JP6639828B2 - Real-time visualization method of temperature measurement information and cooling water flow rate in pipe cooling system of concrete structure - Google Patents

Description

  The present invention relates to a pipe cooling system (or pipe cooling method) implemented for the purpose of "preventing temperature cracking" of concrete after the concrete is poured in the construction of a so-called mass concrete structure. Water is passed through a cooling pipe installed inside the building in advance, measures the temperature inside the cast concrete structure, and controls the temperature of the water appropriately according to the concrete temperature, temperature measurement information and other information in real time. Belongs to the technical field of visualization methods.

Conventionally, when constructing large-scale concrete structures such as concrete dams and large pier foundations (hereinafter sometimes referred to as mass concrete), measures to prevent "temperature cracking" due to thermal contraction of concrete and the like. It is well known that is essential.
Therefore, many countermeasures called pipe cooling systems or pipe cooling methods have already been proposed as shown in Patent Documents 1 to 5 described below.
In other words, cool water is passed through the cooling pipe previously installed in the cross section of the concrete structure to reduce the internal temperature of the cast concrete and reduce the temperature difference from the surface in contact with the outside temperature as much as possible. This is a technique for suppressing the generation of temperature stress by relaxing control.

However, the problems with the existing pipe cooling system or pipe cooling method are that the installation interval of the cooling pipes, the initial temperature of the poured concrete, the water flow temperature, the water flow period, etc. are determined based on the pre-analysis to optimize the implementation. The point is that only the construction conditions that satisfy the target crack index are determined and implemented.
Therefore, the following problems can be raised with respect to the existing pipe cooling system or pipe cooling method.
(A) The measured data such as the initial temperature, the flowing water temperature, and the outside air temperature of the cast concrete cannot be measured and grasped in real time during construction.
(B) Therefore, it is not possible to control the water passage temperature according to the actual temperature of concrete.
(C) It is not configured to be able to immediately detect and deal with water flow troubles or water flow temperature abnormalities during construction. In other words, management and measures for responding immediately to the occurrence of the above-mentioned trouble are not prepared.

Japanese Patent No. 2687737 (Japanese Patent Application Laid-Open No. 4-247167) Japanese Patent No. 4108544 (Japanese Patent Application Laid-Open No. 2004-360333) Japanese Patent No. 4601877 (Japanese Unexamined Patent Application Publication No. 2003-65983) JP 2014-5716 A JP 2014-9530 A

Therefore, an object of the present invention is to establish a pipe cooling system or a pipe cooling method, a concrete temperature measurement system and a water flow temperature measurement system, a water flow temperature control system, and a warning reporting system, respectively, to establish the actual condition of mass concrete. Enabling the control of the water flow temperature according to the temperature,
And it is possible to easily detect and grasp the content of the abnormal situation of the entire system at an early stage, and furthermore, to visualize the measurement information of each abnormal situation in the whole pipe cooling system to the parties in real time,
Furthermore, to develop and use a water temperature control device, alarm device, measuring device, etc. for real-time visualization, establish a practical technology for pipe cooling system with excellent effectiveness, and solve each of the above problems It is.

As means for solving the problems of the prior art described above, the method for real-time visualization of the temperature measurement information and the flow rate of the cooling water in the concrete structure pipe cooling system according to the first aspect of the present invention includes: temperature of the temperature and the surface, and while measuring water flow temperature, respectively, the water flow temperature and water flow rate of the cooling water supplied to the cooling pipe 2 was measured for each key point position, control of each of these measurement data To be sent to the device 50 and to be understood and recognized by various terminals owned by each party;
Predicted temperature history of concrete based on the result of the pre-analysis is registered in the control device 50, and the measurement data and the result of the pre-analysis are displayed on various terminals of each party, and are compared and examined. If there is a possibility to deviate from the alarm control width defined by the alarm limit and the lower limit value of the water flow temperature and through quantity of cooling water and set in advance, or when departing from the alarm control width, or power outage the case When the abnormal situation is detected , the abnormal situation is immediately notified to various terminals owned by the parties through a warning reporting means to prompt the user to take measures.

