JP2009002721A - Method for determining time of demolding concrete - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for determining time of demolding the concrete that simply and accurately estimates the strength when demolding the concrete of a young material age on the way of curing like the coating concrete of a mountain tunnel. <P>SOLUTION: An internal temperature is measured at the end of the crown part 3 of a centering when casting the coating concrete 2 of a tunnel 1 (step 1), a cubic test piece and a columnar test piece, both of which includes the same material of on-the-spot concrete, are made to be aged in a thermostatic ageing chamber to which a measuring temperature is applied (step 2), the measurement of the degree of repulsion of the cubic test piece due to a pendulum type hammer tester and the uniaxial compression test of the columnar test piece are performed at the same time to obtain the degree of repulsion and a uniaxial compression strength curve (step 3) in an elapse of 16 to 24 hrs, the form of the end is partially detached and the degree of repulsion of the on-the-spot concrete is measured by the pendulum type hammer tester and the compression strength of the on-the-spot concrete is estimated using the curve (step 4) and, if the on-the-spot concrete reaches predetermined demoldable strength, the whole of the centering is lowered to demold the concrete. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a concrete demolding time determination method for nondestructively estimating the demolding time of mountain tunnel lining concrete or the like.

  When constructing lining concrete for mountain tunnels, it is necessary to determine the demolding time of the centle (mobile steel formwork) in order to ensure quality. As a method of estimating the strength at the time of demolding, the necessary demolding strength is determined analytically or empirically, and from the uniaxial compressive strength and material age obtained by destructive inspection of the cylindrical specimen prepared by test kneading with a uniaxial compression tester The in-situ necessary curing time was estimated and the mold was removed after confirming the passage of the necessary curing time.

  However, the tunnel tunnel is not at a constant atmospheric temperature from the roadbed to the crown (the top of the arch), and is not the same as the curing temperature of the specimen. For this reason, in the above conventional method, the demolding time is determined from the estimated strength of concrete that has actually hardened due to different curing histories, and the strength at the time of demolding of the actually placed lining concrete is unknown.

On the other hand, as a simple general strength estimation method for concrete, there is an estimation method based on hammer rebound of a nondestructive concrete compressive strength hammer tester (trade name: Schmitt concrete test hammer). This method is applied to hardened concrete. It is an effective method, and cannot be applied to young age concrete such as lining concrete that is generally demolded at about ² to 3 N / mm2.

Among the above hammer testing machines, the pendulum type hammer testing machine can measure the rebound degree of the low strength concrete of 0.2 to 5 N / mm ² described above. The measured degree of repulsion can be read, and the compressive strength can be easily obtained from the strength correlation graph attached to the test machine.

  However, since young concrete is still in the process of hardening, the strength varies depending on the placement shape and materials used, and a universal rebound-uniaxial compressive strength curve cannot be obtained. It was difficult to estimate the intensity.

  Moreover, there exist patent documents 1-3 as a prior art document relevant to this invention. The invention of Patent Document 1 is a method for accurately estimating the compressive strength of lining concrete for a specimen, a step of measuring a temperature history when the tunnel primary lining concrete is cured, and curing while giving the measured temperature history. The process of creating a specimen and performing a compressive strength test on the specimen, the process of obtaining the relationship between the integrated temperature and the compressive strength based on the test results, and the placement of lining concrete during the subsequent construction The process of calculating the integrated temperature by measuring the subsequent temperature history, and estimating the compressive strength of the concrete currently being cured from the relationship between the calculated integrated temperature and the integrated temperature obtained using the specimen before and the compressive strength To do.

  In the invention of Patent Document 2, the temperature of the placed concrete is measured by a temperature sensor, the integrated temperature is calculated from the measured concrete temperature by an arithmetic device, and the integrated temperature is set to a preset concrete mixing condition. It calculates and estimates the compressive strength of concrete using the corresponding calculation formula.

  The invention of Patent Document 3 measures high-precision hardened concrete strength using a simple mathematical formula using a rebound hardness measurement means (Schmidt Hammer).

JP-A-11-271301 JP 2003-279512 A JP 2004-233372 A

  As mentioned above, in the estimation method using a pendulum hammer tester that can measure the resilience of low-strength concrete, young age concrete is still in the process of being cured, There was a problem that the strength was different and a universal rebound-uniaxial compressive strength curve could not be obtained, and it was difficult to estimate practical strength.

  The present invention has been made in order to solve such a problem, and accurately and non-destructively estimates the strength at the time of demolding of a young concrete that is in the middle of curing, such as mountain tunnel lining concrete. An object of the present invention is to provide a method for determining the time for demolding concrete.

