KR101009195B1 - Verticality measuring method - Google Patents

Abstract

Method for measuring the verticality of the present invention comprises the steps of placing a hollow pillar member on the ground; Installing a laser level meter at the center of the jig, which emits the laser beam in the axis direction; Inserting the jig inclined so as to have three contact points with the inner wall of the pillar member; Measuring a vertical degree of the pillar member by measuring a center line of the pillar member and a separation distance of the laser beam or a direction angle of the center line and the laser beam; It includes.

Description

How to measure verticality {VERTICALITY MEASURING METHOD}

The present invention relates to a method for measuring the verticality of a pillar member that is supported by drilling on the ground to support the load of the building structure.

In general pile pillar construction, since the perforated ground is formed to form a drill hole, and then the pillar is inserted from above, it is difficult to directly measure the verticality of the pillar member located in the drill hole. It soon led to a decrease in the structural strength of the structure.

In particular, in the top-down method, the pillars are struck with hammers and the ground is constructed after excavation and removal of the surrounding ground. Therefore, the verticality of the columns is not only in terms of structural strength but also in terms of construction. Has become a more important issue.

This is because, after completing the construction materials and bringing them to the site according to the design specifications, the construction of the basement is carried out through on-site assembly. When the verticality of the columns is shifted, it is necessary to adjust the dimensions of the building materials again according to the measured results. And, in the case of severe errors, it may be more economical to rebuild the columns than to adjust the dimensions of an absolute number of building materials.

Conventionally, a surveying device such as a transit weight or a transit installed on the ground is used as a method for securing the verticality of a column. However, the conventional method using the measurement weight takes a considerable amount of time to stop the pendulum movement, and once the stopped surveying weight moves again according to changes in the external environment such as wind or vibration, the measurement of verticality is very cumbersome. have. In addition, when using a surveying instrument such as a transit, measurement from two directions is required, and the installation of the instrument is not easy.

In addition, in the conventional construction site, since the vertical measurement of the column member is performed based on the experience and intuition of a skilled worker, there is a limitation that a consistent measurement result cannot be obtained.

The present invention is to improve the above-mentioned problems, in the construction of a pile pillar for inserting the pillar member after drilling the ground, or in the top-down construction for excavating and cutting the ground around the ground after inserting the pillar member It is possible to manage the verticality of the pillar member within an error range by providing a method of accurately measuring the verticality of the pillar member that is difficult to visually check.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. will be.

Method for measuring the verticality of the present invention comprises the steps of placing a hollow pillar member on the ground; Installing a laser level meter at the center of the jig, which emits the laser beam in the axis direction; Inserting the jig inclined so as to have three contact points with the inner wall of the pillar member; Measuring a vertical degree of the pillar member by measuring a center line of the pillar member and a separation distance of the laser beam or a direction angle of the center line and the laser beam; It includes.

According to the present invention, the jig is placed on the inner wall of the pillar member by placing the jig three points in contact with the inner wall of the pillar member and placing the laser level meter on the center line so that the triangular center of gravity of the jig shape passes through the center line of the pillar member. And vertical contact and tilted direction of the pillar member can be visualized and quantified through the separation angle formed by the imaging point of the laser level meter and the center line of the pillar member even in contact with the posture. Can greatly improve the construction efficiency.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the contents throughout the specification.

1 is a side cross-sectional view of a pillar member placed on the ground. Referring to this, it can be recognized that the verticality should be measured by the verticality measuring method of the present invention.

For example, the ground on which the new construction is scheduled is divided into the building ground 10 on which the building is to be constructed and the surrounding ground 10 'on which an existing building or road is already constructed. The building ground 10 and the surrounding ground 10 'are partitioned based on the site boundary. In general, the site boundary wall (1) is provided adjacent to the site boundary in order to block dust or noise due to the construction of the building.

After arranging the ground so that the excavation / insertion equipment 31 can be seated at the site boundary between the building ground 10 and the surrounding ground 10 ', and then drill the holes 30 using the excavation / insertion equipment 31. The pillar member 100 is inserted into and fixed to this hole 30. The perforation depth of the hole 30 is determined in proportion to the building height of the building and the building height of the building wall.