The invention described in claim 2 is a real-time visualization method of temperature measurement information and cooling water flow rate in the concrete structure pipe cooling system according to the invention described in claim 1,
The warning reporting means is characterized in that the abnormal situation is visualized and notified to each person in charge by an electronic means by a warning mail or by a rotating light 14 or other mechanical notification means, and prompts the person in charge to take immediate action. I do.

The invention described in claim 3 is a method for real-time visualization of temperature measurement information and the flow rate of cooling water in a pipe cooling system for a concrete structure 1 according to the invention described in claim 1 or 2.
The present invention is characterized in that the actual temperature of the concrete structure 1 is directly and continuously measured, and the temperature and / or amount of cooling water is immediately controlled to an appropriate temperature according to the measured temperature of the concrete structure 1. I do.
The invention described in claim 4 is a real-time visualization method of temperature measurement information and cooling water flow rate in the concrete structure pipe cooling system according to any one of claims 1 to 3,
The control of the flow temperature of the cooling water supplied to the cooling pipe 2 is performed by controlling the flow temperature of the concrete structure 1 until the actual temperature of the concrete structure 1 rises to the maximum value T1 after the start of the method. Step 1 of maintaining the flow temperature R1 much lower than
From the stage where the actual temperature of the concrete structure 1 rises to the maximum value T1, the difference between the water passing temperature R2 and the temperature P of the concrete structure is maintained at a constant value during a period until the temperature falls to a certain target temperature T2. Step 2 and
And, during the pipe cooling period after the actual temperature of the concrete structure 1 has decreased to the target value T2, the step 3 of maintaining the water passing temperature R3 at the same temperature as the initial step 1 again is characterized.

The invention described in claim 5 is a real-time visualization method of temperature measurement information and cooling water flow rate in a pipe cooling system for a concrete structure according to the invention described in claim 3 or 4,
The control of the flow temperature of the cooling water supplied to the cooling pipe 2 is as follows. In Step 1 until the actual temperature of the concrete structure 1 rises to the maximum value T1, the flow temperature R1 is set to be lower than the temperature of the concrete structure 1. Keep it at a much lower 15 ° C,
After the actual temperature of the concrete structure 1 rises to the maximum value T1, and during the step 2 until the temperature of the concrete structure 1 falls to the target temperature T2, the water passing temperature R2 and the concrete structure temperature P And maintain the difference at about 20 ° C,
During the pipe cooling period after the actual temperature of the concrete structure 1 has decreased to the target value T2, the water flow temperature R3 is again maintained at the same temperature as the initial step 1 at 15 ° C. I do.

The real-time visualization method of the temperature measurement information and the flow rate of the cooling water in the concrete structure pipe cooling system according to the present invention has the following effects.
(1) The internal temperature and the surface temperature of the concrete structure 1 are constantly and continuously measured by the temperature sensors 11 and 12 (such as thermocouples) installed at each measurement point during the execution period of the pipe cooling system. measure.
In addition, the temperature of the cooling water supplied to each cooling pipe 2 is constantly and continuously measured in real time by the temperature sensors 6a to 6d installed at each measurement point. Similarly, the flow rate of the cooling water is always measured in real time by the electromagnetic flow meters 20a and 20b installed at each measurement point.
Each of these measurement data is sent to the control device 50 to be used for control information, and each party can always recognize and grasp through various terminals owned by each party of the pipe cooling system. The water flow temperature and the water flow rate can be appropriately controlled in response to the actual internal temperature of the inside and the temperature of the surface portion, thereby enabling the construction of a high-quality concrete structure 1.
Not only that, the control device 50 registers the predicted temperature history of the concrete based on the results of the preliminary analysis and examination, and sequentially compares and compares the above measurement results with the predicted temperature history, and sets in advance. It is monitored whether or not there is a concern that the alarm will deviate from the alarm control range defined by the upper limit value and the lower limit value of the alarm for the water flow temperature and the flow amount. When a concern of the deviation is detected, a configuration for notifying each party of the information of the occurrence of the concern or the abnormal situation is immediately established through the alarm reporting means. The implementation status of the cooling method) and the propriety of the content are constantly monitored while referring to the results of the preliminary analysis and the examination, and the process is automatically controlled to correct the proper content.
And since the content of the construction of the concrete structure that changes every moment can be implemented as automatic control while maintaining the best condition for "preventing temperature cracking" of the concrete structure 1 under construction, it is not affected by the temperature environment of the construction site. The construction and construction of the high-quality concrete structure 1 can be appropriately advanced.

