KR20110007502A - Evaluation method of compressive strength for structural concrete - Google Patents

Abstract

PURPOSE: A method for evaluating compressive strength of structural concrete is provided to efficiently manage a construction process and to improve reliability of concrete quality. CONSTITUTION: A method for evaluating compressive strength of structural concrete comprises: a step of making a test piece having sample mixing condition with the structural concrete; a step of checking curing period and compressive strength of the test piece to draw accumulated temperature-compressive strength relation graph; a step of measuring the temperature by each curing period of structure concrete built in a form to calculate the accumulate temperature; and a step of estimating compressive strength of the structural concrete.

Description

Evaluation method of compressive strength for structural concrete

The present invention provides a method for evaluating the compressive strength of structural concrete that can monitor the strength expression characteristics of early-age concrete through integration temperature and structural strength control specimens, and when the strength evaluation by the structural strength management specimens is impossible, The present invention relates to a method of estimating strength through NDT for.

In the construction site of reinforced concrete structures, there are problems of lack of performance related to the structural concrete, such as the delay in strength expression due to the decrease of outdoor temperature or the lack of compressive strength in the required age. This is because the characteristics of compressive strength of concrete are closely related to curing temperature according to temperature.

Conventionally, after placing a specimen for strength management when placing concrete and placing it next to the structure, compressive strength test was performed at a predetermined age to indirectly evaluate the strength expression characteristics of the structural concrete (see FIG. 1). However, since the specimen for strength management is relatively small compared to the structural member, the compressive strength is different from the structure due to the rapid drying of the specimen and the change in curing temperature according to the change in the outside temperature, unless the condition is similar to the structure. Therefore, in the concrete standard specification and the construction standard specification, the on-site underwater curing (see [Fig. 2]) to cure by dipping the specimen in the water provided next to the structure or the field sealing nursing to prevent moisture evaporation by putting in vinyl ([Fig. 3]) And the like). This method can maintain the moisture state similar to the structure, but the curing temperature difference due to the heat of hydration according to the thickness of the actual structure, concrete mixing conditions, etc. is not considered. Therefore, it was necessary to develop a system for evaluating the strength of concrete by reviewing the temperature history through the thermometer side during the curing of the structure and by performing the compressive strength test with the strength management specimen cured similarly to the temperature history.

An object of the present invention is to provide a reasonable process control technique by monitoring the strength expression characteristics of the cast concrete in the field.

The present invention calculates the integrated temperature by measuring the temperature history of the cast concrete in the field, and by monitoring the strength expression characteristics of the structural concrete with the strength management specimen that is similar to the measured temperature history, the appropriateness of remedial measures for the structure And to determine the need for additional remedial measures and to predict when to proceed with subsequent processes.

By knowing in advance the correlation between integration temperature and compressive strength expression characteristics for concrete to be used in the construction site, the strength expression characteristics can be predicted only by measuring the temperature of the structure, and by curing the specimen for strength management similar to the temperature of the structure, The specimen for strength management can accurately represent the strength of the structural concrete. Depending on the site conditions, if the thermocouple for thermometer measurement is lost or the strength management specimens cannot be maintained to resemble the structure, the precision of the strength prediction of the structure concrete may be degraded. By examining the correlation between the intensity, the ultrasonic velocity, and the rebound hardness (type P Schmidt hammer), the strength can be estimated only by the non-destructive test on the real structural member. By utilizing such a series of systems, the process management can be rationalized.

According to the present invention, it is possible to monitor the strength expression characteristics of the early age concrete, it is possible to efficiently manage the construction process by predicting the target strength reaching time, thereby improving the quality reliability of the early age concrete. In addition to the general concrete construction, the present invention can be applied to determining the cable drawing time of the precast member, determining the time to open the traffic in the case of road paving, and determining the lift up time in the case of the slip foam or the ACS foam.

