KR20020075848A - The face hitting rebound test method for nondestructive test of concrete compressive strength - Google Patents

Abstract

PURPOSE: A surface striking repulsive force testing method is provided to easily and accurately estimate strength of concrete structure, while achieving improved efficiency of test by reducing labor and time taken for the test. CONSTITUTION: A surface striking repulsive force testing method comprises a step of installing a repulsive force tester perpendicular to a concrete surface(2) by allowing an impact plunger(1) to tightly contact the concrete surface; a step of compressing the repulsive force tester such that a compression spring(5) arranged within the repulsive force tester is compressed to push a hammer(9), and permitting the compression spring to transmit motion energy to the hammer by allowing a stopper(8) supporting the compression spring to be released; a step of permitting the hammer to strongly strike the impact plunger by the force of the compression spring; a step of permitting the impact plunger to transmit impact force to the concrete; a step of allowing the repulsive force of the concrete to be transmitted to the impact plunger and allowing the repulsive force to be transmitted to an impact spring(10); a step of moving an indicator(4) of a guide rod by allowing the hammer to be pushed upward by the action of the impact spring and allowing the hammer to spring upward to the level corresponding to the repulsive force of the concrete; and a step of stopping the indicator by pressing a button(6), reading data from a scale board(11) and recording the read data.

Description

The face hitting rebound test method for nondestructive test of concrete compressive strength}

The present invention is to determine the degree of concrete homogeneity or the degree of deterioration of the existing concrete structure, and to measure the change of concrete over time after the concrete is placed in the construction site and predict the time of demolishing formwork and scaffolding accordingly In order to estimate the compressive strength of concrete in the non-destructive test used for the purpose of the present invention.

Recently, the maintenance and reinforcement technology of the structure has been made a lot of materials and methods, and the development of new technology is steadily being made. However, the diagnosis techniques that should be preceded by such reinforcement reinforcement techniques have been applied to the conventional techniques developed in the past 1950 ~ 1960 as they are. Focusing on the convenience of the situation.

Currently, the nondestructive testing method for estimating the compressive strength of concrete has been widely used for measuring the surface repulsion by Schmidthammer and the ultrasonic test using ultrasonic waves.

Among them, the measurement of surface repulsion using the Schmidt hammer estimates the compressive strength by measuring the rebound amount by the hammer in the interior hitting the impact flanger by the compression of the spring. At this time, the end of the impact flanger is processed into a curved surface, so the hitting using the Schmidt hammer is basically introduced the concept of point hitting.

Since Schmitthammer has a small hitting point, the impact force is not transmitted to the inside of the concrete, so it is not only to measure the repulsive force of the concrete material, but also to measure the repulsive force of the concrete surface. Therefore, the integrated measurement of concrete as a cement composite is not made and the average of the measured data at each point is regarded as the resilience of concrete. In other words, the measured value in the presence or absence of aggregate on the concrete surface means that there is a deviation, and finally, the estimation of compressive strength with partial surface repulsion of concrete has a problem that the correlation is deteriorated. It is not there.

In addition, since Schmitthammer has a small impact point, if the foreign matter is stuck on the concrete surface, the measurement error is very large. However, many concrete structures are often coated with cement paste or finished with paint, so when measuring surface resilience for these areas, it is difficult to remove cement paste or paint, but in reality it is difficult to completely remove it. Even if it is completely removed, there is a problem that it must be repaired after measurement.

In particular, the Schmidt hammer is a deviation of the measurement value depending on the shape and properties of the concrete surface to be hit, the presence of aggregate, the presence of rebar, the degree of processing of the impact surface. In order to reduce the error of these measurements, about 20 multi-point strikes are carried out. Therefore, there is a problem that a lot of effort has been administered to obtain data on the measurement surface.

In addition, in the case of Schmidt hammer, the measured value changes according to the angle of attack. When hitting at right angles, hitting 45 °, hitting -90 °, the measured value changes, and the measured value changes at the same time as the angle changes little by little. At present, an auxiliary device has been developed to maintain the angle of the Schmitthammer hitting, but it is cumbersome and inconvenient in use, and is not used in reality, and most hitting is carried out depending on the user's sense. Therefore, in the actual concrete resilience measurement work, an error occurs in the blow angle little by little each time the strike, and when the change of the angle occurs in this way, the reliability of the data is degraded. This is a problem that occurs because it is difficult to maintain a constant measuring angle since the Schmidt hammer is basically a point hitting.

