KR20220088400A - System for Controlling Curing Temperature of Concrete - Google Patents

Abstract

A curing temperature management system for concrete is disclosed. The concrete curing temperature management system according to an embodiment of the present invention collects the surface temperature and internal temperature of the concrete, the humidity of the concrete, the atmospheric temperature of the area where the concrete is poured, and the temperature of the gangform wall through a plurality of temperature sensors and humidity sensors. receiving the curing temperature specified by the surface temperature and the internal temperature of the concrete and the ambient temperature of the zone from the data collection device of the zone in which the concrete is poured through a low-power wide area network, and the curing temperature and the atmosphere The current strength of the concrete is estimated based on the temperature, and the estimated current strength, the daily average temperature obtained from the weather forecast information received from an external source, and the concrete physical properties including the slump, air amount, chloride amount and curing temperature It is characterized in that it includes a curing temperature management device that determines the predicted strength of the concrete by time using the information, and transmits a control command generated according to the predicted strength to the maintenance control device through wireless communication.

Description

Curing Temperature of Concrete {System for Controlling Curing Temperature of Concrete}

The present invention relates to curing temperature management of concrete, and more specifically, monitoring the curing temperature and environmental information of concrete using a data collection device, and transmitting a control command generated using the monitoring result to the maintenance control device By doing so, it relates to a curing temperature management system for concrete that manages the curing temperature of concrete.

Due to the 4th industrial revolution such as smart city and smart construction, the overall industry paradigm is changing, and technological development such as collecting, managing, and visualizing a vast amount of data through technology is progressing. This is becoming active.

Concrete is the most used material enough to occupy an abnormality in construction structures, and since it is produced by mixing various materials such as cement aggregate, water and admixture, the strength development characteristics change according to environmental conditions.

Curing of concrete is the operation of protecting concrete from freezing and retaining moisture so that it fully exerts its hardening action until it is completely hardened after pouring. If the curing temperature of concrete is low, the curing speed of concrete also decreases.

The process of managing the curing temperature of concrete is the process of measuring the curing temperature of the poured concrete, estimating the compressive strength of the concrete using the curing temperature, and based on this, it is the process of demolding the formwork and determining whether to proceed with the subsequent process. It is an important process.

The general method of most construction sites is that the manager personally visits the site and collects the temperature measurement results manually. Specifically, after measuring temperature, humidity, salinity, strain, etc. using a wired data automatic recording means, the work situation and future schedule are determined based on the measurement results based on the operator's experience.

However, since the manager must directly check the measured curing temperature and take appropriate measures, not only does work efficiency decrease, but also prompt response is difficult, and workers have to stay permanently at the health care site. They are exposed to the risk of safety accidents such as disasters.

Therefore, there is a need for a technology for a system for efficiently managing the curing temperature of concrete.

The present invention measures the curing temperature of concrete and controls the maintenance control device based on the measured results so that the curing temperature of concrete can be efficiently managed because it does not require a site visit of the operator or a decision based on the operator's experience. provides a system that

The present invention provides a system capable of determining whether to proceed with demolding of the formwork and subsequent processes by determining the current and predicted strength of concrete using the curing temperature of the concrete.

The curing temperature management method for managing the curing temperature of concrete according to an embodiment of the present invention comprises the steps of receiving the curing temperature of the concrete and the atmospheric temperature of the zone from the data collection device for collecting the curing temperature of the zone in which the concrete is poured ; estimating the current strength of the concrete based on the curing temperature and the ambient temperature; determining the predicted strength of the concrete for each time using the current strength, the weather forecast information, and the physical property information of the concrete; and transmitting a control command generated according to the predicted strength to the maintenance control device to control the curing temperature of the concrete.

The physical property information may include at least one of a slump of the concrete, an air amount, a chloride amount, and a curing temperature. The gangform demolding time of the concrete may be calculated based on the current strength, the weather forecast information, and the physical property information.

The maintenance control device may be connected to a cooler and a heater for controlling the curing temperature of the concrete.

The method may further include determining a time for the current strength to reach a target strength according to the control command in consideration of the current strength and the predicted strength.

The control command, when the curing temperature of the concrete is higher than the predetermined management temperature, the cooler of the maintenance control device may be a command to operate for a control time determined according to the difference between the curing temperature and the management temperature.

The method may further include transmitting the current strength and the predicted strength for each time to a user terminal in order to monitor the curing temperature of the concrete.

