KR20180077812A - Measuring method doe coefficient of thermal expansion of hardening cementitious materials using elastic membrane - Google Patents

Abstract

The present invention relates to a method of measuring a thermal expansion coefficient of a cementitious composite under a curing process by using an elastic membrane. The method includes: a first step of enclosing and sealing the cement composite in the elastic membrane; a second step of measuring a weight of an entire sample; a third step of connecting the sample to a balance, filling an oil-type buoyancy liquid, and immersing the sample in a temperature regulation chamber; a fourth step of measuring a weight variation according to a temperature variation while adjusting a temperature of a water tank at a predetermined time interval; and a fifth step of calculating the thermal expansion coefficient by using measurement values. In the method of the present invention, the thermal expansion coefficient of the cement composite containing an unhardened cement paste or mortar changes as the cement composite is cured, and particularly, the thermal expansion coefficient remarkably changes before and after setting of the cement composite, so that the elastic membrane is used to measure a volume variation according to a temperature in the curing process and measure a linear thermal expansion coefficient from a measurement result in real time. Therefore, the volume variation of the cement composite is accurately predicted at an early material age, and the thermal expansion coefficient obtained by the volume variation is used to accurately design a concrete structure and perform precise analysis.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of measuring a thermal expansion coefficient of a cementitious composite which is being cured using an elastic membrane,

The present invention relates to a method for measuring the thermal expansion coefficient of a cementitious cement composite using an elastic membrane, and more particularly, to a method for measuring a thermal expansion coefficient of a cementitious composition comprising an uncured cement paste or mortar, And the thermal expansion coefficient is measured in real time from the measurement result, and the thermal expansion coefficient obtained by using the thermal expansion coefficient is used to design and precise analysis of the accurate concrete structure. In the curing cement composite using the elastic membrane And a method of measuring the thermal expansion coefficient.

Cement generates heat in the process of reacting with water (hydration process), which increases the temperature inside the concrete. This leads to the volume expansion of the entire concrete, and after the hydration has been finished for a certain period of time, the temperature is reduced and the volume is contracted.

Changes in the volume of cement paste at early ages cause large problems such as cracking of concrete structures. It is very important to accurately predict the changes in the volume of cement composites at early ages because cracks in concrete act as channels of harmful ions to reduce the durability of the structure.

The coefficient of thermal expansion of concrete is a typical parameter indicating the volume change of concrete according to temperature. Thermal stress analysis (eg stress analysis by temperature difference of bridge structure) in the design stage of concrete structure by temperature load, And the like.

However, in general, the coefficient of thermal expansion of concrete used for the design and analysis of concrete structures does not take into consideration changes in properties due to the constituent materials and hydration processes of the concrete, and the values (for example, 10 × 10 ^-6 / .

As described above, the concrete is changed depending on the type, composition ratio, age, temperature cycle and humidity conditions of the constituent materials. Recently, cement has been lacking data on thermal expansion coefficient due to use of industrial by-products such as blast furnace slag and fly ash.

Therefore, various methods and apparatuses for measuring the thermal expansion coefficient of concrete in consideration of these points have been proposed, since the cement paste of the early age has a large volume change and is more sensitive to temperature.

Non-Patent Document 1 uses SUS-304 (coefficient of thermal expansion: 17.3 × 10 ^-6 m / m / ° C), which has a larger thermal expansion coefficient than a concrete specimen and provides a stable value at room temperature, as a calibration specimen, And the coefficient of thermal expansion of the concrete including the recycled aggregate is calculated.

Patent Document 1 discloses a method of measuring the rate of change in temperature and the rate of change in length of a test specimen according to a temperature change in a measurement room by controlling a temperature in a measurement room while holding a measurement specimen of concrete to be measured in a measurement room and maintaining humidity constant , A standard specimen made of a material having a predetermined thermal expansion coefficient is measured under the same conditions as the above specimen to measure the temperature change rate and the rate of change of the length of the standard specimen according to the temperature change in the measuring chamber, Discloses a method and apparatus for measuring the coefficient of thermal expansion of a concrete, which estimates a coefficient of substantial thermal expansion of a test specimen based on a rate of change and a rate of change in length.

However, the above methods and apparatuses have not been able to reflect the characteristic that the thermal expansion coefficient changes with the progress of the curing process, especially the thermal expansion coefficient before and after the curing, as an experiment on the cured concrete specimen.

