KR100545342B1 - a fixing jig for a cylindrical concrete specimens reinforced with fiber sheet - Google Patents

Abstract

The present invention relates to a fixing jig of a compressive strength measuring device for a concrete specimen reinforced with a fiber sheet, more specifically, a plurality of supports (7) and sensor holder 44 is placed on the upper surface of the edge and the lower surface of the specimen A lower fixing plate 4 mounted on the lower fixing plate 4; Fixing jig consisting of; a plurality of elastic rod shaft (3) coupled to the support (7) is formed on the lower surface of the lower fixing plate (4) is installed on the upper side of the lower fixing plate (4) is coupled to the upper surface of the specimen; By providing the jig, it is possible to fix the specimen reinforced with the fiber sheet without damaging the specimen so that the measurement of the compressive strength and physical properties of the specimen can be performed accurately, thereby improving the reliability of the experiment.

Fiber sheet, specimen, compressive strength, fixed jig, LVDT sensor, pressurization, deformation

Description

Fixing jig for compressive strength measuring device for concrete specimen reinforced with fiber sheet {a fixing jig for a cylindrical concrete specimens reinforced with fiber sheet}             

1 is an exploded perspective view showing the structure of the fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention

Figure 2 is a combined perspective view of the fixing jig of the compressive strength measuring device for a concrete specimen reinforced fiber sheet according to the present invention

3 is a cross-sectional view of the fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention

Figure 4 is a perspective view showing an embodiment of a fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention

5 is a perspective view schematically showing an embodiment of a conventional compressive strength measuring device for concrete specimens

* Description of the symbols for the main parts of the drawings *

2: upper fixing plate 3: rod shaft

4: lower fixing plate 5: nut

6: support part 7: support stand

8: coil spring 22: guide stand

24: seating part 26: recessed groove

32; Jam Huck 42: receiving groove

62: fitting 72: round jaw

74: fixing groove 100: pressing portion

110, 130: LVDT sensor 120: vertical bar

200: specimen 250: fiber sheet

The present invention relates to a fixing jig of a compressive strength measuring device for a concrete specimen reinforced with a fiber sheet, and more specifically, to a compressive strength of a test concrete specimen prepared in advance to measure the compressive strength of the concrete structure reinforced with a fiber sheet The present invention relates to a fixing jig of a compressive strength measuring device for a concrete specimen reinforced with a fiber sheet, which is fixed to a measuring device so that the longitudinal displacement of the specimen can be accurately measured through a physical property test.

In general, the concrete column structure supporting the load of the upper structure is designed and constructed to sufficiently support not only the weight of the upper structure but also various live loads (traffic loads, etc.) applied to the upper structure, and loads caused by earthquakes. If the column is destroyed due to the insufficient load capacity of the column, the upper structure formed on the top of the column also fails to destroy, so the load capacity of the column is the load capacity of the upper structure (slab, bridge deck, etc.) formed on the top of the column. have.

The failure pattern caused by insufficient load capacity of the column (corrosion of internal steel due to corrosion of internal reinforcement due to lack of cross section in design or dropping of concrete coating due to neutralization of column concrete after construction) Compression fracture, shear failure, and sectional buckling of pillars are not sufficient, and they are buckling phenomena that occur when pillar lengths are long. These failure patterns are momentary failures (brittle fractures) that cannot be detected in advance, resulting in considerable casualties and economic consequences. Results in loss of phosphorus.

In order to solve the above problems, one of the methods of reinforcing the columnar structure is a column structure reinforcement method using a fiber (carbon fiber or arimid fiber) sheet, which is a fiber sheet or fiberboard outside the concrete columnar structure It is a type of wrapping, it is common to attach the fiber sheet and the like to the columnar structure using an epoxy resin.

Therefore, the repair and reinforcement method of the current structure shows a big difference in the repair and reinforcement performance according to the construction method, the material selection, and the use method. Therefore, it is necessary to identify systematic structural behavior characteristics and to study the effective repair and reinforcement performance improvement methods. will be.

