JP6805068B2 - Floor subsidence displacement monitoring system and floor subsidence displacement monitoring method - Google Patents

Description

The present invention relates to a floor subsidence displacement monitoring system and a floor subsidence displacement monitoring method.

Conventionally, as a building support structure, a ground improvement structure has been used to directly support the building from below or to prevent uneven subsidence of soil concrete having a large area such as a factory or a warehouse.
In such a ground improvement structure, for example, as shown in Patent Document 1, a ground improvement device having an excavation blade at the tip of a rod is used, and the ground is excavated in a block shape or a wall shape and loosened. A method of constructing a ground improvement wall by mixing and stirring a ground improvement material in the ground to support the building from below is known, and the shape along the outer periphery of the building in a plan view or the outer periphery of the building It is common that it is provided in a shape that surrounds.

Japanese Unexamined Patent Publication No. 11-217820

However, the building having the conventional ground improvement structure has the following problems.
That is, for example, when the site area of a factory or warehouse is large, a plate-like solidified body is formed by providing soil concrete in which concrete is placed over the entire site or by improving the surface layer ground. When the plate-shaped solidified body is soil concrete, the load of the concrete to be cast increases and the total weight increases, so that uneven settlement is likely to occur. Further, even when the plate-like solidified body is a surface layer ground improvement body, it is improved by mixing cement or the like with the excavated ground and replacing it, so that the total weight of the surface layer ground improvement body itself is the same as in the case of the above-mentioned soil concrete. There was a risk that it would increase and promote unequal subsidence.

Therefore, in the post-construction building, when monitoring the subsidence displacement of the floor surface on which ground-improved soil concrete is placed, set multiple measurement points on the floor and use the level at those measurement points. The amount of subsidence displacement is measured. Then, since the condition of the floor surface of the building is grasped and the entire floor surface is repaired, there is a problem that a great deal of labor, time, and cost are required.

The present invention has been made in view of the above-mentioned problems, and it is possible to reduce the time and cost required for monitoring and repairing subsidence displacement in a floor using a plurality of independently provided frame-shaped improved walls. It is an object of the present invention to provide a floor subsidence displacement monitoring system and a floor subsidence displacement monitoring method.

In order to achieve the above object, the floor subsidence displacement monitoring system according to the present invention is formed into a rectangular shape in a plan view by mixing a ground improvement material with the excavated ground and stirring it, and is arranged vertically and horizontally at equal intervals. A floor subsidence displacement monitoring system supported by a plurality of independent frame-shaped improved walls, wherein the floor partitioning means for partitioning the floor area corresponding to each frame-shaped improved wall as a block, and the floor partitioning means. It is characterized by including a settlement measuring means for measuring the settlement of the block partitioned by the above, and a settlement analysis means for analyzing the settlement measurement data measured by the settlement measuring means for each block.

Further, the floor subsidence displacement monitoring method according to the present invention is formed into a rectangular shape in a plan view by mixing a ground improvement material with the excavated ground and stirring the ground, and a plurality of independent floors arranged at equal intervals in the vertical and horizontal directions. A method for monitoring subsidence displacement of a floor supported by a frame-shaped improved wall, wherein the floor partitioning step of partitioning the floor area corresponding to each frame-shaped improved wall as a block, and the floor partitioning step partitioned by the floor partitioning process. A settlement measurement step for measuring the settlement of blocks, a settlement analysis step for analyzing the settlement measurement data measured by the settlement measurement step for each block, and each block based on the analysis results obtained in the settlement analysis step. It is characterized by having a determination step of determining the soundness of the floor or the frame-shaped improved wall.

