JPH0531628B2 - - Google Patents

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a method for predicting temperature stress in cured concrete.

<Conventional technology> In general, in concrete before hardening, temperature stress is generated in the concrete due to the heat of hydration generated when cement and water in the ingredients are hydrated, and this temperature stress causes cracks to occur. It is known.

Currently, there are methods to suppress such adverse effects, such as a method of suppressing the heat of hydration of concrete and a method of reinforcing members to resist temperature stress.

In the case of methods for suppressing the heat of hydration, the following methods are employed as specific means for suppressing the heat of hydration.

(b) Method of using special cement such as low calorific cement with low calorific value.

(b) Method of mixing fly assemblies.

(c) A method of reducing the unit amount of cement.

(d) Method using cooled mixing water, cement, aggregate, etc.

(e) A method of cooling mixed concrete by adding flake ice, etc.

(f) A method of lowering the temperature by burying cooling pipes in concrete.

<Problems to be Solved by the Present Invention> As described above, the method of lowering the temperature of concrete has the following problems.

(a) There are various methods for lowering the temperature of concrete, but it took a lot of time and various experiments to decide which method to use.

Therefore, it takes a long time to consider before starting construction.

Furthermore, various tests must be conducted depending on the construction example, which is uneconomical.

<B> Considerable knowledge and skill are required to select a method for lowering the temperature of concrete.

If the selection is incorrect, cracks will occur in the concrete structure, making it impossible to construct a high-quality concrete structure.

<Object of the present invention> The present invention was made to solve the above-mentioned problems, and its purpose is to reduce the temperature stress in curing concrete in order to determine the curing method and curing period of concrete. The object of the present invention is to provide a method for predicting temperature stress in cured concrete, which can be determined without direct measurement.

<Structure of the present invention> An embodiment of the concrete temperature control method according to the present invention will be described below.

<A> Method for predicting temperature stress The present invention automatically measures temperature over time using sensors (for example, thermocouples) placed at appropriate locations in poured concrete.

This measured temperature data is analyzed and processed using a small computer.

How to enter temperature data into a computer
This can be done either offline by inputting the data recorded in a RAM cassette, online by inputting the measured data directly into the computer, or by transmitting the measured data wirelessly to the computer using a telemeter, etc.

For temperature control, a temperature control reference value is set based on the preliminary analysis results, and "Compensation
Compare and examine the temperature stress obtained by the Line method.

Furthermore, this method compares the tensile strength with that of concrete to determine the appropriateness of the curing method and when to discontinue curing.

<B> System of Management Method FIG. 1 shows an example of the management method using a computer according to the present invention.

1 is poured concrete.

2 is a temperature measurement section, 3 is a temperature recording section, 4 is an interpretation section, 5 is a computer (CPU), 6 is a plotting section, 7
8 is a data storage section, and 8 is a display section.

And to control the temperature of concrete 1,
The temperature automatically measured over time by a temperature sensor attached to a suitable place on the concrete 1 is converted into an electrical signal and inputted to a temperature measuring section 2.

Temperature data inputted to the temperature measuring section 2 from various locations is recorded in an internal RAM cassette 9.

Furthermore, the data input to the temperature measuring section 2 is also input to the temperature recording section 3 and continuously recorded.

The above is data processing at the construction site.

Furthermore, the RAM cassette 9 recorded at the scene is taken out, and the RAM cassette 9 is set in the interpretation section 4 set in an office away from the scene, for example.
Recall recorded data.

The data output from the interpreter 4 is sent to the computer 5.
input and analyze it.

Both the analyzed data and the measured temperature data are recorded in the data storage section 7, and are also printed out or displayed on the display section 8.

Furthermore, the diagramming section 6 graphs the measurement results and analysis results.

Examples of the analytical values and the measured temperature results are shown in Figs. 3 and 4.

Figure 3 plots the temperature within the concrete cross section.

FIG. 4 shows the results of analyzing temperature stress using the data in FIG. 3.

Incidentally, the analytical results and the actual measured values of temperature stress almost match, which fully supports the validity of this method.

A calculation formula for calculating the temperature stress from the temperature measurement results will be described later.

Compare and examine the determined temperature stress and the tensile strength of the concrete to determine the appropriateness of the curing method and curing period.

<C> Stress calculation method Stress calculations are performed in the following order:

(1) Multiply the measured temperature by the linear expansion coefficient and convert it into a strain distribution.

(2) Decompose the strain into components as shown in Figure 2.

(3) Assume that the cross section is divided into n pieces with a width of Δx in the height direction.

Average strain component () = _o 〓 ⁱ⁼¹ εi/n Bending strain component (φ) Internal restraint strain (εin) εin=εi−(+φy) where −H/2≦y≦H/2 (4) Stress is calculated in incremental form because the elastic modulus changes depending on the age of the material.

Axial force ΔNR=CN・E(t)・A{ε(ti)−ε(ti−1)} Bending moment ΔMR=CM・E(t)・I{φ(ti)−φ(t−1)} Stress due to external restraint ΔσR=ΔNR/A+ΔMR・y/1 Stress due to internal restraint ΔσI=E(t)・εin Where I: Moment of inertia A: Cross-sectional area CN: Axial force restraint coefficient CM: Bending restraint coefficient <N > An example of temperature control Figure 5 shows another example of concrete temperature measurements.

FIG. 6 shows an example of a graph of temperature differences between measurement points in the concrete.

Further, FIG. 7 shows an example of a graph of temperature stress in concrete.

The temperature of concrete is controlled so that the measured temperature difference does not exceed the allowable temperature difference calculated in advance.

If a dangerous situation occurs, calculate the temperature stress using the above-mentioned "Compensation Line method" and manage the curing so that it does not exceed the tensile stress of the concrete.

<Effects> Since the present invention is as explained above, the following effects can be obtained.

(b) Even without directly measuring the stress within concrete, by measuring the temperature within the concrete, the temperature stress occurring within the concrete can be determined accurately and within a short time.

(b) Based on the temperature stress, it is possible to select the optimal curing method (selection of curing temperature and temperature adjustment method) and curing period for concrete.

[Brief explanation of the drawing]

Fig. 1: An explanatory diagram of an embodiment of the concrete temperature control method according to the present invention; Fig. 2: an explanatory diagram of the concept of the compensation and line method; Fig. 3: an example of concrete temperature measurement results. Explanatory drawing, Fig. 4... An explanatory drawing showing the temperature stress of the concrete shown in Fig. 3, Fig. 5... An explanatory drawing of the temperature measurement results of other concretes, Fig. 6... An explanatory drawing showing the temperature stress of the concrete shown in Fig. 5. An explanatory diagram showing the temperature difference, FIG. 7... An explanatory diagram showing the temperature stress of the concrete in FIG. 5.

Claims (1)

[Scope of Claims] 1. Measure the temperature at multiple locations inside and outside the concrete during curing, analyze the temperature distribution of the concrete based on the measured temperature data, and determine the temperature generated in the concrete based on the measured temperature data and temperature distribution. A temperature stress prediction method for curing concrete that calculates the temperature stress.