In other words, for this study, a concrete cylinder mold was prepared at the same mixing ratio as that of a concrete structure, and a compressive and tensile force was applied to a specimen obtained by winding a fiber sheet on the outer surface or attaching it with an adhesive. , Bending, shear, torsion, impact, acupressure, fatigue, etc.

Figure 5 is a perspective view schematically showing an embodiment of a conventional compressive strength measuring device (compresso meter) for concrete specimens.

A disk-shaped fixing deck 150 'having a receiving groove on which the specimen 200' is seated is formed on an upper surface thereof, and vertical bars 120 'having a predetermined length are vertically installed on both sides thereof, and the vertical bars At 120 ', the linear variable differential transformer (LVDT) sensor 110', which measures the horizontal displacement of the specimen, is installed, respectively, and its tip is grounded at the outer periphery of the specimen 200 '.

A cover 140 'and a pressing part 100' surrounding the upper portion of the specimen are installed on the upper portion of the fixed deck 150 ', and a plurality of fixing bolts are provided on the outer periphery of the specimen seated on the fixed deck 150'. A fixed ring jig (A ') having a circular ring shape having a 50' was covered, and then the fixing bolt 50 'was tightened to fix the fixed jig A' on the outer periphery of the specimen.

In addition, the LVDT sensor 130 'was fixed to the upper ring of the fixed jig (A') having a circular ring shape in order to measure the vertical displacement, and the tip was grounded to the lower ring.

In addition, a cover 140 'surrounding the upper portion of the specimen and a pressing portion 100' are installed on the upper portion of the fixed deck 150 ', and a plurality of fixed portions are provided on the outer circumference of the specimen seated on the fixed deck 150'. Fixing jig (A ') of the circular ring shape having a bolt (50') is covered and tightening the fixing bolt (50 ') to fix the fixing jig (A') to the outer periphery of the specimen.

As described above, after the specimen is seated on the compressive strength measuring device, a compression test is performed while the pressurizing unit compresses the specimen, and the physical characteristics of the material can be determined from the stress-strain curve by measuring the deformation according to the load increase by the LVDT sensor. In addition, basic physical constants are found and used for structural analysis and design.

By the way, the conventional compressive strength measuring device is intended for simple concrete specimens, and when the compressive strength is tested on a specimen with a fiber sheet attached to the outer surface, the result is unclear.

That is, when the specimen with the fiber sheet is put in the fixing jig and the fastening bolt is fastened, the fiber sheet is punched by the fixing bolt, and the punching shear is used to punch the fiber sheet, resulting in a decrease in strength. will be.

In the case of the fiber sheet reinforced specimen, the strength of resisting the compressive force is dominated by the reinforced fiber sheet rather than the concrete specimen, so that the damage of the fiber sheet by the punching shear eventually affects the compressive strength of the fiber sheet reinforced specimen. It has an adverse effect.

Therefore, when using a conventional jig for compressive strength measurement device when compressive strength (stress-strain diagram) test on the fiber sheet reinforced specimens there is a problem that can not obtain accurate experimental data.

The present invention is to solve the above problems of the prior art, can be securely fixed to the specimen so as not to damage the fiber sheet reinforced on the outer surface compressive strength for the concrete specimen reinforced fiber sheet can measure the exact compressive strength The purpose is to provide a fixed jig of the measuring device.

In order to achieve the above object, the present invention provides a compressive strength measuring device for measuring the compressive strength and physical properties of the specimen, a plurality of support is placed on the upper surface of the lower fixing plate to allow the lower surface of the specimen to be seated on the upper surface; The specimen is reinforced with a fiber sheet by having a fixing jig composed of; an upper fixing plate coupled to the upper surface of the lower fixing plate is formed on the upper side of the lower fixing plate while a plurality of elastic rods are coupled to the support; It can be fixed without damage.

