KR101532297B1 - Apparatus and Method for tensile strength test of early age concrete - Google Patents

Abstract

In the present invention, a hollow portion filled with mortar is formed therein, a demarcating portion capable of being attached and detached is formed at a central portion thereof to expose the mortar to the outside at the central portion, and a rounded portion protruding from both sides of the central portion of the hollow portion to reduce the width of the filled mortar And an initial age tensile test apparatus and method equipped with the tensile mold.

Description

TECHNICAL FIELD [0001] The present invention relates to a tensile mold, an early-age tensile test apparatus,

The present invention relates to a tensile mold, an early age tensile test apparatus and a method capable of obtaining tensile properties such as an accurate tensile strength and an elastic modulus at an early age.

 Unlike other construction materials, concrete tends to decrease in volume due to hydration reaction and drying of mixed water. When concrete shrinkage is restrained by internal and external constraint factors (formwork, reinforcing bars, aggregates, etc.) Which is likely to cause cracking due to shrinkage and restraint. This shrinkage crack occurs when the restraint tensile force generated by shrinkage restraint exceeds the tensile strength of concrete. However, the tensile strength of concrete, which is the critical value of shrinkage cracks, that is, the early age tensile strength and tensile elastic modulus of concrete, is difficult to measure before demolding the mold, and even if the mold is demolded, Or a jig for measuring the tensile strength can not be installed. Therefore, it is not easy to estimate and predict the possibility of shrinkage cracking and timing in concrete.

Recently, some researchers have tried to estimate non-destructive tests such as Ultrasonic Pulse Velocity (UPV) method and rebound hardness method. However, reliability is lower than that measured by mechanical method, And the rebound hardness, it is difficult to measure the tensile strength in the above-mentioned early age.

Korean Patent Registration No. 10-0888385

SUMMARY OF THE INVENTION It is an object of the present invention to provide a tensile mold, an experimental apparatus, and a method capable of accurately deriving a tensile characteristic according to a mechanical method even at an early age of concrete.

As a means for solving the above-mentioned problems, a tensile mold according to the present invention includes a space portion filled with mortar therein, and a depression portion capable of being attached and detached is formed at a central portion thereof, so that the mortar is exposed to the outside when the depression- .

In addition, on both sides of the central portion of the space, a round protrusion is formed to reduce the width of the protruded and filled mortar so that cracks due to stress concentration are induced in the central portion of the mortar.

More specifically, the tensile mold includes a pair of units formed with openings at one side thereof and formed with protrusions so that the width of the openings is narrowed, and a second protrusion formed between the units and inside the protrusion, And a demolding portion formed at both ends with a fastening plate fastened to the outer circumference of the unit, respectively.

The present invention also discloses an early age tensile test apparatus in which the demoulding unit is mounted in a detached state in the tensile mold.

The initial tensile test apparatus includes a support having protruding supports at both ends thereof, a pair of slide plates which are slid on a guide bar at the top of the support and are respectively fastened to the units, and both ends of the tension mold, And a load applying means for applying a tensile load to the tension bar.

The load-carrying means comprises a vertically-lowering inlet and a horizontal bar connecting the tension bar to the tension bar through a transmission means to transmit the tensile load to the tension bar, Allow the load to be introduced.

The conveying means includes a pair of frames arranged in a downward direction from the one end of the horizontal bar, a roller having an upper and a lower gap formed between the frames, and a conveying bar slidably connected to the tension bar and connected to the tension bar. .

In addition, a load cell is attached to the tension bar, and a deformation cell is attached to a part where the de-molding part is detached between the units, so that tensile stress and deformation rate due to tensile load can be measured.

The initial age tensile test method of the present invention comprises the steps of filling the tensile mold with mortar; Detaching the demolding portion from the tensile mold and mounting the demolding portion on the initial age tensile testing apparatus; And a step of loading the tensile load.

As described above, tensile mold, initial tensile tensile test apparatus and method according to the present invention induce tensile cracks in a certain portion due to the structure of tensile mold even at the initial stage of concrete pole (coagulation time) It is possible to measure the tensile strength and the elastic modulus by eliminating the noise, and it is possible to grasp the tensile characteristics of the early age of concrete pole.

1 is an exploded perspective view of a tensile mold of the present invention,
FIGS. 2A and 2B are plan views showing an operating state of the tensile mold of the present invention,
3 is a schematic view of an early age tensile test apparatus of the present invention,
Fig. 4 is a side cross-sectional view showing the transmission means in the early age tensile test apparatus of Fig. 3,
5 is a block diagram showing an initial age tensile test method of the present invention.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

As shown in FIG. 1, the tensile mold 100 of the present invention includes a space 110 in which a mortar is filled in a container shape having an opened upper surface, and a defor- mation part 120 is formed at a central part thereof And the mortar is exposed to the outside at the central portion when the demolding portion 120 is detached. Particularly, the tensile mold 100 is characterized in that a round protrusion 130 protruding from both sides of the central portion of the space 110 to reduce the width of the filled mortar is formed.