(2) In particular, the temperature and flow rate of the cooling water can be constantly monitored so as not to deviate from the control range based on the upper limit value and the lower limit value set in advance based on the results of the preliminary analysis and examination. In the event of concern or deviation, or in the event of an accident such as a power outage, the abnormal situation information is immediately notified and displayed on the terminal of each party together with the measurement information and the analysis data, and each party is immediately notified as an alarm mail. In addition to the notification, warning information such as a rotating light 14 that appeals to the eye or a siren that appeals to the auditory is immediately notified to each party to urge urgent measures and countermeasures. Since the surveillance camera 15 is also provided, the above-mentioned respective situations can be visually recognized even from a remote place.
Therefore, each person in charge of the construction of the concrete structure should be aware of the abnormal situation and identify the cause before or immediately after the occurrence of the abnormal situation, and improve the normal implementation of the pipe cooling system. It is possible to perform the construction and construction of the high-quality concrete structure 1, and the effect is exhibited.

FIG. 2 is a perspective view showing a pivotal embodiment of a real-time visualization method of temperature measurement information and a flow rate of cooling water in a case where a pipe cooling system according to the present invention is implemented when constructing a concrete structure. Temperature measurement information by the pipe cooling system implemented in the construction of the concrete structure shown in FIG. 1 and a concrete water flow system of each component in the implementation of the real-time visualization method of the flow rate of the cooling water, temperature measurement means and the like. FIG. 3 is an elevational explanatory view conceptually showing a control system including a cross-sectional view. It is a block diagram (flow diagram) which illustrated the main process of the real-time visualization method of the temperature measurement information and the flow rate of the cooling water in the pipe cooling system of the present invention which is carried out when constructing the concrete structure. It is the graph which visualized and showed the control example of the flowing water temperature with respect to the concrete temperature in the pipe cooling system implemented in the construction of a concrete structure.

