KR20230155137A - Method for monitoring initial strength of concrete using internal relative humidity hysteresis and diagnosis system - Google Patents

Abstract

The present invention relates to a method and diagnostic system for monitoring the initial strength of concrete using internal humidity history.
The method for monitoring the initial strength of concrete using internal humidity history of the present invention includes the first step of securing a database on the internal humidity-strength correlation for each concrete mix, the second step of embedding a humidity sensor during the concrete pouring process, and the humidity history after concrete pouring. The third step is to measure and the fourth step is to predict the initial strength based on the measured humidity history and the database on the internal humidity-strength correlation secured in the first step. Unlike the temperature increase, the humidity decrease is carried out. Reliability is secured by eliminating sensitivity to the size and shape of concrete members, and by measuring changes in internal humidity, the initial strength development process can be estimated in real time and non-destructively, taking into account the speed of concrete strength development during the actual construction process to determine the construction speed. can be adjusted, and ultimately the safety of reinforced concrete structures that are not completely hardened can be secured.

Description

Concrete initial strength monitoring method and diagnosis system using internal humidity history {METHOD FOR MONITORING INITIAL STRENGTH OF CONCRETE USING INTERNAL RELATIVE HUMIDITY HYSTERESIS AND DIAGNOSIS SYSTEM}

The present invention relates to a method and diagnosis system for monitoring the initial strength of concrete using internal humidity history. More specifically, the first step of securing a database on internal humidity-strength correlation for each concrete mix, embedding a humidity sensor during the concrete pouring process. a second step, a third step of measuring the humidity history after placing the concrete, and a fourth step of predicting the initial strength based on the measured humidity history based on the database on the internal humidity-strength correlation secured in the first step. Unlike temperature rise, humidity reduction can exclude sensitivity to the size and shape of the concrete member, ensuring reliability, so the internal humidity history can be used to estimate the initial strength development process in real time and non-destructively by measuring the change in internal humidity. This relates to a concrete initial strength monitoring method and diagnosis system using .

The quality control of current reinforced concrete structures is designed based on the strength when the concrete is completely hardened, usually 28 days after pouring. In other words, structural safety is ensured based on the development of the design strength of concrete and perfect adhesion of reinforcing steel and concrete.

However, concrete strength has the characteristic of changing with time, temperature, and humidity as variables, and is particularly affected by environmental influences in the early aging period (usually 1 week), which is the period before demoulding of the form.

Therefore, in periods of low temperature, strength development may be very slow, resulting in significantly lower strength, and a significant level of horizontal load (wind load) may occur in situations where the reinforcing bar and adhesion performance are not sufficiently secured. In this case, cracks or adhesion failure may occur in the concrete due to strong tensile force. In other words, when poorly hardened concrete supports a significant upper load or when a horizontal load occurs, these two situations can lead to a structural collapse accident during the construction of a high-rise building in winter.

In particular, as casualties frequently occur during the construction of concrete structures, the demand for technology to predict the initial strength of concrete is very high. In fact, due to the recent implementation of the Severe Accident Corporate Punishment Act, the demand for technology related to quality monitoring of concrete before hardening has rapidly increased. I'm doing it.

As the Severe Accident Corporate Punishment Act is effective from large construction companies to medium-sized/small construction companies, the technology is required at all construction sites in Korea, so extensive experiments and a process of securing reliability are necessary to resolve the diversity of concrete material composition and performance uncertainty.

Therefore, if reliable technology is secured to monitor the initial strength development of concrete in real time during the actual construction process, problems such as structural collapse can be prevented in advance by determining the construction progress speed and concrete placement time.

Conventional methods for measuring the strength of concrete structures mainly measure the strength by accumulating the hydration heat of concrete, but are greatly affected by the size of the concrete member and the external temperature, so there are limitations in field applicability.

