KR101968320B1 - Load cell module for ground anchor - Google Patents

Abstract

The present invention relates to a load cell module for a ground anchor, which is installed on the ground anchor to measure tension generated in a steel strand of the anchor. According to one embodiment of the present invention, the load cell for a ground anchor, which is installed on the ground anchor to measure a load generated in the steel strand made of a plurality of strands, includes: a plurality of load cells which has the same number with the number of the steel strands and in which each has a hollow portion formed on the center so that a single strand of the steel strands is possible to be inserted and penetrated; and an exterior surrounding side surfaces of the plurality of load cells to fix the load cells.

Description

Load Cell Module for Ground Anchor {LOAD CELL MODULE FOR GROUND ANCHOR}

The disclosed subject matter relates to a load cell module for a ground anchor, which is installed on a ground anchor and measures tension generated in the strand of the anchor.

In the process of developing mountain areas for roads and mere development, slopes are often formed, often resulting in the collapse of slopes and accidents that threaten life and property.

In order to prevent the collapse of these slopes, various types of retaining and supporting methods have been attempted. Typically, resistance strengthening methods are used as slope reinforcement methods. Rock bolts, ground anchors, and stepped retaining walls are used.

Among these, the ground anchor is normally inserted into a perforation hole formed in a slope and grouted, and a rear end portion thereof is protruded out of the perforation hole to be seated and fixed to the support plate, and a steel bar or a stranded wire is inserted into the perforation hole to transmit tension to the ground .

On the other hand, a load cell is installed on the support plate of the ground anchor, and a load cell is installed in order to detect a ground displacement quickly and prevent a safety accident in advance.

A related art related to such a load cell is a load cell assembly disclosed in Korean Utility Model Registration No. 20-0408757.

Figure 1 is a prior art load cell assembly.

1, a conventional load cell 10 includes a cylinder 11, a vibrating string strain gauge 12 mounted in three holes 12 formed in the upper portion of the cylinder 11, And a cap 14 for attaching the cable 13 to the load cell 10. The cable 13 is connected to the load cell 10 via a cable 13 for transmitting the frequency of the AC voltage generated in the load cell 12 to an external device.

When a load acts on the cylinder 11, the tension of the strand of the strand is changed by the built-in strain gauge 12, the alternating voltage is generated by changing the magnetic field by vibrating the strand by the electric coil inside the sensor, The frequency is equal to the resonance frequency of the stranded wire and is transmitted to the appropriate frequency measuring device through the cable (13), and the load is accurately converted by the change coefficient.

However, such a conventional load cell can not be concentrated on the three strain gauges provided in the cylinder hole 12 due to the structural load of the cylinder 11 and is injected into the entire cylinder, making it difficult to precisely measure the load. The load acting on each strand is not individually measured.

In particular, since the permanent anchor of the ground anchored to the ground has not been able to be used since 2000, the length of the strand is differently applied to the inner lower body and the removed ground anchor method is removed. , It is necessary to measure the individual load to distinguish the strand where the overload is acting and to calculate the load deviation for each underbody body so that the balance of the anchor body can be adjusted.

It is possible to adjust the load deviation of each strand so that it does not exceed the limit load per strand. In case of two strand fixing method, when the load deviation by each underbody deepens, the destruction of the anchor system is prevented can do.

KR 20-0408757 Y1

It is an object of the present invention to measure the load exerted on the stranded wires of the ground anchor individually and check the deviation thereof so as to prevent a part or the whole of the stranded wire from being broken or yielded.

It is of course structured so that the frictional resistance limit of the fixing part can not be reached before the strand breaks.

In particular, since the permanent anchor of the ground anchored to the ground has not been able to be used since 2000, the length of the strand is differently applied to the inner lower body and the removed ground anchor method is removed. , It is necessary to measure the individual load to distinguish the strand where the overload is acting and to calculate the load deviation for each underbody body so that the balance of the anchor body can be adjusted.

It is possible to adjust the load deviation of each strand so that it does not exceed the limit load per strand. In case of two strand fixing method, when the load deviation by each underbody deepens, the destruction of the anchor system is prevented can do.

The technical problem to be solved by this embodiment is not limited to the above-mentioned problems, and other matters not mentioned can be clearly understood by a person skilled in the art from the following description.

The load cell for a ground anchor according to an embodiment is a load cell module for an anchor that is installed on a ground anchor and measures a load generated in a stranded wire composed of a plurality of strands. The load cell module is composed of the same number as the number of stranded wires, A plurality of load cells having a hollow portion formed at a central portion thereof so that a single strand of the load cell can be inserted and penetrated; And an outer casing enclosing the plurality of load cells and fixing the load cell.

An epoxy is formed in the space between the outer tube and the load cell to fix the plurality of load cells.