In order to solve the problems described above, the present invention constitutes the shape of the impact flanger of the resilience tester for estimating the compressive strength of concrete, and increases the compressive force by increasing the compressive force by increasing the diameter of the compression spring and reducing the number of turns. Increasing surface hitting rebound tester enables to measure the integrated repulsion of concrete composites, and to easily estimate the compressive strength of concrete in existing concrete structures or construction sites through non-destructive testing methods It is an object of the present invention to provide a resilience test method.

Important technical tasks required to achieve this purpose include the following.

(1) Measurement of resilience suitable for material properties of concrete

(2) Maintaining the angle of blow for accurate concrete rebound measurement

(3) Reduction of effort and time required for concrete compressive strength peeling test

In the case of (1), each component of concrete, which is a cement composite, should be included in the resilience measurement site at the same time so that the compressive strength performance of the integrated concrete can be measured. Therefore, the present invention is to measure the integrated resilience in consideration of the material properties of the concrete as a cement composite using a surface strike repulsion tester formed in the plane of the impact flanger of the repulsion tester as shown in FIG. There is a characteristic.

In the case of (2), the impact flanger forms a flat surface that can be in close contact with the concrete surface. There is a characteristic that an error of data does not occur due to a change in angle.

In the case of (3), the surface repulsion tester can measure the resilience considering the material properties of concrete, thereby reducing the measurement error of the rebound test, and measuring the resilience against the non-dot surface. This makes it possible to conduct repulsion tests on a larger area. As a result, it is possible to reduce the number of hits, which is characterized by reducing the effort and time required for non-destructive testing of concrete compressive strength.

1 is a cross-sectional view of the surface impact repulsion tester and a cross-sectional view of the impact flanger

Figure 2 is a blow conceptual view of the surface hitting rebound tester

3 is a stress distribution diagram of the surface impact repulsion tester

Figure 4 is an elevation and top, bottom plan view of the impact flanger of the surface impact repulsion tester

5 is a surface hitting repulsion tester installation

6 is an exemplary view illustrating a measurement method of a surface strike rebound tester

<Explanation of symbols for main parts of drawing>

1. Impact flanger 2. Concrete surface

3. Housing 4. Instructions and guide rod

5. Compression spring 6. Pushbutton

7. Back cover 8. Detent

9. Hammer 10. Impact spring

11.Diameter Plate 12.Felt Washers

Hereinafter, the technical configuration of the present invention will be described in detail with reference to the accompanying drawings shown in FIGS. 1 to 6.

Figure 1 (a) is a cross-sectional view of the inside of the surface impact repulsion tester according to the present invention showing the name and configuration of the components, (b) is a view showing a cross section of the impact flanger formed of the surface. The face impact repulsion tester shown in (a) is made of a cylindrical body surrounded by a rear cover 7 and a felt washer 12 and a housing 3 for receiving components therein and a rear portion of the housing 3. A compression spring 5 mounted on the support spring 5 and a detent 8 for supporting the compression force generated by the compression spring 5 to a predetermined position and driving the compression force 5 and the compression spring 5 The hammer (9) and the impact force of the hammer (9), which is operated by the compression force generated by the action of the impact force to the impact flanger (1), is brought into close contact with the concrete surface (2), and thereby It is possible to detect the resilience of the generated internal stress, and it is formed as a face to maintain the right angle with the concrete surface (2) at all times to prevent errors due to the change of the measurement angle when measuring the resilience. Impact spring (10) for impact measurement (1) formed in the face and the impact flanger (1) formed in the face is transmitted to the hammer (9) to push the hammer (9) back up to enable accurate measurement of repulsion Instructions (4) and by the instructions to operate the hammer (9) pushed up by the force of the impact spring (10) to indicate the degree of rebound of concrete to recognize the data When reading the size of the scale plate 11 and the scale plate 11 to indicate the size of the data collected to temporarily fix the guide (4) so that the position of the guide (4) does not change according to the state of the rebound tester The push button 6 is shown.

2 (a), (b), (c) illustrates the concept of hitting the surface repulsion rebound tester step by step compression spring (5) and hammer (9), impact spring (10) and impact flanger (1) The relationship between the concrete surface 2) and the concrete surface 2 is shown by the compression action by the compression spring 5 and the degree of compression force, and the impact spring 10 transmits the impact force.

(A) of FIG. 3 shows a stress distribution diagram in which the impact force of the existing repulsion tester is transmitted into the concrete, and the concrete resists it. It shows the stress distribution that resists this. Existing repulsion tester measures the repulsion of concrete by the point hitting, so it hits the part formed with cement compound and the part with coarse aggregate separately and measures the repulsion by the average value and is transferred to the inside of concrete. The degree of force also has a very small range. On the other hand, the surface impact repulsion tester measures the resilience of the concrete by the surface strike, so that the force is transmitted to the wide and deep parts of the concrete and the stress distribution is formed. You can measure it.