The real-time visualization method of the temperature measurement information and the flow rate of the cooling water in the implementation of the pipe cooling system for the concrete structure according to the present invention is described in detail below. The process is started by installing a cooling pipe 2 for cooling the concrete structure 1 at a desired position by using an installed reinforcing bar or the like.
Further, temperature sensors 11 and 12 (thermocouples and the like) are installed at positions where the internal temperature and the surface temperature of the concrete structure 1 are to be measured, also by using a cooling pipe 2 or a reinforcing bar.
Further, the temperature sensors 6a to 6d for measuring the flow temperature of the cooling water supplied to each of the cooling pipes 2 and the electromagnetic flow meters 20a and 20b for measuring the flow rate are prepared at important locations. I do. The data measured by each of these measurement sensors is sequentially transmitted to the control device 50. In addition, various terminals owned by each party are prepared to be able to immediately grasp and recognize the above information.
On the other hand, in the control device 50, the examination of the pre-analysis and the predicted temperature history of the concrete based on the result are registered, and the temperature measurement data measured by each of the temperature sensors 6a to 6d and the result of the pre-analysis are controlled. Display on the device 50, make a comparison, and adjust the appropriate water flow temperature and water flow in accordance with the actual temperature inside the concrete structure 1 and the temperature of the surface of the skeleton. The structure 1 can be constructed.
In this case, with respect to the water passage temperature, comparison processing is individually performed in advance within the range of the alarm upper limit value and the lower limit value of the water passage temperature. When there is a possibility that the alarm value deviates from the upper limit value and the lower limit value, or when an emergency such as a power failure or an accident occurs, the abnormal situation is immediately and individually notified to the parties through the alarm reporting means.
Control shall be performed under the condition that the control width is smaller than the alarm control width, and in the case where the control width may exceed the alarm control width, or in the event of an emergency such as a power failure, the warning is immediately transmitted through the alarm reporting means. An abnormal situation shall be notified to the parties individually.
On the other hand, in parallel with the progress of concrete placement of the concrete structure 1, the actual temperature inside the concrete structure and the surface temperature of the skeleton are continuously measured by the temperature sensors 11 and 12 and sent to the control device 50. .
The temperature of the cooling water flow is continuously measured by the temperature sensors 6a, 6b and 6c, 6d, and the flow rate of the cooling water is constantly measured in real time by the electromagnetic flow meters 20a, 20b.
Each measurement data is sent to the control device 50 in real time, and recorded and stored. Then, these measured values and the like are compared / examined with the results of the pre-analysis to verify the feasibility of each.

In the control device 50, the concrete predicted temperature history based on the results of the pre-analysis and the examination is registered, and the above-mentioned respective measurement information and the analysis data are simultaneously displayed on various terminals to perform the comparative study and set in advance. When there is a possibility that the alarm control range defined by the upper limit value and the lower limit value of the water flow temperature and the water flow amount may be deviated, the control of the correction is immediately performed, and for example, the water flow temperature and / or the water flow amount are raised or lowered. Let it.
In the event of an abnormal situation that deviates from the alarm control range defined by the set upper limit and lower limit of the set water temperature and water flow rate, or as electronic means such as an alarm mail, An abnormality is immediately notified to a person in charge by a mechanical notification means such as a lamp 14, and the person in charge is urged to take immediate action.

Hereinafter, the present invention will be described based on the embodiment shown in FIGS.
First, FIG. 1 shows a concrete structure 1 shown as an example in which a pipe cooling system for a concrete structure is implemented according to the present invention, and a vertical wall of the concrete structure 1 to be constructed by casting concrete from now on. Prior to the concrete placement of the part 1a, the required number of cooling pipes 2... Are located at the center of the vertical section of the vertical wall part 1a and reach the deepest part where the concrete placement is performed. It shows an arrangement relationship in which the reinforcing members of the vertical wall portion 1a are buried at intervals according to the arrangement of reinforcing bars.
For example, as shown in FIG. 2, the cooling pipe 2 is configured to have a double-pipe structure in which the cooling water purified by the cooling device 5 is formed with the inner pipe 2 a on the center side being the outward path. It is supplied through the water supply main line 4. The water supply main pipe 4 is branched into a required number of branch pipes 4 a at the position of the cooling water pipe 10, and each of the branch pipes 4 a on the outward path is connected to the inner pipe 2 a of each cooling pipe 2. On the other hand, an outer pipe 2b of each cooling pipe 2 is used as a return path, and branch pipes 4b of the return path are connected to upper ends of the outer pipes 2b, respectively.
With the above configuration, the cooling water having the temperature adjusted by the cooling device 5 is equally sent to the cooling pipe 2, and the temperature is measured by the temperature sensors 6a and 6b. The temperature sensor 6a measures the temperature of the cooling water flowing through the water supply main pipe 4, and the temperature sensor 6b measures the temperature of the cooling water flowing separately to the branch pipes 4a in the respective outgoing routes at a position immediately before entering the cooling pipes 2. . Similarly, the flow rate of the cooling water flowing through the water supply main pipe 4 is measured by the electromagnetic flow meter 20a, and the flow rate of the cooling water flowing separately to the branch pipes 4a of the respective outgoing flows flows into the inner pipe 2a of each cooling pipe 2. It is measured at the position immediately before by the electromagnetic flow meter 20b.
On the other hand, after descending the inner pipe 2a of the cooling pipe 2, the cooling water that has risen up the outer pipe 2b of the cooling pipe 2 is recovered through the branch pipe 4b of each return path connected to the upper end of the outer pipe 2b. . Moreover, the temperature of the cooling water immediately after rising the outer pipe 2b of the cooling pipe 2 is measured by the temperature sensor 6c, and thereafter, the cooling water is recovered to the recovery water tank 7 prepared near the construction site of the concrete structure 1.
The cooling water collected in the collecting water tank 7 is pumped up by the submersible pump 8 installed in the collecting water tank 7 and returned to the cooling device 5 shown in FIGS. 1 and 2 again through the return main pipe 4c. At this time, the temperature of the cooling water immediately before returning to the cooling device 5 is measured by the temperature sensor 6d installed on the return main pipe 4c.