The fixing unit may further include a fixing unit installed inside the outer tube to block the horizontal movement of the plurality of load cells.

The fixing unit may include a center member vertically disposed at the center of the outer tube, and a plurality of spacing members extending from the center member and having a plate shape whose end is in contact with the inner surface of the outer tube.

The fixing unit may further include a horizontal member each extending radially from a lower end of the center member and supporting a lower end of the load cells to keep the load cell horizontal.

Here, the horizontal member has a rod shape.

In addition, the load cell is formed in a cylindrical shape, and is closely arranged along the circumferential direction of the circle having the center of the outer tube as the origin.

Further, the outer tube is formed in a rectangular case-like shape with upper and lower portions opened, the load cell and the stranded wire are formed of four pieces, and the gap member has a cross-sectional shape.

According to the disclosed contents, the load applied to the strands is individually measured and the deviation thereof is checked, thereby preventing part or all of the strands from being broken or surrendered in advance.

Further, there is an effect that the frictional resistance limit of the fixing portion can not be reached before the strand breaks.

Since the permanent anchor of the ground anchored to the ground has not been able to be used since 2000, the length of the strand is differently applied to the inner lower body, and the removed ground anchor method is removed after the completion of the construction. In case of acting, the individual load is to be measured so as to distinguish the strand where the overload is acting and calculate the load deviation for each underbody body so that the balance of the anchor body can be adjusted.

It is possible to adjust the load deviation of each strand so that it does not exceed the limit load per strand. In case of the usual two-strand fixing method, when the load deviation by each underbody deepens, it is a sign of local destruction. The destruction of the system can be prevented.

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

1 is a perspective view of a load cell according to the prior art;
2 is a perspective view of a load cell module for a ground anchor according to an embodiment;
3 is a cross-sectional view of a load cell module for a ground anchor according to one embodiment.
FIG. 4 is a perspective view of the load cell shown in FIG. 3; FIG.
5 is a perspective view of the fixing part shown in Fig.

Hereinafter, a load cell for a ground anchor according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

2 is a perspective view of a load cell module for a ground anchor according to an embodiment, FIG. 3 is a cross-sectional view of a load cell module for a ground anchor according to an embodiment, FIG. 4 is a perspective view of the load cell shown in FIG. 3 is a perspective view of the fixing part shown in Fig.

2 to 5, the load cell module 100 according to one embodiment is configured to measure a load generated on a strand of a plurality of strands provided on a support plate of a ground anchor (not shown).

Specifically, the load cell module 100 according to one embodiment may include a plurality of load cells 140, an outer tube 120, and a fixing portion 160.

The load cell 140 has a plurality of, preferably the same number as the number of strands, unlike the conventional load cell used in the ground anchor. In the center of each load cell 140, a single strand of the strand is inserted A portion 140a is formed. The hollow portion 140a includes a hollow portion 142a formed in the body of the load cell 140 to be described later and hollow portions 144a and 146a formed in the upper and lower plates.

Conventionally, in the case of a single load cell, a plurality of stranded strands are inserted into the hollow portion, so that only the sum of load values and average values of stranded strands can be measured and the load of each strand can not be individually measured. Therefore, in the case where the load deviation of the strand is large, there is a problem that a part of the strand breaks or yields even if the measured value is within a predetermined load deviation value.

In this embodiment, since the load cell 140 and the stranded wire are matched at a ratio of 1: 1, there is an advantage that it can be checked immediately when a problem occurs in a specific stranded wire among a plurality of stranded wires. The load balance can be adjusted through the load.

In addition, when the load applied to the lower body is fixed to each other by the two-stranded fastening method, it is possible to prevent the destruction of the anchor system because it is a sign of local destruction.

4, each of the load cells 140 includes a body 142 having a hollow portion 142a formed at a central portion thereof and a body 142 formed at an upper portion and a lower portion of the body 142, 140 and a lower plate 146 for uniformly transferring the load applied to the upper plate 144 and the lower plate 146. At this time, a single strand of the strand is inserted into the hollow portion 144a, and the strand is inserted into the perforation hole formed on the slope. The upper and lower plates are formed with through holes 144a and 146a corresponding to the hollow portion 142a of the body 142 so that the stranded wire inserted into the hollow portion 144a passes through the upper and lower portions of the load cell 140. [

As shown in FIG. 2, each of the plurality of load cells 140-1, 140-2, 140-3, and 140-4 may be formed into a cylindrical shape, and the circumferential direction of a circle Can be closely arranged. Therefore, when the container is housed inside the outer tube, the accommodation space is minimized and the container is stably fixed.

In this embodiment, the cylindrical load cell 140 is exemplified. However, the shape of the load cell 140 is not limited thereto, but may be a polygonal shape in order to enhance the fixing force of the load cell 140. Since a single stranded wire is inserted into the hollow portion 140a of the load cell 140, the volume of each load cell 140 and the diameter of the hollow portion can be largely reduced.