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

In the accompanying drawings, Figure 1 is an exploded perspective view showing the structure of the fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention, Figure 2 is a compression for a concrete specimen reinforced with a fiber sheet according to the present invention Combined perspective view of the fixing jig of the strength measuring device, Figure 3 is a cross-sectional view of the fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention.

According to the present invention, vertical bars 120 having a predetermined height are installed on both sides of a fixed jig A for accommodating the cylindrical specimen 200, and the vertical bars 120 are provided on the side of the specimen 200. An LVDT (Linear Variable Differential Transformer) sensor 130 for measuring horizontal displacement while being contacted is installed, while an LVDT sensor for measuring vertical displacement while being in contact with the upper end of the specimen 200 on the upper side of the fixing jig A ( 130) is installed, and a compression strength measuring device (common name: COMPRESSO METER) for a concrete specimen, which is provided with a pressing part 100 for compressing the upper end of the specimen 200 on the upper portion of the fixing jig (A). Follow the basic configuration.

In the above-described configuration, the present invention is composed of a specimen jig (A) is composed of a disk-shaped lower fixing plate 4 and the upper fixing plate (2) to be raised and lowered by elasticity by fitting to the upper portion of the specimen 200 It is possible to fix only the upper and lower ends of the) to prevent damage to the fiber sheet 250 attached to the outer periphery, and also easy to assemble and disassemble, characterized in that it is easy to use and easy to store.

As shown in FIG. 1, the lower fixing plate 4 has a circular accommodating groove 42 formed therein to allow the cylindrical specimen 200 to be seated on an inner upper surface thereof, and an outer edge of the accommodating groove 42. On the upper side, a support 7 having a round recess 72 formed with a fixing groove 74 at the top, and a sensor fixing stand 44 having a ground portion 46 at the top are formed.

At this time, the specimen 200 is usually manufactured in the same size of 10 × 20 cm, so that the diameter of the receiving groove 42 is made of 10 cm so that the specimen is seated, the specimen is manufactured to 15 × 30 cm as needed If so, the diameter of the receiving groove is manufactured to 15 cm to suit this.

In addition, the sensor holder 44 is the upper surface so that the front end of the lower body 444 and the vertical displacement measurement LVDT sensor 130 is fixed to the outer periphery of the lower fixing plate 4 with a screw portion formed on the outer periphery The flat ground portion 46 is formed on the upper portion, and the upper body 442 having a threaded portion formed on the inner circumference thereof is screwed with the lower body 444 so that the lifting and lowering is possible.

The upper fixing plate 2 is formed in a disk shape to be fitted to the upper end of the specimen 200, the upper surface is formed with a predetermined seating portion 24 is in contact with the pressing portion 100, the outer periphery is measured vertical displacement A cradle 26 is formed to install the LVDT sensor 130 for use, and a circular recessed groove 20 is formed on the inner upper surface so that the upper end of the specimen is fitted (see FIG. 3).

In addition, a plurality of elastic support members (b) are lifted up and down by elasticity while being coupled to the support (7) of the lower fixing plate (4) below the edge of the recess groove (20).

The elastic support member (b) is a guide table 22 having a predetermined length having a hollow portion, a coil spring 8 inserted into the hollow portion 220, and a support portion 6 having a fitting protrusion 62 at a lower end thereof. Is formed, the upper end of the engaging ring projection 32 is formed of the rod shaft 3 is fitted to the inner hollow portion 220 of the guide stand 22.

At this time, the hooking jaw 32 is formed to have a predetermined thickness to widen the contact area between the rod shaft 3 and the guide table 22 to perform a smooth lifting operation, the support portion at the lower end of the rod shaft (3) After screwing (6), the rod shaft 3 is inserted into the guide stand 22, and then the nut 5 is fastened to the lower end of the guide stand 22 to complete the coupling of the elastic support member b. do.