As shown in FIG. 2A, the mortar m is filled in the space 110, and the mortar m filled with the structure of the round protrusion 130 has a narrow width at the center thereof. So that a groove is formed. Next, as shown in FIG. 2B, the mortar m is exposed at the central portion at the time of detachment of the demolding portion 120. The central portion of the filled mortar m is exposed to the outside. Thus, when the tensile load F is applied to the tensile mold 100, the stress is concentrated at the exposed portion so that the crack c is induced. In other words, the tensile strength and the tensile elastic modulus can be measured by inducing a crack in a certain portion. In this measurement, too, by the detachment of the deformed portion 120 at the portion where cracks occur, Since there is no noise such as friction, it is possible to obtain accurate measurement value, and the mortar (m) is exposed only in a narrow part of the width, thereby preventing deformation due to the self weight of the mortar (m) will be.

1, the tensile mold 100 includes a pair of units 140 and a deformable portion 120. The tensile mold 100 has three segments, as shown in FIG.

The unit 140 has an opening formed at one side thereof and a protrusion 141 is formed at the opening to narrow the width of the opening 140. The unit 140 is formed as a pair and the deformed portion 120 is disposed therebetween to form the tensile mold 100 . The pair of units 140 are mounted on the slide plate 220, which will be described later, in a state where the demolding portion 120 is detached, and act as a segment for applying a tensile load to the mortar m, respectively.

The demolding portion 120 is formed with a second protruding portion 121 which forms a round protruding portion 130 in the form of a "C" -shaped cross section and communicates with the protruding portion 141, And a fastening plate 122 fastened to the periphery of the fastening plate 122. The tightening of the fastening plate 122 and the unit 140 is performed by bolt connection (not shown). In other words, the defective portion 120 is disposed between the units 140, and the space portion 110 is formed inside each of the defective portions 120. The deflected portion 120 is detachably attached to the second protruding portion 121, (Not shown in the drawing) of the mortar m is exposed to the outside.

The present invention also discloses an early-age tensile test apparatus 200 in which the tensile mold 100 is mounted. The early-age tensile test apparatus 200 will be described in more detail with reference to FIG. 3, A pair of slide plates 220 slidable in a guide bar 222 on the pedestal 210 and fastened to the unit 140, A pair of tension bars 230 connecting both ends of the tension bar 230 and the support table 211 and load tension means 240 and 250 on the tension bar 230.

The pedestal 210 corresponds to a structure in which the guide bar 222 is mounted on the upper surface and the pedestal 211 is protruded at both ends.

The slide plate 220 is formed in a pair so that a pair of units 140 are fastened to each other in the tension mold 100. A slide hole 221 is formed on the lower surface of the slide plate 220, 221 are mounted on the guide bar 222 to be slidable. The configuration for allowing the slide member 221 to be mounted and slid by the guide bar 222 may be configured in various manners, and a description thereof will be omitted. In this way, the slide plate 220 can be integrally moved with the unit 140 so that the tensile load applied to the unit 140 can be accurately derived without being affected by the frictional force at the lower surface. Although the unit 140 and the slide plate 220 are not shown in the drawings, the unit 140 can be fastened and fixed on the slide plate 220 by bolt coupling or the like so that the unit 140 and the slide plate 220 can be easily attached and detached. do.

The tensile bar 230 is formed of a pair so as to connect both ends of the tensile mold 100 and the support 211. Both ends of the tensile mold 100 (one end of the unit 140) Both ends of the tension bar 230 are connected to the couplers 231 and 232 formed in the coupling portion 211 by a fitting method. The tension bar 230 is configured to transmit a tensile load applied by the load-carrying means 240 and 250 to each unit 140. The tensile bar 230 transfers the tensile load applied to each unit 140, A tensile load is applied in the opposite direction and the tensile load concentrates the stress on the portion of the mortar m exposed in the tensile mold 100 to induce cracking.

The vertical barrel 241, the horizontal bar 242, the transmitting means 250, and the vertical barrel 242 are provided as means for applying a tensile load to the tension bar 230, .

The vertical load-lowering mouth 241 is configured to apply an upper load to one end of the horizontal bar 242, and a conventional UTM (Universal Testing Machine) can be used.

The horizontal bar 242 has a configuration in which one end of the horizontal bar 242 is in contact with the vertical load lowering mouth 241 and the other end is connected to the tension bar 230 by the transmission means 250 to transmit the upper load .

The transfer means 250 includes a pair of frames 251 arranged in a downward direction from one end of the horizontal bar 242, rollers 252 configured to form an upper and a lower gap between the frames 251, And a transfer bar 254 which is slid between the rollers 252 and connected to the tension bar 230 at one end.