  Claim 1 of the present invention is a method for determining the demolding time of concrete placed using a mold, and measuring the internal temperature during setting of the cast concrete at the site (original position) (step 1) ), A step of preparing a specimen by curing at the measured temperature (step 2), a step of obtaining a correlation between the degree of rebound and the uniaxial compressive strength based on the test result of the specimen (step 3), and this It consists of a step (step 4) of estimating the possibility of demolding by estimating the uniaxial compressive strength of the cast concrete at the site (original position) from the repulsion degree of the cast concrete at the site (original position) using the correlation. This is a method for determining the demolding time of concrete characterized by the following.

  Claim 2 of the present invention is a method for determining the demolding time of tunnel lining concrete cast using a formwork (centre or the like), and during the hardening of the cast tunnel lining concrete at the site (original position) Correlation between the degree of rebound and uniaxial compressive strength according to the test result of this specimen, the process of measuring the internal temperature of the specimen (process 1), the process of preparing the specimen by curing at this measured temperature (process 2) Using this correlation, the uniaxial compressive strength of the tunnel lining concrete at the site (original position) is estimated from the rebound of the tunnel lining concrete at the site (original position) using this correlation. It is a demolding time determining method for tunnel lining concrete, characterized by comprising a step (step 4) for determining whether or not it is possible.

  According to a third aspect of the present invention, in the tunnel lining concrete demolding time determination method according to the second aspect, the internal temperature is measured and rebounded at the end portion of the crown portion (the top portion of the arch portion) of the tunnel lining concrete. This is a method for determining the demolding time of tunnel lining concrete, characterized by measuring the degree of the temperature.

  INDUSTRIAL APPLICABILITY The present invention is effective for estimation of strength at the time of demolding of young concrete in the middle of hardening, such as cast concrete or tunnel lining concrete (see FIG. 1) of a building or structure, that is, judgment of demolding time. Applied.

  In step 1, a concrete thermometer is inserted into the concrete being placed and cured at the in-situ location, the internal temperature is measured, and the average value of the internal temperatures within the set time is obtained.

  In Step 2, using the same material as the concrete at the site, a cube specimen for a pendulum hammer test and a cylinder specimen for a uniaxial compression test (see Fig. 2) corresponding to the concrete thickness are prepared. Curing in a constant temperature curing room.

  In step 3, when a predetermined time (for example, 16 to 24 hours) elapses, the repulsion degree of the cubic specimen is measured by a pendulum hammer tester capable of measuring the repulsion degree of the low-strength concrete, and the uniaxial compression of the cylindrical specimen. The test is performed simultaneously to obtain a resilience-uniaxial compressive strength curve (see FIG. 3).

  In step 4, a part of the concrete mold under curing at the in-situ location is removed, and the degree of repulsion is measured using the above pendulum hammer tester. The compressive strength of the on-site cast concrete is estimated using the resilience-uniaxial compressive strength curve obtained in step 3, and the mold is removed after confirming that it has reached a predetermined demoldable strength.

  Since young age concrete is still in the process of hardening, its strength varies depending on the placement shape and materials used, and is also affected by the curing temperature. Further, for example, the lining concrete is a concrete having a thickness of 300 mm or more, and the internal temperature and the atmospheric temperature are greatly different. For this reason, the curing process at the ambient temperature cannot provide the same curing process as the placed concrete. Also, different concrete materials have different internal heat generation temperatures. Therefore, in the present invention, by measuring the heat generation temperature inside the actually placed concrete and curing the specimen of the same concrete material at that temperature, a hardening process similar to that of the concrete placed on site can be obtained. .

  By performing a pendulum hammer test and a uniaxial compression test on the specimen cured in the same hardening process as that of the actual cast concrete, the resilience-uniaxial compressive strength is the same as that of the actual cast concrete. A curve is obtained. Further, by measuring the resilience of the actual cast concrete using the pendulum hammer tester, and estimating the compressive strength of the actual cast concrete using the above repulsion-uniaxial compressive strength curve. In addition, the strength at the time of demolding of the young concrete during curing can be easily and accurately estimated without breaking.

  In tunnel lining concrete, the internal temperature and the resilience may be measured at the end of the crown of the tunnel lining concrete (the top of the arch) (see FIG. 1). That is, the crown end portion of the lining concrete is a portion where the concrete is finally filled, and if the strength at this position is confirmed, it can be estimated that the strength of other portions is higher.

  Since this invention consists of the above structures, there can exist the following effects.

  (1) Non-destructive and accurate estimation of the demolding strength of young concrete that is in the process of curing, such as mountain tunnel lining concrete, enables highly reliable construction management and quality assurance. Become.

  (2) A concrete thermometer, a conventional hammer tester, a uniaxial compression tester, and the like can be used, and it is possible to accurately determine the demolding time at a low cost.

