KR101186711B1 - Method for concrete curing using curing-controllable formwork system - Google Patents

Abstract

The present invention, the step of performing a test for obtaining the strength estimation coefficient, the step of installing the formwork body equipped with curing equipment, the step of installing a wireless thermometer in the formwork body, monitoring the temperature sensed through the wireless thermometer in real time And the step of building the curing system through the control unit for controlling the curing equipment in accordance with the temperature of the concrete monitored in real time, the step of inputting the input data to the control unit, and determines the demoulding time of the form body according to the strength estimation equation and the input data, Establishing the operation plan of the curing system according to the demoulding time, placing concrete and operating the curing equipment according to the operation plan of the curing system, real-time monitoring the temperature of the concrete through the controller, and monitoring the strength of the concrete through the monitored temperature. The estimated intensity meets the intensity setting conditions. When the compressive strength of the concrete site curing specimens is tested, the compressive strength of the concrete specimens is tested, and if the test results meet the conditions for setting the compressive strength, the operation of the curing equipment is stopped and the form body is deformed to carry out subsequent work. It provides a concrete curing method comprising the step. Therefore, after the concrete is poured, the temperature history of the concrete itself is monitored in real time, the curing state of the concrete is estimated from the measured temperature history, and the strength is predicted to determine the mold demoulding timing to support the subsequent process as soon as possible. Can be.

Description

Method for concrete curing using formwork system that can control curing {Method for concrete curing using curing-controllable formwork system}

The present invention relates to a concrete curing method using a formwork system capable of curing control, and more particularly, to a concrete curing method using a formwork system capable of curing control to secure the quality of the concrete structure and shorten the framework air. will be.

In general, after the concrete is placed, the form remains until the concrete hardens and can withstand the load, but based on the compressive strength (fcu) of the concrete, 5 MPa or more for sidewalls such as expansion foundations, beams, columns, etc. In case of slab, beam bottom and arch inner surface, more than 2/3 (14MPa or more) of the design standard strength is to be applied. However, when the concrete compressive strength is not tested, the foundations, beams, columns and side walls are to be maintained for a certain period of time, dismantled from the unloaded part and pay attention to form and concrete breakage. Here, for a certain period of time to maintain the concrete, for the rough steel cement, ordinary cement and blast furnace cement, blast furnace cement and fly ash cement, the average temperature is 2 days, 4 days, 5 days, the average temperature is 10 ℃ If it is ˜20 ° C., it is 3 days, 6 days, and 8 days.

Therefore, in most of the domestic sites, a set of three test specimens are manufactured to confirm the 5MPa or more capable of dismantling wall formwork when concrete is poured, and the compressive strength test is performed, where the strength of the three average specimens is 5MPa or more. , Dismantling is possible. On the other hand, the daily average temperature falls below 10 degrees for about five months from late autumn to early spring, and the average daily temperature falls below 4 degrees for about two months from the end of December to the middle of February. In the case of many domestic countries, it is essential to adhere to the form life span through curing management for concrete quality.

However, in the related art, the compression strength test timing of the specimen which can be dismantled in the mold is incorrectly judged, and thus it is not possible to dismantle in a timely manner, which often causes a problem in the progress of the subsequent process. Particularly, in the case of slip form or ACS foam, which is mainly applied to a member having a large cross section, due to the characteristics of the method of continuously pouring concrete, it is impossible to determine the mold demoulding timing through strength prediction, which causes air delay. A problem occurred.

An object of the present invention is to provide a concrete curing method using a formwork system capable of curing control to estimate the curing state of the concrete, predict the strength and determine the formwork demoulding time to enable a subsequent process within a short time.

The present invention, the concrete body is poured into the formwork body, the formwork body is provided, curing equipment for inducing curing of the concrete by supplying heat to the concrete, installed in the formwork body to sense the temperature of the concrete, and detect One or a plurality of wireless temperature measuring instruments for wirelessly transmitting the temperature and the strength estimation information for the concrete mixture to be poured in the field are stored, and receiving the movement or demoulding time information of the form body from the user, the wireless temperature It provides a formwork system including a control unit for controlling the curing equipment to fit the time information on the basis of the temperature and the strength estimation information of the concrete monitored in real time through a measuring instrument.