The present invention comprises the steps of preparing a specimen under the same mixing conditions as the structural concrete; (b) deriving an integrated temperature-compressive strength relation graph by grasping temperature and compressive strength for each curing period of the specimen; And (c) calculating an integrated temperature by measuring temperatures for curing periods of the structural concrete poured in the formwork, and estimating the compressive strength of the structural concrete through the integrated temperature-compression strength relationship graph; It provides a method of evaluating the compressive strength of the structural concrete comprising a.

In general, in the construction site, after the concrete is laid, the compressive strength test of the specimen for strength management is carried out after a certain age, and when the target strength is reached, the subsequent process such as formwork demoulding is performed. However, it is impossible to control the strength of the structural concrete when the construction site for the strength management specimen is incorrectly managed or when the strength evaluation age is not properly predicted, and the compressive strength test is performed several times so that no specimen for strength management remains. .

On the other hand, it is relatively easy to measure the temperature by curing period of specimen or structure concrete and calculate the accumulated temperature based on this. Therefore, if the relationship between the integrated temperature and the compressive strength of the concrete to be used can be grasped in advance, The compressive strength of concrete can be estimated.

In the present invention, the relationship between the integration temperature and the compressive strength of the specimen prepared under the same conditions as the concrete to be used is determined in advance, and based on this, the compressive strength of the structural concrete actually constructed is indirectly estimated through the calculated integration temperature. The key is to make sure that you can. Accumulation temperature can be calculated only by the result of the thermometer on the structure concrete, and when the data on the curing period and the data on the curing temperature are derived through the temperature sensor such as the thermocouple and the thermometer measuring device of FIG. It can be calculated automatically by the formula.

Based on the relation graph and the general formula between the accumulated temperature and the compressive strength, the accumulated temperature of the actual structure has reached the value corresponding to the target strength, or has the structural concrete reached the appropriate strength for the mold demoulding? It is possible to judge whether the level of rehabilitation is appropriate or, if not, how much additional rehabilitation (increase curing temperature) should be done.

Hereinafter, the present invention will be described in detail for each step.

1.step (a)

This step (a) is a step of producing a specimen under the same mixing conditions as the structure concrete.

The final compressive strength and speed of strength development of concrete depend on the type of cement, water-cement ratio, composition ratio of materials used, and slump value. In addition, the curing speed is different depending on the climatic conditions, the temperature of the outside air, and the like.

In this step, in order to derive the correlation between integration temperature and compressive strength, the specimens are manufactured under the same mixing conditions as the structure concrete, and when the specimens are manufactured, the thermo-couple is pre-filled for temperature measurement by curing period. I can let you do it.

2. Step (b)

This step is a step of calculating the integrated temperature by measuring the temperature for the curing period of the specimen.

When concrete hardens through condensation and develops strength, it is affected by various external environmental conditions, among others, by curing temperature. It is well known that the strength of concrete is quickly expressed in summer and the strength expression of concrete is delayed in winter, and the concept of integration temperature is derived from the concept of rationalizing the characteristics of concrete.

The cumulative temperature is calculated by curing temperature x age and there are various proposed equations, but the present invention provides the following [Formula 1] for calculating the accumulated temperature.

[Equation 1]:

: 적산온도

: Accumulation temperature

: 양생기간(day)

: Curing period (day)

:

기간 중의 평균 양생온도(℃)

:

Average curing temperature (℃) during the period

The reason for adding 10 ℃ to the concrete temperature in the above equation is based on the concept that the strength of concrete can be expressed little by little under the condition of minus 10 ℃. If the average curing temperature is below 10 ℃, the sigma term becomes 0. Accumulation temperature becomes 0 even if it increases. That is, minus 10 ℃ can be said to be the limit temperature that the concrete can express the strength.

[Reference Figure 1]

[Reference Figure 1] is a graph showing the curing period (young age) on the horizontal axis, the curing temperature on the vertical axis. In this case, the cumulative temperature is calculated by the cumulative sum of (average curing temperature) × (age) of the fixed section.

That is, if the integration temperature of the a-b section is M1 and the integration temperature of the b-c section is M2,

Calculated as M1 = (average from x to y) × (b-a),

M2 = (average of y to z) × (c-b)

The integration temperature M of the a-c section can be calculated as M = M1 + M2.