In the present invention, the floor area of a building or the like is divided into blocks for each area where a plurality of frame-shaped improved walls are arranged, and the floor settlement measurement data measured by the settlement measurement is associated with each block to block. The state of floor subsidence / displacement can be analyzed for each area. That is, since the plurality of formwork improved walls have independent structures, it is possible to analyze the subsidence / displacement of the blocks set for each of the formwork improved walls and manage the stress state of the floor surface. It becomes. Furthermore, based on the analysis results, the soundness of the floor or formwork improvement wall for each block can be evaluated and judged, and the formwork improvement wall to be repaired can be narrowed down, and an excellent repair plan can be formulated. In addition to being able to do this, the work efficiency of repairs can be improved.

As described above, in the present invention, only the formwork improved wall to be repaired can be partially repaired, and it is not necessary to construct the entire floor surface of the building. For example, it can be limited to a part of the construction area or a block. It is possible to construct each one in order, it is possible to avoid constructing the entire floor surface at the same time, and it is possible to efficiently repair the building in use. That is, since it is not necessary to perform the repair work on the block that does not need to be repaired, the cost can be reduced.

Further, in the present invention, since the frame type improvement wall in which each block forming the area for partitioning the floor surface is independently integrated is targeted for the section, the frame type improvement is performed by analyzing the subsidence / displacement in each block. The inclination and posture of the wall itself can be estimated. Therefore, the best repair including the formwork improvement wall can be performed.
Furthermore, by comparing a plurality of blocks with each other, it is possible to evaluate the subsidence / displacement of the entire floor surface. For example, it is possible to make a repair plan that identifies a block with a fast sinking speed. It is also possible to estimate the cause of subsidence by evaluating the entire floor surface.

Further, in the floor subsidence displacement monitoring system according to the present invention, it is preferable that the subsidence measuring means is a three-dimensional laser measuring device capable of measuring three-dimensional displacement of a plurality of the blocks.

In the present invention, the height difference of the entire floor surface in a predetermined region can be easily measured by performing laser scanning using a three-dimensional laser measuring device, and the measured floor surface shape can be grasped. In this case, it is not necessary to use the target for the measurement point as in the measurement using the level, and the work efficiency required for the measurement can be improved.

Further, in the floor subsidence displacement monitoring method according to the present invention, in the subsidence analysis step, it is preferable to compare the subsidence states of the adjacent formwork improved walls and detect the inclination of each of the formwork improved walls. ..

In this case, the state of the ground of these formwork improvement walls can be estimated by grasping the inclination of the adjacent formwork improvement walls. For example, when adjacent formwork improvement walls are tilted in the direction close to each other, it can be estimated that the ground between the two formwork improvement walls is the cause of subsidence, and for example, additional improvement is made to the ground. It is possible to take measures such as.

Further, in the method for monitoring the subsidence displacement of the floor according to the present invention, in the determination step, the determination standard set in advance is compared with the analysis result, and the floor or the frame type of the block that deviates from the determination standard. It may be characterized in that it is determined to repair the improved wall.

In the present invention, it is possible to determine whether or not the frame-shaped improved wall is repaired in a specific block by comparing the determination standard with the analysis result based on the settlement measurement data.

According to the floor subsidence displacement monitoring system and the floor subsidence displacement monitoring method of the present invention, the time and cost required for monitoring and repair work of subsidence displacement in a floor using a plurality of independently provided frame-shaped improved walls. Can be reduced.

It is a vertical cross-sectional view which shows the structure of the formwork improved wall constructed on the ground of a building by embodiment of this invention. It is a top view which shows the plurality of formwork improved walls constructed on the ground shown in FIG. It is a top view which shows the 1st section drawing divided into a plurality of blocks. It is a block diagram which shows the schematic structure of the settlement displacement monitoring system. It is a figure which shows the flow of the settlement displacement monitoring method using the settlement displacement monitoring system shown in FIG. It is an example of the 1st section drawing, and is the figure which shows the 3D model which made each block 1/4 in a plan view. (A) to (c) are diagrams showing an example of a second section drawing created by analysis.

Hereinafter, the floor subsidence displacement monitoring system and the floor subsidence displacement monitoring method according to the embodiment of the present invention will be described with reference to the drawings.