In addition, according to another aspect of the present invention, the present invention, by performing a test to obtain a strength estimation coefficient by producing a test specimen for the concrete mixture to be poured in the field, heat for curing the concrete to be poured Installing a form body equipped with a curing device for supplying, and installing a plurality of wireless thermometers for sensing the temperature and wirelessly transmitting the detected temperature to the form body, the temperature detected by the wireless thermometers in real time The step of building a curing system through a control unit for controlling the curing equipment according to the temperature of the concrete monitored in real time and monitored in real time, input data including the construction conditions of the concrete structure to be constructed in the field and the form body information Inputting to the controller, the strength estimation equation and the input Determining the demolding time of the form body according to the data, and establishing an operation plan of the curing system according to the demolding time, placing concrete in the form body according to the operation of the curing system and providing the control unit according to the curing system. Operating the curing equipment by the step, real-time monitoring the temperature of the concrete guided by the curing equipment through the control unit, and estimating the strength of the concrete through the monitored temperature, the estimated strength is Testing the compressive strength of the on-site curing specimens made of the same or similar concrete as the concrete when the strength setting conditions are satisfied; and testing the compressive strength of the on-site curing specimens to satisfy the compressive strength setting conditions. Phases and phases to stop equipment It provides a concrete curing method comprising the step of demolding the formwork body to perform subsequent work.

In addition, according to another aspect of the present invention, the present invention, by preparing a test specimen for the concrete mixture to be poured in the field to perform a test for obtaining the coagulation rate estimation formula and strength estimation coefficient coefficient, curing the concrete to be poured Installing a form body equipped with curing equipment for supplying heat to be installed, and a plurality of wireless thermometers for sensing the temperature and wirelessly transmitting the detected temperature to the form body, the sensing through the wireless thermometer Monitoring the temperature in real time and constructing a curing system through a control unit for controlling the curing equipment according to the temperature of the concrete to be monitored in real time, including the construction conditions of the concrete structure to be constructed in the field and information of the form body Inputting said input data to said control unit, said intensity Determining a moving time of the form body according to a formality and the input data, and establishing an operation plan of the curing system according to the moving time, placing concrete on the form body according to the operation of the curing system, and Operating the curing equipment by the control unit, real-time monitoring the temperature of the concrete guided by the curing equipment through the control unit, and estimating the strength of the concrete through the monitored temperature, When the estimated strength satisfies the strength setting condition, the step of testing the compressive strength of the site cured specimen made of the same or similar concrete as the concrete and the compressive strength of the concrete site cured specimen were tested. If satisfied, start the curing equipment. It provides a concrete curing method comprising the step of stopping and moving the formwork to perform subsequent work.

Therefore, the present invention, after pouring concrete, monitors the temperature history of the concrete itself in real time, estimates the curing state of the concrete from the measured temperature history of the concrete, predicts the strength and determines the mold demoulding time to follow up the process within a short time I can support this to be possible.

In addition, the present invention can secure the quality of the concrete structure, can shorten the frame air, the wireless network using a Zigbee (Zigbee) in large form (G / F or Slip Form, ACS Form) ) Can be used to predict the strength of concrete in real time.

1 is a view schematically showing the configuration of a formwork system according to an embodiment of the present invention.
2 is a cross-sectional view of the wireless thermometer in FIG.
3 is a procedure showing a concrete curing method according to an embodiment of the present invention.
4 is a view schematically showing a method of climbing foam to which the concrete curing method of FIG. 3 is applied.
FIG. 5 illustrates an overall configuration diagram of a curing system including the wireless thermometer and the controller of FIG. 1.
FIG. 6 illustrates an embodiment in which basic data is input in the curing system of FIG. 5.
FIG. 7 illustrates an embodiment in which the maturity and compressive strength of concrete calculated from the temperature data transmitted from the curing system and the temperature data are output on the monitor screen as a graph.
8 shows a flowchart of concrete curing quality control in the site by the curing system.
9 is a graph showing the result of comparing the compressive strength of the concrete structure estimated using the temperature data history transmitted from the curing system with the strength of the core taken from the actual structure.
10 is an embodiment of the electric heater arrangement of the curing equipment in the curing system.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 1, a formwork system according to an embodiment of the present invention includes a formwork body 100, curing equipment 200, wireless temperature measuring instruments, and a controller 400.

The formwork body 100 is a known formwork body 100 installed to make a concrete structure 10 including walls, beams, columns, and the like, and has a receiving space in which concrete 10 is to be placed. . In this embodiment, the form body 100 is preferably formed of a steel sheet as a large formwork for making a large concrete structure. On the other hand, the formwork body 100, a climbing form (Climbing form (ACS form) and gang form (G / F; Gang form) or concrete 10, which is demolded by dismantling the formwork, while pouring the sliding form (sliding continuously) Sliding form) and slip form (Slip form) can be installed in a systemized formwork body 100, which can be installed and dismantled at a time by simplifying the assembly of a small member or the large size that does not repeat disassembly, and various Can be applied.

