents

Abstract

The present invention relates to a method for correcting vertical and horizontal displacement of an atypical high-rise building comprising a plurality of vertical members made of a concrete material, comprising the steps of monitoring the deformation amount of a vertical member based on a point of time after concrete pouring of an atypical high- A step of selecting a creep adjustment member to adjust the amount of creep deformation in the vertical member so as to adjust the deformation amount of the vertical member with a creep deformation amount according to the applied load based on the deformation amount of the vertical member, And adjusting the vertical and horizontal displacements of the atypical high-rise buildings by adjusting the loads. The present invention also provides a method for correcting vertical and horizontal displacements of atypical high-rise buildings.
Therefore, by considering the vertical and horizontal deformation of atypical high - rise buildings after concrete pouring, the verticality of atypical high - rise buildings can be predicted and corrected more reliably and the verticality of atypical high - rise buildings can be maximized.

Description

Technical Field [0001] The present invention relates to a method of compensating vertical displacement of a high-

More particularly, the present invention relates to a vertical and horizontal displacement compensation method of an atypical high-rise building which can maximize the verticality of an atypical high-rise building.

Generally, due to physical properties such as modulus of elasticity, creep, shrinkage and shrinkage of the material, the frame of the building continuously deforms not only during construction but also over a long period of time. These deformations generally accumulate and increase in proportion to the number of stories in a building, so a higher amount of deformation may occur in vertical and horizontal directions in a skyscraper.

In particular, long-term deformations increase continuously after completion of the frame, which can cause problems with finish and equipment performance and construction, and seriously affect structural stability. Accordingly, after the long-term deformation of the frame is predicted through the analysis of the construction phase and the like, there has been developed a method of preliminarily constructing the frame in the opposite direction in which the deformation occurs.

As an example of such a correction technique, Korean Patent No. 1011553 discloses a method of selecting a horizontal member or a vertical member that is expected to be corrected and estimating the amount of deformation based on the time of pouring concrete through structural analysis, A method of correcting the framing deformation during the construction of a skyscraper is described in which a correction amount per process is determined for each process based on the deformation amount,

However, in the above-described conventional frame deformation correcting method, the reference time point when selecting the correction amount is divided into the frame posture, the bottom dead point, and the exterior material deadline, respectively. The correction is made only for the viewpoint.

That is, in the past, the amount of correction was reflected at the time of concrete pouring to compensate the column shrinkage amount, and the calculated correction amount was determined by the concrete properties reflected in the analysis, and may be different from the actual site conditions. Therefore, the amount of correction applied at the time of concrete pouring is difficult to reflect the physical properties of the concrete in a timely manner, and thus it is difficult to predict and secure the verticality of the atypical high-rise building as much as possible.

The present invention relates to a vertical horizontal displacement of an atypical high-rise building capable of minimizing the difference in the amount of reduction of the vertical member causing the lateral displacement of the uppermost layer by predicting and securing the vertical degree by considering the vertical and horizontal deformation of the atypical high- It is an object to provide a calibration method.

According to one aspect of the present invention, there is provided a vertical and horizontal displacement correction method for an atypical high-rise building including a plurality of vertical members made of concrete, comprising the steps of: Monitoring the amount of deformation of the member; Selecting a creep adjustment member to adjust a creep deformation amount of the vertical member so that a deformation amount of the vertical member can be adjusted to a creep deformation amount according to a load applied based on the deformation amount of the vertical member monitored; And adjusting the vertical and horizontal displacements of the atypical high-rise building by adjusting a load applied to the selected creep adjustment member, thereby providing a vertical and horizontal displacement compensation method for an atypical high-rise building.

According to another aspect of the present invention, there is provided a method of monitoring an amount of deformation of a vertical member, comprising the steps of: monitoring a deformation amount of the vertical member with reference to a point of time after concrete pouring of the atypical high- Selecting a creep control zone for controlling the amount of creep deformation in the atypical high-rise building so that the deformation amount of the vertical member can be adjusted to a creep deformation amount according to a load applied based on the deformation amount of the vertical member monitored; And adjusting the vertical and horizontal displacements of the atypical high-rise building by adjusting a load applied to the selected creep control zone, thereby providing a vertical and horizontal displacement compensation method for an atypical high-rise building.