The floor subsidence displacement monitoring system according to the present embodiment is a system for monitoring the subsidence / displacement of the floor 3 of the building 1 supported by the formwork improvement wall 2 shown in FIG.

As shown in FIGS. 1 and 2, in the ground improvement structure according to the present embodiment, the ground improvement material is mixed with the excavated ground in a predetermined target ground (the area surrounded by the alternate long and short dash line shown in FIG. 2). It is formed by stirring with water, and is provided with a plurality of (six in this case) independent frame-shaped improved walls 2, 2, ... Arranged at equal intervals in the vertical and horizontal directions.
As shown in FIG. 2, the frame-shaped improvement wall 2 is formed by using a ground improvement device (not shown), and by mixing the excavated ground G with the ground improvement material and stirring the ground G, the ground G is viewed in a plan view. It is integrally formed in a square shape. In each frame-type improved wall 2, the distance between the opposing walls (span D between walls) is not more than twice the length dimension in the depth direction (improved wall length L shown in FIG. 1) (D ≦ 2 × L). It is provided so as to be.

The ground improvement device for constructing the frame type improvement wall 2 is used as an attachment attached to the tip of the arm of a work machine such as a backhoe, and the excavation blades provided at the lower ends of a plurality of arranged rods are rotated. While excavating by moving the ground G downward in the vertical direction, the ground improving material is added to the excavated soil, mixed, and agitated to construct the above-mentioned frame type improving wall 2. As the ground improvement device, for example, a device provided with a three-axis excavation blade described in Japanese Patent Application Laid-Open No. 2011-226254 can be used. Further, as the ground improvement material added to the excavated soil, an appropriate chemical such as a liquid material such as cement milk or a powder material can be adopted depending on the purpose of the ground improvement.

The vertical and horizontal arrangement spans d of the plurality of frame type improvement walls 2 are provided with the same length dimension as the inter-wall span D of the above-mentioned frame type improvement walls 2 along the vertical and horizontal arrangement directions. Then, in the present embodiment, each frame type improved wall 2 is provided in the ground G directly under the floor 3 so as to surround a part of the ground G (this is referred to as the in-wall ground G1), and a plurality of frames. Even in the ground within the range located between the form improvement walls 2, the frame type improvement wall 2 is arranged around the ground, so that the movement of the entire ground G in the horizontal direction is restricted and the rigidity is increased. It is possible to prevent unequal subsidence of the building 1 provided on the ground G and reduce the shaking of the building 1 on the floor 3 at the time of an earthquake.

The floor 3 made of soil concrete is provided on the ground portion in a state of being placed on the upper ends 2a (see FIG. 1) of a plurality of frame-shaped improved walls 2 having a predetermined thickness dimension.
The reference numerals P shown in FIGS. 1 and 2 indicate the soil load at the position between the formwork improvement walls 2.

Next, the floor subsidence displacement monitoring system 10 will be described with reference to FIG. 3 and the like.
The subsidence displacement monitoring system 10 is composed of a floor partition processing unit 11 (floor partition means) for partitioning the area of the floor 3 corresponding to each frame-shaped improved wall 2 shown in FIG. 4 as blocks K1 to K6, and a floor partition processing unit 11. A three-dimensional laser measuring device 12 (settling measuring means) for measuring the sinking of the partitioned blocks K1 to K6 and a sinking analysis for analyzing the sinking measurement data D measured by the three-dimensional laser measuring device 12 for each block K1 to K6. A unit 13 (sink analysis means) and a determination unit 14 for determining the soundness of the floor 3 based on the result of the subsidence analysis unit 13 are provided. The floor partition processing unit 11, the settlement analysis unit 13, and the determination unit 14 are incorporated in a processing device 15 including a computer or the like.

The processing device 15 is provided with a settlement measurement data storage unit 16 for inputting and accumulating the settlement measurement data D measured by the three-dimensional laser measuring device 12.
The processing device 15 is connected to a display unit 17 such as a monitor for displaying a determination result or the like of the determination unit 14.

