KR200405462Y1 - mono load cell for measuring axial strength of anchors using strong strands or cables, and anchoring structure - Google Patents

Abstract

The present invention measures the axial force of each strand in various types of anchor structures such as building anchors, buoyancy anchors, and retaining wall permanent anchors, and calculates the sharing ratio of loads acting on the undercarriage through abnormal displacement. It provides a mono-load cell for anchor force measurement and its anchor structure to cope with the risks of safety accidents such as collapse accidents during construction through precise and accurate measurement.

The monotonic cell for axial force measurement of the anchor is a load cell for measuring a load which is a tensile force acting on each of the steel wires 10 to be fixed for the anchor structure, and the passage hole 59 through which the steel wire 10 passes is The deformed pillar portion 58 is formed and deformed by compression, tension, or the like when the tensile force is applied to the steel wire 10, and for transmitting the tensile force of the steel wire 10 relatively above and below the deformable pillar portion 58. An electrical resistance strain gauge 54 attached to the first support plate 56 and the second support plate 57 and the outer surface of the deformable pillar 58 to generate different electrical signals according to deformation due to compression, tension, or the like. Or 55).

Anchor, mono load cell, steel wire, deformation column, strain gauge

Description

Mono load cell for measuring axial strength of anchors using strong strands or cables, and anchoring structure}

FIG. 1A is an explanatory diagram schematically illustrating a conventional anchor type clogging method, and FIG. 1B is a detailed view thereof.

Figure 2a is a detailed cross-sectional view showing the configuration of a mono load cell according to an embodiment of the present invention, Figure 2b is a schematic exploded perspective view of the mono load cell.

3 is a front view and a rear view schematically showing a configuration in which two pairs of electric strain gauges are installed.

Figure 4 is a schematic diagram showing an anchor structure using a mono load cell according to the present invention.

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

1: vertical H beam 2: horizontal beam

3: pressure plate 4: side wall

5: grouting ball 6: grout

7: Bracket 10: Steel wire (tensile member)

11: anchor head 12: tensioning cylinder

13: tension head 13a: tensile wedge

20: steel wire head 30: multi load cell

50: mono load cell 51: housing

52: main body 53: filler

54, 55: electric strain gauge 56: first support plate

57: second support plate 58: deformed column

59: through hole 60: anchor head

61: fixing wedge

The present invention relates to various types of anchor structures such as building anchors, buoyancy anchors, retaining wall permanent anchors, etc., and the axial force state of each strand in the manner of a load cell used to check the axial force state of the anchors. The present invention relates to a mono load cell for axial force measurement of an anchor composed of an electrical resistive strain gauge and an anchor structure thereof in order to accurately and precisely measure.

In general, in the various types of anchor structures such as construction anchors, buoyancy anchors, and retaining wall permanent anchors for civil engineering, construction, construction, etc., the state of the axial force acting on each strand of a plurality of steel wire anchors is different. This problem results in the surrender of some steel wires, and the axial force of the steel wires that lost its function after the surrender is transferred to the adjacent anchors, resulting in chain breakdown and collapse of the excavation surface.

The configuration for a conventional multiload cell is shown in FIG. 1A as a schematic sectional view, and in FIG. 1B in some detail of FIG. 1A. 1A and 1B, one end of the plurality of steel wires 10 is fixed to the head inner body or the steel wire head 20, the grouting hole 5 is formed on the side wall 4, and then the steel wire head 20 is formed. It is inserted into the grouting hole (5) together with the steel wire (10). Thereafter, generally, the through hole 3a of the pressure plate 3 provided in the vertical H beam 1 or the horizontal beam 2, the anchor head 11, the split wedge for fixing thereof, the tension cylinder 12, and the tension holder The grouting is performed with the concrete 6 in the state where the other end of the plurality of steel wires 10 is passed through the head 13 and its tensioning split wedges. When the grout 6 is cured, the plurality of steel wires 10 are tensioned by the tension cylinder 12 with respect to the anchor head 11 and the steel wire head 20, and a split wedge is used at the anchor head 11. By fixing the steel wires, the side wall 4 is prevented from collapsing during construction work.