Next, among the respective components of the pipe cooling system, the configuration and function of the cooling device 5 whose configuration is shown in detail in FIG. 2 will be described.
According to FIG. 2, the concrete structure 1 to be constructed has an inverted T-shaped cross section as an example. The temperature sensor 11 (thermocouple) for continuously measuring the actual temperature inside the concrete that is cast to construct the vertical wall portion 1a of the concrete structure 1 is provided by a surface portion of the outer pipe 2b constituting the cooling pipe 2. If necessary, the required number is added at a position at a certain measurement interval in the vertical direction. The vertical distance between the temperature sensors 11 installed on the outer surface of the outer pipe 2b is determined in advance by a preliminary experiment or the like to determine a dimension appropriate for measuring the actual temperature of the concrete structure 1 cooled by water flow. It is carried out after deciding.
However, the temperature sensor 11 is not limited to a configuration that is attached to the outer pipe of the cooling pipe 2. Attachment to the outer pipe of the cooling pipe 2 is merely an example in the sense of convenience. In some cases, it suffices to appropriately select and attach a reinforcing bar or other support existing as a component of the concrete structure 1.

On the other hand, in the embodiment shown in FIG. 2, the temperature sensor 12 for measuring the surface temperature (or the outside air temperature in the vicinity of the surface) of the (vertical wall portion 1a) of the concrete structure 1 is assembled, for example, for concrete casting. If necessary, the required number is provided at an appropriate position on the inner surface portion (or the outer surface portion or the like) of the concrete formwork (not shown) at an appropriate temperature measuring interval in the vertical direction if necessary. The distance between the temperature sensors 12 in the vertical direction is also determined beforehand by confirming appropriate dimensions required for measuring the surface temperature of the concrete structure 1.
The respective measured values by the temperature sensors 11 and 12 are sent to a control device 50 connected by wire or wireless, and are recorded and stored as needed and continuously, and are used for control of the system described below.
On the other hand, the flow rate and temperature of the cooling water supplied to the cooling pipe 2 by the pump 58 of the cooling device 5 are the same as those described with reference to FIG. It is continuously measured by the primary electromagnetic flow meter 20a and the temperature sensor 6a, and each measured value is also sent to the above-described control device 50 connected by wire or wirelessly.
Further, at the position immediately before being supplied to each cooling pipe 2, the flow rate of the cooling water is measured by the electromagnetic flow meter 20b, and the temperature of the cooling water flowing into the inner pipe 2a of each cooling pipe 2 is measured by the temperature sensor 6b. , And each measurement value is also sent to the control device 50 connected by wire or wirelessly.

