KR20120083706A - Apparatus for measuring vertical deformation of structure under construction and apparatus for computing compensatoin value against column shortening of structure under construction - Google Patents

Abstract

PURPOSE: A device for measuring a vertical displacement amount of a structure under the construction and a device for calculating a correction value of a column reduction amount of the structure under the construction are provided to enhance the safety and the completeness of a building structure. CONSTITUTION: A device for measuring a vertical displacement amount of a structure under the construction comprises a reference measuring unit(110), a temporary deflection measurement unit(120), and an actual reflection calculator(130). The reference value measuring unit measures a vertical direction reference coordinate value at a reference position of a top layer of a structure under the construction. The temporary deflection measurement unit measures the vertical temporary displacement of the top layer of the structure. The actual displacement calculator calculates the actual vertical displacement of the top layer of the structure by comparing a vertical displacement value measured by a vertical displacement measuring unit and the reference coordinate value measured by the reference value measuring unit.

Description

FIELD OF MEASURING VERTICAL DEFORMATION OF STRUCTURE UNDER CONSTRUCTION AND APPARATUS FOR COMPUTING COMPENSATOIN VALUE AGAINST COLUMN SHORTENING OF STRUCTURE UNDER CONSTRUCTION}

The present invention relates to a monitoring device for a building structure under construction. In particular, the present invention relates to a device for measuring the amount of vertical displacement of the floor of the top floor of a building under construction using a GPS device and a laser scanner, and a device for calculating a correction value for the measured column shrinkage.

In the construction of high-rise buildings and general buildings, the floor surface may not be horizontal due to a construction mistake or contraction during the construction. If this is not quantitatively monitored, not only unforeseen member stresses will occur, but also adversely affect the usability of the occupants.

Conventional devices that measure the floor level of such high-rise buildings or buildings have inclinometers, but relatively accurate measurements can be made at close range, but when the scale is large and the distance is large, as in the case of large buildings such as high-rise buildings or large space structures, There was a problem of poor precision.

In addition, the post-monitoring method for the constructed building has been studied in various ways, but the correction of the reduction of the pillars of the building structure under construction is carried out by the field empirical methods. Therefore, it is necessary to measure the exact amount of column shrinkage and to correct it during construction.

An apparatus for measuring vertical displacement of a structure under construction and an apparatus for calculating a correction value for a contraction amount of a pillar of a structure under construction according to the present invention aims to solve the following problems.

First, we want to monitor the vertical displacement of the entire floor, not local monitoring, for the building structure under construction.

Second, not only the relative displacement value of the floor under construction but also the absolute displacement of the floor under construction is to be measured.

Third, by measuring the shrinkage of the column generated in the building structure under construction to allow correction during construction.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

The vertical displacement measuring apparatus for a structure under construction according to the present invention includes a reference value measuring unit for measuring a vertical reference coordinate value at a reference point of the uppermost floor of the structure under construction, and a variable displacement measurement in which the vertical displacement of the uppermost floor of the structure is measured. It includes a real displacement calculation unit for calculating the actual vertical displacement of the uppermost layer of the structure by comparing the reference coordinate value measured in the unit and the reference value measuring unit and the vertical displacement value measured in the vertical displacement measuring unit.

The apparatus for measuring the vertical displacement amount of a structure under construction according to the present invention may further include a display unit which divides the uppermost layer of the structure under construction into a measurement region and displays a real displacement calculated by the real displacement calculator for each measurement region.

The vertical displacement measurement apparatus of a structure under construction according to the present invention may further include an alarm generating unit for generating an alarm when the real displacement calculated by the real displacement calculation unit exceeds the limit displacement.

The reference value measuring unit according to the present invention includes a GPS device for measuring the three-dimensional behavior of the structure by using a GPS carrier emitted from a GPS (Global Positioning System) satellite, and using the GPS device to measure the absolute vertical reference coordinate value It is characterized by.

The GPS device according to the present invention compares a reference coordinate receiver for measuring a comparison position, a reference coordinate receiver arranged at a reference point, and a reference coordinate to calculate a reference coordinate value by comparing the coordinate values measured at the reference coordinate receiver. It includes a coordinate operator.