The curing temperature management method for managing the curing temperature of concrete according to an embodiment of the present invention receives the curing temperature of the concrete and the atmospheric temperature of the zone from a data collection device that collects the curing temperature of the zone in which the concrete is poured. to do; determining whether the concrete is abnormal based on the curing temperature and the ambient temperature; generating a control command in consideration of the detected abnormality when the abnormality of the concrete is detected; and transmitting the generated control command to a maintenance control device for controlling the curing temperature of the concrete.

When the abnormality of the concrete is detected, the method may further include transmitting an emergency notification to the user terminal.

In the determining of the abnormality, when the curing temperature does not belong to a preset reference temperature range, it may be determined that an abnormality has occurred in the concrete.

In the curing temperature management device for managing the curing temperature of concrete according to an embodiment of the present invention, the curing temperature management device includes a processor, the processor, data for collecting the curing temperature of the concrete is poured area Receive the curing temperature of the concrete and the atmospheric temperature of the zone from the collecting device, estimate the current strength of the concrete based on the curing temperature and the atmospheric temperature, the current strength, the weather forecast information, and the physical property information of the concrete It is possible to determine the predicted strength of the concrete for each time using using, and transmit a control command generated according to the predicted strength to the maintenance control device in order to control the curing temperature of the concrete.

The physical property information may include at least one of a slump of the concrete, an air amount, a chloride amount, and a curing temperature.

The processor, based on the current strength, the weather forecast information, and the concrete physical property information may calculate the gangform demolding time of the concrete.

The maintenance control device may be connected to a cooler and a heater for controlling the curing temperature of the concrete.

The processor may determine a time for the current strength to reach a target strength according to the control command in consideration of the current strength and the predicted strength.

The control command, when the curing temperature of the concrete is higher than the predetermined management temperature, the cooler of the maintenance control device may be a command to operate for a control time determined according to the difference between the curing temperature and the management temperature.

The processor may transmit the current strength and the predicted strength for each time to the user terminal in order to monitor the curing temperature of the concrete.

In the curing temperature management device for managing the curing temperature of concrete according to an embodiment of the present invention, the curing temperature management device includes a processor, wherein the processor collects the curing temperature of the area in which the concrete is poured. Receives the curing temperature of the concrete and the atmospheric temperature of the zone from the data collection device, determines whether the concrete is abnormal based on the curing temperature and the atmospheric temperature, and when the abnormality of the concrete is detected, the detected abnormality In consideration of generating a control command, it is possible to transmit the generated control command to the maintenance control device for controlling the curing temperature of the concrete.

The processor may transmit an emergency notification to the user terminal when the abnormality of the concrete is detected.

The processor, when the curing temperature does not belong to a preset reference temperature range, may determine that an abnormality has occurred in the concrete.

According to an embodiment of the present invention, the curing temperature of concrete is efficiently controlled because it does not require a site visit of the operator or a decision based on the operator's experience by measuring the curing temperature of the concrete and controlling the maintenance control device based on the measured result. can be managed with

According to an embodiment of the present invention, it is possible to determine the current strength and predicted strength of concrete using the curing temperature of the concrete to determine whether to proceed with the demolding of the formwork and the subsequent process, so that it is possible to comply with the process period and control the quality.

According to an embodiment of the present invention, since sensing information is collected by using LPWAN technology in collecting sensing information, the sensing information is simply installed through the installation of a sensor terminal without a separate installation due to the characteristics of an LPWAN capable of long-distance communication. It is possible to collect and secure communication stability.

1 shows the structure of a curing temperature management system according to an embodiment of the present invention.
Figure 2 shows a flow chart of a curing temperature management method according to an embodiment of the present invention.
3 is a flowchart of a curing temperature management method according to another embodiment of the present invention.
4 is a diagram illustrating a structure of a data collection device according to an embodiment of the present invention.
5 is a view showing the structure of the maintenance control device in an embodiment of the present invention.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, since various changes may be made to the embodiments, the scope of the patent application is not limited or limited by these embodiments. It should be understood that all modifications, equivalents and substitutes for the embodiments are included in the scope of the rights.

The terms used in the examples are used for the purpose of description only, and should not be construed as limiting. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as "comprise" or "have" are intended to designate that a feature, number, step, operation, component, part, or a combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the embodiment belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

In addition, in the description with reference to the accompanying drawings, the same components are given the same reference numerals regardless of the reference numerals, and the overlapping description thereof will be omitted. In describing the embodiment, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the embodiment, the detailed description thereof will be omitted.

