JPS62164964A - Method for ageing concrete - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a concrete curing method for preventing cracking due to temperature stress.

<Prior Art> In concrete structures such as dams, the temperature of concrete increases significantly due to heat generated during hydration of cement (heat of hydration).

It is known that when the temperature difference between the inside and outside of concrete increases, the risk of cracking due to temperature stress increases.

Therefore, the following methods are currently being used to avoid cracking of concrete due to temperature stress.

(a) Countermeasures regarding mixed ingredients 0 Method of using special cement such as low calorific cement with low calorific value.

■How to mix fly ash.

■Method to reduce the amount of cement per unit.

■Method of using cooled mixing water, cement, aggregate, etc.

(b) Method of cooling concrete ■ Method of cooling concrete by adding flake ice, etc.

■A method of lowering the internal temperature of concrete by burying cooling pipes in the concrete.

kuha〉Other countermeasures■Method of dividing the number of times of pouring into several times and further reducing the amount of pouring each time.

■Method that allows for deformation by providing contraction joints.

■Methods such as reinforcing with reinforcing bars or introducing prestress to counter deformation.

Problems to be Solved by the Present Invention> As described above, the method for preventing cracks in concrete has the following problems.

(b) In the case of countermeasures related to concrete composition, high strength of concrete cannot be expected.

In addition, since high strength cannot be obtained at the early stage of the wood, the curing period is long.

(Example) In the case of high-strength concrete, the temperature inside the concrete increases and the temperature difference between the inside and outside increases.

When the angle of the temperature gradient in the cross section of concrete becomes large in this way, it becomes difficult to control cracks.

(c) Other solutions have problems such as complicated processes, limitations on structures that can be adopted, and high construction costs.

OBJECTS OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide the following concrete curing method.

(a) A method of curing concrete that can easily control cracks by reducing the temperature difference between the inside and outside of the concrete.

(b) A concrete curing method that can shorten the curing period.

(c) An economical method of curing concrete that does not require any special changes to the ingredients or amounts.

Structure of the present invention> An embodiment of the present invention will be described below.

Kui〉Principle of the curing method of the present invention Conventional methods cool the inside of concrete, but the purpose is not just to cool the inside.
The aim is to bring the temperature as close to the outside temperature as possible.

In other words, its purpose is to reduce the temperature difference between the inside and outside of the concrete.

Therefore, the concrete curing method according to the present invention actively heats the external surface of poured concrete to reduce the temperature difference between the inside and outside, thereby curing while controlling the temperature stress that causes cracks. method was adopted.

In other words, the present invention attempts to reduce the temperature difference from both the inside and outside of the concrete by not only cooling the inside of the concrete as in the past (but also heating the outside surface of the concrete, a method previously unthinkable). It's a method.

<Exposure> Heating means and cooling means (Fig. 1) In this embodiment, as a means for heating the outer surface of the concrete 1, for example, an adiabatic curing method is adopted.

That is, the entire concrete 1 cast in the formwork 5 is covered with a covering material 2 such as a sheet, and a heating element 3 is provided within the covering material 2, so that the temperature of the outer surface of the concrete 1 can be adjusted. Configure.

Moreover, as a cooling means for cooling the inside of the concrete 1, for example, a pipe cooling method is adopted.

That is, the cooling pipe 4 is buried in the concrete 1,
The structure is such that cooling water is passed through the cooling pipe 4 to absorb the heat of hydration inside the concrete 1.

Furthermore, it is also possible to heat the water heated in the cooling pipe 4 by bringing it into contact with the outer surface of the concrete 1.

In this embodiment, a case will be described in which a water tank 6 is provided on the upper surface of the concrete 1 to heat the upper surface, but it is also possible to bring hot water that has absorbed the heat of hydration into contact with the side surface of the concrete 1.

〉Curing process (1) Internal cooling, external heating Packing machine for heating the external surface of the poured concrete 1, and cooling vibrator 4 for internal cooling of the concrete 1
Deliver each.

Further, a temperature sensor such as a thermocouple is attached to the concrete 1, so that the temperature at various locations within the concrete 1 can be determined.

Then, the heating element 3 generates heat to warm the outer surface of the concrete 1, and at the same time, cooling water is supplied to the cooling pipe 4, thereby starting curing of the concrete 1 at the same time inside and outside.

(2) Temperature control of concrete The concrete 1 is heated at its outer surface and approaches its internal temperature.

The internal temperature of concrete 1 is cooled by cooling water,
It is close to the external temperature (.

On the other hand, the external temperature of the concrete 1 is heated within the closed space and approaches the internal temperature (.

In this way, the inside and outside temperatures are close to each other (therefore, the temperature difference between the inside and outside of the concrete 1 is significantly reduced in a short period of time.