Patent Document 1 discloses an embedded smart sensor for estimating concrete strength using guided ultrasonic measurement. The piezoelectric sensor used in the conventional concrete curing strength expression measurement device using guided ultrasonic waves is highly brittle, so when inserted into concrete, it is destroyed by impact or compaction during concrete mixing or deformation during curing, so it cannot perform its role as a sensor. In order to solve the problem that it is difficult to measure the guided ultrasonic signal traveling through the concrete medium because it is attenuated and reflected by internal aggregates, an embedded smart sensor with guided ultrasonic transmitting and receiving ends installed on both ends of the main body is provided to protect against external shock. It is reported that by protecting the guided ultrasonic wave and providing a transmission path for the guided ultrasonic wave, the guided ultrasonic signal can be measured more efficiently, and the strength of the concrete can be estimated by measuring the change in the guided ultrasonic signal inside the measured concrete.

However, the above invention measures salt damage and heat damage to concrete structures in real time using embedded smart sensors after construction is completed, and is suitable for estimating the strength of solid objects such as fully hardened concrete.

Therefore, it is not suitable for estimating the initial strength of concrete where the cement paste has not completely hardened. This is because the inclusion of moisture is the main cause of error in the strength estimation method using ultrasound, so it is not suitable as a means of measuring strength in the early age state when it contains a large amount of moisture.

Patent Document 2 is an invention regarding an apparatus and method for estimating the early strength of concrete using impedance, by embedding a piezoelectric element sensor inside a concrete structure and measuring the strength for about 20 hours after placing the concrete using the impedance change in the piezoelectric element sensor. It has been reported that early strength can be evaluated by estimation.

The above invention is also applied to concrete in a fully hardened state, and in evaluating early strength through strength estimation for 20 hours, there is a limit to estimating the strength of concrete at an early age that is not fully hardened.

In addition, Patent Document 3 discloses a method for evaluating the compressive strength of structural concrete that can monitor the strength development characteristics of early-aged structural concrete through the integrated temperature by estimating the strength by accumulating the heat of hydration of concrete. Since the heat of hydration varies depending on the size and shape of the concrete member and the external temperature, different strength values are derived depending on the location within the structure. Therefore, since the inside of the concrete is not completely insulated, the thinner the thickness and the lower the outside temperature, the faster the internal heat cools down. The internal temperature history of concrete is different depending on the size and shape of the numerous members used in reality, making field applicability difficult. There is a very low limit to this.

Accordingly, as a result of the present inventors' continuous efforts to solve the existing problems, the development of concrete's strength is basically achieved through a hydration reaction, which is a chemical reaction that consumes free water, and as a result, the internal humidity naturally decreases. , the conventional method of measuring the initial strength by accumulating the heat of hydration of concrete is greatly affected by the size of the concrete member and the external temperature, so it has low field applicability. However, unlike the above temperature increase, the decrease in humidity is sensitive to the size and shape of the concrete member. The present invention was completed by providing a concrete initial strength monitoring method that can measure the change in internal humidity and estimate the strength development process at an early age that is not completely hardened in real time and non-destructively, as reliability is ensured because it can be excluded.

Republic of Korea Patent No. 1184049 (announced on September 28, 2012) Republic of Korea Patent No. 1184048 (announced on September 27, 2012) Republic of Korea Patent No. 1082737 (announced on November 10, 2011)

The purpose of the present invention is to provide a method for monitoring the initial strength of concrete using internal humidity history, which measures the change in internal humidity and estimates the initial strength development process in real time and non-destructively.

Another object of the present invention is to provide a concrete strength diagnosis system using internal humidity history.

In order to achieve the above object, the present invention involves the first step of securing a database on the internal humidity-strength correlation for each concrete mix,

The second step is to bury the humidity sensor during the concrete pouring process,

The third step of measuring the humidity history after pouring concrete and

Concrete initial strength monitoring method using internal humidity history, performed in the fourth step of predicting the initial strength based on the humidity history measured in the third step and the database on internal humidity-strength correlation secured in the first step. provides.

More preferably, in the method for monitoring the initial strength of concrete using the internal humidity history of the present invention, the first step is to store information for each concrete mix ID, and to test the concrete for the same mix among the specimens for each mix ID produced according to the information. A specimen for humidity measurement with an embedded humidity sensor attached and a specimen for strength measurement without the humidity sensor attached were prepared respectively, and a group of specimens for each combination ID equipped with the specimen for humidity measurement and a specimen for strength measurement were cured under the same conditions and maintained at a constant constant. The concrete internal humidity and concrete strength are measured from the specimen at time intervals, the measured values are stored in the terminal, and the internal humidity-strength correlation for each mix ID is calculated from the measured values to secure a database.