The pillar member 100 is manufactured in advance as a finished product using a concrete or steel tube as a hollow cylindrical shape. The pillar member 100 is used to be supplied to the desired number of work sites. The pillar member 100 is spaced apart at predetermined intervals in the hole 30 of the site boundary, and the rear surface of the outer circumference of the cylinder supports the rear soil to serve as an earth retainer.

However, the verticality of the hole 30 may be distorted due to an error when drilling the hole 30, and the verticality of the pillar member 100 may be distorted due to an error when placing the pillar member 100.

At this time, by continuously monitoring the pouring process itself of the pillar member 100 by using the method of measuring the verticality of the present invention, the pillar member 100 is placed within the verticality standard range, or the vertical degree of the pillar member 100 that has already been poured. If the measurement is out of the vertical standard range, it is possible to manage the verticality of the pillar member 100 by adding a new pillar member 100 next to it.

It is explanatory drawing explaining the principle of the perpendicularity measuring method of this invention. Referring to this, three triangles T1, T2, and T3 are shown to be in three-point contact with the inner wall 110 of the pillar member 100. These vertices T1, T2, and T3 have their vertices in contact with the inner wall of the pillar member, and the center of gravity, which is the intersection point of the center line of each side, passes through the center line 101 of the pillar member even when the triangle T3 is inclined.

That is, each vertex of the three triangles T1, T2, and T3 is in contact with the inner wall 110 of the pillar member 100, respectively, and the centers of gravity of the three triangles T1, T2, and T3 are C1, C2, and T3. C3) passes through the centerline 101 of the pillar member.

In this way, using the property of the present invention that the center of gravity of the triangle passes through the centerline of the pillar member, the laser beam of the laser level meter is emitted just by placing the laser level meter at the center of gravity of the triangle at any position and posture. The starting point is placed on the center line of the pillar member, the inclination angle (or separation angle θ, see FIG. 4) or the separation distance (d, FIG. 4) formed by the laser beam emitted in the vertical direction and the center line of the pillar member at all times. The verticality of the pillar member can be known by measuring.

That is, if the laser level meter that emits the laser beam in the direction of the axis perpendicular to the ground can be matched to the center line of the pillar member, the verticality of the pillar member can be easily measured.

In other words, the triangle inscribed into the circle is an isosceles triangle, and the center of gravity of the circle is the same as the center of the circle. Mount it.

However, in order to insert the jig smoothly into the inside of the pillar member, the outside size of the jig should be smaller than the diameter of the pillar member. In this case, the gap is generated due to the gap between the jig and the pillar member. This is impossible. A countermeasure against this is provided by the three-point contact structure of the jig and the connection position of the cable.

For example, the jig is made in the shape of a triangular column with three columns and connecting plates connecting them. The jig having such a structure can be inserted into the pillar member smoothly, as well as the jig can be inserted into the pillar member without shaking regardless of the size of the gap between the jig and the pillar member, thereby enabling a consistent verticality measurement.

3 is a side cross-sectional view showing a jig of the present invention inserted into a pillar member. 4 is a perspective view showing a jig of the present invention inserted into a pillar member.

In the vertical measurement method of the present invention, the jig 200, the laser level meter 300, and the measurement plate 400 are used.

The jig 200 has a size smaller than the diameter of the inner wall 110 of the pillar member 100 so that the jig 200 can be easily inserted into the inner wall 110 of the pillar member 100 placed on the ground. It has contact points V1, V2, and V3. The shape of the jig 200 is an imaginary triangular pillar or triangular pyramid including the three contact points V1, V2 and V3 as vertices V1, V2 and V3, and a laser level meter 300 at the center point of the triangular pillar or triangular pyramid. Is emitted from the laser beam L.

In an embodiment, the jig 200 includes a triangular-shaped connecting plate 210, a first column 201, a second column 202, and a third column 203 connected to each vertex of the connecting plate 210. ). At this time, the upper end of the first column 201, the lower end of the second column 202, the lower end of the third column 203 is in point contact with the inner wall 110 of the pillar member 100, the laser level meter The 300 is installed at the center of gravity C position of the connecting plate 210 and is disposed on the center line 101 of the pillar member 100.