The measuring device developed and used so far to measure the load of the tensioned steel wire 10, as shown in Figure 1a and Figure 1b, the state of all the steel wire is inserted into one grouting hole (5) and tensioned together The multi-load cell 30 to measure as a target was adopted, and the vibration-type one was widely used as the multi-load cell 30.

However, such a construction is easy to manufacture and install, but it is difficult to detect when an eccentricity and axial force is applied only in some steel wires, and the cause can be identified only after the occurrence of a problem (some yielding of steel wires). That is, there is a problem in that the measuring instrument as used in the prior art can not know the axial state of each load, steel wire.

Therefore, until now, the value estimated by design based on the data obtained from the measurement shows a significant difference between the measured value and the actual measured value at the construction site. As a result, the entire anchor yields, and the axial force dissipated by the anchor is transferred to the adjacent anchor, and the adjacent anchor surrenders due to excessive axial force, causing the risk of a large safety accident such as the collapse of the entire excavated wall.

The present invention measures the axial force of each strand in various types of anchor structures, such as building anchors, buoyancy anchors, retaining wall permanent anchors for civil engineering, construction, construction, etc. It is possible to calculate the share of the load applied to each steel wire, and to measure the axial force of the anchor to cope with the risks of safety accidents such as collapse accidents during construction through precise and accurate measurement of abnormal displacement, and its anchor structure The purpose is to provide.

That is, it is installed in each steel wire to calculate the axial force of each steel wire to grasp the overall axial force state, calculate the state of axial force acting on each load bearing body and load sharing ratio of each steel wire, and exceed the design allowance standard of each steel wire. The status can be known in advance. These results can be known before the steel wire yields during installation and measurement management. Based on these measurement results, supplementary and reinforcement methods can be sought.

Furthermore, the monoload cell and its anchor structure for axial force measurement of the anchor according to the present invention, respectively, may be employed in the method of applying the equal tensile force to the steel wire and the uniform tensile force monitoring system during construction or installation.

The present invention for achieving the above object in the construction of a load gauge used in the measuring instrument for measuring the detailed behavior of the anchor used in various types of anchor structures, such as anchors for construction, buoyancy anchors, retaining walls, hollow The internal resistance sensor made of a thin foil (Foil) inside the housing of the fixed one end to the main body and the external force causes the change in the length of the thin plate and uses the change of resistance according to the length of the thin plate.

In order to achieve this purpose, the mono-load cell for axial force measurement of an anchor according to an embodiment of the present invention, a tensile force acting on each of the steel wire to be fixed for various types of anchor structures, such as construction anchors, buoyancy anchors, retaining wall permanent anchors In a load cell for measuring the phosphorus load, a deformable pillar portion deformed by compression, tension, or the like when a through hole through which the steel wire passes and a tensile force acts on the steel wire, and a tensile force of the steel wire are relatively above and below the deformable pillar portion. And a first resistance plate portion and a second support plate portion for transmitting the electrical resistance strain gauge attached to the outer surface of the deformation pillar portion to generate different electrical signals according to deformation due to compression, tension, or the like. do.

In addition, the present invention, in the anchor structure for fixing a plurality of steel wires to be fixed for various types of anchor structures, such as building anchors, buoyancy anchors, retaining wall permanent anchors, through the wedge, anchor head and pressure plate, The anchor heads are provided separately for each steel wire and have a plurality of anchor heads having fixing wedges for each steel wire so as to evenly apply a load that is tensile for each steel wire, and between the bearing plates for each of the anchor heads. Provides an anchor structure characterized in that the mono load cell is installed in each.

Hereinafter, preferred embodiment (s) of the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 2A and FIG. 2B, the mono load cell 50 according to the embodiment of the present invention is composed of a separate body 52 and a housing 51, and compressive deformation of the body 52 is possible therebetween. At the same time, the filler 53 is filled and solidified so that the housing 51 and the main body are not separated from each other. However, the monoload cell 50 of the present invention can be operated even if the main body 52 is composed of only the main body 52. The base plate 53a may be installed to easily fill and solidify the filler 53.

As shown in the drawing, the main body 52 is divided into a deformation pillar 58 to which the electric resistance strain gauges 54 and 55 are attached, a first support plate 56 and a second support plate 57. . The deformation column 58 has a through hole 59 through which the steel wire 10 passes, and a load to be measured as a portion where compression deformation occurs when a tensile force is applied to the steel wire 10 and its allowable range. It is preferable to be formed of a material having a suitable strain.