The GPS device according to the present invention is characterized by measuring a coordinate value measured by the reference coordinate receiver during the reference coordinate reference time, and using the average value of the measured coordinate values.

The variable displacement measuring unit according to the present invention includes one or more laser scanners disposed on the uppermost layer of the structure, and the laser scanner measures relative vertical displacement of the uppermost layer of the structure on the basis of the disposed position.

At least one of the laser scanners according to the present invention is disposed at a reference point to measure the variable position of the uppermost layer of the structure.

When at least one laser scanner according to the present invention is disposed on the uppermost floor of the structure, or when the position of one laser scanner is changed to measure the variable position of the uppermost floor of the structure, the real displacement calculator may measure one measurement area measured by one laser scanner. After converting to the variable position for the uppermost layer of the structure, it is characterized by calculating the real displacement based on the reference coordinate value.

The laser scanner according to the present invention is characterized in that the variable displacement is repeatedly measured during the displacement reference time, and the real displacement calculator calculates the real displacement using the average value of the values repeatedly measured by the laser scanner.

The apparatus for calculating a correction value for a pillar reduction amount of a structure under construction according to the present invention is based on a reference value measured by a reference value measuring unit and a reference value measuring unit for measuring a vertical reference coordinate value at a reference point of the uppermost floor of the structure under construction. In addition, the reduction amount measuring unit for measuring the column reduction amount of the uppermost layer of the structure and a correction value calculation unit for calculating a value to be corrected in the uppermost structure of the structure by using the reduced column amount measured in the reduction amount measuring unit.

The reference value measuring unit according to the present invention includes a GPS device for measuring the three-dimensional behavior of the structure by using a GPS carrier emitted from a GPS (Global Positioning System) satellite, and using the GPS device to measure the absolute vertical reference coordinate value It is characterized by.

The GPS device according to the present invention compares a reference coordinate receiver for measuring a comparison position, a reference coordinate receiver arranged at a reference point, and a reference coordinate to calculate a reference coordinate value by comparing the coordinate values measured at the reference coordinate receiver. It includes a coordinate operator.

The GPS device according to the present invention is characterized by measuring a coordinate value measured by the reference coordinate receiver during the reference coordinate reference time, and using the average value of the measured coordinate values.

The reduction amount measuring unit according to the present invention includes one or more laser scanners disposed on the uppermost layer of the structure, and the laser scanner measures relative column shrinkage of the uppermost layer of the structure on the basis of the disposed position.

At least one of the laser scanners according to the present invention is disposed at a reference point to measure the reduction of the column of the uppermost layer of the structure based on the reference coordinate value measured by the reference value measuring unit.

In the reduction amount measuring unit according to the present invention, when one or more laser scanners are disposed on the uppermost floor of the structure, or when the position of one laser scanner is measured to measure the variable position of the uppermost floor of the structure, the column reduction is performed for each measurement area measured by one laser scanner. The amount is calculated, and the correction value calculating unit calculates a correction value for each measurement area.

In the reduction amount measuring unit according to the present invention, when one or more laser scanners are disposed on the uppermost floor of the structure, or when the position of one laser scanner is measured to measure the reduction of the pillars on the uppermost floor of the structure, one reduction area is measured by one laser scanner. Converted to the column reduction amount for the whole of the top structure of the structure, the correction value calculating unit is characterized in that for calculating the correction value for one top structure.

The laser scanner according to the present invention is characterized in that the pillar reduction amount is repeatedly measured during the reduction amount reference time, and the pillar reduction amount is measured using the average value of the repeatedly measured values.

Apparatus for measuring the vertical displacement of the structure under construction and the apparatus for calculating the correction value for the column shrinkage of the structure under construction according to the present invention has the following effects.

Firstly, the vertical displacement of the top floor of the building structure under construction is accurately measured, and reinforcement is performed when displacement occurs above the limit value. This increases the safety and completeness of the building structure.

Second, in the case of measuring the displacement on the top floor of the building structure under construction, since the displacement occurring at the measuring point is considered using GPS, accurate vertical displacement is measured.