The laser level meter 300 emits a laser beam L in a direction of an axis that is perpendicular to the ground. The laser level meter 300 emits a laser beam L in a vertical direction of the ground to measure verticality of the pillar member 100. Provide a baseline or reference point for

With respect to the laser beam L serving as a reference line or reference point, when the separation distance d or the separation angle θ of the center line 101 of the pillar member 100, which is a measurement object, is measured, the pillar member 100 The vertical degree can be seen.

In this case, the material of the jig 200 may be formed of a transparent plate such as acrylic resin, for example, in a size and shape such that the progress of the laser beam L is not blocked by the jig 200 (for example, the first column 201). , The second column 202, the third column 203, and the connecting plate 210 are preferably cut and bonded to each other.

Three vertices V1, V2, and V3 of the jig 200 are inscribed to the inner wall 110 of the pillar member 100 for such three-point contact. In addition, the cable 260 for lifting and supporting the load of the jig 200 inserted into the inner wall 110 of the pillar member 100 is connected to the cable connection portion 261 which is the eccentric position of the jig 200, The 200 is in contact with the inner wall 110 of the pillar member 100 in an inclined state. As such, the cable connection 261 is in an eccentric position at the centerline C of the column member. The cable 260 is exposed to the outside through the top opening of the pillar member 100.

Therefore, even if the jig 200 is lowered at any position of the pillar member 100, the three-point contact structure of the jig 200 causes the laser level meter 300 to match the centerline 101 of the pillar member 100. As a result, the verticality of the pillar member 100 can be measured consistently.

On the other hand, even when the diameter of the pillar member 100 is greatly increased, if the jig 200 having the same size is used as it is, the jig 200 is inclined too much, so that it is difficult to obtain an accurate point contact state, or as a result, the accuracy of verticality measurement is high. Can fall.

An example of such a case is shown well in FIG. 3 as an imaginary line (dotted and dashed line). Referring to this, when the inner wall diameter of the pillar member 100 increases, the inclination angle of the jig 200 may be maintained within a predetermined range by increasing the size of the connecting plate 210 to increase the size of the jig 200. In addition, by increasing the width of the jig 200 by increasing the widths of the first column 201, the second column 202, and the third column 203, the inclination angle of the jig 200 is fixed within a predetermined range. Embodiments to keep within are also possible.

That is, in FIG. 3, when the diameter of the pillar member 100 is large, three contact points are moved from V1, V2, V3 to V1 ", V2", V3 ", but the inclination angle of the jig 200 is An example is shown as it is.

On the other hand, the measuring plate 400 attached to the upper side of the pillar member 100 is a means for quantitatively visualizing the verticality of the pillar member 100. The measuring plate 400 is a transparent plate on which the laser beam L is formed, and at least one measuring source is drawn.

Mounting the measuring plate 400 so that the measuring source is the center of the pillar member 100, the laser beam L emitted from the laser level meter 300 is formed on the measuring plate 400 beam spot (P2) ) And the inclination angle θ of the pillar member 100 can be determined quantitatively by measuring the separation distance d between the center line position P1 of the pillar member.

In this case, for example, the radian value of the inclination angle θ may be calculated by dividing the separation distance d by the insertion length l of the jig 200. In other words, a relation of d = l × θ holds. The insertion length l of the jig 200 may be calculated by measuring the change in the length of the cable before and after the jig 200 is inserted into the pillar member 100.

In addition, the alignment system 410 and the measuring plate 400 is arranged in the east-west, north-west direction so as to coincide with the orientation system 410, and then the center line position P1 and the laser beam L of the pillar member 100 are measured. When the direction angle of the straight line connecting the beam spot P2 formed on the plate 400 is measured, the inclined direction of the pillar member 100 can be known.