The first support plate portion 56 and the second support plate portion 57 are portions which are slightly widened so as to stably support the tensile force of the steel wire 10 with respect to the side wall 4 only above and below the deformation column 58. As shown in FIG. 4, the bottom surface of each anchor head 60 is supported on one side and fixed to the side wall 4 via the pressure plate 3, and on the other side, a load acting on each steel wire 10 is applied. Is supported in contact. Depending on the anchor structure, such as a building anchor, buoyancy anchor, retaining wall permanent anchor, etc., the bearing plate 3, the side wall 4, etc. may be changed in name or structure.

The electrical resistance strain gauges 54 and 55 are thin films, which are attached to the outer surface of the deformable pillar portion 58 and are deformed identically according to the deformation of the deformable pillar portion 58, thereby different electric signals for the same input electrical signal. Will be generated. For example, since the resistance values of the electric resistance strain gauges 54 and 55 change according to their deformation, different voltages are output from the output side even when the same voltage is applied to the input side. Typically, the resistive strain gauges 54 and 55 may be employed, but may be applied as long as the electrical values change depending on the strain rate. In addition, the electric resistance strain gauges 54 and 55 have small deformations and thus small resistance values, which are small values, so that they can be efficiently represented as voltage values, and corrections for temperature changes and eccentric loads are automatically performed. It is preferable to form a Wheatstone bridge so that a pair of electrically resistive strain gauges 54 and 55 corresponding to axial and circumferential deformation are attached to the front and rear of the deformation column 58, respectively, to complement each other. Although not shown in FIG. 3, one electric resistance strain gauge may be attached thereto, and there may be a method of measuring only two sensors instead of four, and an electric resistance corresponding to a deformation in a diagonal direction as needed. An equation strain gage may be attached.

In addition, the concept of temperature compensation according to the method of attaching the electrical resistance strain gage is different, for this purpose, for example, it is possible to correct the built-in temperature sensor, the dummy gauge gauge housing 51 It can also be installed on the inner wall and corrected.

The housing 51 surrounds the main body 52 so as to safely handle and install the main body 52 in which the deformation column 58, the first support plate 56, and the second support plate 57 are integrated. As described above, the filler 53 is filled and solidified so that the deformation of the deformation pillar 58 is not hindered, but the present invention is not limited thereto. The housing 51 is preferably formed with a through hole 51a through which the electric wire 51b connected to the electric resistance strain gauges 54 and 55 passes.

Referring to Figure 4 describes the anchor structure according to the present invention with the action of the mono-load cell 50 configured as described above are as follows.

First, referring to FIG. 1A, a grouting hole 5 is drilled to prevent collapse of the side wall 4, and a plurality of steel wires 10 are fixed to the steel wire head 20 according to a designed load. Inserted into the grouting hole (5), the through hole (3a) of the pressure plate (3) installed in the vertical H beam (1) or horizontal beam (2), the anchor head 11 and the split wedge for fixing thereof, the tension cylinder (12) Grout to concrete 6 while passing through the other end of the plurality of steel wires 10 through the tensioning head 13 and the tensioning split wedges thereof. When the grout 6 is cured, each monolithic cell 50 is passed through the central through hole 59 for each of the plurality of steel wires 10 so that one mono-load cell 50 is placed on the pressure plate 3. The anchor head 60 and the fixing wedge 61 through the steel wire 10 on the mono load cell 50, and the plurality of fixing wedges 61 on the plurality of fixing wedges 61. A tension cylinder 12 is installed to allow the steel wire 10 to pass therethrough, and a tension head 13 is installed by passing the fixing wedge 61 through each steel wire 10. Insertion grooves may be formed in the pressure plate 3 to facilitate the installation of the mono load cell 50.

Thereafter, the tension cylinder 12 is actuated at a predetermined pressure to tension the plurality of steel wires 10, and the deformation pillars 58 are compressively deformed by the tensile force acting on the steel wires 10. Thus, the tensile force acting during tensioning can also be measured. Accordingly, it can be seen that different tensile forces acting outside the permissible ranges on each steel wire 10 during the tensioning, so that proper cause analysis and measures can be performed in the middle. In any case, when the tensile force of the maximum allowable range is applied to the steel wire 10, it is preferable to stop the tension for the protection of the steel wire 10.