Third, with respect to column shrinkage that occurs during construction, it is possible to appropriately correct the construction of a detailed area of each layer or a group including all or several layers of each layer.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a block diagram showing the configuration of a structure vertical displacement measurement apparatus for a structure under construction according to the present invention.
2 illustrates an example in which a comparative coordinate receiver and a reference coordinate receiver are arranged in the GPS device of the reference value measuring unit.
FIG. 3 illustrates an example in which a laser scanner is disposed at a reference point SA and a reference point at the top floor of a building structure.
4 illustrates an example in which one or more laser scanners are arranged on the top floor of a building structure, or an example of scanning a measurement area while moving one laser scanner.
5 (a) shows an example in which the amount of vertical displacement or pillar reduction measured in each measurement region is measured differently, and FIG. 5 (b) shows the amount of vertical displacement or pillar reduction measured in each measurement region for the entire uppermost layer. One displacement diagram shows an example of conversion to column shrinkage.
Figure 6 is a block diagram showing the configuration of a correction value calculation device for the column shrinkage for the structure under construction according to the present invention.

As used herein, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It is to be understood that the present invention means that there is a part or a combination thereof, and does not exclude the presence or addition possibility of one or more other features or numbers, step operation components, parts or combinations thereof.

Hereinafter, with reference to the drawings will be described in detail with respect to the vertical displacement measuring device 100 of the structure under construction and the correction value calculation device 200 for the reduction of the column of the structure under construction. The device for measuring the vertical displacement of the structure under construction and the device for calculating the correction value for the column shrinkage of the structure under construction have a common configuration. Basically, a device for measuring the amount of vertical displacement of the bottom surface of the structure under construction is used. The vertical displacement amount is for measuring whether the floor surface to be constructed has a displacement in the up or down direction with respect to the reference plane. In other words, it is to measure the level of the floor surface currently being constructed based on the reference horizontal plane.

1 is a block diagram showing the configuration of the structure vertical displacement measurement apparatus 100 for a structure under construction according to the present invention.

Vertical displacement measuring apparatus 100 of the structure under construction according to the present invention is a reference value measuring unit 110 for measuring the vertical reference coordinate value at the reference point (SA) of the top layer of the structure under construction, the vertical direction of the top layer of the structure ( Iii) comparing the reference coordinate value measured in the variable displacement measuring unit 120 and the reference value measuring unit 110 in which displacement is measured with the vertical displacement value measured in the vertical displacement measuring unit, and It includes a real displacement calculation unit 130 for calculating the displacement.

The reference value measuring unit 110 is for measuring the absolute reference coordinate value of the uppermost layer of the structure currently being constructed. It is possible to measure the amount of vertical displacement of the floor of the current building structure without measuring the absolute reference coordinate value. In this case, however, it is difficult to consider the amount of displacement occurring in whole or in part on the uppermost floor that is currently constructed due to the amount of column shrinkage that may occur in high-rise buildings. Further, the displacement value measurement of the bottom surface is performed through the laser scanner 125. If the position where the laser scanner 125 is disposed has a displacement, inaccurate data may be calculated as a whole. Therefore, it is desirable to measure the absolute reference coordinate value in advance.

The reference value measuring unit 110 includes a GPS device for measuring the three-dimensional behavior of the structure by using a GPS carrier radiated from a GPS (Global Positioning System) satellite, and measures an absolute vertical reference coordinate value using the GPS device. It is preferable.

GPS is a global positioning system using satellites. It is a system that finds unknown positions by observing the time required or the phase of radio waves emitted from satellites that know the exact position to the receiver installed on the magnetic field.

In the present invention, since a precise measurement method for measuring up to several mm of displacement is required, the GPS measurement method preferably uses a post-process relative positioning method. This method performs GPS observation simultaneously at the point where the precise position is known and the point where the position measurement is required, and increases the precision significantly by processing the data using the carriers received by the two receivers. There is also a need for a post-processing program that has the ability to eliminate many of the misidentifications that can occur with data processing in order to improve precision.

The point of knowing the precise position is the comparative coordinate receiver 111 is installed, the reference coordinate receiver is installed at a specific location on the top floor of the building under construction. FIG. 2 illustrates an example of the comparative coordinate receiver 111 and the reference coordinate receiver 112 in the GPS device of the reference value measuring unit 110.