5, the frame 251 is formed as a roller 252 in the shape of a plate and the transfer bar 254 is connected to the tension bar 230 between the rollers 252, (242) so as to have an integral behavior. The reason why the upper and lower rollers 252 are formed is that when a tension load is applied to the transmission bar 254 and a tensile load is applied to the tension bar 230, noise is prevented from being generated in the tensile load due to the friction of the device To provide accurate measurements.

The transfer bar 254 is configured to slide between upper and lower rollers 252. One end of the transfer bar 254 passes through the through hole 211-1 of the support base 211, And a hook head 255 having a large diameter is formed at the other end so as to be engaged with the pair of frames 251. [

When the upper load is applied to one end of the horizontal bar 242 by the vertical load lowering mouth 241, the horizontal bar 242 and the frame 251 are integrally interlocked with each other A tensile load is applied to the transfer bar 254 by the hooking head 255 caught by the frame 251. The tensile load applied to the transfer bar 254 is transmitted to the tension bar 230, (m). As described above, the initial age-stretching test apparatus 200 of the present invention interlocks with the tensile mold 100 to convert a vertical load into a tensile load (horizontal load) in order to derive a tensile characteristic such as an accurate tensile strength in an early- By applying the tensile load in a state in which the tensile mold 100 is horizontally placed, it is possible to perform experiments in a state in which the tensile mold 100 is placed horizontally, So as to minimize the influence.

The initial aging tensile test apparatus 200 according to the present invention may measure the tensile load applied to the tension bar 230 by attaching the load cell 230 to the tension bar 230, The deformation cell 270 is attached to the part where the de-molding part 120 is detached, and the deformation rate is measured.

In the present invention, as shown in FIG. 5, an early age tensile test method is also presented.

In this test method, the tensile mold 100 is filled with the mortar m (S10).

And then detaching the deformed portion 120 from the tensile mold 100 and mounting the deformed portion 120 to the initial tensile testing device 200 (S20). In this step, it is not necessary to limit the detachment time of the deflecting part 120, but since it is the primary purpose to measure the tensile characteristic at the initial age, detachment of the defective part 120 is performed in about 8 hours, The tensile mold 100 is mounted on the initial age tensile testing apparatus 200 by exposing the mortar m. The tensile bar 100 is connected to each unit 140 and the supporting table 211 by fastening and fixing each unit 140 to the slide plate 220 in the tension mold 100, The mold 100 is attached to the initial age-stretching test apparatus 200. The load cell 260 and the deformed cell 270 are also mounted.

When the tensile mold 100 is attached to the early age tensile testing apparatus 200, the tensile load is measured (S30). The upper load is applied by the vertical loader 241 and the upper load applied to the tension bar 230 is applied to the tension bar 230 by the horizontal bar 242 and the transmission means 250 interlocked with each other, So that the tensile load is applied to each of the units 140. As a result, stress is concentrated on the exposed mortar (m) in the tensile mold 100 and cracks are induced. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

100: tensile mold 110:
120: Deformable portion 130: Tension bar
140: Unit 200: Initial age tensile test apparatus
210: pedestal 220: slide plate
230: Tension bar

Claims (9)

Wherein a hollow portion for filling the mortar therein is formed, and a demolding portion capable of being attached and detached is formed at the center portion, and the mortar is exposed to the outside at the central portion,
The tensile mold
A pair of units each having an opening formed at one side thereof and a protrusion formed so as to have a narrowed width at the opening portion; a second protrusion formed between the unit and the inside to form a round protrusion by the protrusion and the second protrusion; And a demolding portion formed at both ends with a fastening plate to be fastened to the outer circumference of the unit, respectively.
The method according to claim 1,
And a round protrusion is formed on both sides of the center of the space to reduce the width of the protruded and filled mortar.
delete An initial age tensile test apparatus in which the demoulding unit is mounted in a detached state in the tensile mold of claim 1.
5. The method of claim 4,
A pedestal having protruding supports at both ends thereof;
A pair of slide plates which are slidable in a guide bar on an upper portion of the pedestal and to which the units are respectively fastened;
A pair of tension bars connecting both ends of the tensile mold with the support;
Load applying means for applying a tensile load to the tension bar;
And an initial age tensile test apparatus.
6. The method of claim 5,
The load-
And a horizontal bar which is connected at one end thereof to the vertical load-lowering mouth and at the other end by the tension bar and the transmission means.
The method of claim 6,
The conveying means includes a pair of frames arranged in a downward direction from the one end of the horizontal bar, a roller having an upper and a lower gap formed between the frames, and a conveying bar slidably connected to the tension bar and connected to the tension bar. Characterized in that the initial age tensile test apparatus is characterized by:
6. The method of claim 5,
Wherein the tensile bar is attached with a load cell, and a deformed cell is attached to the detached portion between the units.
Filling the mortar with the tensile mold of claim 1;
Detaching the demoulding part from the tensile mold and mounting it on the initial age tensile testing device of any one of claims 4 to 8;
Loading a tensile load;
Wherein the initial tensile tensile test method comprises:

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