The load acting on each of the steel wires 10 is measured when the fixing wedge 61 is fixed and the steel wire 10 is fixed after the tension cylinder 12 is not acted after being tensioned at a predetermined pressure. desirable. At this time, except for the load within the allowable range of each of the steel wire 10, it is desirable to have the appropriate tensile force to re-tension the steel wire 10 is still less tension to the load within the allowable range. At this time, it may be one method to separate the tension wedge 13a for the steel wire 10 within the allowable range.

In this way, the loads within the same allowable range are equally applied to all the steel wires 10, so that construction can be performed as designed, thereby preventing the risk of collapse and the like. In addition, even when an abnormal displacement occurs, it is possible to make sure through accurate and accurate measurement.

In addition, the above-described configuration measures and detects the load from the electric resistance strain gauges 54 and 55 as a change in an electrical signal such as a voltage through the wire, but may also incorporate a suitable battery such as a button type. Although omitted, the chip and antenna, such as a radio frequency electronic card (RFID), may be embedded so that measurements can be made by wireless communication using RF signals instead of wires.

Furthermore, the load of the load may be monitored by the above-described mono load cell 50 even during construction or construction of civil engineering or installation of facilities, and in particular, it may be employed as a monitoring system during rain or at night to ensure safety. The monitoring system may also be configured with alarm means such as LED lights or horns.

Above, the anchor structure can be modified to be suitable for various kinds of anchor structures such as building anchors, buoyancy anchors, retaining wall permanent anchors, except for the main configuration.

According to the configuration and action of the mono-load cell for measuring the axial force of the anchor and the anchor structure according to the embodiment of the present invention described above, it is possible to measure the axial force of each steel wire and to calculate the share of the load acting on the steel wire. Through accurate and accurate measurement of abnormal displacement, it is possible to cope with the risk of safety accident such as collapse accident during construction.

Claims (4)

In the load cell for measuring the load that is the tensile force acting on each of the steel wires 10 to be fixed for various types of anchor structures, such as anchors for construction, buoyancy anchors, retaining wall permanent anchors, through-holes through which the steel wire 10 passes (59) is formed and the deformation column portion 58 which is deformed by compression, tension or the like when the tensile force is applied to the steel wire 10, and the tensile force of the steel wire 10 relatively above and below the deformation column portion 58 Electrical resistance type that is attached to the outer surface of the first support plate 56 and the second support plate 57 and the deformation pillar 58 for transmitting a different electrical signal according to the deformation by compression, tension, etc. A mono-load cell for measuring the axial force of the anchor, characterized in that comprising a strain gauge (54 or 55). The method of claim 1, wherein the deformation column 58, the first support plate 56 and the second support plate 57 integrally constitute the body 52, so that the handle can be installed easily and safely A through hole 51a through which an electric wire 51b connected to the electric resistance strain gauges 54 and 55 passes is formed, and has a housing 51 surrounding the body 52. Anchor, characterized in that it further comprises a filler 53 is filled and solidified between the housing 51 and the main body 52 so as not to be separated from the housing 51 and the main body. Mono load cell for measuring axial force. In the anchor structure for tensioning a plurality of steel wires 10 to be fixed for various types of anchor structures, such as construction anchors, buoyancy anchors, retaining wall permanent anchors, through the wedge, anchor head and pressure plate 3, A plurality of anchor heads having the anchor heads installed separately for each steel wire 10 and having fixing wedges 61 for each steel wire 10 so as to evenly apply a tensile force for each steel wire 10. An anchor structure, characterized in that the mono-load cell (50) is provided between the pressure plate (3) for each of the anchor head (60). According to claim 3, The mono-load cell 50, the deformed column is deformed by compression, tension, etc. when the through-hole 59 through which the steel wire 10 passes and the tensile force is applied to the steel wire 10 The first support plate portion 56 and the second support plate portion 57 for supporting the tensile force of the steel wire 10 relatively above and below the portion 58, the deformable pillar portion 58, and the deformable pillar portion ( Anchor structure characterized in that it comprises an electrical resistance strain gauge (54 or 55) attached to the outer surface of the 58 to generate a different electrical signal according to the compression deformation.

Images