FIG. 2 is a conceptual diagram illustrating a configuration example using a plurality of water tanks as a specific configuration example of the cooling device 5, and the configuration will be briefly described below.
As described specifically in FIG. 2, the temperature of the cooling water collected in the collecting water tank 7 of FIG. 1 is firstly set at a position immediately after rising inside the outer pipe 2b of the cooling pipe 2 and the respective return pipes 4b The temperature of the cooling water is continuously measured by the temperature sensor 6c installed in the control device, and the measured value is also sent to the control device 50 connected by wire or wirelessly.
The temperature of the recovered water pumped up by the submersible pump 8 in the recovery tank 7 and returned to the cooling device 5 through the return main pipe 4c is continuously measured by a temperature sensor 6d installed at a position near the cooling device 5 in the return main pipe 4c. And the measured value is also sent to the control device 50 connected by wire or wirelessly.
The cooling water returned to the first water tank 51 of the cooling device 5 is guided to the pipeline in the cooling tank 53 on the right side by the submersible pump 52 in the water tank 51 and passes through the pipeline in the cooling tank 53. Cooling can be applied during the process. After that, the temperature of the cooling water is immediately again appropriately controlled by the circulation returning to the first water tank 51 in response to the temperature measured by the temperature sensors 11 and 12 which measure the actual temperature of the concrete structure 1. To the target value by controlling the water temperature.
Subsequently, the cooling water in the first water tank 51 is pumped up by another underwater pump 54 and sent to the second water tank 55. Then, the cooling water contained in the second water tank 55 is again guided into the cooling tank 57 at the adjacent position by the submersible pump 56 in the second water tank 55, and is further increased while passing through the cooling tank 57. Cooling. In this way, the cooling water adjusted to the temperature set in advance as necessary for the cooling of the cast concrete is returned to the second water tank 55 again. Then, the cooling water in the second water tank 55 cooled to a predetermined temperature is pumped up by the submersible pump 58, and a circulation process for sending the cooling water to the cooling pipe 2 through the water supply main pipe 4 is performed again.
However, as the configuration of the cooling device 5, in the embodiment of FIG. 2, two sets of a water tank and a cooling tank are configured, but the present invention is not limited to this. Depending on the capacity, one set of configurations may be used, or conversely, three sets of configurations may be implemented in exactly the same manner.

With the above-described configuration, the cooling water controlled and cooled to a temperature appropriate for “preventing temperature cracking” of the cast concrete is supplied to the concrete structure 1 through the water supply main pipe 4 by the submersible pump 58 in the second water tank 55. Sent to the concrete casting site. Then, the cooling water diverted in parallel to the cooling pipes 2... Is sent to the cooling pipes 2... In the above-described configuration, and the above-mentioned purpose of “prevention of temperature cracking” is achieved by the cooling action of the cooling water.
Thus, the pipe cooling system for the concrete structure is implemented as automatic control by the devices controlled by the control device 50, including the cooling device 5 illustrated in FIG.
The control device 50 constantly determines the actual temperature inside the concrete structure 1 obtained through the control device 50, the temperature of the cooling water sent to the cooling pipe 2, the surface temperature of the concrete structure 1, and the amount of water flow. It is continuously monitored and automatically controlled appropriately.
Further, a power failure monitoring device 13 of a power supply 16 for operating the pipe cooling system, a rotating light 14 for visually notifying an abnormality of the operating state of the system to each party in the vicinity, and / or a situation at the site are imaged and converted into video information. In addition to managing the image signal of the monitoring camera 15 to be transmitted, the control of sounding an alarm (not shown) such as a siren or turning the rotary lamp 14 for notifying the abnormal situation at the site is also performed when an abnormal situation occurs. Done.