According to still another aspect of the present invention, there is provided a method for designing a high-rise building, the method comprising: performing a first construction stage analysis through a structural analysis based on a structural design of the atypical high-rise building; Establishing a correction plan according to the first construction phase analysis; Constructing the atypical high-rise building by pouring concrete based on the correction plan; Monitoring a deformation amount of the vertical member by unit layer based on a point of time after the concrete pouring of the atypical high-rise building through structural analysis; Comparing the monitored data with a first construction stage interpretation prediction result; Monitoring the deformation amount of the vertical member if the data satisfies the first construction stage analysis prediction result, and if the data is not satisfied, performing a second construction stage analysis by reflecting the monitored data; If the result of analysis of the second construction step satisfies the target deformation, the deformation amount of the vertical member is monitored again, and if the deformation amount of the vertical member is not satisfied, the deformation amount of the vertical member Selecting a creep adjustment member to adjust the creep deformation amount in the vertical member so as to adjust the creep deformation amount; And adjusting the applied load to the selected creep adjusting member to reflect the vertical and horizontal displacement of the atypical high-rise building in the correction plan.

The vertical and horizontal displacement correction method of an atypical high-rise building according to the present invention can provide the following effects.

First, by considering the vertical and horizontal deformation of atypical high-rise buildings after concrete pouring, it is possible to predict and correct the verticality of atypical high-rise buildings more reliably, and to minimize the difference in the amount of vertical member shrinkage, The verticality of the building can be maximized.

Second, various correction control methods such as adjusting the loading time point or adjusting the applied load amount can be taken in consideration of the change of the creep deformation amount and the like.

Third, it is possible to analyze the behavior depending on the correction of creep deformation by reviewing and reflecting the characteristics of long - term behavior of atypical high - rise buildings.

Fourth, it is possible to establish a vertical plan according to the displacement monitoring and correction layer, and to determine the amount of creep correction considering interlayer vertical and building vertical.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flowchart illustrating a method for correcting vertical and horizontal displacement of an atypical high-rise building according to an embodiment of the present invention.
2 is a graph showing the behavior characteristics of creep deformation of the atypical high-rise building of FIG.
FIG. 3 is a graph showing the behavior characteristics with respect to creep deformation according to the applied load in FIG.
Fig. 4 is a front view schematically showing the layer rotation angle of Fig. 1. Fig.
5 is a flowchart showing another embodiment of the vertical and horizontal displacement compensation method of the atypical high-rise building of FIG.
6 is a flowchart showing another embodiment of the vertical and horizontal displacement compensation method of the atypical high-rise building of FIG.
7 is a flowchart showing an algorithm of the vertical and horizontal displacement compensation method of the atypical high-rise building of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a vertical and horizontal displacement correction method of an atypical high-rise building according to an embodiment of the present invention is a method for correcting vertical and horizontal displacement of an atypical high-rise building including a plurality of vertical members made of a concrete material, A step S110 of monitoring the deformation amount of the vertical member, a step S120 of selecting a creep adjustment member, and a step S130 of adjusting the vertical horizontal displacement by adjusting the applied load.

First, the step of monitoring the amount of deformation of the vertical member (S110) is a step of measuring and monitoring a deformation amount of the vertical member based on a point of time after the concrete is poured into the atypical high-rise building through a structural analysis. Here, a known use program or the like can be applied to the structural analysis, and a detailed description thereof will be omitted.

In the step (S120) of selecting the creep adjustment member, the amount of creep deformation in the vertical member may be adjusted so that the deformation amount of the vertical member can be adjusted to a creep deformation amount according to a load applied based on the deformation amount of the vertical member And selecting a creep adjustment member.

Hereinafter, a method of selecting the creep adjustment member will be described in detail. First, before the creep control member is selected, analysis of the construction stage analysis of the atypical high-rise building or data measured during construction is examined to determine whether the vertical and horizontal displacement is corrected (S121).

Then, the amount of creep deformation according to the application time of the load to the vertical member is examined (S122). As shown in FIG. 2, the creep deformation is characterized in that the final deformation amount varies depending on the time when the load acts in the concrete curing total period. In addition, the creep strain has characteristics that the final creep deformation amount varies depending on the addition (action) or removal timing of the additional load as shown in Fig.

That is, it means that the final deformation amount can be adjusted by adjusting (adding or removing) the load acting on the vertical member. Therefore, to examine the amount of creep deformation according to the application time of each member, it is to examine how much deformation can be controlled by the creep when the application time of the load acting on the vertical member is different.

에 의한 층회전각 발생여부를 검토한다. As shown in FIG. 4, whether or not the layer rotation angle is generated according to the reduction amount of the vertical member is also examined.

And whether or not the layer rotation angle is generated by the above-

After the above-described process, the creep adjustment member for minimizing the layer rotation angle of the vertical member is selected (S124). That is, when the amount of reduction of the vertical member is varied to cause the horizontal displacement of the uppermost layer, a creep control member or a creep control zone is selected to minimize the layer rotation angle due to the difference in the amount of reduction of each vertical member.