While maintaining this shortened state of temperature difference, the average temperature inside and outside the concrete 1 is lowered.

(3) Control of curing degree and curing period The curing degree of concrete 1 and the end of the curing period can be determined by the following method.

A temperature sensor embedded inside the concrete 1 automatically measures the temperature over time.

Temperature analysis is performed using a computer, etc. based on the measured temperature.

Both the analyzed data and the measured temperature data are
Both data can be printed out or displayed on a display while being recorded.

The measurement results and analysis results may also be graphed.

Furthermore, based on these data, rCompensati
Temperature stress is calculated by the "on line method" or the like.

To prevent the temperature stress from exceeding the tensile stress of the concrete,
External heating degree of concrete 1 and concrete 1
Controls the degree of internal cooling.

Ultimately, the determined temperature stress and the tensile strength of the concrete are compared to determine the suitability of the curing method and the curing period.

[How to calculate stress] Stress calculations are performed in the following order:

■ Multiply the measured temperature by the coefficient of linear expansion and convert it into a strain distribution.

■Dissolve the strain into its components as shown in Figure 2.

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

Average strain component (g) Bending strain component (φ) Internal restraint strain (εin) εin=εi−(ε+φy) Here, −H/2≦y≦H/2 Stress is expressed in incremental form because the elastic modulus changes depending on the age of the material. Calculate with.

■Axial force ΔNR=CN-E(t>・A (ε(ti)-ε(ti
-1) 1■ Bending moment ΔMn=CM・E(t)・1 (φ(ti)−φ(t−
1) 1 ■ Stress due to external restraint ΔσR = ΔNII / A + ΔMI'l-y / 1 ■ Stress due to internal restraint ΔσI = E (t) · εin where I: Moment of inertia A: Cross-sectional area CN Biaxial force restraint coefficient CM: Bending restraint coefficient If a dangerous situation occurs, rC as described above.

Temperature stress is calculated using the ``Pensation Line Method'' and curing is managed so as not to exceed the tensile stress of the concrete.

Other Examples> When constructing a structure that is subject to significant external restraints, it is expected that the temperature of the concrete will have to be lower than the temperature assumed in the above example.

In such a case, if the temperature rise can be suppressed to an allowable amount at low cost, the following method can be used in combination.

A method of using special cement such as low calorific cement with low calorific value.

■How to mix fly ash.

■Method to reduce the amount of cement per unit.

■Method using cooled mixing water, cement, aggregate, etc.

In addition, if the temperature rise cannot be controlled within the allowable amount,
As shown in FIG. 2, the concrete 1 is constructed in a layered manner so that the temperature inside and outside can be adjusted, and cracking can be controlled by reducing the external restraining force.

That is, the strength development characteristics of the concrete 1 are adjusted for each layer using a retarder or the like.

Specifically, excluding the first layer 11 at the bottom (each layer 12, 13
... cools the upper layer of concrete before the lower layer to develop strength.

Finally, by developing the strength of the first layer 11, the influence of external restraining force is avoided and cracking is controlled.

Effects of the Present Invention> Since the present invention is as described above, the following effects can be obtained.

(a) When placing mass concrete, conventionally it was necessary to divide the casting into several parts.

By adopting the curing method of the present invention, even if mass concrete is poured all at once, cracks will not occur (and the period from pouring to completion of curing can be significantly shortened).

Note: Since the heat generation of the concrete itself is not suppressed, there is no need to change the mix ratio of concrete or add special admixtures.

Additionally, there is no need to pre-cool the material, and regular concrete can be used, reducing construction costs.

Kuha〉According to conventional curing techniques, the development of initial strength is slow (
There was a tendency to

In the present invention, even concrete with a rich mix can develop initial strength earlier than in the prior art.

Kuji〉The cooling water usually used for pipe cooling is 5~
The cooling water used in the present invention, which is often cooled to about 10° C., does not need to have a particularly low temperature, and ordinary water can also be used.

If cooling water heated by absorbing the heat generated by concrete is used as flooding, a good moist environment will be obtained and the strength will increase at a certain age.

When concrete temperature is controlled using a computer, cracks can be easily controlled because the measured temperature at various points in the concrete can be instantly determined.

Furthermore, the degree of curing and the timing to discontinue curing can be easily determined.

[Brief explanation of drawings]

Fig. 1 - Explanatory diagram of the concrete curing method according to the present invention

Claims (1)

[Scope of Claims] The temperature inside and outside of poured concrete is measured, and based on the measured temperatures inside and outside of the concrete, the outside surface of the concrete is heated, the inside of the concrete is cooled, and the concrete is heated. A concrete curing method characterized by curing while minimizing the temperature difference between inside and outside.