In the above, the information for each mix ID is set according to cement type, water-cement ratio, aggregate size, aggregate content, and type and content of admixture, and the curing is performed for 7 to 14 days to meet the initial strength prediction. will be.

In addition, in the method for monitoring the initial strength of concrete using the internal humidity history of the present invention, the second stage humidity sensor is installed at multiple member positions of the concrete structure to collect measured values at various locations, and the humidity sensor is used for the Internet of Things (IoT). ) It is a wireless sensor.

In the concrete initial strength monitoring method using internal humidity history of the present invention, in the third step, concrete pouring is the point at which the internal humidity measurement of the sensor begins, and in the fourth step, the humidity history received for each humidity sensor installed at multiple member locations From the information, the initial strength of each member location of the concrete structure is predicted.

Therefore, the time to remove the formwork after pouring can be determined by the prediction in the fourth step, and the experimental value measured based on the database on internal humidity-strength correlation can be converted to the mixing ratio estimation mode of the initial mixing ID and predicted.

In addition, the present invention provides a concrete strength diagnosis system using internal humidity history based on a database on internal humidity-strength correlation for each concrete mix.

Specifically, an information storage unit that stores information for each concrete mix ID;

Among the specimens for each mix ID produced according to the above information, a specimen of the same mix was prepared as a specimen for humidity measurement with a concrete embedded humidity sensor attached and a specimen for strength measurement without the humidity sensor attached, and the specimen for humidity measurement and strength were measured. A measurement value storage unit that cures a group of specimens for each mix ID and measures the concrete internal humidity and concrete strength from the specimens at regular time intervals at regular time intervals and stores them in a terminal;

An information processing unit regarding internal humidity-strength correlation for each formulation ID from the measured values; and

It provides a concrete strength diagnosis system using internal humidity history consisting of a display unit that predicts and visualizes real-time strength when the actual internal humidity measurement value on site is input to the information processing unit.

The concrete strength diagnosis system is based on a database on the internal humidity-strength correlation for each concrete mix, and can predict the strength of each concrete age or diagnose the strength of the structure by measuring changes in internal humidity and curing time.

The concrete initial strength monitoring method using the internal humidity history of the present invention can estimate the initial strength development process in real time and non-destructively by measuring changes in internal humidity that can exclude sensitivity to member size and external temperature.

Therefore, according to the concrete initial strength monitoring method using the internal humidity history of the present invention, it can be used for quality control and accident prevention of concrete considering various weather conditions at construction sites.

In addition, according to the method of monitoring the initial strength of concrete using the internal humidity history of the present invention, the construction speed can be adjusted by considering the speed of concrete strength development during technology development, and ultimately the safety of reinforced concrete structures that are not completely hardened can be secured. .

Therefore, the present invention will have very high market competitiveness as it can estimate the initial strength development process in real time and non-destructively by measuring changes in concrete internal humidity by securing high reliability in strength prediction and building an extensive database.

Furthermore, since the main purpose of the present invention is to prevent accidents that may occur during the initial hardening process of concrete, it can be mainly used in the concrete or construction industry. In addition, as it is closely related to the moisture contained in the soil, a sensor is buried inside the ground. Ground-related disasters such as landslides and ground collapse accidents can be prevented.

Figure 1 is a flowchart of the concrete initial strength monitoring method using internal humidity history of the present invention,
Figure 2 shows the measurement results of internal relative humidity for three types of concrete with different mixes in the concrete initial strength monitoring method of the present invention;
Figure 3 is a schematic diagram of the manufacturing process of a specimen for humidity measurement and a specimen for strength measurement in the concrete initial strength monitoring method of the present invention;
Figure 4 shows the step of calculating the internal humidity-strength correlation for each mix ID from the concrete internal humidity and concrete strength results measured in each specimen after curing in the concrete initial strength monitoring method of the present invention,
Figure 5 is a schematic diagram of the second step in the concrete initial strength monitoring method of the present invention;
Figure 6 shows that in the method for monitoring the initial strength of concrete of the present invention, humidity sensors are installed at multiple member positions of the concrete structure,
Figure 7 is a schematic diagram of the third step in the concrete initial strength monitoring method of the present invention;
Figure 8 is In the concrete initial strength monitoring method of the present invention, an example of real-time application of internal humidity and strength within a concrete structure is shown through the fourth step,
Figure 9 is a schematic diagram of the concrete strength diagnosis system using internal humidity history of the present invention.