FIG. 3 shows the main control steps (procedures) for executing the concrete structure pipe cooling system according to the present invention.
First, a study (a) based on the pre-analysis regarding the construction of the concrete structure 1 is advanced, and based on the result, the outline of the following construction contents is determined.
Next, based on the result of the preliminary analysis (a), the cooling pipe is installed and the equipment of the control system is prepared (b).
After that, concrete casting (c) is performed inside the formwork.
The step (d) of measuring the outside air temperature and the inside temperature of the concrete accompanying the concrete placement is advanced. Then, in the process, the necessary water flow start and the water flow temperature control step (e) are executed, and the flow rate is also controlled. This water flow is performed during the period determined by the preliminary analysis. The water flow temperature is controlled based on the three steps described below in accordance with the temperature of the concrete poured.
Finally, the effect is confirmed and verified (f) by post-mortem analysis.

Incidentally, the control of the water flow temperature (e) described above is performed as shown in FIG. 4 as an example.
The line P in the figure indicates a change in the temperature of the poured concrete, and the line Q indicates a change in the outside air temperature. R ₁ , R ₂ , and R ₃ each represent a change in the water passage temperature controlled by the cooling device 5.
In other words, looking at the temperature curve P of pouring the concrete, under the influence of the hydration reaction and the outside air temperature Q of the concrete, the maximum temperature T ₁ after hitting設直has risen to about 50 degrees.
So as a method of controlling water flow temperature in the range of Step 1 after concrete設直until the temperature of the concrete reaches a maximum temperature T _1, in order to Arashimeru the effectiveness of the cooling effect, water flow temperature R ₁ indicates that the control is performed at 15 degrees.
Thereafter, at the stage of step 2 where the temperature of the concrete reaches the maximum temperature T ₁ (about 50 degrees in the example of FIG. 4), the temperature of the concrete is gradually (closer to nature), so that the water passing temperature R ₂ , like the difference between the temperature and the water flow temperature of the concrete is maintained at 20 degrees, first, it has increased the water flow temperature R ₂ to initially 30 degrees near. Then, so as to follow the temperature drop of the concrete is lowered water passing temperature R ₂ gradually.
Then, after the temperature P of the cast concrete has dropped to the predetermined temperature T ₂ = about 35 ° C., in the step 3 until the pipe cooling system is terminated, the water passing temperature R _{3 is set} to the initial 15 ° C. FIG. 4 shows the process of controlling and maintaining the temperature in ° C.
When the pipe cooling system with the control of the water flow temperature was implemented as described above, with regard to the cast concrete, the construction contents of the concrete structure, which is constantly changing, were reliably recorded and saved, and the "temperature of the mass concrete structure under construction" It was specifically confirmed that good results for "prevention of cracks" were obtained. As for the cast concrete, it was confirmed that the construction could be advanced as an automatic control while keeping the best conditions, and as a result, the construction of a high-quality concrete structure could be promoted without being affected by the temperature environment at the site.

In particular, the flow temperature and flow rate, including the influence of the outside air temperature, can always monitor whether or not to deviate from the control range of the upper limit or lower limit set in advance based on the analysis result in advance. Can be recorded and stored.
In addition, if there is a concern or deviation from the condition, or in the case of an accident such as a power outage, the abnormal situation is immediately reported along with the measurement information and the analysis data to a smartphone or the like connected via the Internet 70. It is displayed on a portable terminal such as a tablet or a PC terminal 80, and immediately notified to each party as an alarm mail, and also by a rotating light 14 or a surveillance camera 15 that appeals to the eyes, or by alarm information such as a siren that appeals to the hearing. Immediate notification to each party to prompt urgent countermeasures and countermeasures enables non-trivial measures to be taken beforehand.
In particular, each person involved in the construction of the concrete structure before the occurrence of the abnormal situation, or immediately after the occurrence, has a great advantage that it can know the abnormal situation and take appropriate response measures, It is possible to determine the cause of the trouble ahead of time or at an early stage, and proceed to correct the normal operation of the pipe cooling system. Therefore, it is effective to perform construction and construction of a high-quality concrete structure within a predetermined construction period.