The step of adjusting the vertical and horizontal displacements by adjusting the applied load may adjust the creep deformation amount by adjusting a member force applied to the selected creep adjusting member so that the vertical Adjust the horizontal displacement. Here, the amount of creep deformation is controlled by controlling the magnitude of the load acting on the member and the point of time when the member operates.

Meanwhile, a detailed method of controlling the vertical and horizontal displacement of the atypical high-rise building may change the gravity load transmission path as a method for adjusting the amount of creep deformation. For example, a gravity load acting on a vertical member may be provided to a lower layer to reduce the axial force of the column during a desired period of construction, thereby reducing the amount of creep deformation.

Alternatively, a gravity load may be added to control the amount of creep deformation. In this case, additional material or weight may be added to the selected creep control member or creep control zone to add gravity load acting on the vertical member, The creep strain can be increased by adding the axial force of the column during the desired period of time.

5 is a view showing another embodiment of the vertical and horizontal displacement correction method of the atypical high-rise building. Referring to the drawings, the vertical and horizontal displacement correction method of the atypical high-rise building includes steps of monitoring a deformation amount of the vertical member (S210), selecting a creep control zone (S220) And adjusting the displacement (S230). Here, the step of monitoring the deformation amount of the vertical member (S210) and the step of adjusting the vertical and horizontal displacements by adjusting the applied load are substantially the same as the respective steps of FIG. 1, and a detailed description thereof will be omitted , And we will focus on the major components.

The step of selecting the creep control zone (S220) may include adjusting the creep deformation amount of the atypical high-rise building to adjust the deformation amount of the vertical member to the creep deformation amount according to the applied load based on the deformation amount of the vertical member It is the stage to select the zone.

The method of selecting the creep control zone will now be described in detail. The vertical and horizontal displacement correction is examined to analyze whether the creep control zone is analyzed during the construction phase analysis or during construction of the atypical high-rise building. The amount of creep deformation according to the application time of the load to the vertical member is examined.

Then, whether or not the layer rotation angle is generated according to the reduction amount of the vertical member is examined, and the creep control zone for minimizing the layer rotation angle of the vertical member is selected based on the check.

6 is a view showing another embodiment of the vertical and horizontal displacement compensation method of the atypical high-rise building. Referring to the drawings, the vertical and horizontal displacement correction method of the atypical high-rise building includes a step S310 of performing a first construction step analysis, a step S320 of establishing a correction plan, a step of constructing an atypical high- S320), monitoring the deformation amount of the vertical member (S340), comparing the monitored data with the first construction stage analytical prediction result (S350), performing the second construction phase analysis (S360) A step S370 of selecting a creep adjustment member, and a step S380 of reflecting a content for adjusting the vertical and horizontal displacement.

Hereinafter, a vertical and horizontal displacement correction method of the atypical high-rise building will be described in detail with reference to FIG. 7, which shows an algorithm of the vertical and horizontal displacement correction method of the atypical high-rise building.

First, a first construction phase analysis is performed through a structural analysis program based on the structural design of the atypical high-rise building (S310), and then a correction plan is established according to the first construction phase analysis (S320) And the irregular high-rise building is installed (S330) by pouring concrete on the basis of the correction plan.

At this time, the deformation amount of the vertical member is measured and monitored (S340) on the basis of the time point after the pouring of the concrete of the atypical high-rise building after the construction, and the monitored data is compared with the first construction stage analytical prediction result do.

After the comparison, if the data satisfies the first construction stage analysis prediction result, the deformation amount of the vertical member is monitored again.

However, if the data does not satisfy the first construction stage analysis prediction result, the second construction stage analysis is performed by reflecting the monitored data (S360).

Here, at the time of analyzing the second construction step, the concrete material test, the construction schedule, the measurement and the deformation amount of the vertical member monitored are reflected.

When the result of the second construction step analysis satisfies the target deformation, the deformation amount of the vertical member is monitored again. On the other hand, if the analysis result of the second construction step is not satisfied with the target deformation, the creep adjustment member to adjust the creep deformation amount in the vertical member is selected (S370) so as to satisfy the target deformation.

Here, the creep adjustment member is for adjusting the amount of deformation of the vertical member by the amount of creep deformation according to the applied load on the basis of the deformation amount of the vertical member monitored, and is the same as that in the above- Do.

In detail, the method for selecting the creep adjustment member may include a review of the creep deformation amount at the application time of the load to the vertical member after the review of the correction (S371) (S372) After the occurrence of each occurrence is examined (S373), the creep adjustment member for minimizing the layer rotation angle of the vertical member is selected (S374) based on the generated creep adjustment member (S373). They will be omitted because they are substantially similar.

