KR102129975B1 - Automatic measement apparatus of concrete mixture setting time - Google Patents

Abstract

The present invention relates to an automatic measuring device for concrete setting time, which calculates the melting time, which is the point at which the concrete is hardened, by using the shrinkage characteristics at the initial age of concrete.
In the concrete setting time measuring device of the present invention, concrete is poured into a space formed between two circular molds having different diameters to generate stress due to a change in volume of concrete at an early age through a strain gauge installed in the inner circular mold. The condensation time can be calculated by automatically measuring the time. Furthermore, the test body containing the coarse aggregate is also applicable due to the automatic measuring device for concrete setting time of the present invention, and it is possible to accurately measure in real time the point at which stress of concrete can occur.

Description

Automatic measuring time for concrete setting time {AUTOMATIC MEASEMENT APPARATUS OF CONCRETE MIXTURE SETTING TIME}

The present invention relates to a device for automatically measuring the setting time of concrete, and more specifically, by pouring concrete in a space formed between two circular molds having different diameters, the volume of concrete at an initial age through a strain gauge installed in the inner circular mold. The present invention relates to an automatic measuring device for concrete setting time, which automatically calculates a setting time by automatically measuring a point in time at which stress occurs due to a change.

The concrete reacts with cement and water to increase strength by hydration, and heat and volume change occur in this process. When the microstructure of the cement matrix has a certain stiffness due to the hydration reaction, condensation occurs in the concrete. The point of time having this stiffness is the setting time.

Specifically, condensation is a process of hardening while losing fluidity with a slight exotherm when kneading by adding an appropriate amount of water (water/cement = about 0.3 to 0.7%) to the cement (c ₃ A, C ₃ S, etc.) react with water to form new tissue. At this stage, the plasticity of the cement disappears and the shape is maintained, but the hardened cement does not yet exhibit strength.

Condensation is generally divided into an initial setting and a final setting.

Initial setting is a step in which fluidity disappears even though the cement paste is still soft, and final setting refers to a step that shows solid state as solidification continues over time. .

After termination, the concrete becomes a solid state, has an elastic modulus, and condensation occurs when a strain occurs. Therefore, since the stress is generated, accurate timing is very important for predicting and preventing the occurrence of cracks in concrete structures.

Conventional concrete condensation test has been performed by measuring the depth or resistance of the needle manually entering the test body according to the time determined by the non-capping or penetration resistance method to measure the setting time [Patent Document 1 and Patent Document 2]. In addition, Patent Document 3 discloses an apparatus capable of automatically measuring the concrete setting time by ultrasonic velocity measurement.

However, this method shows a large difference in results depending on the user's skill level, and also has an inefficient aspect because it takes about 10 hours.

In particular, conventional condensation test methods or devices have been limited to test bodies that do not contain coarse aggregates, such as cement paste or mortar, and have had limitations in measuring the natural coagulation test of coarse aggregates.

In addition, as measuring indirect setting time through intrusion depth or resistance, there is a need for an apparatus or method capable of accurately measuring a point in time when actual concrete stress can occur.

Thus, the present inventors have tried to solve the conventional problems, as a result of preparing a concrete receptor consisting of two circular molds with different diameters, and pouring concrete into the space formed between the two circular molds to deform the strain installed in the inner circular mold The present invention was completed by confirming that the condensation time can be calculated by automatically measuring the point at which stress occurs using a shrinkage characteristic according to the volume change of concrete at an early age through a gauge.

Republic of Korea Patent No. 0932380 (December 16, 2009 announcement) Republic of Korea Patent No. 1374625 (Announcement on March 17, 2014) Republic of Korea Patent No. 0140826 (announced on July 1, 1998)

An object of the present invention is to provide an automatic measuring device for concrete setting time.

In order to achieve the above object, the present invention is composed of a first circular mold, a second circular mold having the same centrifugal shape as the first circular mold, and having a radius of 50 to 100 mm greater than that of the first circular mold. A concrete receptor in which the mold and the second circular mold are fixed by pins; And

A strain gauge installed inside the first circular mold of the concrete container provides an automatic measuring device for concrete setting time connected to an automatic data recording device.

In the concrete setting time measuring device of the present invention, a Teflon sheet may be attached to the bottom surface of the concrete container.

In the concrete container, the first circular mold and the second circular mold have the same height, and the height is preferably 100 to 200 mm.

In addition, the first circular mold and the second circular mold are preferably made of stainless material.

Concrete is poured into the space formed between the first circular mold and the second circular mold, and a strain rate generated when the concrete is cured can be automatically measured through a strain gauge installed inside the first circular mold of the concrete receptor.

The automatic setting time of concrete setting device according to the present invention is also possible to test the setting of concrete containing coarse aggregate. When the initial setting is done, it automatically measures the strain that occurs when the concrete is cured to determine the setting time, which is when the concrete is cured. Can be measured.