As shown in FIG. 4, a plurality (six) of floor partition processing units 11 are provided for each frame type improvement wall 2 in the basic drawing R0 of the floor 3 of a predetermined building which has been previously imported into the processing device 15 as a database. Blocks K1 to K6 are divided into blocks K1 to K6, and a process of creating a first section drawing R1 is performed.

The settlement measurement data D measured by the three-dimensional laser measuring device 12 may be before or after being incorporated on the basic drawing R0. That is, the settling measurement data D composed of three-dimensional data may be incorporated into the first section drawing R1 that has been partitioned, or the settling measurement data D composed of three-dimensional data may be incorporated into the basic drawing R0. Later, it may be a process of forming a second section drawing R2 divided into six blocks K1 to K6 by a section process.

As the three-dimensional laser measuring instrument 12, for example, a known scanning type such as Focus ^3D X130 (manufactured by FARO), which is easy to carry, can be adopted. In the three-dimensional laser measuring instrument 12 of the present embodiment as described above, the swing angle is 360 ° and the measurement range is 360 ° when the vertical direction is the rotation axis in the horizontally installed state. That is, it is measured by scanning the entire floor surface 3a of the building 1 by changing the swing angle of the laser irradiation unit while irradiating the laser with the three-dimensional laser measuring device 12, and the shape of the entire floor surface 3a due to the three-dimensional displacement. (Height) data can be obtained. Since the data of the height difference can be the data with respect to the reference value, it becomes the settlement measurement data D. The measured data is wirelessly or wiredly output from the three-dimensional laser measuring device 12 to the sinking measurement data storage unit 16.
The subsidence measurement data D of the entire floor surface 3a by the three-dimensional laser measuring device 12 is, for example, if the entire floor surface 3a in the building 1 can be measured from one measurement point, the three-dimensional laser measurement is performed at that measurement point. The device 12 may be installed for measurement. Further, when it is difficult to measure the entire floor surface 3a at a time due to a partition wall or the like in the space inside the building 1, a plurality of measurement points may be set and the entire floor surface 3a may be measured.

The settlement measurement data storage unit 16 receives and accumulates the settlement measurement data D measured by the three-dimensional laser measuring device 12 as described above. Then, the settlement measurement data storage unit 16 is connected to the floor partition processing unit 11 and the settlement analysis unit 13, and each processing unit appropriately processes the data.

The subsidence analysis unit 13 performs image processing in association with the subsidence measurement data D measured by the three-dimensional laser measuring device 12 with respect to the first section drawing R1 in which the basic drawing R0 is divided into a plurality of blocks K1 to K6. This is a processing unit that creates a section drawing R2. Further, the subsidence analysis unit 13 is a processing unit that analyzes the stress state of the floor surface 3a or the frame-shaped improved wall 2 in each block K1 to K6 by, for example, FEM analysis, using the second section drawing R2.

The determination unit 14 compares the preset determination criteria with the analysis results, and performs a process of determining whether or not the frame type improvement wall 2 of the blocks K1 to K6 that deviates from the determination criteria is repaired.

Next, the method of monitoring the subsidence displacement of the floor 3 using the above-mentioned subsidence displacement monitoring system 10 will be described in detail with reference to the flow chart shown in FIG.
The method of monitoring the subsidence displacement of the floor 3 is a method of monitoring the subsidence displacement of the floor supported by a plurality of independent formwork improved walls 2, 2, ... Arranged at equal intervals in the vertical and horizontal directions.

Specifically, in the floor partition processing unit 11 shown in FIG. 3, a floor partition step for partitioning the area of the floor 3 corresponding to each frame type improvement wall 2 as blocks K1 to K6, and a block K1 partitioned by the floor partition process. ~ K6 settling measurement step, settling measurement data D measured by the settling measurement step is analyzed for each block K1 to K6, and the analysis result obtained in the settling analysis step in the determination unit 14. It has a determination step of determining the soundness of the floor 3 or the frame-shaped improved wall 2 for each of the blocks K1 to K6 based on the above.