The curing equipment 200 serves to induce rapid curing of the concrete 10 by supplying heat to the concrete 10 to be poured in the form body 100, the heat generated is controlled As a result, the mold body 100 exhibits a curing temperature at which the die main body 100 can be demoulded within a predetermined time. The curing equipment 200, the heating wire 210 is disposed on the surface of the form body 100 at a predetermined interval, the heating wire 210 and the heat insulating material 220 which is coated on the surface of the form body 100. It is made, it is possible to adjust the amount of heat generated in accordance with the arrangement interval of the heating wire (210). Here, in the present embodiment, the curing equipment 200 was used as the electric heating wire and the heat insulating material as described above, which can be used as an embodiment according to the skeleton cycle (cycle), such as an electric hot air blower and an electric heat sheet. In addition, by supplying heat to the concrete 10, such as a heating device to induce curing of the concrete 10, and if the temperature is controlled to control the curing is all possible.

The wireless thermometer 300, one or more installed in the form body 100 detects the temperature of the concrete 10, and transmits the detected temperature wirelessly, the temperature sensor 310 and wireless Communication means 321 is included.

The temperature sensor 310 is inserted through the insertion hole formed in the form body 100, and measures the temperature of the concrete structure 10 after the concrete 10 is poured. The temperature sensor 310, in the present embodiment is shown a structure that is partially embedded in the concrete 10, but can be installed in contact with the surface of the concrete 10 in accordance with the form of the double hollow method. On the other hand, after lifting the form body 100, the groove portion of the concrete structure 10 resulting from the installation of the temperature sensor 310 is face-treated by the extraction proceeding in the subsequent work in the safety scaffold of the lower gauge.

The wireless communication unit 321 is connected to the temperature sensor 310 to wirelessly transmit the temperature detected by the temperature sensor 310 to the controller 400. The wireless communication means 321 may be any one selected from the Zigbee, RFID, infrared communication device, smart communication device, and code division multiple access (CDMA) terminal according to the structure of the form body 100 and the field environment. have. In this embodiment, the ZigBee has a simple structure and a ZigBee having excellent transmission without applying interference or blocking due to building materials in a complex site environment. The wireless communication means 321 may have a structure in which power is not supplied from the outside, and a battery is embedded in itself to supply its own power. Here, reference numeral 320 denotes a communication bridge that connects the temperature sensor 310 and the controller 400 to serve as a data relay on a network, and enables battery and commercial power operation.

2, the wireless communication means 321 and the temperature sensor 310 are integrally formed with each other. In this case, the installation method in the form body 100, the temperature sensor 310 is inserted into the iron plate of the form body 100 by using a gage for working the system form the body 100. The radio communication means 321 is fixed, and after the concrete 10 is placed, the concrete structure 10 surface temperature measurement is possible. On the other hand, the wireless communication means 321 and the temperature sensor 310, the form body 100 with respect to the structural shape, design, etc. of the concrete structure 10 may vary the installation position and number.

The control unit 400, the strength estimation information for the concrete 10 to be poured in the field is stored, receives the movement or demoulding time information of the form body 100 from the user, and in real time through the wireless thermometers It controls the curing equipment 200 to be suitable for the time information on the basis of the temperature of the concrete 10 and the strength estimation information of the concrete 10 to be described later. The control unit 400, the concrete 10 strength estimating program is built through the wireless temperature measuring instrument, it is made of a screen configuration through the graphic by estimating the strength through the real-time temperature sensor 310 data collection and temperature analysis A detailed description of the operation of the controller 400 will be described later. On the other hand, the present embodiment, using the concrete 10 strength estimation program built in the control unit 400 through the pre-simulation or required calorie analysis, such as heat insulation or surface heat for the surface of the form body 100 at an appropriate cost It is possible to select a curing method, and even after the concrete 10 is placed, it is possible to remotely control the curing equipment 200 through temperature management. In addition, in the present embodiment, when placing the winter concrete 10, the amount of heat and the installation location of the curing equipment 200 (heat source) is selected from the result of analyzing the required heat in advance, and then the appropriate temperature management level for securing the required strength. Can be simulated.

As described above, the formwork system according to the present embodiment, wireless measurement and monitoring of the temperature of the poured concrete 10 itself in real time, thereby controlling the curing equipment 200 can be optimally managed management In addition, it is possible to predict whether the die body 100 can be demoulded, and thus shorten the entire air, such as to accelerate the preparation of a subsequent process.

Thus, the curing method of the concrete through the formwork described above will be described.

Figure 3 is a process diagram showing a concrete curing method according to an embodiment of the present invention, with reference to the drawings to look at the concrete curing method, the following main configuration is substantially the same as the configuration of the formwork system described above Detailed description thereof will be omitted.