The present inventors have made efforts to obtain an effective method for measuring the coefficient of thermal expansion of a concrete, and as a result, it has been found that the cement composites containing cement pastes or mortars during curing have a real time linear thermal expansion coefficient And by using the thermal expansion coefficient obtained by using the thermal expansion coefficient, it is confirmed that accurate design and accurate analysis of the concrete structure can be performed. Thus, the present invention has been completed.

1. Korean Patent No. 1365972 (Registered on February 17, 2014)

1. International Journal of Highway Engineering, 2015, 17, 7-16.

It is an object of the present invention to provide a method for measuring the thermal expansion coefficient of a non-hardened cementitious composite.

In order to accomplish the above object, the present invention provides a method for manufacturing a cement composite, comprising: a first step of holding a cement composite in an elastic membrane,

A second step of measuring the mass of the entire sample after the sealing,

A third step of connecting the sample to a balance, filling a buoyancy solution of oil flow into the chamber and immersing it in a temperature control chamber,

A fourth step of adjusting the water bath temperature to a range of 17 to 23 캜 at a predetermined time interval after the immersion and measuring a mass change with temperature change,

And a fifth step of calculating the thermal expansion coefficient of the cementitious composite under cure using the measured value.

In the first step, the elastic membrane is selected from the group consisting of a natural rubber latex, a composite of the natural rubber latex and polyurethane, and polyisoprene.

It is preferable that the buoyancy solution of the oil flow in the third step uses silicone oil, and the sample in the third step is immersed in the center so as not to touch the bottom of the water tank.

According to the present invention, it is possible to measure the linear thermal expansion coefficient in real time from the measurement of the volume change according to the temperature and the measurement result in the curing process before the completion of curing, with respect to the cement composite containing the uncured cement paste or mortar.

Accordingly, the method of measuring the thermal expansion coefficient of a cement composite during curing according to the present invention accurately predicts a change in volume of a cement composite at an early age, and can accurately design and precise analysis of a concrete structure utilizing the thermal expansion coefficient obtained by using the thermal expansion coefficient.

1 is a view illustrating a process of filling a cement composite in an elastic membrane of a first process according to a method of measuring a thermal expansion coefficient of a cement composite during curing of the present invention,
FIG. 2 is a view showing a process of fixing an elastic membrane filled with the cement composite of FIG. 1 with an iron clamp,
3 shows a method of conducting the thermal expansion coefficient test of FIG. 1,
FIG. 4 shows the temperature change inside the temperature control chamber and the temperature change of the cement composite according to the method of FIG. 1,
FIG. 5 shows the result of the change in the volume of the cement composite according to the temperature change and the elapsed time from the results of FIG. 4,
FIG. 6 shows the results of calculation of the thermal expansion coefficient with time from the results of FIG.

Hereinafter, the present invention will be described in detail.

The present invention relates to a method for manufacturing a cement composite, comprising a first step of holding a cement composite in an elastic membrane,

A second step of measuring the mass of the entire sample after the sealing,

A third step of connecting the sample to a balance, filling a buoyancy solution of oil flow into the chamber and immersing it in a temperature control chamber,

A fourth step of adjusting the water bath temperature to a range of 17 to 23 캜 at a predetermined time interval after the immersion and measuring a mass change with temperature change,

And a fifth step of calculating the thermal expansion coefficient of the cementitious composite under cure using the measured value.

The cement composite used in the first step includes cement paste or mortar. The measurement method of the present invention is a method of measuring a volume change according to temperature in a curing process before raw material is completed and measuring the linear thermal expansion coefficient And the thermal expansion coefficient of the cement composite under cure can be measured while keeping the kind, composition ratio, age, temperature cycle and humidity condition of the raw material constituting the cement composite as it is.

The elastic membrane used in the first step can be sealed with the cement composite as a raw material, and a material that does not deform the membrane itself by heat can be used. Preferably, the elastic membrane is selected from the group consisting of a natural rubber latex, a composite of the natural rubber latex and polyurethane, and polyisoprene.

FIGS. 1 and 2 illustrate the step of sealing the cement composite in the first step by clamping it with an elastic membrane.

The buoyancy liquid in the third step uses silicone oil in the embodiment of the present invention, but it is not limited to this, and it is possible to substitute normal oils in the buoyancy liquid, and water can be used in consideration of ease of handling . At this time, in the third step, the sample is immersed in the center portion so as not to touch the bottom of the water tank.