1 shows the structure of a curing temperature management system according to an embodiment of the present invention.

The present invention relates to a method and apparatus for efficiently managing the curing temperature of concrete.

The curing temperature management system of the present invention includes a curing temperature management device 101 , a data collection device 102 , a maintenance control device 103 , and a user terminal 104 . The curing temperature management device 101 determines the current strength of concrete and the predicted strength according to time using the curing temperature and atmospheric temperature of the concrete measured from the data collection device 102 .

Then, the curing temperature management device 101 generates and transmits a control command for controlling the maintenance control device 103 in consideration of the determined current strength and the predicted strength. The maintenance control device 103 controls the curing temperature of the concrete by controlling the cooler or the heater according to the control command received from the curing temperature management device 101 .

The curing temperature management device 101 uses the predicted strength to determine the specimen test time, the concrete gang form demolding time, and the management temperature for compliance with the construction period. And, the curing temperature management device 101, the current strength determined using the curing temperature and the curing temperature of the concrete measured from the data collection device 102, the predicted strength, the gangform demolding time and the specimen test time, such as the user terminal 104 ) so that the manager can know the condition of concrete in real time.

The data collection device 102 and the curing temperature management device 101 are connected through a wireless communication network. As an example, the data collection device 102 transmits the sensing information collected by using a low power wide area network (LPWAN) technology suitable for IoT to the curing temperature management device 101 because resources for communication and calculation are insufficient. . For example, a low-power, long-distance, and low-range (LoRa) network that supports simultaneous access of multiple devices may be used.

The data collection device 102 may collect sensing information including the curing temperature of the concrete, the atmospheric temperature at the point where the concrete is poured, and the gangform wall temperature. The curing temperature is determined by measuring the surface temperature and internal temperature of the concrete. The data collection device 102 is connected to sensors such as a plurality of temperature sensors and humidity sensors, and collects sensing information through the temperature sensor or humidity sensor. The data collection device 102 transmits the sensing information to the curing temperature management device 101 .

The curing temperature management device 101 is a device including a processor and a wireless or wired communication terminal, such as a PC, a laptop computer, a desktop, or a tablet. The curing temperature management device 101 not only collects sensing information from the data collection device 102 , but also receives weather forecast information from an external source. Curing temperature management device analyzes the sensing information and public data received from the data collection device 102 using artificial intelligence technology and big data technology.

In addition, the curing temperature management device 101 is connected to the user terminal 104 through a wired network or a wireless network, and transmits an emergency notification to the user terminal 104, or schedules a situation such as a concrete gang form demolding time or current strength. It is transmitted to the user terminal 104 every cycle.

The user terminal 104 is a device including a processor and a wireless or wired communication terminal, such as a smart phone, PC, notebook, or tablet. Data received from the curing temperature management device 101 are provided as a user interface of the web or app. The condition of the site in which the concrete is poured may be monitored through the user terminal 104 .

In addition, the curing temperature management device 101 transmits a control command to the maintenance control device 103 via wireless communication. As an example, the curing temperature management device 101 and the maintenance control device 103 communicate through LTE technology. Specifically, the curing temperature management device 101 may use LTE Cat.M1 standardized in 3GPP to control the maintenance control device 103 .

The maintenance control device 103 is connected to a cooler and a heater for controlling the curing temperature of the concrete according to the control command of the curing temperature management device 101 . In one example, the cooler corresponds to the sprinkler, and the water heater corresponds to the hot air blower. The maintenance control device 103 may control the curing temperature of the concrete by controlling the cooler or the heat supply.

Figure 2 shows a flow chart of a curing temperature management method according to an embodiment of the present invention.

In step 201 , the data collection device 102 collects sensing information including the surface temperature of the concrete, the internal temperature, the atmospheric temperature of the area in which the concrete is poured, and the temperature of the gangform wall through the temperature sensor. The data collection device 102 collects the curing temperature of the concrete by collecting the surface temperature and the internal temperature. Specifically, the data collection device 102 collects sensing information at predetermined predetermined intervals. The cycle can be changed by the administrator.

In addition, the data collection device 102 may additionally measure humidity, salinity, strain, etc. as well as temperature. Accordingly, the sensing information may additionally include the humidity of the concrete, the humidity of the area where the concrete is poured, the salinity of the concrete and the strain rate of the concrete.