First, prior to placing the site concrete 10, a test specimen is prepared for the concrete 10 compounding to be placed in the field and subjected to a test for obtaining the strength estimation formula coefficient (S10).

Herein, the strength estimation coefficient is obtained by performing standard curing and air curing of the test specimen, obtaining a temperature history and compressive strength for each age, and obtaining a correlation between integration temperature, equivalent age, and compressive strength.

Then, install the formwork body 100 is provided with the curing equipment 200, and install a plurality of wireless thermometers in the formwork body (100) (S20).

As described above, after the form body 100 and the wireless thermometer is installed, the curing system is connected by connecting the wireless thermometer and the controller 400 (S30). The curing system transmits the information sensed by the wireless thermometers to the controller 400 wirelessly, and thus the controller 400 receives the temperature information (history) received from the wireless thermometer. Monitoring in real time, according to the temperature of the concrete 10 to be monitored in real time is a system that allows the control unit 400 to control the curing equipment 200.

As described above, after preparing the form body 100 and the curing system for pouring and curing the concrete 10, the step of inputting the input data to the control unit 400 (S40). Here, the input data, the construction conditions of the concrete structure 10 to be constructed in the field, for example, the type of the structure, such as walls, columns, beams, form of the form body 100 and the lifting method of the concrete 10 accordingly It is a series of information that can be selected by the user, including the information of the form body 100 and the lifting speed.

Thereafter, when the strength estimation equation and the input data are secured, the demoulding time of the form body 100 is determined according to the strength estimation equation and the input data, and an operation plan of the curing system is established according to the demolding time ( S50). At this time, the operation plan of the curing system includes determining the location and location of the curing equipment 200 to exert a curing temperature capable of demoulding the die body 100 within a predetermined time (Target day) according to the strength estimation equation. On the other hand, at this time, in determining the dismantling time by predicting the demolding strength of the form body 100, the strength prediction utilizes a strength estimation graph through the thermometer-side monitoring.

Placing concrete 10 in the form body 100 according to the operation of the curing system and operating the curing equipment 200 by the control unit 400 according to the curing system (S60).

Real-time monitoring the temperature of the concrete 10 guided by the curing equipment 200 through the control unit 400, and estimates the strength of the concrete 10 through the monitored temperature (S70) .

Thereafter, it is determined whether the strength setting condition is satisfied (S80).

When the estimated strength satisfies the strength setting condition, the compressive strength of the concrete 10 spot curing specimen is tested (S90). Here, the on-site curing specimens refer to specimens made of the same or similar concrete 10 as the concrete 10 to be poured.

Then, by testing the compressive strength of the concrete 10 site curing specimens to determine whether the test results satisfy the compressive strength setting conditions (S100). Here, the strength setting condition of the concrete 10 is 5MPa or more capable of disassembling the formwork when placing concrete, and it is determined whether the form main body 100 can be demoulded by checking the expression of the strength setting condition.

On the other hand, if the compressive strength test results do not satisfy the compressive strength setting conditions, by controlling the curing equipment 200 through the control unit 400 (S110), real-time monitoring the temperature of the concrete 10 again, monitoring The process of estimating the strength of the concrete 10 through the temperature is repeated (S70). Here, the control unit 400, by testing the compressive strength of the site curing specimens, if the test results do not meet the compression strength setting conditions, the mold demolding time (Target day) of the form body 100 in accordance with the operation of the curing system The curing unit 200 is controlled to exhibit the curing temperature of the concrete 10 so that the die body 100 can be demolded in the die body 100. That is, the controller 400 controls the heating temperature of the curing equipment 200 or operates the additional curing equipment 200 when lack of strength expression due to a sudden drop in external temperature or the test result is not approved. Reapprove by (automatic control).

On the other hand, if the test result satisfies the compression strength setting conditions, the operation of the curing equipment 200 is stopped (S120).

Then, the mold body 100 is demolded to perform subsequent work (S130). At this time, since the form body 100 is provided with the wireless temperature measuring instrument, the form body 100 provided with the wireless temperature measuring instrument can be utilized as it is without the need for providing the wireless temperature measuring instrument to the form body 100 again. have.

On the other hand, the concrete curing method of the bar, the form body 100, after curing the climbing form (Climbing form) or gang form (Gang form) form of the die body 100 to lift and raise it to cure As a preferable concrete curing method for the case, Figure 4, as shown briefly showing the CGS (Climbing guiderail system) method of the lifting method of the formwork to which the concrete curing method of the present embodiment described above, the present CGS method, as well as the present embodiment As the formwork body 100 applied to the concrete curing method of the example, a method of lifting in various forms, such as a guide rail climbing system (GCS) method, an ACS (Automatic Climbing System) method and a rail climbing system (RCS) can be applied.