Hereinafter, the present invention will be described in detail.

Figure 1 shows a flowchart of the concrete initial strength monitoring method using internal humidity history of the present invention, and provides a method for estimating the initial strength development process in real time and non-destructively by measuring changes in concrete internal humidity.

More specifically, the present invention includes the first step (S10) of securing a database on internal humidity-strength correlation for each concrete mix,

The second step (S20) of embedding a humidity sensor inside the concrete pouring process,

The third step (S30) of measuring humidity history after placing concrete, and

The initial strength of concrete using the internal humidity history was performed in the fourth step (S40) of predicting the initial strength based on the humidity history measured in the third step and the database on internal humidity-strength correlation secured in the first step. Provides a strength monitoring method.

In general, the initial strength of concrete is secured through a cement hydration reaction, which is a process that releases heat while consuming water. Therefore, at the same time as strength is developed, the internal temperature of concrete increases and internal humidity decreases.

While the conventional technique of estimating strength by integrating the heat of hydration of concrete has limitations in field applicability because it is greatly influenced by the size of the concrete member and the external temperature, the method for monitoring the initial strength of concrete of the present invention measures the change in internal humidity to determine the initial strength. It is a method of estimating the strength development process in real time and non-destructively. Unlike temperature increase, humidity decrease is not sensitive to the size and shape of the concrete member, so the reliability of the initial strength estimation of concrete can be increased by using internal humidity as a parameter.

Hereinafter, the characteristics of each stage will be described in detail using drawings.

Specifically, in the first step, information for each concrete mix ID is stored, and a humidity measurement specimen with a concrete embedded humidity sensor attached to a specimen of the same mix among the specimens for each mix ID produced according to the information and the humidity sensor are used. Each specimen was prepared as an unattached specimen for strength measurement, and a group of specimens for each mix ID including the specimen for humidity measurement and specimen for strength measurement were cured under the same conditions, and the internal humidity and concrete strength of the concrete were measured from the specimens at regular time intervals. Then, the measured values can be stored in the terminal, and the internal humidity-strength correlation for each formulation ID can be calculated from the measured values to secure a database.

The information for each concrete mix ID determines the mix ID by considering the type of cement, water-cement ratio, aggregate size, aggregate content, and type and content of admixture.

Figure 2 shows the measurement results of internal relative humidity for three types of concrete with different mixes in the concrete initial strength monitoring method of the present invention, and different internal humidity history and strength development graphs can be obtained for each mix.

Specifically, when the water-cement ratio was 0.4, 0.215, and 0.255, respectively, from the results of measuring the internal relative humidity during the curing period of 10 days, the initial strength development and internal humidity reduction of concrete due to hydration reaction depend on the mixing characteristics. can confirm. In particular, it is useful for identifying quantitative internal humidity reduction trends when the water-cement ratio is 0.215 and 0.255.

Accordingly, accurate strength estimation will be possible only if data on the strength development and internal humidity reduction of concrete according to the mixing characteristics are secured in advance.

Figure 3 is a schematic diagram of the manufacturing process of a specimen for humidity measurement and a specimen for strength measurement in the concrete initial strength monitoring method of the present invention, in which a specimen is manufactured according to the information stored in the information storage unit, and a specimen (110) for each mixture ID produced. ), a specimen of the same mix was prepared as a specimen for humidity measurement (10) with a concrete embedded humidity sensor (120) attached and a specimen for strength measurement (20) without the humidity sensor attached, respectively, on the N day, preferably at the beginning. Since the purpose is to monitor strength, curing is based on 7 to 14 days after pouring concrete.

