KR200217820Y1 - Compression tester of concrete - Google Patents

Abstract

The present invention uses a compression pad and a compression ring made of synthetic rubber to measure the compressive strength of concrete specimens. As a result, the compressive strength can be measured quickly and accurately without processing the upper and lower surfaces of the concrete specimens. The present invention relates to a crimping member for measuring the compressive strength of concrete specimens that can reduce the material cost and labor cost according to capping when measuring the compressive strength of concrete specimens. In the concrete specimen compressive strength measuring instrument that combines the hydraulic cylinder and the lower pressing plate to be driven upward and downward by height and the upper and lower directions by a certain height, the compression ring installed at the center of the upper structure and the lower structure A recessed groove having a constant depth is formed in the pressing groove As the rod is inserted and the crimping member and the concrete specimen are combined, even if both sides of the cured concrete specimen are not coarse and flat, stress concentration on part of the compression can be prevented and the work for measurement is simple, easy and quick. It is economical because it can be used semi-permanently as well as accuracy.

Description

Compression member for compressive strength measurement of concrete specimens {COMPRESSION TESTER OF CONCRETE}

The present invention relates to a crimping member for measuring the compressive strength of a concrete specimen, and more specifically, to measure the compressive strength of the concrete specimen, by using a crimp pad made of synthetic rubber and a steel crimp ring, the upper and lower parts of the concrete specimen Compression member for measuring the compressive strength of concrete specimens that can measure the compressive strength quickly and accurately without additional processing and semi-permanently reuse them to reduce materials and labor costs according to the measurement of the compressive strength of concrete specimens. It is about.

In general, the structure should be constructed using concrete, rebar, and a variety of materials, and therefore have durability, watertightness, and safety.

Since the concrete used in the construction of the structure must maintain the appropriate compressive strength according to the characteristics of the structure to be constructed, the compressive strength measurement of the concrete before and after the construction of the structure must be carried out.

A measuring device for measuring the compressive strength of concrete is already widely used. As a capping method when measuring the compressive strength using concrete specimens, a capping method using cement paste, a capping method using a powdered sulfur compound (compound), and a polishing machine And the compressive strength measurement by the concrete specimen capping method by the grinding method using the abrasive stone is made, this measurement method will be described by the accompanying drawings as follows.

1 is a front schematic view for explaining a compressive strength measurement of a conventional concrete specimen, by measuring the compressive strength of the concrete specimen (C) using cement paste capping, the handle installed on the upper portion of the body portion 10 (12) to be driven upward and downward by a predetermined height by the upper compression plate 14 and the lower compression cylinder 16 coupled to the lower and upper direction by the screw 13 according to the operation to be driven in a vertical direction. Positioning the separately cured concrete specimen (C) between the combined lower pressing plate 18 to measure the compressive strength of the cured concrete specimen (C), Figure 2 shows the compressive strength of another conventional concrete specimen Front schematic diagram showing the measuring device, the upper pressing plate 14 coupled to be driven in a vertical direction by a predetermined height by a screw according to the operation of the handle 12 installed on the upper portion of the body portion 10 By measuring the compressive strength by placing the cured concrete specimen (C) separately between the lower pressing plate 18 coupled to be driven in the up and down direction by a predetermined height by the compression cylinder 16 in the lower portion, Sulfur compounds (W) solidify on both sides of the concrete specimen (C) to maintain the plane when measuring the compressive strength.

However, the following problems occur in the measurement of the compressive strength of the concrete specimen using the conventional concrete specimen compressive strength measuring device as described above (see FIGS. 1 and 2).

First, as shown in FIG. 1, when measuring the compressive strength of a concrete specimen using an auxiliary crimp plate without capping the concrete specimen, both sections of the cured specimen are not evenly flat, so that stress on a part of the compression As the concentration occurs, accurate compressive strength measurement cannot be made. Therefore, the capping method must be provided by separate processing at all times. Therefore, the workability is inferior and the work time is reduced and the continuous and repeated replacement of the auxiliary pressing plate is inefficient. As shown in FIG. 2, in order to measure the compressive strength of the concrete specimen using sulfur compounds, a separate dissolution mechanism for dissolving sulfur compounds and a ventilation device for ventilation are required. It is burdened by the equipment and harmful to human body. Since sulfur is used, not only is it harmful to the user's safety accidents and health, but also has a wasteland that environmental pollution is contaminated by sulfur compounds discarded after use.