Looking at the concrete curing method according to another embodiment of the present invention when the form body 100 is a sliding form (Sliding form) or a slip form (Slip form) that is continuously raised while pouring concrete 10 as follows. same.

Concrete curing method according to another embodiment of the present invention, compared with the concrete curing method of Figure 3, from the step of performing a test for obtaining the strength estimation coefficient coefficient, inputting the input data to the control unit 400 The process is substantially the same, and the process thereafter is similar. However, in another embodiment of the present invention, since it is a curing method of continuously raising the formwork body 100 while pouring concrete 10, the condensation rate estimation formula and the strength estimation formula and the input data are secured accordingly. Determining the movement time of the formwork body 100, according to the operation plan of the curing system, and then made the step of moving the formwork body 100 to perform subsequent work.

In order for the strength predicted by the formwork system and the concrete curing method to be the same as the test result of the compressive strength of the actual specimen, the result value will be more accurate as D / B is established through continuous field monitoring. . On the other hand, it is possible to install and operate not only the temperature of the concrete structure 10 but also the temperature in the winter curing space by the wireless temperature measuring instrument so as to be confirmed in real time in the field office, and by the bidirectional signal of the wireless temperature measuring instrument. It can be systemized to allow remote control.

Hereinafter, referring to FIG. 5 to FIG. 10, the concrete curing management system will be described.

Figure 5 shows the overall configuration of the thermometer side of the concrete and the wireless transmission and reception system. Here, the wireless transmission / reception system of FIG. 5 has a difference in configuration and terminology on a network such as a server as compared to a system including the wireless temperature measuring instrument and the controller of the present invention of FIG. The main configuration for wireless transmission can be said to be substantially the same configuration.

Referring to FIG. 5, the concrete curing management system is a system for managing the curing of concrete by transmitting temperature data measured in the concrete curing process through a wireless communication network to a PC and analyzing the temperature sensor 310 and a signal processor 311. ), A Zigbee 321, a reception modem 322, and a PC 401, 402, and it is possible to further include a server 500.

The temperature sensor 310 is generally used thermocouple (Tr-Type), which is confirmed to be excellent in the measurement range or accuracy for the temperature measurement of concrete made in the laboratory, but the cost is expensive and construction site It is unreasonable to apply in. Therefore, in this system, it is preferable to apply a thermistor (resistance value of 15 kV) that can be measured up to -30 ~ 100 ℃ (error range: ± 1 ℃). Thermistors are not only physically similar to thermocouples, but also much cheaper, and are the most suitable considering the temperature conditions caused by the heat of hydration of concrete and domestic outdoor air temperature conditions.

The signal processor 311 includes a constant voltage unit and a filter unit. The constant voltage unit relays a power supply for operating the temperature sensor 310, and the filter unit removes a noise signal transmitted from the temperature sensor 310. The power supply method may be both a method of directly supplying power using a power cable and a method of supplying power using a storage battery.

The Zigbee 321 is composed of a CPU board, a power board and a wireless modem. The CPU board includes an analog digital converter (ADC), a CPU, a flash ROM, and an SDRAM, and digitally converts data passed through the signal processor 311.

In addition, it is preferable that the power board is designed to proceed in a power saving mode, and thus power can be supplied only at a time when data is to be processed to save electricity.

The wireless modem serves to wirelessly transmit the temperature data provided from the CPU board, and the present invention usually has an office in the field and performs wireless transmission at a short distance.

Receiving modem 322 serves to receive the temperature data transmitted through the transmission wireless modem built in the Zigbee 321, the receiving modem 322 is a PC 401 and RS232C cable or USB cable of the field office Will be connected via

Here, the method of wirelessly transmitting temperature data from the ZigBee 321 to the PC 401 may use any one of infrared rays, Zigbee, Bluetooth, and RF. However, in the present invention, it is preferable to use a local area network because it is sufficient to be able to use it in the field rather than a long distance.

That is, in this embodiment, it is preferable to use the Zigbee communication method. Unlike conventional wireless sensor networks, ZigBee communication is attracting attention as a short-range communication that can be operated at low cost, low speed, and low power in homes and offices.It has a small amount of data but can last several months or years with a single battery. This is because of its advantages, network flexibility and scalability.

In addition, the temperature data information received by being connected to the reception modem 322 through an RS232C cable or a USB cable should be stored in the PC 401, and the PC 401 should be provided with curing management software.