Cured under the above conditions, the humidity measurement value from the specimen 10 for humidity measurement with the humidity sensor 120 embedded under the same conditions as the specimen for strength measurement is stored in the terminal at intervals of 5 to 10 minutes. At the same time, the strength measurement specimen 20 in which the humidity sensor is not embedded is subjected to a strength test on a set date.

Figure 4 is information processed by calculating the internal humidity-strength correlation for each mix ID from the concrete internal humidity and concrete strength results measured in each specimen after curing.

After securing a database on the internal humidity-strength correlation for each formulation ID secured in the first step above, it can be applied to the field.

Figure 5 shows the second step in the method for monitoring the initial strength of concrete of the present invention, in which a humidity sensor 50 is installed inside the concrete during the concrete pouring process. Figure 5 shows an example of installing a humidity sensor inside the formwork 30, but it is not limited to this and can also be applied to a concrete surface exposed to the air. At this time, it is also possible to tie the humidity sensor 50 tightly with a sensor fixing member 51 next to the pre-assembled rebar 40 (inward direction of the member) to prevent it from moving when pouring concrete, or to plant a bar-shaped sensor. If the purpose is to fix the sensor, it can be carried out by applying or adapting known means.

Figure 6 shows that in the concrete initial strength monitoring method of the present invention, the humidity sensor 50 is installed at multiple member positions of the concrete structure. In this case, the humidity sensor 50 is installed at multiple member positions of the concrete structure to measure various Measurements are collected at the location, and the humidity sensor 50 uses an Internet of Things (IoT) wireless sensor.

Humidity history for each location is measured and collected from the installed humidity sensor 50, which is selected in consideration of the location and type of the member and the type of concrete mix.

Figure 7 is a schematic diagram of the third step in the method for monitoring the initial strength of concrete of the present invention. Concrete pouring is the point at which internal humidity measurement by the humidity sensor begins, and after concrete pouring, the internal humidity value is displayed on the terminal every hour at 5 to 10 minute intervals. Save.

Figure 8 is In the concrete initial strength monitoring method of the present invention, the initial strength of each member position of the concrete structure can be monitored in real time from the humidity history information received for each humidity sensor 50 installed at a plurality of member positions through the fourth step.

In addition, by linking the measurement results with 2D or 3D drawings, the internal humidity and strength of the concrete at the relevant location can be checked in real time, and at the actual construction site, the time to remove the formwork after pouring can be determined.

Therefore, considering the speed of concrete strength development, the construction progress speed and concrete pouring time can be determined, and ultimately, the safety of reinforced concrete structures that are not completely hardened can be secured.

In the fourth step of the present invention, the strength of a specific mixture is predicted on a time basis (e.g., 1 hour) using the internal humidity change over time measured by the humidity sensors 50 installed at multiple member locations and the secured database. Since the database is built into the terminal, the internal humidity and intensity over time are visualized in table or graph format on the terminal in real time from the display unit.

In addition, if the used mixture is not known, the mixing ratio can be estimated by converting to a mode that estimates the mixing ratio of the initial mixing ID from the recorded humidity history based on the database on internal humidity-strength correlation, and then an approximation of the strength can be presented. .

The concrete initial strength monitoring method using the internal humidity history of the present invention has excellent practical usability because it can measure strength values that vary with time in real time in a completely non-destructive manner without pretreatment of specimens for strength testing and without special equipment.

In addition, as ground collapse accidents such as landslides are also closely related to moisture contained in the soil, humidity sensors can be buried inside the ground to prevent ground-related disasters.

Furthermore, the present invention provides a concrete strength diagnosis system using internal humidity history based on a database on internal humidity-strength correlation for each concrete mix.

Figure 9 is a schematic diagram of a concrete strength diagnosis system using internal humidity history of the present invention, which includes an information storage unit that stores information for each concrete mix ID;

Among the specimens for each mix ID produced according to the above information, a specimen of the same mix was prepared as a specimen for humidity measurement with a concrete embedded humidity sensor attached and a specimen for strength measurement without the humidity sensor attached, and the specimen for humidity measurement and strength were measured. A measurement value storage unit that cures a group of specimens for each mix ID and measures the concrete internal humidity and concrete strength from the specimens at regular time intervals at regular time intervals and stores them in a terminal;

An information processing unit regarding internal humidity-strength correlation for each formulation ID from the measured values; and

It consists of a display unit that predicts and visualizes the real-time intensity when the actual internal humidity measurement value of the field is input to the information processing unit.