The GPS device compares the coordinate values measured by the reference coordinate receiver 112 and the reference coordinate receiver 112 and the reference coordinate receiver 112 disposed at the reference point SA to measure the comparison position and the reference position. A reference coordinate calculator 113 for calculating a reference coordinate value.

The reference coordinate calculator 113 compares the coordinate value of the comparison position, which already knows the exact coordinate value, with the coordinate value measured at the reference point SA, which is to be measured, and removes the noise that becomes an dimensional person, if necessary, to precisely correct the reference coordinate. Calculate the value.

The reference coordinate receiver 112 for measuring the reference coordinate value is disposed on the top floor of the construction structure to be constructed, and it is preferable to measure the coordinate value for one reference point SA, but the reference coordinate value is measured at a plurality of points. It can also be used.

In the present invention, to obtain the absolute coordinates of the vertical position using GPS. In general, the vertical measurement of the GPS may be relatively inferior to the precision of the horizontal measurement of the GPS. Therefore, after measuring the GPS for a long time (for example, about 30 minutes to 1 hour), it is preferable to perform vertical measurement by post-processing the average value of the entire data.

In addition, it is preferable that the GPS device measures the coordinate value measured by the reference coordinate receiver 112 during the reference coordinate reference time, and measures the reference coordinate value using the average value of the measured coordinate values. The reference time is preferably determined in consideration of the construction time of the uppermost layer.

The variable displacement measurement unit 120 includes one or more laser scanners 125 disposed on the uppermost layer of the structure, and the laser scanner 125 measures the relative vertical displacement of the uppermost layer of the structure based on the disposed position.

The laser scanner 125 is a measurement device for obtaining relative coordinates with respect to a target object based on the laser scanner 125 measuring instrument itself. The laser scanner 125 scans the floor of the building under construction to evaluate the precision during construction.

Depending on the type of laser scanner 125, it may be classified into a TLS (Terrestrial Laser Scanner or 3D Scanner) system and a 2D laser scanner 125 system. The TLS can statically obtain three-dimensional information about an object, while the 2D laser scanner 125 measures two-dimensional coordinate information about a specific part of the object. The 2D laser scanner 125 may repeatedly obtain relative two-dimensional information of a target object. Therefore, it is preferable to use the 2D laser scanner 125 in the present invention.

The laser scanner 125 measures the position and shape of an object by scanning a desired angular range to use a laser beam as a point light source. It measures the one-dimensional distance by the correlation law according to the change of light time, and based on this, data is collected at angles of a certain interval through a mirror rotating the laser beam of the light emitting unit. For example, when setting the data for one scan at a specified angle of 100 degrees and setting the angle angle to 0.5, the number of output data can be processed by collecting 201 pieces of distance information.

The vertical displacement data measured by the laser scanner 125 also preferably performs mathematical correction and post-processing. Depending on the performance of the laser scanner 125, the closer to the measurement object, the higher the accuracy. Therefore, if the top floor of a building structure under construction is wide, it may be difficult to measure with one laser scanner 125. In this case, the uppermost layer may be divided into a plurality of measurement zones, and a plurality of laser scanners 125 may be used, or one laser scanner 125 may be measured while moving.

3 illustrates an example in which the laser scanner 125 is disposed at the reference point SA and the reference point SA at the top floor of the building structure. As described above, since the entire top layer to be constructed may be lower than the vertical position by the column shrinkage, and the laser scanner 125 performs measurement based on the position where it is placed, the vertical displacement of the position to be placed is prearranged. It is preferable to measure to. Accordingly, as shown in FIG. 3, at least one of the laser scanners 125 may be disposed at the reference point SA to measure the variable position of the uppermost layer of the structure.

The real displacement calculator 130 calculates a final vertical displacement (absolute vertical displacement) with respect to the vertical displacement value measured by the laser scanner 125 based on the reference coordinate value.

4 illustrates an example in which one or more laser scanners 125 are arranged on the top floor of a building structure, or an example of scanning a measurement area while moving one laser scanner 125. The topmost measuring area is shown in _six from A ₁ to A ₆ .