  Although the present invention has been described with the embodiments, the present invention is not limited to the contents of the above embodiments. It should be noted that the present invention covers a range of so-called person skilled in the art as needed, alterations and design changes.

DESCRIPTION OF SYMBOLS 1 Concrete structure 2 Cooling pipe 4 Water supply main pipe 4a Outgoing branch pipe 4b Return path branch pipe 4c Return path main pipe 5 Cooling devices 6a to 6d Temperature sensor 7 Recovery water tank 8 Submersible pump 10 Cooling moisture pipes 11, 12 Temperature sensor (thermoelectric versus)
20a, 20b electromagnetic flow meter 50 controller

Claims (5)

Internal temperature and the surface temperature of the concrete structure, and while measuring water flow temperature, respectively, to measure the water flow temperature and water flow rate of the cooling water supplied to each key point position to the cooling pipe, each of these Sending the measurement data to the control device, as well as being able to grasp and recognize with various terminals owned by each party,
In the control device, the predicted temperature history of the concrete based on the result of the pre-analysis is registered, and the measurement data and the result of the pre-analysis are displayed on various terminals of each party, and the comparison is performed. If there is a possibility to deviate from the alarm control width determined by the preset alarm limit value and the lower limit value of the water flow temperature and through quantity of cooling water, or when departing from the alarm control width, or a power failure the cases When an abnormal situation is detected, it is characterized in that the abnormal situation is immediately notified to various terminals owned by the parties through the alarm report means to prompt the user to cope with the temperature measurement information and temperature measurement information in the concrete structure pipe cooling system. Real-time visualization of cooling water flow . A real-time visualization method of temperature measurement information and a flow rate of cooling water in a pipe cooling system for a concrete structure according to the invention described in claim 1,
The warning report means is characterized in that the abnormal situation is visualized and notified to each person in charge by an electronic means by a warning mail or a rotating light or other mechanical notification means to prompt the person in charge to take immediate action. . In a real-time visualization method of temperature measurement information and a flow rate of cooling water in a pipe cooling system for a concrete structure according to the invention described in claim 1,
The present invention is characterized in that the actual temperature of the concrete structure is directly and continuously measured, and the temperature and / or amount of cooling water is immediately and appropriately controlled according to the measured temperature of the concrete structure. A real-time visualization method of temperature measurement information and cooling water flow rate in a concrete structure pipe cooling system according to any one of claims 1 to 3,
The control of the water flow temperature of the cooling water supplied to the cooling pipe is such that the water flow temperature is much higher than the concrete structure temperature during the period from the start of the method until the actual temperature of the concrete structure rises to the maximum value. Step 1 to maintain a very low water flow temperature;
From the stage where the actual temperature of the concrete structure has risen to the maximum value, during the period until the temperature has dropped to the predetermined target temperature, maintaining the difference between the water passing temperature and the temperature of the concrete structure at a constant value;
In addition, during the pipe cooling period after the actual temperature of the concrete structure has dropped to the target value, Step 3 is to maintain the water passing temperature again at the same temperature as Step 1 at the beginning. A real-time visualization method of temperature measurement information and a flow rate of cooling water in a pipe cooling system for a concrete structure according to the invention described in claim 3 or 4,
The control of the flow temperature of the cooling water supplied to the cooling pipe is as follows. In step 1 until the actual temperature of the concrete structure rises to the maximum value, the flow temperature is set to be much lower than the temperature of the concrete structure. ℃,
After the actual temperature of the concrete structure reaches the maximum value, during step 2 until the temperature of the concrete structure decreases to the target temperature, the difference between the water passing temperature and the temperature of the concrete structure is set to 20 ° C. To the extent that
During the pipe cooling period after the actual temperature of the concrete structure has dropped to the target value, the water flow temperature is maintained again at a temperature of about 15 ° C., which is almost the same as that in Step 1 at the beginning, and is carried out.

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