In addition, the temperature data transmitted to the PC 401 is stored in a predetermined server through a wired or wireless communication network, it is possible to download and utilize the PC anywhere. In other words, if the temperature data is stored in the server, even if the expert does not reside in the field, in case of emergency, the expert can download the temperature data from the server and advise on the abnormality during concrete curing. If so, an expert can also run software that calculates the compressive strength by calculating the maturity level.

The curing management software estimates the compressive strength of the concrete by using the temperature data of the transmitted concrete to determine whether there is an abnormality in the concrete curing process and to respond immediately, and further curing, demoulding of the formwork and the progress of the subsequent process. Makes sense.

The curing management software mounted on the PC 401 is a basic data input module for inputting a condition related to concrete curing, and the maturity and compression of concrete for estimating concrete strength using the input basic data and received temperature data. It includes a calculation module for calculating the strength and the output module for outputting the received temperature data, the maturity of the concrete and the compressive strength as a graph over time on the monitor screen.

The basic data input module inputs basic contents related to concrete curing to a computer. The basic data input includes basic physical properties of concrete to be poured and an installation position of a temperature sensor for each channel of Zigbee.

Figure 6 shows an embodiment of the appearance that the basic data is input in the concrete curing management system. Referring to Figure 6, as the basic properties of the concrete 28 days strength of the ready-mixed concrete (below Equation 8) f ' _c (28): age of compressive strength of 28 days, corresponds to), which is applied to Equation 8 below Information necessary for applying the following Equations 1, 2, and 3, such as a and b, is input. In addition, the temperature sensor for each channel of Zigbee is also input.

The maturity of concrete in the calculation module is calculated by the equivalent age by Nurse-Saul function or Arrhenius equation, and the compressive strength of concrete is calculated by the modified equation of ACI strength estimation equation.

In this embodiment, ultimately, the strength of concrete is to be estimated, and for this purpose, a maturity method is used to estimate the strength of concrete from the temperature history measured in real time from the concrete structure. That is, the temperature data measured and transmitted by the wireless sensor network is converted into a temperature change graph by the concrete curing management software, and then, it is constructed to calculate the concrete maturity and estimate the compressive strength from the relationship between temperature and time. .

First, the maturity of concrete is calculated by the equivalent age using the Nurse-Saul function or Arrhenius equation.

Equivalent age (T _es or T _ea ) of concrete shown in Equation 1 and Equation 2 is the structure of the concrete concrete whose temperature history is not constant due to the heat of hydration of cement and the influence of the outside temperature or curing method, the cross-sectional size of the member, etc. The degree of curing (or maturity) of the concrete in the structure whose temperature history is not constant due to the curing method and the cross-sectional size of the member is the standard curing period corresponding to the maturity of the specimens cured in water at or around 20 ℃, the standard curing condition. The converted value. That is, by measuring the temperature history of the structure from the point of concrete placement to a certain point, it is possible to calculate the equivalent age of the concrete up to that point. In this system, the compressive strength was estimated by substituting the calculated equivalent age into the strength-expression equation of the aged cured concrete.

Where T _es : equivalent age (hr or day) by the Nurse-Saul function

T _r : Standard curing temperature (℃), 20 ℃ for calculating equivalent age

        θ: Daily average temperature (or average concrete temperature) (℃)

T ₀ : Standard temperature (℃), generally -10 ℃

Where T _ea : equivalent age (hr or day) by the Arrhenius equation

T _a : 293 ℃, absolute temperature (K) + 20 ℃

E: Activation energy (intrinsic value according to cement type), in case of Class 1 cement, when T _a ≤20 ℃, E = 33.5 + 1.47 (20-T _a ) KJ / mol, T _a ≥20 ℃ E = 33.5 KJ / mol

        R: Gas constant 8.314 J / mol˚K

Next, the compressive strength of the structural concrete uses a modified formula of the ACI strength estimation equation. That is, as shown in Equation 3 below, by converting the equivalent age (T _es or T _ea ) calculated from the temperature history instead of the actual age (t) to the age (t _e ) of the right side. In addition, the compressive strength of 28 days means the average compressive strength of the 28 days of the age when the concrete applied to the site as a standard curing, but in order to estimate the strength to the safety side in consideration of the temperature difference according to the part of the structure, applying the nominal strength of the ready-mixed concrete It is also possible.