3 shows an experimental method for measuring the thermal expansion coefficient of a cementitious composite under curing.

According to the method of measuring the thermal expansion coefficient of the curing composite of the present invention, from the results shown in FIGS . 4 to 6 , the linear thermal expansion coefficient is measured in real time from the measurement of the volume change according to the temperature in the curing process before completion of the curing, Can be measured.

Accordingly, it is possible to accurately predict the change in volume of the cement composite at an early age through the method of measuring the thermal expansion coefficient of the cement composite during curing of the present invention, and to accurately design and precise analysis of the concrete structure utilizing the thermal expansion coefficient have.

Hereinafter, the present invention will be described in more detail with reference to Examples.

The present invention is intended to more specifically illustrate the present invention, and the scope of the present invention is not limited by these examples.

< Example  1>

Pour the buoyancy liquid into a thermostable water bath. At this time, care should be taken not to evaporate the solution during the experiment, and water and silicone oil were used as the buoyancy solution. After setting the temperature (17 ° C) to start the experiment, wait until the temperature of the solution stabilizes.

As shown in Fig. 1, the elastic membrane was clamped to the clamp, and the elastic membrane was prepared as a very thin natural rubber latex material so that the volume change was negligible. Thereafter, 150 g of the cement paste blended through a vacuum mixer was filled in the elastic membrane.

As shown in FIG. 2, the elastic membrane filled with the cement paste was tightly sealed so as to prevent air bubbles, secured with an iron clamp, and sealed.

Silicon strings (fishing rods) were tied to the iron clamps and connected to the scales to prepare masses, and the mass of all samples including the silicon strings was measured through the scales. At this time, the balance shall be able to measure and record the mass change over time in 1-minute increments. The prepared sample was connected to a balance and immersed in a temperature adjustable water tank filled with a buoyancy solution. At this time, the sample was placed so that it could reach the middle part of the water tank, being careful not to sink to the bottom of the water tank.

3 shows an experimental method for measuring the thermal expansion coefficient of the present invention.

After the above procedure was completed, the temperature of the water tank was adjusted to 17 to 23 ° C at intervals of 1 hour, and mass change data according to the temperature change was measured and recorded.

The obtained measurement value was calculated by the following equation to calculate the thermal expansion coefficient of the cement composite.

As a result, FIG. 4 shows the result of observing the temperature change inside the temperature control chamber and the temperature change of the cement composite for 30 hours after controlling the temperature change in the range of 17 to 23 ° C at intervals of 1 hour. Through the iterative process of cooling and cooling, it is possible to observe the result that the cement composite reacts by the temperature change.

FIG. 5 shows the results of the volume change of the cement composite according to the time under the temperature change condition in which the measurement time was extended to 110 hours or more from the results of FIG. 4. As shown in FIG. 5, And after 30 hours, complete curing was confirmed.

FIG. 6 is a graph showing the linear thermal expansion coefficient calculated by the formula 1 according to the measurement result of FIG. 5, and it is possible to calculate the linear thermal expansion coefficient in real time through the volume change according to the temperature change of the cement composite at an early age.

Accordingly, through the method of measuring the thermal expansion coefficient of the cement composite during curing, precise prediction of the volume change of the cement composite at the initial age, and accurate design of the concrete structure and accurate analysis using the thermal expansion coefficient .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

10: cement composite 20: elastic membrane
30: Clamp 31: Metal clamp
32: Silicone Rope 40: Balance
50: Temperature control device 51: Temperature control chamber
52: Buoyancy solution

Claims (4)

Cement composite in an elastic membrane and clamping it with a clamp to seal the cement composite,
A second step of measuring the mass of the entire sample after the sealing,
A third step of connecting the sample to a balance, filling a buoyancy solution of oil flow into the chamber and immersing it in a temperature control chamber,
A fourth step of adjusting the water bath temperature to a range of 17 to 23 캜 at a predetermined time interval after the immersion and measuring a mass change with temperature change,
And a fifth step of calculating the thermal expansion coefficient of the cementitious composite under cure using the measurement value.

The cement composition according to claim 1, wherein the elastic membrane in the first step is any one selected from the group consisting of a natural rubber latex, a composite of the natural rubber latex and polyurethane, and polyisoprene. How to measure. The method according to claim 1, wherein the buoyant solution of the oil flow in the third step is a silicone oil. The method according to claim 1, wherein the sample is immersed in a central portion of the cage so that the sample does not contact the bottom of the water tank in the third step.

Images