As schematically shown in FIG. 5 (a), when one or more laser scanners 125 are disposed on the top layer of the structure, or the position of one laser scanner 125 is changed to measure the variable position of the top layer of the structure, The displacement calculator 130 may calculate a real displacement for each measurement area measured by one laser scanner 125.

Referring to Figure 5 (a), A1 is the reference point and A ₆ has no vertical displacement, A ₂ is 15, A ₃ and A ₅ represents a vertical shift downward by 20 values, A ₄ is a vertical shift 5 upwards Has The laser scanner measures a relative value according to the measured position. FIG. 5 (a) shows a result of measuring a relative vertical displacement value with respect to the reference area with the reference area SA in A ₁ . In general, the displacement is lowered by column reduction, but the A ₄ region is measured to have a displacement upward rather than a construction error. The displayed numerical values are arbitrarily selected to indicate relative size, and actually have numerical units such as mm and cm.

As shown in FIG. 5 (b), when the laser scanner 125 is disposed at the top or the top of the structure, or the variable displacement of the top layer of the structure is measured by changing the position of one laser scanner 125, the real displacement calculator 130 may convert the measurement area measured by one laser scanner 125 into a variable position for the top layer of the structure, and then calculate a real displacement of the entire top layer based on the reference coordinate value. FIG. 5B is an example of calculating the vertical displacement of the entire top layer as an average value of the vertical displacement of the measurement region of FIG.

In addition to the display method, a vertical displacement may be expressed in the form of contour lines continuous in one layer.

The laser scanner 125 may repeatedly measure the variable displacement for the displacement reference time, and the real displacement calculator 130 may calculate the actual displacement using the average value of the values repeatedly measured by the laser scanner 125.

In another aspect of the present invention, in addition to measuring the vertical displacement amount of the top floor of the building structure under construction, it may further include a device for displaying the measured vertical displacement amount or to generate an alarm.

The uppermost floor of the structure under construction may be divided into a measurement area, and may further include a display unit 140 displaying a real displacement calculated by the real displacement calculation unit 130 for each measurement area. Of course, the real displacement may be displayed for the entire top layer without distinguishing the measurement area, or the real displacement may be displayed in the form of contour lines without dividing the measurement area.

The real displacement calculator 130 may further include an alarm generator 150 for generating an alarm when the real displacement calculated by the displacement exceeds the limit displacement. If an alarm occurs during construction, it is desirable to additionally perform construction to identify the specific point that caused the alarm in the field and correct vertical displacement.

6 is a block diagram showing the configuration of the apparatus 200 for calculating a correction value for the contraction amount of a pillar for a structure under construction according to another embodiment of the present invention. The same configuration as the vertical displacement measuring apparatus of the above-described structure will be briefly described.

The apparatus 200 for calculating a correction value for a pillar reduction amount for a structure under construction according to the present invention includes a reference value measuring unit 210 and a reference value for measuring a vertical reference coordinate value at a reference point SA of the uppermost floor of the structure under construction. On the top floor of the structure using the reduction amount measurement unit 220 and the reduction amount measurement unit 220 to reduce the column reduction amount of the top layer of the structure based on the reference coordinate value measured by the measuring unit 210 And a correction value calculator 230 for calculating a value to be corrected.

The reference value measuring unit 210 includes a GPS device for measuring a three-dimensional behavior of a structure by using a GPS carrier emitted from a GPS (Global Positioning System) satellite, and measures an absolute vertical reference coordinate value using the GPS device. .

The GPS device compares the coordinate values measured by the reference coordinate receiver 212 with the reference coordinate receiver 211, the reference coordinate receiver 212 disposed at the reference point SA, and the reference coordinate receiver 212 for measuring the comparison position. A reference coordinate calculator 213 for calculating a reference coordinate value.

The GPS device preferably measures the coordinate value measured by the reference coordinate receiver 212 during the reference coordinate reference time, and measures the reference coordinate value using the average value of the measured coordinate values.