Therefore, when the pressurization operation is made from the upper portion of the upper fixing plate 2, the upper fixing plate 2 can be lowered in proportion to the pressing force so that the deformation of the specimen 200 can be tested, and the pressurizing part 100 is again completed after the experiment. Ascending to the original state was to be restored by the elasticity of the coil spring (8) of the guide (22).

Referring to the operation of the present invention configured as described above is as follows.

After mounting the concrete specimen 200 with the fiber sheet 250 reinforced on the outer periphery and seating in the receiving groove 42 of the lower fixing plate 4, the upper fixing plate 2 is placed on the upper portion of the specimen 200. The elastic support of the upper fixing plate 2 is fitted so that the fitting protrusion 62 formed at the end of the supporting portion 6 of the rod shaft 3 is fitted into the fixing groove 74 formed in the annular 72 of the support 7. Fit the support member (7) of the member (b) and the lower fixing plate (4).

Thereafter, the horizontal displacement measurement LVDT sensor 110 is installed on the side of the specimen 200, and the vertical displacement measurement LVDT sensor 130 is installed on the cradle 26 of the upper fixing plate 2 in the same manner as the conventional test method. Then, the pressing unit 100 is operated to measure the deformation data while pressing the specimen 200.

When the test part is finished and the pressing part 100 rises to the original state, the upper fixing plate 2 of the fixing jig A rises by elasticity and returns to the original state, and the upper fixing plate 2 of the upper fixing plate 2 The support member 7 of the elastic support member b and the lower fixing plate 4 may be separated and stored.

As described above, the fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet according to the present invention can be securely fixed to the specimen so as not to damage the fiber sheet reinforced on the outer surface compression through experiment Accurate measurements of strength and property change data provide useful effects that can improve the reliability of your experiments.

Claims (3)

Vertical bars of a certain height are installed on both sides of the fixed jig for accommodating the cylindrical specimens, and the vertical bars are installed with a linear variable differential transformer (LVDT) sensor that measures horizontal displacement while being in contact with the sides of the specimens. Meanwhile, the upper side of the fixing jig is provided with an LVDT sensor for measuring vertical displacement while being in contact with the upper end of the specimen, and a compression part for compressing the upper end of the specimen is installed on the upper portion of the fixing jig. In the measuring device, The fixing jig, The upper surface is formed with a predetermined seating portion 24 is in contact with the pressing portion 100, the outer peripheral edge is formed with a cradle 26 to install the LVDT sensor for vertical displacement measurement, the upper surface of the specimen is fitted on the inner upper surface An upper fixing plate (2) having a circular concave groove (20) formed to be formed, and a plurality of elastic support members (b) being lowered by elasticity at the lower edge of the concave groove (20);  Receiving groove 42 is formed in the recess so that the specimen 200 is seated on the inner upper surface, and the support (7) coupled to the elastic support member (b) on the outer edge side of the receiving groove 42 A lower fixing plate (4) having at least one sensor fixing member (44) having a ground portion (46) formed at an upper portion thereof and having an upper body (442) and a lower body (444) screwed thereto; Fixing jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet, characterized in that it comprises a. The method of claim 1, wherein the elastic support member (b) is a guide length 22 having a predetermined length having a hollow portion 220, the coil spring (8) inserted into the hollow portion 220, the lower end is fitted A support part 6 having a protrusion 62 is formed, and a locking ring jaw 32 is formed at an upper end thereof, and includes a rod shaft 3 fitted to the inner hollow part 220 of the guide stand 22. Fixed rod of the compressive strength measuring apparatus for a concrete specimen reinforced with a fiber sheet, characterized in that the rod shaft (3) is raised and lowered by the elasticity of the coil spring (8) and the pressing force of the pressing portion (100). The method of claim 2, The support 7 is a fixed jig of the compressive strength measuring device for a concrete specimen reinforced with a fiber sheet, characterized in that the upper projection 72 is formed with a recessed groove 72 is formed in the upper portion of the fitting groove 62 is fitted. .

Images