On the other hand, as described above, as a method for measuring the compressive strength of a concrete specimen without using a cement paste or a sulfur compound, a method of grinding both sides of the specimen using a grinder and abrasive stone is used. Problems have arisen.

First, separate grinding equipment is required to grind both sides of the cured specimen.

Second, the grinding machine and abrasive stone used in the grinding are relatively expensive.

It is not economical because set materials and abrasives are easily worn and their lifespan is short, requiring frequent replacement.

Therefore, the above-mentioned compressive strength measuring device requires a separate processing work and expensive equipment, so it is not efficient due to poor workability, and requires a lot of processes, materials and working time according to the measurement, and it is not economical as well. There are common problems that are harmful to people and the environment.

The present invention is to solve the conventional problems as described above, the purpose is to measure the compressive strength of the concrete specimen, by using a compression pad and the compression ring made of synthetic rubber having elastic force, the cured concrete specimen Even if both sides are not rough and flat, it is possible to prevent stress concentration on the part during compression, and it is economical and environmentally friendly because it can be used semi-permanently as well as easy, easy, quick and accurate measurement work. It is to provide a compression member for a compressive strength measuring instrument of the specimen.

In order to achieve the above object, the present invention is a screw is installed to be driven up and down by a certain height by a handle operation installed on the upper portion of the body portion and to be driven up and down by a certain height by a compression cylinder in the lower portion In the compressive strength measuring device of the concrete specimen coupled to the lower pressing plate, a seating groove having a predetermined depth is formed in the center of the screw and the lower pressing plate is characterized in that the pressing member is inserted into the pressing pad.

1 is a front schematic view showing a compressive strength measurement of a conventional concrete specimen,

Figure 2 is a front schematic view showing a compressive strength measurement of another conventional concrete specimen,

3 is an exploded perspective view showing a pressing member for compressive strength measuring device of a concrete specimen according to the present invention,

4 is a front schematic view showing a compressive strength measuring device of a concrete specimen with a pressing member according to the present invention,

FIG. 5 is an enlarged cross-sectional view of part A of FIG. 4.

<Explanation of symbols for main parts of the drawings>

30: pressing member 32: seating groove

34: Crimping pad 36: Crimping ring

40: A body part 42: A steering wheel

44: screw 46: crimping cylinder

48: lower pressing plate D: pressing pad diameter

d: concrete specimen diameter

C: concrete specimen

Hereinafter, the present invention in more detail by the accompanying drawings as follows.

3 is an exploded perspective view showing a compressive member for measuring the compressive strength of the concrete specimen according to the present invention, the seating groove 32 having a predetermined radius of curvature D and depth is formed in the center of the upper surface and the pressing pad ( 34) is combined.

At this time, the pressing pad 34 is made of synthetic rubber having a predetermined elastic force.

4 is a front schematic view showing a compressive strength measuring device of a concrete specimen equipped with a pressing member according to the present invention, so as to be driven up and down by a predetermined height by operating a handle 42 provided with a screw 44 on an upper portion of a body part. And a pressing member having a pressing pad 34 and a pressing ring 36 in the concrete compressive strength measurer to be driven upward and downward by a predetermined height by a pressing cylinder 46 having a pressing plate 48 coupled thereto. 30) is installed.

At this time, the pressing member 30 is coupled to the screw 44 and the lower pressing plate 48 of the compressive strength measurer while being spaced a predetermined distance apart, and the pressing member 30 is a pressing pad inserted into the seating groove 32. (34) takes the opposite position on the same center line and the cured concrete specimen (C) is fixed to both sides are pressed by each pressing pad 34, the pressing member 30 the distance between the concrete specimen ( According to the size (height and diameter) of C) is set to an appropriate separation distance and the separation distance adjustment is set by the rotation of the screw 44 according to the handle 42 operation.