In step 202 , the data collection device 102 transmits the collected sensing information to the curing temperature management device 101 . As an example, the data collection device 102 transmits i) a curing temperature specified by the surface temperature and internal temperature of the concrete and ii) the ambient temperature to the curing temperature management device 101 . As an example, the data collection device 102 transmits sensing information by using an LPWAN.

The curing temperature management device 101 analyzes the curing temperature and atmospheric temperature of the concrete received from the data collection device 102, the weather forecast information and the physical property information of the concrete received from an external source, and manages the curing temperature of the concrete. Generate control commands. Public data may include weather forecast information received from an external source, such as a meteorological agency.

In step 203 , the curing temperature management device 101 estimates the current strength of concrete based on the curing temperature and the ambient temperature of the concrete received from the data collection device 102 . The current strength of concrete means the strength of concrete at the point in time when sensing information is collected.

In step 204, the curing temperature management device 101 determines the predicted strength of concrete for each time using the estimated current strength, weather forecast information obtained from an external source, and physical property information of concrete. In addition, the curing temperature management device 101 may additionally use previous records for the current strength estimation and the predicted strength estimation.

The physical property information of concrete may include at least one or more of slump, air amount, chloride amount, and curing temperature of concrete. The curing temperature management device 101 correlates and analyzes current strength, weather forecast information, and concrete property information based on big data.

은 일평균기온 또는 하루 평균 콘크리트의 양생 온도를 의미한다. Tr은 등가 재령 산정을 위한 표준 양생 온도를 의미하고, 주로 영상 20도씨이다.

t는 온도 측정의 시간 간격을 의미한다. In Equation 1, Tes means an equivalent age, To means a reference temperature, and is mainly minus 10 degrees Celsius.

is the average daily temperature or the average daily curing temperature of concrete. Tr means the standard curing temperature for calculating the equivalent age, and it is mainly 20 degrees Celsius above zero.

t denotes the time interval of temperature measurement.

In Equation 2, Tea means the equivalent age, and Ta means the average curing temperature of the concrete for dt time. Ts means 293 degrees Celsius and represents the result of adding absolute temperature (K) + 20 degrees Celsius. E is the activation energy determined by the type of cement. For example, in the case of type 1 cement, when Ta is below 20°C, the activation energy is determined to be greater than 33.5 KJ/mol, and when Ta is above 20°C, the activation energy is determined to be 33.5 KJ/mol . R stands for the gas constant.

And, the curing temperature management device 101 may determine the predicted strength over time from the equivalent age using any one of Equation 3 or Equation 4 below. Specifically, through Equation 1

In Equation 3, f'c(t) means the predicted strength of concrete at the actual age t. T is any real age. t _e means the equivalent age at any age t day and is determined by Equation 1 or 2. f'c(28) means the current intensity at the age of 28 days. And, a and b mean the coefficients according to the mixing conditions of the concrete.

That is, the curing temperature management device 101 may determine the equivalent age by using the daily average temperature obtained from the curing temperature and weather forecast information of the concrete, and determine the predicted strength over time in consideration of the mixing combination of concrete.

Alternatively, the curing temperature management device 101 may determine the equivalent age by using the activation energy determined according to the curing temperature of the concrete and the type of concrete, and determine the predicted strength over time in consideration of the mixing combination of concrete.

The curing temperature management apparatus 101 may determine the time for the current strength to reach the target strength according to the control command in consideration of the current strength and the predicted strength. The target strength may be determined in consideration of the strength required to proceed with the next process at the current point in the entire construction period in order to comply with the construction period.

When the current strength reaches the target strength, the strength of the specimen is checked, the gangform of the structure is demolded, and the next process of construction can proceed. The time to reach the target intensity means the time at which the predicted intensity with time becomes the target intensity. That is, the curing temperature management apparatus 101 may calculate how many hours or days after which the curing temperature is maintained by using the predicted strength to reach the target strength.

In addition, the curing temperature management device 101, based on the current estimated strength, weather forecast information, concrete physical property information, determines the predicted strength according to the elapsed time, and using the predicted strength test specimen test time or concrete gang form demolding time , it is possible to determine the management temperature for compliance with the construction period. For example, the specimen test time and the concrete gang form demolding time may correspond to the time when the current strength of the concrete reaches the target strength. In step 205 , the curing temperature management device 101 may determine the gangform demoulding time in consideration of the time to reach the target strength.

The specimen test is to confirm the strength of the specimen and proceed with the next process of the structure, and is a procedure conducted in the field laboratory to estimate the normal expression of the structure. If the strength of the specimen is not developed, the next process does not proceed.