  Hereinafter, the present invention will be described based on the illustrated embodiments. FIG. 1 is a sectional view showing an example of a mountain tunnel to which the concrete demolding time determination method of the present invention is applied. The lining concrete 2 at the arch part of the mountain tunnel 1 is placed by a centle (movable steel formwork). The demolding time determination method of the present invention is applied to the crown portion (top portion of the arch portion) 3 of the lining concrete 2.

FIG. 2 is a perspective view and a front view showing an example of a specimen used in the present invention. The specimen is manufactured using the same material as the lining concrete on site. FIG. 2 (a) shows a cube specimen 20 of a pendulum hammer tester (trade name: Schmidt concrete test hammer) 10 capable of measuring the repulsion degree of low-strength concrete of 0.2 to 5 N / mm ² , which is a lining concrete. A cubic concrete having a thickness of 30 cm × 30 cm × 30 cm corresponding to the thickness of 2 or larger than this dimension is used. Measurement points are marked on the surface of the cube specimen 20. In addition, since the repulsion degree of a pendulum type hammer test is influenced by the dimension and boundary conditions of an object specimen, a cube specimen is fixed and used as a specimen that can ignore this influence. FIG. 2B shows a cylindrical specimen 30 used for a uniaxial compression test.

  The demolding time determination method of the present invention is carried out in the following procedure.

(1) Step 1: Insert a concrete thermometer into the lining concrete 2 from the crown end of the centle during the first lining concrete placement, measure the internal temperature, and average the internal temperature within the set time Ask for.

(2) Process 2: Cubic specimen 20 and cylindrical specimen 30 were made using the same material as lining concrete 2 in situ at the site, and these were subjected to isothermal curing with the concrete temperature measured in process 1 Curing in the room.

(3) Process 3: When each time period from 16 hours to 24 hours elapses, the rebound degree measurement by the pendulum hammer tester 10 on the legislative specimen 20 and the uniaxial compression test of the cylindrical specimen 30 are simultaneously performed, Obtain correlation of uniaxial compressive strength. FIG. 3 shows an example of the obtained resilience-uniaxial compressive strength curve.

(4) Process 4: Prior to the demolding for placing the lining concrete for the second and subsequent times, part of the formwork of the crown wife of the centle is removed and in situ using the pendulum hammer tester 10 The rebound degree of the lining concrete 2 during curing is measured at a plurality of points over a predetermined range. After estimating the compressive strength of the lining concrete 2 during curing using the resilience-uniaxial compressive strength curve obtained in step 3 and confirming that it has reached a predetermined demoldable strength, Lower and remove the mold.

  The crown end portion of the lining concrete 2 is a portion where the concrete is finally filled, and if the strength at this position is confirmed, it can be estimated that the strength of other portions is higher.

  The demolding time determination method as described above is repeated every time concrete is cast using a mobile centle.

  In addition, although the example applied to the judgment of the demolding time of tunnel lining concrete was shown above, it is not restricted to this, It can apply also to the judgment of the demolding time of other placement concrete.

It is sectional drawing which shows an example of the mountain tunnel to which the demolding time determination method of the concrete of this invention is applied. It is an example of the specimen used by this invention, (a) is a perspective view and front view of a cube specimen, (b) is a perspective view of a cylindrical specimen. It is a graph which shows the correlation of the repulsion degree and uniaxial compressive strength in this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Mountain tunnel 2 ... Lined concrete 3 ... Crown part 10 ... Pendulum type hammer testing machine 20 ... Cube specimen 30 ... Cylindrical specimen

Claims (3)

It is a method to determine the demolding time of concrete placed using a formwork,
Correlation between resilience and uniaxial compressive strength according to the process of measuring the internal temperature during hardening of the cast concrete on site, the process of preparing the specimen by curing at this measured temperature, and the test results of this specimen And determining the possibility of demolding by estimating the uniaxial compressive strength of the cast concrete at the site from the resilience of the cast concrete at the site using this correlation. Demolding time judgment method. It is a method to determine the demolding time of tunnel lining concrete placed using a formwork,
The process of measuring the internal temperature during hardening of the cast tunnel lining concrete at the site, the process of preparing the specimen by curing at this measured temperature, and the resilience and uniaxial compressive strength according to the test results of this specimen And determining the possibility of demolding by estimating the uniaxial compressive strength of the tunnel lining concrete at the site from the resilience of the tunnel lining concrete at the site using this correlation. A method for determining the demolding timing of tunnel lining concrete.   3. The method of determining the demolding time of tunnel lining concrete according to claim 2, wherein the inner temperature is measured and the degree of rebound is measured at the end of the crown portion of the tunnel lining concrete. Demolding time judgment method.

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