First, as shown in FIGS. 3 and 5, the floor partition processing unit 11 in the processing device 15 corresponds to each of the six frame-shaped improved walls 2 with respect to the basic drawing R0 previously stored in the processing device 15. The floor surface 3a of the building 1 is partitioned as a plurality of (six) blocks K1 to K6 (see FIG. 4), and the first section drawing R1 is created (step S1). FIG. 6 is an example of the first section drawing R1, and shows a three-dimensional model in which each rectangular block K1 to K6 is divided into 1/4 in the vertical and horizontal directions passing through the center in a plan view.

Next, in step S2, the subsidence / displacement of the blocks K1 to K6 partitioned in step S1 is measured with respect to the floor surface 3a using the three-dimensional laser measuring device 12. If the entire floor surface 3a of the building 1 can be measured from one measurement point, a three-dimensional laser measuring device 12 is installed at the one measurement point for measurement, and a plurality of measurement points are required. In the case (when the entire floor surface 3a cannot be measured at one measurement point), a three-dimensional laser measuring device 12 is installed at each of the plurality of measurement points for measurement.

Subsequently, in step S3, the settlement measurement data D measured in step S2 is input to the settlement measurement data storage unit 16 of the processing device 15, and the settlement analysis unit 13 associates the blocks K1 to K6 with each other. Image processing for creating R2 is performed. As a method of inputting the sinking measurement data D to the sinking measurement data storage unit 16, the sinking measurement data D can be input wirelessly or by wire from the three-dimensional laser measuring device 12.

Next, in step S4, the second section drawing R2 for each block K1 to K6 created in step S3 is analyzed by the settlement analysis unit 13 using, for example, three-dimensional FEM analysis. Then, this analysis result is displayed on the monitor or the like of the display unit 17.
Here, FIGS. 7 (a) to 7 (c) are examples of the second section drawing R2, and is an analysis example analyzed as a stress diagram by incorporating the settlement measurement data D in the three-dimensional model shown in FIG. 6 described above. Is shown. FIG. 7A shows a stress diagram of the floor surface 3a in one direction in the X direction. In this case, it is an analysis example in which the stress of the portion 2A along the Z direction of the frame type improved wall 2 becomes large. FIG. 7B shows a stress diagram of the floor surface 3a in two directions in the XY directions. In this case, it is an analysis example in which the stress of the portion 2B along the X direction of the frame type improved wall 2 becomes large. FIG. 7 (c) shows a stress diagram in one direction of the Y direction of the formwork improved wall 2 in which the floor 3 (soil concrete) is omitted. In this case, it is an analysis example in which the stress of the upper corner portion 2C of the frame type improved wall 2 becomes large.
By analyzing in this way, the stress state of the floor surface 3a and the formwork improvement wall 2 can be visually grasped, and further, the deformation and stress state of the ground under the floor and the ground around the formwork improvement wall 2 can be grasped. can do.

Next, the determination unit 14 of the processing device 15 determines the soundness of the frame type improvement wall 2 for each block K1 to K6 based on the analysis result obtained in step S4 (step S5). Specifically, the determination criteria set in advance and the analysis result are compared, and the determination is made so as to repair the floor 3 or the frame-shaped improved wall 2 of the blocks K1 to K6 that deviate from the determination criteria. Here, the determination criterion is, for example, a value at which the permissible amount of subsidence / displacement in a predetermined period is set.
Then, if the determination in step S5 results in the determination that the blocks K1 to K6 deviate from the determination criteria, the frame type improvement wall 2 is repaired by an appropriate repair method in step S6, or a repair plan is made. Will be done. If it is determined in step S5 that repair is unnecessary, repair is not necessary.