And, the management temperature may be determined to comply with the construction period in consideration of the construction period, target strength, and current strength. As an example, the management temperature may be determined such that the greater the difference between the target strength and the current strength, the greater the difference from the curing temperature at the current time.

Then, the curing temperature management device 101 transmits a control command generated according to the predicted strength to the maintenance control device 103 in order to control the curing temperature of the concrete. Specifically, the curing temperature management device 101 may generate a control command based on the management temperature and the curing temperature.

When the curing temperature of the concrete is higher than the predetermined management temperature, the cooler of the maintenance control device 103 may be a command to operate for a control time determined according to the difference between the curing temperature and the management temperature.

When the curing temperature of the concrete is lower than the predetermined management temperature, in step 206, which is a command to operate the cooler of the retaining control device 103 for a control time determined according to the difference between the curing temperature and the management temperature, the curing temperature management device (101) transmits the generated control command to the maintenance control device (103). The maintenance control device 103 controls the cooler or the heater according to the received control command to adjust the curing temperature.

As an example, when the control command is a command to increase the curing temperature, the maintenance control device 103 operates the heater to increase the curing temperature. Alternatively, when the control command is a command to lower the curing temperature, the maintenance control device 103 operates the cooler to lower the curing temperature.

In step 207 , the curing temperature management device 101 transmits the current strength and the predicted strength for each time to the user terminal 104 to monitor the curing temperature of the concrete. In addition, the curing temperature management device 101 transmits the collected curing temperature, atmospheric temperature, time to reach the target strength, gang form demolding time, specimen test time, etc. to the user terminal 104 .

3 is a flowchart of a curing temperature management method according to another embodiment of the present invention.

In step 301 , the data collection device 102 collects sensing information including the surface temperature of the concrete, the internal temperature, the atmospheric temperature of the area in which the concrete is poured, and the temperature of the gangform wall through the temperature sensor. The data collection device 102 collects the curing temperature of the concrete by collecting the surface temperature and the internal temperature. Specifically, the data collection device 102 collects sensing information at predetermined predetermined intervals.

In addition, the data collection device 102 may additionally measure humidity, salinity, strain, etc. as well as temperature. Accordingly, the sensing information may additionally include the humidity of the concrete, the humidity of the area where the concrete is poured, the salinity of the concrete and the strain rate of the concrete.

In step 302 , the data collection device 102 transmits the collected sensing information to the curing temperature management device 101 . As an example, the data collection device 102 transmits i) a curing temperature specified by the surface temperature and internal temperature of the concrete and ii) the ambient temperature to the curing temperature management device 101 . As an example, the data collection device 102 transmits sensing information by using an LPWAN.

In step 303 , the curing temperature management device 101 determines whether the concrete is abnormal based on the curing temperature and the ambient temperature. The curing temperature management device 101 determines in advance a reference temperature section for curing temperature maintenance management. The reference temperature section may be determined in consideration of i) the construction period, ii) the progress period, iii) the current strength, and iv) the time to reach the predicted strength. Alternatively, the reference temperature section may be predetermined at the time of construction design according to the characteristics of the construction site (building method, mixing conditions, management method, etc.).

Alternatively, the formwork can be demolded only when the current strength reaches 5Mpa 24 hours before the concrete is poured. When the concrete formwork is demolded, the curing temperature management device 101 considers the time to reach the predicted strength (eg, 5Mpa) and generates an alarm when the predicted strength is reached, or the current strength is the target You can set an alarm to occur when the robbery occurs.

The curing temperature management device 101 determines that an abnormality has occurred in the concrete when the collected curing temperature does not belong to a preset reference temperature range. Alternatively, the curing temperature management device 101 determines an abnormal temperature section in advance, and when the curing temperature belongs to the abnormal temperature section, it is determined that an abnormality has occurred in the concrete.

The curing temperature management device 101 may set a reference humidity section in advance, and when the collected humidity does not belong to the reference humidity section, it may be determined that an abnormality has occurred in the concrete. Alternatively, the curing temperature management device 101 may determine whether the concrete is abnormal by applying different weights to the collected curing temperature or humidity, and determining whether the summed result falls within a preset abnormality criterion.

Alternatively, the curing temperature management device 101 may set a reference temperature section or a reference humidity section differently for each atmospheric temperature, and determine whether the concrete is abnormal according to the atmospheric temperature and the curing temperature received from the data collection device 102 . have.