When the creep adjustment member is selected in accordance with the above, the load applied to the selected creep adjustment member in correspondence with the target deformation value is adjusted to reflect the adjustment of the vertical and horizontal displacement of the atypical high-rise building in the correction plan (S380) to establish a correction plan during construction. However, the present invention is applicable to any structure correction method that can reflect the vertical and horizontal displacement of the atypical high-rise building, even if it is not an atypical high-rise building. to be.

As described above, the correction method of the vertical and horizontal displacement of the atypical high-rise building can reflect the measurement and monitoring result and the concrete material characteristic after the concrete pouring, while the correction amount can be reflected only at the time of the conventional concrete pouring, It is possible to maximize the vertical degree by correcting the vertical and horizontal deformation in consideration of the creep characteristics of the member, as well as to minimize the difference in the vertical member reduction amount causing the horizontal displacement of the uppermost layer.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (10)

A vertical and horizontal displacement compensation method for an atypical high-rise building including a plurality of vertical members made of a concrete material,
Monitoring a deformation amount of the vertical member based on a point of time after the pouring of the concrete of the atypical high-rise building through a structural analysis;
Selecting a creep adjustment member to adjust a creep deformation amount of the vertical member so that a deformation amount of the vertical member can be adjusted to a creep deformation amount according to a load applied based on the deformation amount of the vertical member monitored; And
And adjusting vertical and horizontal displacement of the atypical high-rise building by adding a gravity load to the selected creep adjustment member to adjust the amount of creep deformation. The method according to claim 1,
Wherein the step of selecting the creep adjustment member comprises:
Analyzing the construction stage analysis of the atypical high-rise building or the measured data during the construction and examining whether or not to correct the vertical and horizontal displacement;
Examining the amount of creep deformation with respect to the application time of the load on the vertical member;
Examining whether a layer rotation angle is generated according to a reduction amount of the vertical member,
And selecting the creep adjustment member to minimize the layer rotation angle of the vertical member. A vertical and horizontal displacement compensation method for an atypical high-rise building including a plurality of vertical members made of a concrete material,

Monitoring a deformation amount of the vertical member based on a point of time after the pouring of the concrete of the atypical high-rise building through a structural analysis;

Selecting a creep control zone for controlling the amount of creep deformation in the atypical high-rise building so that the deformation amount of the vertical member can be adjusted to a creep deformation amount according to a load applied based on the deformation amount of the vertical member monitored; And

And adjusting a vertical and horizontal displacement of the atypical high-rise building by adding a gravity load to the selected creep control zone to adjust the amount of creep deformation. The method of claim 3,
The step of selecting the creep control zone comprises:
Analyzing the construction stage analysis of the atypical high-rise building or the measured data during the construction and examining whether or not to correct the vertical and horizontal displacement;
Examining the amount of creep deformation with respect to the application time of the load on the vertical member;
Examining whether or not a layer rotation angle is generated according to a reduction amount of the vertical member;
And selecting the creep control zone to minimize the layer rotation angle of the vertical member. delete delete A vertical and horizontal displacement compensation method for an atypical high-rise building including a plurality of vertical members made of a concrete material,
Performing a first construction phase analysis through structural analysis based on the structural design of the atypical high-rise building;
Establishing a correction plan according to the first construction phase analysis;
Constructing the atypical high-rise building by pouring concrete based on the correction plan;
Monitoring a deformation amount of the vertical member by unit layer based on a point of time after the concrete pouring of the atypical high-rise building through structural analysis;
Comparing the monitored data with a first construction stage interpretation prediction result;
Monitoring the deformation amount of the vertical member if the data satisfies the first construction stage analysis prediction result, and if the data is not satisfied, performing a second construction stage analysis by reflecting the monitored data;
If the result of analysis of the second construction step satisfies the target deformation, the deformation amount of the vertical member is monitored again, and if the deformation amount of the vertical member is not satisfied, the deformation amount of the vertical member Selecting a creep adjustment member to adjust the creep deformation amount in the vertical member so as to adjust the creep deformation amount; And
And adjusting the vertical and horizontal displacements of the atypical high-rise building in the correction plan by adding a gravity load to the selected creep adjustment member to adjust the creep deformation amount. Correction method. The method of claim 7,
Wherein the step of selecting the creep adjustment member comprises:
Analyzing the construction stage analysis of the atypical high-rise building or the measured data during the construction and examining whether or not to correct the vertical and horizontal displacement;
Examining the amount of creep deformation with respect to the application time of the load on the vertical member;
Examining whether a layer rotation angle is generated according to a reduction amount of the vertical member,
And selecting the creep adjustment member to minimize the layer rotation angle of the vertical member. The method according to claim 7 or 8,
The vertical and horizontal displacement of the atypical high-
Wherein the gravity load transmission path is changed to adjust the amount of creep deformation. delete

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