The reduction amount measuring unit 220 includes one or more laser scanners 225 disposed on the uppermost layer of the structure, and the laser scanner 225 measures the relative column reduction amount of the uppermost layer of the structure based on the disposed position. Since the column shrinkage is to be measured by the absolute value of the structure under construction rather than the relative value of each floor, it is always desirable to measure the column shrinkage at the top floor based on the reference coordinate value.

Therefore, at least one of the laser scanners 225 may be disposed at the reference point SA to measure the column reduction amount of the uppermost layer of the structure based on the reference coordinate value measured by the reference value measuring unit 210.

The reduction amount measuring unit 220 is one laser scanner 225 when one or more laser scanners 225 are disposed on the uppermost layer of the structure, or the variable position of the uppermost layer of the structure is measured by changing the position of one laser scanner 225. The column reduction amount is calculated for each measurement area measured by), and the correction value calculator 230 may calculate a correction value for each measurement area.

As another embodiment, the reduction amount measuring unit 220 is one or more laser scanner 225 is disposed on the uppermost floor of the structure, or when changing the position of one laser scanner 225 to measure the column reduction amount of the uppermost floor of the structure, The measurement area measured by one laser scanner 225 may be converted into a reduction amount of the entire column on the top layer of one structure, and the correction value calculator 230 may calculate a correction value of the top layer of one structure.

 The laser scanner 225 repeatedly measures the pillar reduction amount for the reduction amount reference time, and preferably measures the pillar reduction amount using the average value of the repeatedly measured values.

The correction value calculating unit 230 calculates a correction value by comparing a difference between a vertical position (coordinate value) of a specific measurement area of the uppermost floor of the building structure or the entire floor and a vertical position of a corresponding floor designed in advance.

The correction for the column reduction is preferably performed for each floor, but for practical construction reasons, the correction can be performed by grouping several floors into one group. In each case, the correction value calculator 230 may accurately calculate how much correction is necessary in which area of the uppermost floor currently under construction.

The display device 240 may further include a display unit 240 displaying the correction value for the uppermost measurement area or the entire layer calculated by the correction value calculator 230.

Furthermore, the correction value calculating apparatus according to the present invention may further include an alarm generating unit 250 for giving an alarm to be immediately corrected during construction, if the vertical displacement of the top floor of the building structure exceeds the limit value.

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. Modifications that can be made and specific embodiments will be apparent that all fall within the scope of the present invention.

100: vertical displacement measuring device of the structure
110: reference value measuring unit 111: comparative coordinate receiver
112: reference coordinate receiver 113: reference coordinate calculator
120: variable position measuring unit 125: laser scanner
130: real displacement calculator 140: display unit
150: alarm generator
200: correction value calculating device
210: reference value measuring unit 211: comparative coordinate receiver
212: reference coordinate receiver 213: reference coordinate calculator
220: reduction amount measuring unit 225: laser scanner
230: correction value calculation unit

Claims (19)