Next, the operation of the floor subsidence displacement monitoring system and the floor subsidence displacement monitoring method described above will be specifically described with reference to the drawings.
As shown in FIG. 2, in the present embodiment, the area of the floor surface 3a of the building 1 is divided into blocks K1 to K6 for each area where a plurality of frame-shaped improvement walls 2 are arranged, and as shown in FIG. The subsidence measurement data D of the floor surface 3a measured by the subsidence measurement can be associated with each block K1 to K6, and the state of the subsidence / displacement of the floor 3 can be analyzed for each region of the blocks K1 to K6. That is, since the plurality of frame-shaped improved walls 2 have independent structures, the subsidence / displacement of the blocks K1 to K6 set for each of the frame-shaped improved walls 2 can be analyzed, and the stress state of the floor surface 3a can be analyzed. Can be managed. Further, based on the analysis result, the soundness of the frame-shaped improved wall 2 for each block K1 to K6 can be evaluated and judged, and the frame-shaped improved wall 2 to be repaired can be narrowed down. In addition to being able to make a plan, it is possible to improve the work efficiency of repairs.

As described above, in the present embodiment, only the frame-shaped improved wall 2 to be repaired can be partially repaired, and it is not necessary to construct the entire floor surface 3a of the building 1, for example, in a part of the construction area. It can be limited, or it can be constructed in order for each block K1 to K6, it is possible to avoid constructing the entire floor surface 3a at the same time, and efficient repair can be performed in the building 1 being used. .. That is, since it is not necessary to perform repair work on the blocks K1 to K6 that do not need to be repaired, the cost can be reduced.

Further, in the present embodiment, since the frame-shaped improved wall 2 in which the blocks K1 to K6 forming the area for partitioning the floor surface 3a are independently integrated is targeted for the partition, the subsidence / displacement in each block K1 to K6 By analyzing the above, the inclination and posture of the frame-shaped improved wall 2 itself can be estimated. Therefore, the best repair including the frame type improved wall 2 can be performed.
Further, by comparing the plurality of blocks K1 to K6 with each other, the subsidence / displacement of the entire floor surface 3a can be evaluated. For example, it is possible to make a repair plan that specifies blocks K1 to K6 having a high sinking speed. It is also possible to estimate the cause of subsidence by evaluating the entire floor surface 3a.

Further, in the present embodiment, by adopting the three-dimensional laser measuring instrument 12 as the sinking measuring means, the height difference of the entire floor surface 3a in the predetermined region can be easily obtained by performing the laser scanning using the three-dimensional laser measuring instrument 12. It is possible to grasp the measured shape of the floor surface 3a. Then, unlike the measurement using the level, it is not necessary to use the target for the measurement point, and the work efficiency required for the measurement can be improved.

Further, in the present embodiment, in the determination step of step S5 described above, the presence or absence of repair of the frame type improvement wall 2 in the specific blocks K1 to K6 is performed by comparing the determination criteria set in advance with the analysis result. Can be determined.

As described above, in the floor subsidence displacement monitoring system and the floor subsidence displacement monitoring method according to the present embodiment, the subsidence displacement monitoring and repair work is performed on the floor using a plurality of independently provided frame-shaped improved walls 2. The time and cost required for this can be reduced.

Although the embodiment of the floor subsidence displacement monitoring system and the floor subsidence displacement monitoring method according to the present invention has been described above, the present invention is not limited to the above-described embodiment and does not deviate from the gist thereof. Can be changed as appropriate.

For example, in the above embodiment, the three-dimensional laser measuring device 12 is adopted as the settlement measuring means, but the present invention is not limited to this. For example, it may be a settlement measuring means using a level surveying instrument conventionally used for settlement measurement.

Further, in the subsidence analysis step of the subsidence displacement monitoring method according to the above-described embodiment, the analysis is performed so as to compare the subsidence states of the adjacent formwork improvement walls 2 and 2 and detect the inclination of each formwork improvement wall. It is also possible to do it.
In this case, the state of the ground of these formwork improvement walls 2 and 2 can be estimated by grasping the inclination of the adjacent formwork improvement walls 2 and 2. For example, when the adjacent formwork improvement walls 2 and 2 are tilted in the direction in which they are close to each other, it can be estimated that the ground between the two formwork improvement walls 2 and 2 is the cause of subsidence. For example, it is possible to take measures such as making additional improvements.