The temperature by curing period of the specimen can be collected by time zone using a temperature sensor such as a thermocouple buried at the time of manufacture of the specimen, and the integration temperature can be calculated by substituting the curing temperature and curing period collected in [Equation 1] above. have.

On the other hand, in the step (b), it is necessary to derive the integrated temperature-compression strength relation graph.

The integrated temperature-compressive strength relationship graph is derived from the test, and the relationship between the integrated temperature and the compressive strength can be generalized by the following [Equation 2].

[Equation 2]:

: 적산온도

: Accumulation temperature

: 적산온도에서의 압축강도(MPa)

: Compressive strength at integration temperature (MPa)

: 최종 도달강도(MPa)

: Final attainment strength (MPa)

,

: 실험상수

,

: Experimental Constant

[Equation 2] is a model of the regression model presented by the logistic curve. The logistic curve has an upper limit (y = a, x = ∞) and a lower limit (y = 0, x = -∞), as shown in [Reference 2] below, and in coordinates (m / k, a / 2). ) Is the inflection point, the inflection point is symmetrical, and the inflection point increases upward, and after passing the inflection point, the width of increase decreases and converges to the upper limit a.

[Reference Figure 2]

Accordingly, the integrated temperature-compressive strength relationship graph can be derived. [Reference FIG. 3] is an example of preparing the integrated temperature-compressive strength relationship graph.

[Reference Figure 3]

In the graph above, the integration temperature reaching 5MPa, which is generally the minimum compressive strength required for the early freeze protection of Korea-China concrete and the formability of the side formwork of the vertical member, is about 35 ° D · D. . This is because when the same concrete is placed on site, if the accumulated temperature reaches 35 ° D · D based on the thermometer result of the structural concrete, the compressive strength of the structural concrete is likely to reach 5 MPa. It can be determined that the test period for the specimen strength control for the structure has been reached.

3. Step (c)

This step is a step of estimating the integrated temperature by measuring the temperature of curing of the structural concrete placed in the formwork, and estimating the compressive strength of the structural concrete through the integrated temperature-compression strength relationship graph.

Even in this step, the temperature is collected by curing period of the concrete using a temperature sensor such as a thermocouple embedded inside the formwork and embedded in the structure concrete, and the collected curing temperature and curing period are integrated into [Equation 1]. The temperature can be calculated, and the intensity expression state of the structural concrete can be estimated by reflecting and analyzing the accumulated temperature in the integrated temperature-compressive strength relationship graph.

4. Step (d)

This step estimates whether the structural concrete has reached the target compressive strength based on the result of calculating the accumulated temperature of the structural concrete and the integrated temperature-compressive strength relationship graph. It is the step of determining whether or not.

According to the `` Concrete Standard Specification '' of the Korea Concrete Institute, molds can be demoulded when the expansion base, beam side, column, wall, etc. are exposed to compressive strength of 5 MPa or more. It can be seen that the form can be demoulded when 2/3 or more of 2, and 2) the compressive strength expression conditions of 14 MPa or more are satisfied. Accordingly, it is possible to predict whether the compressive strength of the structural concrete is expressed to the extent that the formwork can be dismantled for each part of the building by matching the integrated temperature of the structural concrete with the integrated temperature-compressive strength relationship graph.

When it is determined that the die demoulding is possible through the above process, the specimen for structural strength management is cured under the same temperature condition as the structure (see [Fig. 5]), and the compressive strength is tested (see [Fig. 6]). After reconfirming the above determination result, the mold can be demoulded. It is unreasonable in terms of time, effort, and cost to test compressive strength arbitrarily on the specimen for structural strength management. According to the present invention, the method for evaluating the compressive strength of structural concrete is to estimate the compressive strength of the structural concrete, and to reconfirm the estimated compressive strength for the structural strength management specimen as necessary, thereby minimizing the destruction of the specimen. .