Therefore, the automatic measuring time of the concrete setting time according to the present invention can accurately measure the point in time when the stress of the actual concrete can occur, and is also efficient in terms of shortening the test time.

1 is a schematic view of an automatic measuring device for concrete setting time of the present invention,
2 is a plan view of the concrete receptor in the automatic measurement time of the concrete setting time of Figure 1,
Figure 3 is a schematic view showing the pressure acting on the first circular mold in the concrete receptor of Figure 2,
Figure 4 is a front view of the automatic setting device of the concrete setting time of Figure 1,
Figure 5 shows the average value of the strain gauge measured over time placed inside the first circular mold of the concrete receptor of Figure 3,
6 is a result of measuring the concrete setting time using the automatic concrete setting time measuring device of the present invention,
7 is a concrete condensation time measurement result by a conventional method using a non-cupid,
8 is a result of measuring the concrete setting time by a conventional ultrasonic measuring method.

Hereinafter, the present invention will be described in detail.

The present invention provides a device for measuring the setting time, which is the point at which the concrete is hardened, by using the shrinkage properties at the initial age of concrete.

1 shows a schematic diagram of an automatic measuring device for concrete setting time of the present invention, specifically, the present invention has the same centrifugal shape as the first circular mold 11 and the first circular mold, and is 50 to 50 compared to the first circular mold. A concrete receptor 10 made of a second circular mold 12 having a large radius of 100 mm, wherein the first circular mold and the second circular mold are fixed by pins 13; And

Provided is an automatic measuring device for concrete setting time in which a strain gauge (14) installed inside the first circular mold of the concrete container is connected to an automatic data recording device (30).

Figure 2 shows a plan view of the concrete container in the concrete setting time automatic measuring device of the present invention.

The first circular mold 11 and the second circular mold 12 are preferably durable materials, and a stainless steel mold is used in the present invention.

In addition, in the concrete receptor, the first circular mold 11 becomes the inner diameter of the receptor, and the second circular mold 12 having a larger radius of 50 to 100 mm than the first circular mold is determined by the outer diameter of the receptor, and the two circular shapes Concrete 30 is poured into the space formed between the molds.

At this time, the radius range of the second circular mold 12 is preferably 50 to 100 mm larger than the first circular mold, and generally, the maximum dimension of the coarse aggregate of concrete used in the field is 25 mm. Therefore, if it is less than 50 mm, the space formed between the first circular mold and the second circular mold is narrow, so that the coarse aggregate cannot be randomly distributed, and there is a difficulty in representing the properties of concrete. On the other hand, if it exceeds 100 mm, there is a disadvantage in that the maximum size of the concrete coarse aggregate is rarely used more than 50 mm, so only the amount of concrete required for the test and the size of the test device become larger than necessary.

3 is a diagram schematically showing the pressure acting on the first circular mold in the concrete receptor of the present invention, initially a tensile strain due to the heat of hydration occurs and the strain gauge 14 installed inside the first circular mold of the concrete receptor Is detected, and after the setting time (termination), a compressive strain is generated.

At this time, when the thickness of the concrete is different depending on the direction, as shown in Figure 3, the pressure acting on the inner ring is different, and the resulting value of the strain gauge installed therein is different.

In order to solve this problem, the concrete container 10 composed of the first circular mold 11 and the second circular mold 12 is fixed to the number of pins equal to the circumferentially distributed angle, preferably. As shown in FIG. 2, the pins 13 having three predetermined lengths (fixed 50 mm) are fixed at an angle of 120° in the mold, thereby allowing concrete to be poured uniformly and uniformly.

In addition, the thickness of the concrete test body for measuring the concrete setting time can be easily and uniformly produced.

In addition, FIG. 4 is a front view of the automatic measuring device for concrete setting time of the present invention. In the automatic measuring device for concrete setting time of the present invention, the first circular mold 11 and the second circular mold 12 should have the same height. At this time, the height is preferably 100 to 200 mm.

In concrete, stress acts not only in the transverse direction but also in the height direction. Accordingly, in order to minimize the effect of the longitudinal stress in the transverse direction, it is preferable that the size of the specimen in the longitudinal direction, that is, in the height direction, be at least twice the size of the transverse direction. Since shrinkage is dominant with a smaller cross-section, creating a dominant shape with transverse deformation can reduce measurement errors.

If the heights of the first circular mold 11 and the second circular mold 12 are less than 100 mm, problems may arise when pouring concrete, and as a test body for measuring the concrete setting time, it is small in size. Can be produced. On the other hand, if it exceeds 200 mm, for a reason similar to limiting the size of the transverse specimen, that is, the concrete specimen becomes larger than necessary, and the size of the apparatus becomes larger.