Further, in the present embodiment, a determination unit 14 is provided in the processing device 15, and the result of analysis by the settlement analysis unit 13 can be determined by the determination unit 14 for each block to determine whether or not repair is necessary. However, it is also possible to have a system configuration in which the determination unit 14 is omitted. That is, it is also possible to display only the analysis result of the subsidence analysis unit 13 on the display unit 17 without going through the determination unit 14, and to confirm this to formulate a repair plan.

In addition, regarding the configuration of the size and size of the building 1 to which the subsidence displacement monitoring system 10 and the subsidence displacement monitoring method are applied, the size and quantity of the formwork improved wall 2, the thickness of the floor 3, etc. The form is not limited to, and can be set as appropriate.

Further, the present embodiment is not limited to the structure in which the shed of the building is provided, which targets the floor 3 of the building 1. In short, the structure may be such that only the floor 3 is provided on the plurality of frame-shaped improved walls 2 and only the floor 3 is provided, and the structure may not have a shed of the building.
Further, the number of blocks for partitioning the floor surface is not limited to six as in the present embodiment, and may be provided corresponding to each frame type improved wall 2.

In addition, it is possible to replace the components in the above-described embodiment with well-known components as appropriate without departing from the spirit of the present invention.

1 Building 2 Formwork improved wall 10 Subsidence displacement monitoring system 11 Floor partition processing unit (floor partition means)
12 Three-dimensional laser measuring instrument (sinking measuring means)
13 Subsidence analysis unit (subsidence analysis means)
14 Judgment unit 15 Processing device 16 Subsidence measurement data storage unit 17 Display unit D Subsidence measurement data R0 Basic drawing R1 First section drawing R2 Second section drawing K1 to K6 Block G Ground

Claims (5)

A floor subsidence displacement monitoring system that is formed into a rectangular shape in a plan view by mixing a ground improvement material with the excavated ground and agitating it, and is supported by a plurality of independent frame-type improvement walls arranged at equal intervals in the vertical and horizontal directions. And
A floor partitioning means for partitioning the floor area corresponding to each frame-type improved wall as a block,
A settlement measuring means for measuring the settlement of the block partitioned by the floor partitioning means,
A settlement analysis means for analyzing the settlement measurement data measured by the settlement measurement means for each block, and a settlement analysis means.
A floor subsidence displacement monitoring system characterized by being equipped with. The floor subsidence displacement monitoring system according to claim 1, wherein the subsidence measuring means is a three-dimensional laser measuring device capable of measuring three-dimensional displacements of a plurality of the blocks. A method for monitoring subsidence displacement of a floor that is formed into a rectangular shape in a plan view by mixing a ground improvement material with the excavated ground and agitating it, and is supported by a plurality of independent frame-type improvement walls arranged at equal intervals in the vertical and horizontal directions. And
A floor partitioning process for partitioning the floor area corresponding to each formwork improved wall as a block,
A settlement measurement step of measuring the settlement of the block partitioned by the floor partitioning step, and a settlement measurement step.
A settlement analysis step of analyzing the settlement measurement data measured by the settlement measurement step for each block, and a settlement analysis step.
A determination step of determining the soundness of the floor or the frame-shaped improved wall for each block based on the analysis result obtained in the settlement analysis step, and
A method for monitoring floor subsidence displacement, which comprises having. The floor subsidence displacement monitoring method according to claim 3, wherein in the subsidence analysis step, the subsidence states of adjacent frame-shaped improved walls are compared and the inclination of each of the frame-shaped improved walls is detected. .. The determination step is characterized in that a preset determination criterion is compared with the analysis result, and determination is made so as to repair the floor or the frame-shaped improved wall of the block that deviates from the determination criterion. The method for monitoring floor subsidence displacement according to claim 3 or 4.