On the other hand, in the step (d) can be performed in parallel with the non-destructive test for determining the compressive strength of the structural concrete. The non-destructive test can be selectively carried out depending on the site conditions such as when the thermocouple embedded in the structural concrete is broken and it is difficult to calculate the integration temperature, or when there is no specimen for examining the compressive strength. It may be done in parallel to improve the reliability of the estimate of the compressive strength of concrete.

The non-destructive test can be carried out by measuring the concrete rebound hardness as shown in [7], or can be carried out through an ultrasonic test using the device as shown in [8].

9 is a flowchart illustrating a process of determining whether a subsequent process is performed by using the method for evaluating the compressive strength of structural concrete according to the present invention.

If there are no specimens for strength control, nondestructive testing of the structural concrete can be carried out from time to time until the target strength is expressed.

If the specimen for strength control is manufactured separately, check whether the thermometer side for the structural concrete is possible. If the temperature cannot be measured because the temperature sensor is not buried in the structure concrete in advance, the nondestructive test on the structure concrete can be conducted from time to time until the target strength is expressed. .

If the thermometer side of the structural concrete is possible, the thermometer side is carried out while rehabilitation is carried out, and the integrated temperature is calculated based on this, and the integrated temperature-compressive strength relationship graph is used to estimate whether the integrated compressive temperature has reached the integrated temperature. . When the accumulated temperature expressing the target strength is reached, the compressive strength test is performed on the specimen whose temperature history is similar to that of the structure concrete, so that the above estimates can be confirmed and the progress of the subsequent process can be determined. On the other hand, when the compressive strength test cannot be performed on specimens due to various factors, the above estimation can be confirmed through the non-destructive test on the structural concrete.

1 is a curing front image of a specimen for structural strength management generally carried out at a construction site.

Figure 2 is a foreground photo of the site underwater curing of the specimen for strength control structure.

Figure 3 is a photograph of the field sealing curing foreground of the specimen for structural strength management.

4 is a photograph of the concrete temperature measuring device.

5 is a photograph of a device capable of curing the structure strength specimens similar to the structure temperature history.

6 is a photograph taken of the specimen compressive strength test process.

7 is a photograph taken of the concrete compressive strength nondestructive testing process by measuring the concrete rebound hardness.

8 is a photograph of a compressive strength nondestructive testing device using ultrasonic waves.

Figure 9 is a flow chart of the process of determining whether or not to proceed with the subsequent process using the method of evaluating the compressive strength of the structure concrete according to the present invention.

Claims (5)

(a) preparing a specimen under the same mixing condition as that of the structural concrete; (b) deriving an integrated temperature-compressive strength relation graph by grasping temperature and compressive strength for each curing period of the specimen; And (c) calculating an integrated temperature by measuring temperatures for curing periods of the structural concrete poured in the formwork, and estimating the compressive strength of the structural concrete through the integrated temperature-compression strength relationship graph; Compressive strength evaluation method of the structural concrete, characterized in that it comprises a. In claim 1, Step (b), the compressive strength evaluation method of the structural concrete, characterized in that to calculate the integrated temperature through the following [Equation 1]. [Equation 1]:

: Integration temperature (° D · D, degree days)

: Curing period (day)

:

Average curing temperature during the period (℃) In claim 1, Step (b) is a method for evaluating the compressive strength of the structural concrete, characterized in that to calculate the integrated temperature-compression strength relationship graph by calculating the compressive strength for each curing period of the specimen by the following [Equation 2]. [Equation 2]:

: Accumulation temperature

: Compressive strength at integration temperature (MPa) : Final attainment strength (MPa)

,

: Experimental Constant The method according to any one of claims 1 to 3, (d) After estimating whether the structural concrete has reached the target compressive strength based on the result of calculating the integrated temperature of the structural concrete and the accumulated temperature-compressive strength relationship graph, if it is determined that it has reached the test, the compressive strength of the specimen is tested. Determining whether to proceed; Compression strength evaluation method of the structural concrete, characterized in that it further comprises. In claim 4, In the step (d), the compressive strength evaluation method of the structural concrete, characterized in that to perform a non-destructive test for determining the compressive strength of the structural concrete.

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