Figure 4 (a) is an elevation view of the impact flanger (1) of the surface impact repulsion tester, (b) is a top plan view of the impact flanger (1), (c) is a bottom plan view of the impact flanger (1) The lower part is machined to face the impact flanger (1) part of the tester to measure the resilience of the concrete by the impact force of the compression spring (5). When closely contacted for over-measurement, it is possible to maintain the right angle at all times to prevent errors due to the change of the measured angle when measuring rebound and to measure accurate rebound.

Figure 5 (a) and (b) shows the installation of the surface impact repulsion tester provided with the impact flanger (1) formed of the surface.

Figure 6 shows how to measure the resilience of the concrete using such a surface strike repulsion tester. (a) and (b) are conceptual diagrams showing the measurement method, and the figures (c) to (f) show the actual measurement. The measurement method will be described with reference to the names of the parts specified in FIG. 1. As shown in FIGS. 6A and 6B, the impact flanger 1 formed as a surface is brought into close contact with the concrete surface 2 to be measured. Mounting the repulsion tester at right angles to the concrete surface (2) and compressing the repulsion tester to push the hammer (9) while the compression spring (5) inside the rebound tester contracts, detent (8) The compression spring 5, which was supported by the step, causes the detent 8 to be released and transmit kinetic energy to the hammer 9, and the hammer 9 is forced by the force of the compression spring 5 to the impact flanger 1 ) Strong impact and the impact flanger (1) hit by the hammer (9) to transmit the impact force to the concrete and the impact resilience inside the concrete is transmitted to the impact flanger (1) the impact spring (10) ) And the impacts The action of the ring 10 pushes up the hammer 9, moves the guide 4 on the guide rod 4 and pushbutton 6 as the hammer 9 springs up by the repulsive force of the concrete. Press to fix the guide (4) and read the data of the scale plate 11, and then recording the step of measuring the resilience of the concrete using a surface blow repulsion tester.

As described above, when the surface strike repulsion test method using the surface strike repulsion tester according to the present invention is applied to the concrete compressive strength nondestructive test, the resilience of the concrete due to the surface strike is measured so that the material of the concrete of the cement composite By reflecting the specific properties in the test data, it is possible to measure the concrete resilience as an integrated material, and by simultaneously measuring the cement compound part and the coarse aggregate part of the concrete at the same time, it is necessary to strike several times to average the rebound degree data. Save time and effort.

In addition, since the repulsion is measured by the surface strike, the impact force transmitted by the surface strike is transmitted to the deep part of the concrete, so that a wider range of the repulsion can be measured, so that the state of the structure can be accurately and accurately measured. Can be.

As described above, the present invention, by forming a shape of the impact flanger of the rebound tester for estimating the compressive strength of the concrete to the surface, the compression force is increased by increasing the compressive force by increasing the diameter of the compression spring and reducing the number of points It relates to a surface hitting rebound test method using a surface hitting repulsion tester.

According to the present invention is expected to have the following effects in technical and economic aspects.

Technically, inventing the surface impact resilience test method using the advanced surface impact repulsion tester, unlike the existing test method using the point impact repulsion tester, enables the nondestructive test suitable for the material properties of concrete. It was. Accordingly, it is possible to clarify the analysis of the performance of concrete structures and the determination of the quality, so that the judgment on the reinforcement and dismantling of existing structures can be made accurately. It has the effect of making scientific analysis possible.

In economic terms, it is possible to secure economic feasibility by shortening the effort and time required for the rebound test and increasing the efficiency of the measurement, thereby reducing the input of technical manpower required for the diagnosis of the structure.

Claims (1)

In the resilience test method for evaluating the performance and quality of concrete, Step of mounting the resilience tester at a right angle to the concrete surface (2) in close contact with the concrete surface (2) to measure the impact flanger (1) formed of the surface: The repulsion tester is compressed to compress the spring (5) inside the repulsion tester to push the hammer (9), and the compression spring (5) supported by the detent (8) is detent (8) And release the kinetic energy to the hammer (9). The hammer 9 hitting the impact flanger 1 strongly by the force of the compression spring 5; The impact flanger (1) hit by the hammer (9) and transmitting the impact force to the concrete and: Repulsive force is transmitted to the impact flanger (1) inside the concrete to transfer the repulsive force to the impact spring (10) and: Pushing up the hammer (9) by the action of the impact spring (10) and moving the instructions (4) in the guide rod (4) as the hammer (9) springs up by the repulsive force of concrete; After pressing the push button 6 to fix the guide (4) and read the data of the scale plate 11, and recording the step: Concrete repulsion measuring method, characterized in that using a surface strike rebound tester including .