As described above, after measuring the verticality of the pillar member 100, the beam spot P2 is applied to the pillar member 100 in order to correct the verticality of the pillar member 100. 101), or if the measured value of the verticality is outside the tolerance range, besides, it is possible to control the quality of the pillar construction by additionally placing a new column member 100 in the correct vertical.

5 is a flowchart showing a method for measuring verticality according to the present invention. First, the pillar member is poured into the ground (S1). The jig provided at the center of the laser level meter is inserted into the inner wall of the pillar member in an inclined state (S2). At this time, the jig and the inner wall have three contact points. When the jig is inserted to the set depth, the insertion length of the jig is measured.

And a measuring plate is arrange | positioned in the center of a column member (S3). The distance or direction angle between the center line of the pillar member and the beam spot is measured (S4). Thereby, the perpendicularity of a pillar member can be calculated. If the vertical degree is within the tolerance range, the operation ends (S7).

If the verticality is outside the tolerance, apply force to the column member to adjust the verticality to converge in the tolerance, or add a new column member next to the pillar member with verticality outside the tolerance ( S6).

Although embodiments according to the present invention have been described above, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments of the present invention are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

1 is a side cross-sectional view of a pillar member placed on the ground.

It is explanatory drawing explaining the principle of the perpendicularity measuring method of this invention.

3 is a side cross-sectional view showing a jig of the present invention inserted into a pillar member.

4 is a perspective view showing a jig of the present invention inserted into a pillar member.

5 is a flowchart showing a method for measuring verticality according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100 ... without pillar 101 ... centerline

110.Interior walls V1, V2, V3 ...

C ... weight center 200 ... jig

201 ... Column 1 202 ... Column 2

203 ... column 3 ... 210

260 ... cable 261 ... cable connection

300 ... laser level meter 400 ... measuring plate

410 ... orientation L ... laser beam

P1 ... Center line position of column member P2 ... beam spot

Claims (9)

Placing a hollow pillar member on the ground; Installing a laser level meter at the center of the jig, which emits the laser beam in the axis direction; Inserting the jig inclined so as to have three contact points with the inner wall of the pillar member; Measuring a vertical degree of the pillar member by measuring a center line of the pillar member and a separation distance of the laser beam or a direction angle of the center line and the laser beam; Vertical measurement method comprising a. The method of claim 1, And vertically measuring the jig so that the upper end of the jig and the lower end of the jig contact the inner wall of the pillar member. The method of claim 1, The jig includes a triangular-shaped connecting plate and a first column, a second column, and a third column provided at each vertex of the connecting plate. The upper end of the first column, the lower end of the second column, the lower end of the third column are in point contact with the inner wall of the pillar member, And the laser level meter is disposed at the center of gravity of the connecting plate. The method of claim 3, When the inner wall diameter of the pillar member is increased, the size of the connecting plate is increased or the width of the first column, the second column and the third column is increased, thereby maintaining the inclination angle of the jig within a predetermined range. Degree measuring method. The method of claim 1, A measuring plate on which at least one measuring source is drawn is installed on the upper side of the pillar member such that the measuring source and the pillar member are concentric; And measuring a distance between the beam spot formed on the measuring plate and the center line of the pillar member to measure the perpendicularity of the pillar member. The method of claim 5, And calculating the inclined inclination angle of the pillar member by dividing the separation distance by the insertion length of the jig. The method of claim 6, Insertion length of the jig, And measuring the change in the length of the cable before and after inserting the jig into the pillar member with respect to the cable whose one end is fixed to the cable connection portion of the jig and the other end is exposed to the outside of the pillar member. The method of claim 1, The measuring plate provided with an azimuth system is provided on the upper side of the pillar member so as to be in the center of the pillar member. And measuring a direction angle of a straight line connecting the beam spot formed on the measuring plate to the measuring plate and the center line of the pillar member to calculate a direction in which the pillar member is inclined. The method according to any one of claims 1 to 8, If the verticality of the pillar member is out of the error range, the pillar member is adjusted by applying a force to the pillar member so that the laser beam is aligned with the center line of the pillar member, or additionally installing the pillar member next to the pillar member. step; Vertical measurement method comprising a.

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