In the information storage unit, a database is created where information by mix ID is stored by cement type, water-cement ratio, aggregate size, aggregate content, and type and content of admixture.

The concrete strength diagnosis system of the present invention is based on a database on the internal humidity-strength correlation for each concrete mix, and can predict the strength of each concrete age or diagnose the strength of the structure depending on the curing time.

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

10: Specimen for humidity measurement
20: Specimen for strength measurement
110: Specimens by mixture ID
120: Concrete embedded humidity sensor
30: formwork
40: rebar
50: Humidity sensor
51: Sensor fixing member

Claims (12)

The first step is to secure a database on internal humidity-strength correlation for each concrete mix,
The second step of embedding the humidity sensor during the concrete pouring process,
The third step of measuring the humidity history after pouring concrete and
Concrete initial strength monitoring method using internal humidity history, performed in the fourth step of predicting the initial strength based on the humidity history measured in the third step and the database on internal humidity-strength correlation secured in the first step. . The method of claim 1, wherein the first step is
Stores information by concrete mix ID,
Among the specimens for each mix ID produced according to the above information, specimens of the same mix were prepared as a specimen for humidity measurement with a concrete embedded humidity sensor attached and a specimen for strength measurement without the humidity sensor attached,
Curing a group of specimens for each mix ID equipped with the specimen for humidity measurement and specimen for strength measurement under the same conditions, measuring the concrete internal humidity and concrete strength from the specimen at regular time intervals, and storing the measured values in the terminal,
A concrete initial strength monitoring method using internal humidity history, characterized in that the internal humidity-strength correlation for each mix ID is calculated from the above measurements and a database is secured. The method of monitoring initial strength of concrete using internal humidity history according to claim 2, wherein the information for each mix ID is set according to cement type, water-cement ratio, aggregate size, aggregate content, and type and content of admixture. . The method of monitoring initial strength of concrete using internal humidity history according to claim 2, wherein the curing is performed for 7 to 14 days. The method of monitoring the initial strength of concrete using internal humidity history according to claim 1, wherein in the second step, humidity sensors are installed at multiple member positions of the concrete structure. The method of monitoring initial strength of concrete using internal humidity history according to claim 5, wherein the humidity sensor is an Internet of Things (IoT) wireless sensor. The method of monitoring initial strength of concrete using internal humidity history according to claim 1, wherein in the third step, pouring of concrete is the starting point of measurement of internal humidity by the sensor. The method for monitoring the initial strength of concrete using internal humidity history according to claim 1, wherein in the fourth step, the strength of each member position of the concrete structure is predicted from the humidity history information received for each humidity sensor installed at a plurality of member positions. The method of monitoring initial strength of concrete using internal humidity history according to claim 1, wherein in the fourth step, the experimental values measured based on a database on internal humidity-strength correlation are converted into the mixing ratio estimation mode of the initial mixing ID. . An information storage unit that stores information for each concrete mix ID;
Among the specimens for each mix ID produced according to the above information, a specimen of the same mix was prepared as a specimen for humidity measurement with a concrete embedded humidity sensor attached and a specimen for strength measurement without the humidity sensor attached, and the specimen for humidity measurement and strength were measured. A measurement value storage unit that cures a group of specimens for each mix ID and measures the concrete internal humidity and concrete strength from the specimens at regular time intervals at regular time intervals and stores them in a terminal;
An information processing unit regarding internal humidity-strength correlation for each formulation ID from the measured values; and
A concrete strength diagnosis system using internal humidity history consisting of a display unit that predicts and visualizes real-time strength when the actual internal humidity measurement value on site is input to the information processing unit. The method of claim 9, wherein the information for each mix ID in the information storage unit is a database stored according to cement type, water-cement ratio, aggregate size, aggregate content, and type and content of admixture. Concrete strength diagnosis system used. The concrete strength diagnosis system using internal humidity history according to claim 9, wherein the strength of each concrete age is predicted according to the curing time.