A reference value measuring unit for measuring a vertical reference coordinate value at a reference point of the uppermost floor of the structure under construction;
A variable displacement measuring unit measuring vertical displacement of the uppermost layer of the structure; And
And a real displacement calculator configured to calculate a real vertical displacement of the uppermost layer of the structure by comparing the reference coordinate value measured by the reference value measurer and the vertical displacement value measured by the vertical displacement measurer. Device for measuring the amount of vertical displacement of the structure under construction. The method of claim 1,
And a display unit for classifying the uppermost floor of the structure under construction into a measurement area and displaying a real displacement calculated by the real displacement calculation unit for each measurement area. The method of claim 1,
And an alarm generator for generating an alarm when the real displacement calculated by the real displacement calculation unit exceeds a limit displacement. The method of claim 1,
The reference value measuring unit includes a GPS device for measuring the three-dimensional behavior of the structure by using a GPS carrier emitted by a GPS (Global Positioning System) satellite, and measuring the absolute vertical reference coordinate value using the GPS device. A device for measuring the amount of vertical displacement of a structure under construction. The method of claim 4, wherein
The GPS device calculates the reference coordinate value by comparing a reference coordinate receiver for measuring a comparison position, a reference coordinate receiver disposed at the reference point and coordinate values of the comparison position and coordinate values measured by the reference coordinate receiver. Apparatus for measuring the vertical displacement of the structure under construction, characterized in that it comprises a reference coordinate calculator. The method of claim 1,
The GPS device measures the vertical displacement amount of the structure under construction, characterized in that for measuring the coordinate value measured by the reference coordinate receiver for the reference coordinate reference time, using the average value of the measured coordinate value. The method of claim 1,
The variable displacement measuring unit includes one or more laser scanners disposed on the uppermost layer of the structure, and the laser scanner measures the relative vertical displacement of the uppermost layer of the structure based on the disposed position. Device. The method of claim 7, wherein
At least one of the laser scanners is disposed at the reference point to measure a variable position of the uppermost layer of the structure. 9. The method according to claim 7 or 8,
When one or more laser scanners are disposed on the uppermost floor of the structure, or the variable position of the uppermost floor of the structure is measured by changing the position of one laser scanner, the real displacement calculator may measure one measurement area measured by one laser scanner. The apparatus for measuring the vertical displacement amount of a structure under construction, wherein the real displacement is calculated based on the reference coordinate value after converting to a variable position for the uppermost layer of the structure. 9. The method according to claim 7 or 8,
The laser scanner repeatedly measures the variable displacement during the displacement reference time, and the real displacement calculator calculates the actual displacement using the average value of the values repeatedly measured by the laser scanner. Device. A reference value measuring unit for measuring a vertical reference coordinate value at a reference point of the uppermost floor of the structure under construction;
A reduction amount measuring unit measuring a reduction amount of the pillar of the uppermost layer of the structure based on the reference coordinate value measured by the reference value measuring unit; And
And a correction value calculator configured to calculate a value to be corrected in the uppermost layer of the structure by using the pillar reduction amount measured by the reduction amount measurement unit. The method of claim 11,
The reference value measuring unit includes a GPS device for measuring the three-dimensional behavior of the structure by using a GPS carrier emitted by a GPS (Global Positioning System) satellite, and measuring the absolute vertical reference coordinate value using the GPS device. Compensation value calculation device for the column shrinkage of the structure under construction. The method of claim 12,
The GPS device calculates the reference coordinate value by comparing a reference coordinate receiver for measuring a comparison position, a reference coordinate receiver disposed at the reference point and coordinate values of the comparison position and coordinate values measured by the reference coordinate receiver. Compensation value calculation device for the column shrinkage of the structure under construction, characterized in that it comprises a reference coordinate calculator. The method of claim 11,
The GPS device corrects the pillar reduction amount of the structure under construction by measuring a coordinate value measured by the reference coordinate receiver during the reference coordinate reference time, and using the average value of the measured coordinate values. Value calculation device. The method of claim 11, wherein
The reduction amount measuring unit includes one or more laser scanners disposed on the uppermost layer of the structure, and the laser scanner measures relative pillar reduction of the uppermost layer of the structure on the basis of the disposed position. Device for calculating the correction value for the quantity. 16. The method of claim 15,
At least one of the laser scanner is disposed at the reference point correction for the reduction of the pillars of the structure under construction, characterized in that for measuring the reduction of the pillars of the uppermost floor of the structure based on the reference coordinate value measured by the reference value measuring unit Value calculation device. 17. The method according to claim 15 or 16,
The reduction amount measuring unit reduces the column for each measurement area measured by one laser scanner when one or more laser scanners are disposed on the uppermost floor of the structure or when the position of one laser scanner is changed to measure the variable position of the uppermost floor of the structure. Calculate the quantity,
And a correction value calculating unit calculating a correction value for each measurement area. 17. The method according to claim 15 or 16,
When one or more laser scanners are disposed on the top layer of the structure or the position of one laser scanner is changed to measure the reduction of the pillars on the top layer of the structure, the reduction amount measuring unit measures one measurement area measured by one laser scanner. Convert the column reduction to the entire top of the structure,
And a correction value calculating unit calculating a correction value for the one uppermost layer of the structure. 17. The method according to claim 15 or 16,
The laser scanner calculates a correction value for the column reduction amount of the structure under construction, by measuring the pillar reduction amount repeatedly for a reduction amount reference time and measuring the pillar reduction amount using the average value of the repeated measured values. Device.

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