Where f ' _c (t) is the concrete compressive strength at actual age t

t: arbitrary actual age

t _e : equivalent age at any age t

f ' _c (28): compressive strength at 28 days of age. It is appropriate to apply the nominal strength of the applied concrete in order to estimate the strength to the safety side in all parts of the structure.

a, b: Coefficients according to the mixing conditions of concrete. 4.0 and 0.85 are applied for general formulations using ordinary Portland cement. However, in the case of ordinary Fordland cement applied concrete, the early strength expression property is excellent when the crude admixture is applied. Therefore, the coefficient value is calculated from the 7-day and 28-day strength of the standard curing regime of concrete. Is correct.

9 is a graph showing the result of comparing the compressive strength of the concrete structure estimated by using the temperature data history transmitted from the concrete curing management system of the present invention and the strength of the core taken from the actual structure.

Referring to FIG. 9, it can be seen that the estimation result and the actual tendency of compressive strength expression of the structure are very similar. In addition, it is possible to increase the accuracy of the strength estimation result by grasping the relationship between the maturity and the compressive strength by the temperature history of the site curing specimens made of concrete applied to each sage.

In addition, the curing management software mounted on the PCs 401 and 402 can select start, pause, continuation, and end of work for collecting and analyzing data.

FIG. 7 illustrates an example in which the maturity and compressive strength of concrete calculated from the temperature data transmitted from the concrete curing management system and the temperature data are output on a monitor screen in a graph.

As shown in FIG. 7, the transmitted temperature data can be shown in graphs over time on the monitor screen by the curing software. In addition, it is possible to calculate the maturity and compressive strength of concrete over time in the curing management software using the transmitted temperature data, and it is also possible to show a graph over time on the monitor screen.

8 shows a flowchart of concrete curing quality control in the site by the concrete curing management system of the present invention.

Referring to FIG. 8, after embedding the temperature sensor 310 at the site where the temperature history of the concrete is to be measured before the concrete is placed in the site, the temperature sensor 310 is connected to the Zigbee installed at the site to start the thermometer side. . When concrete pouring begins, real-time measurements of the concrete temperature and temperature history over time are made, and the measured temperature values are simultaneously transmitted to a receiver connected to the PC in the field office. The transmitted temperature data is stored on the field computer and displayed on the screen, and stored on the server via the internet network, so that the temperature data can be shared with concrete specialists in remote offices to receive technical support for concrete curing management. have.

On-site quality control personnel can check the temperature change of structural concrete in real time and estimate the degree of strength development of concrete at any point in time, and manage curing in response to various on-site conditions including changes in external weather environment conditions. You can do Through this process, it is possible to determine the adequacy of the curing management in real time, and to determine the additional curing period or when to start the subsequent process.

10 is an embodiment of the electric heater arrangement of the heating device (curing equipment).

The electric heater is a spiral coil that generates heat by electricity, a cylindrical heating tube through which air flowing from the outside comes into contact with the spiral heating coil and is heated, and blows the heated air to a distance with a constant pressure. Possible blower fan, cut-off sensor to automatically cut off the power supply when the temperature of heating equipment is over a certain level or the temperature of the rapid heating space is over a certain level, even if the power supply of the heater is stopped due to the temperature rise of the heating equipment. Is configured to include an automatic on-off device to keep it running.

In addition, the electric heater has an integrated metal cover for protecting the heating device from the mixing water or paste falling from the slab formwork gap of the concrete pouring layer, the blowing height of the heating device is about 1m when the lignite stove is applied in parallel to the lignite stove heat It can be configured to further include a pedestal for fixing and supporting the heating device to blow out, it is also possible to configure the turntable device to rotate like a fan.

In addition, in using the electric heater, the electric heaters installed in the same household using a power supply socket installed in the electric heater and connected to a power supply cable may be connected in parallel.

The electric heater is not necessarily used alone, but may be used in parallel with a heating device using a conventional fossil fuel. At this time, when the blower is continuously operated by the automatic on-off device serves to convection the heat generated in the heating device using a conventional fossil fuel in the curing space.

On the other hand, the heating device may be a heating device according to a preferred embodiment of the present invention, or a heating device using a conventional fossil fuel such as lignite. In addition, the form surface rapid heating method by the electric heating wire is capable of adjusting the calorific value (20 ~ 30W / m) according to the hot wire interval. For example, when the heating wires are arranged at 20 cm intervals per 1 m ² , the length of the heating wires is 5 m, so 100 to 150 W / m ² of heat can be supplied. In the case of installation on site, the installation is completed by arranging heating wire on the surface of steel sheet or wooden formwork and then covering insulation on the final surface.