As shown in Figure 4, by attaching the Teflon sheet 20 to the bottom of the concrete receptor 10, it is possible to minimize the frictional resistance. At this time, the size of the Teflon sheet will not be particularly limited if it is prepared to be larger than the second circular mold 12.

The automatic concrete setting time measuring device of the present invention is characterized in that it calculates the setting time by automatically measuring the point at which stress occurs due to the change in volume of concrete at an early age.

Figure 5 shows the average value of the strain gauge measured over time placed inside the first circular mold of the concrete container of the present invention, and when the tensile strain becomes maximum, that is, the strain begins to decrease by compressive stress. The time point can be calculated as the setting time (end).

Thus, FIG. 6 is a result of measuring the concrete setting time using the automatic measuring device for concrete setting time of the present invention, showing a tendency similar to that of FIG. 5, wherein the concrete setting time is calculated as 530 minutes.

Therefore, the automatic concrete setting time measuring device of the present invention can measure the concrete setting time by pouring concrete in the space formed between the first circular mold and the second circular shape, so that the mortar or cement irrespective of whether or not the coarse aggregate is included. Can be applied.

In addition, the automatic concrete setting time measuring device of the present invention can accurately measure in real time the point at which stress occurs due to the volume change of concrete at an early age after pouring concrete.

Hereinafter, the present invention will be described in more detail through examples.

This example is intended to illustrate the present invention in more detail, and the scope of the present invention is not limited to these examples.

<Example 1>

In the concrete receptor shown in FIG. 2, two stainless circular molds (height of 100 mm) having an outer diameter of 150 mm (second circular mold) and an inner diameter of 100 mm (second circular mold) are fixed to the base plate, and the first circular mold and the second In the space formed between the circular molds, mortar formulated under the following conditions was poured. As the concrete was hardened, the volume change of the concrete transferred from the strain gauge installed inside the first circular mold of the receptor was monitored over time to calculate the stress generation time.

Mortar mixing ratio (weight ratio)

Water-cement ratio, 0.3

Cement to aggregate ratio, 1:1

The results are shown in Figure 6, the concrete setting time was 530 minutes.

<Comparative Example 1>

The condensation time was measured by the conventional method for measuring the condensation time by non-capping [KS F 2436 "Test method for time of setting of concrete mixture by penetration resistance"]. At this time, the aggregate was not included by the criteria presented in the measurement method.

The results are shown in Fig. 7, and the concrete setting time was 435 minutes.

<Comparative Example 2>

The condensation time was measured by the conventional method for measuring the condensation time by an ultrasonic method, and mortars under the same conditions as in Example 1 were used.

The results are shown in FIG. 8. The concrete setting time was determined to be 645 minutes.

From the above results, the method for measuring the setting time by non-capping in Comparative Example 1 can be determined that the setting time is short because the non-caching is difficult to apply to a test body containing a coarse aggregate or because the reproducibility is poor and does not include aggregate.

On the other hand, the setting time of the concrete calculated by the method of Example 1 for the test body containing the coarse aggregate showed a shorter effect than the result by the conventional ultrasonic method.

In the above, the present invention has been described in detail only with respect to the described embodiments, but it is apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and it is natural that such modifications and modifications belong to the appended claims.

10: concrete receptor 20: teflon sheet
30: automatic data recorder 40: concrete
11: first circular mold 12: second circular mold
13: fixing pin 14: strain gauge

Claims (5)

First circular mold, has the same centrifugal shape as the first circular mold, is composed of a second circular mold having a radius of 50 to 100 mm larger than the first circular mold, and the first circular mold and the second circular mold are equivalent to the circumference Concrete receptor fixed to the number of pins by the angle divided by
A strain gauge installed inside the first circular mold of the concrete container is connected to an automatic data recording device,
In the space formed between the first circular mold and the second circular, a mortar or cement paste that does not contain coarse aggregate or concrete or coarse aggregate is poured to produce a test specimen,
Automatic measuring device for concrete setting time, characterized in that the longitudinal direction of the specimen is more than twice the size of the lateral direction, so that the lateral deformation is produced in a dominant form. According to claim 1, Concrete concrete setting time automatic measuring device, characterized in that the Teflon sheet is attached to the bottom of the concrete receptor. According to claim 1, wherein the first circular mold and the second circular mold has the same height and the concrete setting time automatic measuring device characterized in that the height is 100 to 200㎜. The automatic condensation time measurement device of claim 1, wherein the first circular mold and the second circular mold are made of stainless steel. According to claim 1, Concrete is poured into the space formed between the first circular mold and the second circular mold,
Automatic measuring device for concrete setting time, characterized in that the volume change at the initial age of concrete is monitored in real time through a strain gauge installed inside the first circular mold of the concrete container.

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