In step 304 , the curing temperature management device 101 transmits the current strength, curing temperature, humidity, predicted strength, etc. to the user terminal 104 when an abnormality is detected in the concrete. In addition, the curing temperature management device 101 transmits an emergency notification to the user terminal 104, so that the manager can check whether the concrete is abnormal and take action. In addition, the curing temperature management device 101 transmits an emergency notification to the user terminal 104 when an abnormality occurs in the maintenance control device 103 .

In step 305 , the curing temperature management device 101 generates a control command in consideration of the detected abnormality when an abnormality is detected in the concrete. As an example, the curing temperature management device 101 generates a control command for lowering the curing temperature when the curing temperature is higher than the reference temperature section. Alternatively, the curing temperature management device 101 generates a control command to increase the curing temperature when the curing temperature is lower than the reference temperature section.

In step 306 , the curing temperature management device 101 transmits the generated control command to the maintenance control device 103 . The maintenance control device 103 controls the cooler or the heater according to the received control command to adjust the curing temperature.

As an example, when the control command is a command to increase the curing temperature, the maintenance control device 103 operates the heater to increase the curing temperature. Alternatively, when the control command is a command to lower the curing temperature, the maintenance control device 103 operates the cooler to lower the curing temperature.

In addition, the maintenance control device 103 transmits the operating state of the cooler or heater to the curing temperature management device 101 , and the curing temperature management device 101 sends the operating state of the cooler or heat supply to the user terminal 104 . send

4 is a diagram illustrating a structure of a data collection device 102 according to an embodiment of the present invention.

The data collection device 102 may collect sensing information including the curing temperature of the concrete, the atmospheric temperature at the point where the concrete is poured, and the gangform wall temperature. The curing temperature is determined by measuring the surface temperature and internal temperature of the concrete. The data collection device 102 is connected to sensors such as a plurality of temperature sensors and humidity sensors, and collects sensing information through the temperature sensor or humidity sensor. The data collection device 102 transmits the sensing information to the curing temperature management device 101 .

The data collection device 102 may include a communicator 407 , a sensing data collector 405 , and a processor 406 , and is connected to a plurality of sensors 401 - 404 . As an example, each sensor may be one of a temperature sensor and a humidity sensor.

The sensor may be installed in various locations. The sensor 402 for measuring the internal temperature or humidity of concrete, the sensor 401 for measuring the surface temperature or humidity of concrete, the sensor 403 for measuring the temperature or humidity of the gangform wall, and the air temperature or A sensor 404 that measures humidity may be used.

A plurality of sensors used at each location may be used according to the area of the concrete. Specifically, sensors may be embedded in the upper and lower portions of the concrete surface, respectively. The location where the sensor is buried or installed may vary depending on the concrete construction method, and may be installed around the lignite or inside the specimen.

The data collector collects sensing information from a plurality of sensors. The sensing data collector 405 collects sensing information from each sensor. At this time, the sensing information is stored separately for each position of the sensor, and is transmitted to the curing temperature management device 101 through the communicator 407 . The processor 406 controls the sensor, the sensing data collector 405 and the communicator 407 .

For example, the processor 406 controls the sensor and the sensing data collector 405 to collect sensing information at regular intervals. In addition, the processor 406 controls the communicator 407 to transmit the sensing information to the curing temperature management device 101 at regular intervals or whenever the sensing information is stored in excess of a certain amount.

The data collection device 102 and the curing temperature management device 101 are connected through a wireless communication network. For example, since the data collection device 102 lacks resources for communication and calculation, it transmits the sensing information collected using an LPWAN suitable for IoT to the curing temperature management device 101 . For example, a LoRa network supporting low-power, long-distance, and simultaneous access to multiple devices may be used.

5 is a view showing the structure of the maintenance control device 103 in an embodiment of the present invention.

The maintenance control device 103 is connected to the cooler 502 and the heat exchanger 501 for controlling the curing temperature of the concrete according to the control command of the curing temperature management device 101 . In one example, the cooler 502 corresponds to a water sprinkler, and the water heater 501 corresponds to a hot air blower. The maintenance control device 103 may control the curing temperature of the concrete by controlling the cooler 502 or the heater 501 .

The maintenance control device 103 includes a communicator 505 , a controller 503 , and a processor 504 . The care control device 103 may receive a control command from the care temperature management device 101 through the communicator 505 , or transmit state information of the care care control device 103 to the care temperature management device 101 . As an example, the curing temperature management device 101 and the maintenance control device 103 communicate through LTE technology. Specifically, the curing temperature management device 101 may use LTE Cat.M1 standardized in 3GPP to control the maintenance control device 103 .