As described above, the concrete curing method according to the present embodiment, the formwork body 100 is provided with a wireless temperature measuring instrument and curing equipment and comprises a control unit for controlling the curing temperature by monitoring the temperature of the concrete in real time Through the system, if the curing degree of concrete to obtain the target strength is determined in advance, and the time required for the required strength to be expressed, the target temperature can be maintained so that the subsequent process can be prepared quickly. Can shorten the air.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10 ... concrete structure 100 ... formwork body
200 ... Curing Equipment 210 ... Heating
220. Insulation material 300 .. Wireless thermometer
400 ... control unit

Claims (15)

delete delete delete delete delete Preparing a test specimen for the concrete mixture to be poured in the field and performing a test to obtain a strength estimation coefficient;
Installing a formwork body equipped with curing equipment for supplying heat for curing concrete to be poured, and installing a plurality of wireless thermometers for sensing a temperature and wirelessly transmitting the sensed temperature to the formwork body;
Monitoring the temperature sensed by the wireless temperature measuring instruments in real time and establishing a curing system through a control unit controlling the curing equipment according to the temperature of the concrete monitored in real time;
Inputting, to the controller, input data including construction conditions of the concrete structure to be constructed in the field and information of the form body;
Determining a demolding time of the form body according to the strength estimation equation and the input data, and establishing an operation plan of the curing system according to the demolding time;
Placing concrete on the form body according to the operation of the curing system and operating the curing equipment by the control unit according to the curing system;
The temperature of the concrete guided by the curing equipment is monitored in real time through the controller, and the strength of the concrete is estimated through the monitored temperature, and if the estimated strength satisfies the strength setting condition, Testing the compressive strength of on-site cured specimens made of the same or similar concrete;
Testing the compressive strength of the concrete site curing specimens and stopping the operation of the curing equipment if a test result satisfies the compression strength setting condition; And
Concrete curing method comprising the step of performing the subsequent work by demolding the formwork body. Preparing a test specimen for the concrete mixture to be cast in the field and conducting a test to obtain a condensation rate estimation formula and a strength estimation coefficient;
Installing a formwork body equipped with curing equipment for supplying heat for curing concrete to be poured, and installing a plurality of wireless thermometers for sensing a temperature and wirelessly transmitting the sensed temperature to the formwork body;
Monitoring the temperature sensed by the wireless temperature measuring instruments in real time and establishing a curing system through a control unit controlling the curing equipment according to the temperature of the concrete monitored in real time;
Inputting, to the controller, input data including construction conditions of the concrete structure to be constructed in the field and information of the form body;
Determining a movement time of the form body according to the condensation speed estimation equation and the strength estimation equation and the input data, and establishing an operation plan of the curing system according to the movement time;
Placing concrete on the form body according to the operation of the curing system and operating the curing equipment by the control unit according to the curing system;
The temperature of the concrete guided by the curing equipment is monitored in real time through the controller, and the strength of the concrete is estimated through the monitored temperature, and if the estimated strength satisfies the strength setting condition, Testing the compressive strength of on-site cured specimens made of the same or similar concrete; And
And testing the compressive strength of the concrete site curing specimen and stopping the operation of the curing equipment and moving the form body to perform subsequent work if the test result satisfies the compression strength setting condition. The method according to claim 7 or 8,
The wireless thermometer may be provided with a battery to secure its own power source,
The wireless temperature measuring instrument includes a temperature sensor for measuring the temperature of the concrete that is inserted through the insertion hole formed in the form body and the wireless communication means for wirelessly transmitting the detected temperature in combination with the temperature sensor to the controller. Concrete curing method comprising a. The method according to claim 8,
The wireless communication means, Zigbee (Zigbee), a concrete curing method comprising any one selected from RFID, infrared devices, smart communication devices and CDMA terminal. The method according to claim 8,
The temperature sensor,
Concrete curing method installed in the surface contact with the surface of the concrete, or embedded in the concrete. The method according to claim 7 or 8,
The strength estimation coefficient is
The concrete curing method obtained by performing the standard curing and air curing of the test specimen, and obtain the correlation between the cumulative temperature, equivalent age and compressive strength by obtaining the temperature history and compressive strength for each age. The method according to claim 7 or 8,
The control unit,
If the test results do not satisfy the compressive strength setting conditions by testing the compressive strength of the concrete site curing specimens, the form body is demoulded or moved within the mold body during the mold body movement or target day according to the operation of the curing system. Concrete curing method for controlling the curing equipment so that the curing temperature of the concrete to be exerted. The method of claim 7,
The form body is a concrete curing method (Climbing form) or Gang form (Gang form). The method according to claim 8,
The form body is a concrete curing method of the sliding form (Sliding form) or slip form (Slip form) to continuously raise while pouring concrete. The method according to claim 7 or 8,
The curing equipment, concrete curing method is any one selected from the electric hot air fan, electric heating wire and electric heating sheet.

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