In addition, the load cell 140 applied to the present embodiment may be composed of various types of load cells such as a vibrating suspension type load cell or an electric resistance type load cell.

At least one strain gage 143 as a load measuring sensor is installed along the circumferential direction inside the body 142 of the load cell 140. A strain gauge 143 is attached to the outer surface of the body 142 of each load cell 140, (Not shown) that is electrically connected to the power supply terminal. These conductors are electrically connected to the cable 150 through a cable terminal 124 provided on one side of the outer tube 120 to transmit an AC voltage signal generated by the strain gage 143 to an external control device. Here, the cable 150 may preferably be made of conductors 152 that are electrically associated with the leads of the load cell 140.

The outer tube 120 has a structure in which a plurality of load cells 140 are wrapped around each other and fixes the load cell 140. The outer tube 120 preferably has a rectangular shape in which upper and lower portions are opened to stably receive and fix a plurality of load cells 140 Lt; / RTI > However, it may be formed in various shapes such as a cylindrical shape depending on the number of strands and the shape of the load cell 140.

When the plurality of load cells 140 are accommodated in the outer tube, the epoxy 180 may be formed in the empty space between the outer tube 120 and the load cell 140. The epoxy 180 may be formed by various methods but preferably the load cells 140 are disposed inside the outer tube 120 and then the liquid epoxy 140 is inserted into the space between the outer tube 120 and the load cell 140. [ ) ≪ / RTI > resin and incorporating the curing agent in a certain proportion. Accordingly, the load cell 140 can be firmly fixed inside the outer tube.

Referring to FIG. 5, the fixing unit 160 is installed inside the outer casing 160 to block the vertical movement of the load cells 140. In particular, the fixing part prevents the load cells 140 from being displaced in the process of filling the epoxy 180, thereby stably fixing the load cells 140.

The fixing portion 160 may include a center member 162, a spacing member 164, and a horizontal member 166. [

The center member 162 is vertically disposed at the center of the outer tube 120 and serves to hold the center of the outer tube 162. The spacing member 164 is formed of a plurality of pieces, each extending from the center member 162, (Not shown).

The number and shape of the spacing members 164 may be different according to the number of the strands and the load cells 140. For example, if the load cell 140 and the strand 160 are formed of four pieces, the cross-sectional shape may be a cross-sectional shape, and each end may be fixed to the inner surface of the outer tube 120.

The horizontal member 166 provided at the lower end of the center member 162 is configured to maintain the horizontal position of the load cells 140 accommodated in the outer tube 120 and extends radially from the lower end of the center member 162 Thereby supporting the lower ends of the load cells 140. In this case, the horizontal member 166 may have various shapes. However, it is preferable that the horizontal member 166 is formed in a bar shape so as to minimize the volume and stably support the load cell 140, .

The horizontal member 166 may be disposed so as to support the lower end of the load cell 140 as in the present embodiment. However, the horizontal member 166 may be disposed at a lower end of the other load cell 140, Of course.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the present invention. It is to be understood that various equivalents and modifications may be substituted for those at the time of the present application.

100: Load cell module for ground anchor 120: Appearance
124: Cable terminal
140: Load cell 150: Cable
152: lead 160:
162: center member 164: spacing member
166: Horizontal member 180: Epoxy

Claims (8)

A load cell module for an anchor, which is installed in a ground anchor and measures a load generated in a strand composed of a plurality of strands,
A plurality of load cells having the same number as the number of strands, each having a hollow portion at a central portion thereof so that a single strand of the strand can be inserted and penetrated;
An outer tube for enclosing the plurality of load cells and fixing the load cell; And
A fixing member provided inside the outer tube and having a central member disposed vertically at the center of the outer tube and a plurality of spacing members extending from the center member and having a plate shape whose end is in contact with the inner surface of the outer tube; Wherein the load cell module includes:
The method according to claim 1,
Wherein an epoxy is formed in the space between the outer tube and the load cell to fix the plurality of load cells.
The method according to claim 1,
Wherein the fixing unit blocks the right and left up and down movements of the plurality of load cells.
delete The method according to claim 1,
The fixing unit includes:
Further comprising a horizontal member each extending radially from a lower end of the center member and supporting a lower end of the load cells to maintain a horizontal position of the load cell.
6. The method of claim 5,
Wherein the horizontal member has a rod shape.
The method according to claim 1,
Wherein the load cell has a cylindrical shape and is closely disposed along a circumferential direction of a circle having the center of the outer tube as an origin.
The method according to claim 1,
Wherein the outer tube has a rectangular case shape with upper and lower portions opened, the load cell and the stranded wire are formed of four pieces,
Wherein the spacing member has a cross-sectional shape.

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