The processor 504 of the maintenance control device 103 processes the received control command to control the cooler 502 or the heater 501 through the controller 503 . As an example, when the control command is a command to increase the curing temperature, the maintenance control device 103 operates the heater 501 to increase the curing temperature. Alternatively, when the control command is a command to lower the curing temperature, the maintenance control device 103 operates the cooler 502 to lower the curing temperature.

In addition, the maintenance control device 103 cures the status information of the maintenance control device 103 (the operating state of the cooler or heater, the temperature of the maintenance control device 103, etc.) at regular intervals for diagnosing whether the device is malfunctioning. It can transmit to the temperature management device 101 .

Meanwhile, the method according to the present invention is written as a program that can be executed on a computer and can be implemented in various recording media such as magnetic storage media, optical reading media, and digital storage media.

Implementations of the various techniques described herein may be implemented in digital electronic circuitry, or in computer hardware, firmware, software, or combinations thereof. Implementations may be implemented for processing by, or controlling the operation of, a data processing device, eg, a programmable processor, computer, or number of computers, a computer program product, ie an information carrier, eg, a machine readable storage It may be embodied as a computer program tangibly embodied in an apparatus (computer readable medium) or a radio signal. A computer program, such as the computer program(s) described above, may be written in any form of programming language, including compiled or interpreted languages, as a standalone program or in a module, component, subroutine, or computing environment. It can be deployed in any form, including as other units suitable for use in A computer program may be deployed to be processed on one computer or multiple computers at one site or distributed across multiple sites and interconnected by a communications network.

Processors suitable for processing a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processors of any kind of digital computer. In general, a processor will receive instructions and data from either read-only memory or random access memory or both. Elements of a computer may include at least one processor that executes instructions and one or more memory devices that store instructions and data. In general, a computer may include, receive data from, transmit data to, or both, one or more mass storage devices for storing data, for example magnetic, magneto-optical disks, or optical disks. may be combined to become Information carriers suitable for embodying computer program instructions and data are, for example, semiconductor memory devices, for example, magnetic media such as hard disks, floppy disks and magnetic tapes, Compact Disk Read Only Memory (CD-ROM). ), optical recording media such as DVD (Digital Video Disk), magneto-optical media such as optical disk, ROM (Read Only Memory), RAM (RAM) , Random Access Memory), flash memory, EPROM (Erasable Programmable ROM), EEPROM (Electrically Erasable Programmable ROM), and the like. Processors and memories may be supplemented by, or included in, special purpose logic circuitry.

In addition, the computer-readable medium may be any available medium that can be accessed by a computer, and may include both computer storage media and transmission media.

While this specification contains numerous specific implementation details, they should not be construed as limitations on the scope of any invention or claim, but rather as descriptions of features that may be specific to particular embodiments of particular inventions. should be understood Certain features that are described herein in the context of separate embodiments may be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment may also be implemented in multiple embodiments, either individually or in any suitable subcombination. Furthermore, although features operate in a particular combination and may be initially depicted as claimed as such, one or more features from a claimed combination may in some cases be excluded from the combination, the claimed combination being a sub-combination. or a variant of a sub-combination.

Likewise, although acts are depicted in the drawings in a particular order, it should not be construed that all acts shown must be performed or that such acts must be performed in the specific order or sequential order shown to obtain desirable results. In certain cases, multitasking and parallel processing may be advantageous. Further, the separation of the various device components of the above-described embodiments should not be construed as requiring such separation in all embodiments, and the program components and devices described may generally be integrated together into a single software product or packaged into multiple software products. You have to understand that you can.

On the other hand, the embodiments of the present invention disclosed in the present specification and drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. It will be apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

101: curing temperature management device
102: data acquisition device
103: aphrodisiac control device
104: user terminal
105: concrete