FIG. 5 is an enlarged cross-sectional view of part A of FIG. 4, in which the concrete specimen C is compressed by the pressing member 30 coupled to the screw 44, and both surfaces of the concrete specimen C are rough and flat during curing. Even if not, since the front surface is evenly contacted by the elastic force of the compression pad 34 made of synthetic rubber, it indicates that the concentrated stress generated on a part is solved.

At this time, the diameter D of the pressing pad 34 of the pressing member 30 is about 6 mm larger than the diameter d of the concrete specimen (C).

In the drawings, reference numeral 50 denotes a control panel, and 52, 54, and 56 denote switches.

Referring to the use state of the present invention as follows.

3 to 5, the compressive strength of the concrete specimen (C) is cured by using the pressing member 30 is inserted into the pressing pad 34 made of synthetic rubber is formed with a mounting groove 32 In order to measure, first, the pressing member 30 is coupled to the lower end of the screw 44 of the concrete compressive strength measuring instrument to be driven up and down by operating the handle 42, and then the other pressing member C is moved. It is installed on the upper surface of the lower pressing plate 48 coupled to the pressing cylinder 46 of the concrete compressive strength meter.

In this state, the concrete specimen (C) to measure the compressive strength, as shown in Figure 4, the upper end is to be in close contact by the pressing pad 34 of the pressing member 30 coupled to the screw 44 and the lower end When it is fixed to be in close contact by the pressing pad 34 of the pressing member 30 coupled to the lower pressing plate 48, the preparation for measuring the compressive strength of the concrete specimen (C) is completed.

At this time, when the size of the concrete specimen (C), that is, the height is too high or too low, the handle 42 may be turned in one direction to adjust the distance between the pressing members 30.

In this way, when the preparation for measuring the compressive strength of the concrete specimen (C) is completed, when operating the switch 52 installed in the control unit 50 to drive the compression cylinder 46, by the compression cylinder 46 As the compression plate 48 is raised to compress the concrete specimen C, the compression process and the compressive strength measurement process of the concrete specimen C by the compression cylinder 46 are well known techniques, and thus detailed descriptions thereof will be omitted. do.

As such, when the concrete specimen C pressed by the pressing member 30 exceeds its own compressive strength allowable range, the concrete specimen C is broken by the pressing force of the pressing cylinder 46, and the concrete specimen C is broken. ) Is measured in the state that both sides are not processed flat, and even when both sides are not processed, that is, accurate measurement is made even in a rough and uneven state, as shown in FIG. Since the contact pad is made to be evenly distributed by the compression pad 34 made of a whole to prevent the stress concentration phenomenon.

Meanwhile, the compressive strength measured by the conditions using the concrete specimen cured under the same conditions using the capping method for the concrete compressive strength measurement using the pressing member according to the present invention and the conventional concrete compressive strength is shown in Table 5 and below. same.

Table 5. Compressive strength by condition

Rebirth (Sun) Comparison of Compressive Strength Test Values (㎏ / ㎠)-Standard Curing, Planar Condition No treatment cement Crimp Pad grinding Sulfur compounds One 84 106 96 105 108 3 158 184 175 186 195 7 205 283 280 269 277 14 291 281 332 321 337 28 340 306 387 369 390 56 339 356 417 405 428 91 375 396 462 474 464

Therefore, as shown in Table 5, the test value of the compressive strength using the compression pad according to the present invention can be seen that the results of the method by the polishing method and the sulfur compound is almost similar.

Thus, by measuring the compressive strength of the concrete specimen by using a pressing member having a pressing pad having a predetermined elastic force, even if both sides of the cured concrete specimen is not rough and flat, it is possible to prevent stress concentration on part of the compression during compression. It is economical because it can be used for measurement and easy, easy, quick and accurate as well as semi-permanent.

Claims (1)

By operating the screw 44 and the handle 42 installed in the upper portion of the body portion 40 to be driven up and down by a predetermined height, the lower portion is fixed by the pressing cylinder 46 to which the lower pressing plate 48 is coupled. In the compressive strength measuring device of the concrete specimen to drive up and down by the height, In the center of the screw 44 and the lower pressing plate 48 is formed with a pressing groove 30 having a predetermined depth and a pressing pad 34 is inserted into the mounting groove 32 is characterized in that it is provided with Compression member for compressive strength measuring of concrete specimen.