Claims (13)

a data collection device for collecting surface temperature and internal temperature of concrete, humidity of concrete, air temperature of a concrete-filled area, and gangform wall temperature through a plurality of temperature sensors and humidity sensors;
Receive the curing temperature specified by the surface temperature and the internal temperature of the concrete and the ambient temperature of the zone from the data collection device of the zone in which the concrete is poured through a low-power wide area network, and the concrete based on the curing temperature and the atmospheric temperature Estimate the current strength of , and use the estimated current strength, daily average temperature obtained from weather forecast information received from an external source, and physical property information of concrete including slump, air amount, chloride amount and curing temperature of concrete for each hour A curing temperature management system for determining the predicted strength of the concrete, and transmitting a control command generated according to the predicted strength to the maintenance control device through wireless communication; and a curing temperature management system for concrete.
The method according to claim 1, The processor of the curing temperature management device,
The curing temperature management system for concrete, characterized in that the time for the estimated current strength of the concrete to reach a target strength according to the control command is determined in consideration of the estimated current strength of the concrete and the predicted strength of the concrete.
The method according to claim 1, wherein the processor of the curing temperature management device,
In order to enable the user to monitor the curing temperature of the concrete, the concrete curing temperature management system, characterized in that the estimated current strength of the concrete and the predicted strength of the concrete for each time are transmitted to a user terminal.
The method according to claim 1, The processor of the curing temperature management device,
It is determined whether the concrete is abnormal based on the curing temperature and the atmospheric temperature of the concrete, and when the abnormality of the concrete is detected, a control command is generated in consideration of the detected abnormality, and the generated control command is sent to the maintenance control device Concrete curing temperature management system, characterized in that the transmission box.
The method according to claim 4, The processor of the curing temperature management device,
Curing temperature management system for concrete, characterized in that transmitting an emergency notification to the user terminal when the abnormality of the concrete is detected.
The method according to claim 4, The processor of the curing temperature management device,
When the curing temperature of the concrete does not belong to the preset reference temperature section, it is determined that an abnormality has occurred in the concrete and a control command is transmitted to the maintenance control device, but the reference temperature section is the construction period, progress period, current strength, prediction A curing temperature management system for concrete, characterized in that it is determined in consideration of the time to reach strength.
a data collection device for collecting the surface temperature and internal temperature of concrete, the humidity of the concrete, the atmospheric temperature of the area in which the concrete is poured, and the temperature of the gangform wall through a plurality of temperature sensors and humidity sensors;
Receive the curing temperature specified by the surface temperature and the internal temperature of the concrete and the ambient temperature of the zone from the data collection device of the zone in which the concrete is poured through a low-power wide area network, and the concrete based on the curing temperature and the atmospheric temperature Estimate the current strength of the concrete, and determine the predicted strength of the concrete by time using the estimated current strength, the daily average temperature obtained from the weather forecast information received from an external source, and the physical property information of the concrete, or the time of gang form demoulding of the concrete Curing temperature management system for concrete comprising a; curing temperature management device to determine and transmit to the user terminal.
The method according to claim 7, The processor of the curing temperature management device,
Curing temperature management system for concrete, characterized in that generating a control command according to the determined predicted strength of the concrete and transmitting it to the maintenance control device through wireless communication.
The method according to claim 8, The processor of the curing temperature management device,
Curing temperature management system for concrete, characterized in that the time for the estimated current strength of the concrete to reach a target strength according to the control command is determined in consideration of the estimated current strength of the concrete and the predicted strength of the concrete.
The method according to claim 7, The processor of the curing temperature management device,
It is determined whether the concrete is abnormal based on the curing temperature and atmospheric temperature of the concrete, and when the abnormality of the concrete is detected, a control command is generated in consideration of the detected abnormality, and the generated control command is transmitted to the maintenance control device Curing temperature management system for concrete, characterized in that
The method according to claim 10, The processor of the curing temperature management device,
Curing temperature management system for concrete, characterized in that transmitting an emergency notification to the user terminal when the abnormality of the concrete is detected.
The method according to claim 7, The processor of the curing temperature management device,
When the curing temperature of the concrete does not belong to the preset reference temperature range, it is determined that an abnormality has occurred in the concrete and a control command is transmitted to the maintenance control device, but the reference temperature section is the construction period, progress period, current strength, and predicted strength Curing temperature management system for concrete, characterized in that it is determined in consideration of the time to reach.
a data collection device for collecting a surface temperature and an internal temperature of the concrete through one or more temperature sensors;
Receive a curing temperature specified as a surface temperature and an internal temperature of concrete from the data collection device in an area where concrete is poured through a low-power wide area network, and estimate the current strength of the concrete based on the curing temperature and the ambient temperature, Curing temperature management system for concrete comprising a; a curing temperature management device that determines the predicted strength of the concrete by time using the estimated current strength or determines the gang form demolding time of the concrete and transmits it to the user terminal .

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