JP2009098055A - Method for estimating compressive strength of concrete - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for estimating the compressive strength of concrete which can estimate the compressive strength of the concrete more quickly, in comparison with a conventional technique, with accuracy. <P>SOLUTION: A strength-estimating equation is previously established, wherein compound data of a concrete material, quality data on concrete manufactured by kneading the concrete material, and a compressive strength obtained from a compressive strength test of a sample made of the concrete after a prescribed curing period, are related to another. Construction-use compound data of a construction-use concrete material and construction-use quality data of a construction-use concrete, manufactured by kneading the construction-use concrete material, are substituted in this strength-estimating equation, thereby estimating the compressive strength of the construction-use concrete, after a prescribed period, at an early stage. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a concrete compressive strength estimation method for estimating concrete compressive strength from a plurality of data obtained during concrete production and inspection.

  Concrete is usually manufactured at a ready-mixed concrete factory (hereinafter referred to as a ready-mixed concrete factory) and subjected to acceptance inspection at a construction site. And the specimen is produced from the concrete sample extract | collected at the time of a receiving test | inspection, and it is confirmed whether predetermined | prescribed compressive strength is obtained. The compressive strength test by the acceptance test differs depending on the specifications, specifications, etc., but generally a compressive strength test on the age of 28 days is performed on a plurality of specimens collected. For example, according to JASS5, a compressive strength test is performed using specimens collected one by one (three in total) from three transport vehicles spaced at appropriate intervals.

  In a compressive strength test using such a concrete specimen, it is not possible to confirm whether or not a predetermined compressive strength is obtained unless concrete is driven into a member and cured. If the predetermined compressive strength is not obtained, enormous labor and cost are required for the subsequent response. Therefore, an inspection method capable of grasping the compressive strength of concrete with high accuracy as early as possible has been demanded.

As a method for determining the compressive strength of concrete at an early stage, Non-Patent Document 1 established as a JIS standard describes a compressive strength test method using a specimen subjected to warm water curing. According to this method, the specimen subjected to pre-curing at room temperature (5 to 30 ° C.) for 44 to 52 hours is cured in warm water at 40 ° C. until the age of 7 days. And it is supposed that the concrete compressive strength of the 28-year-old material which carried out standard curing can be calculated by performing the compressive strength test of the 7-day-old specimen. Moreover, in patent document 2, the estimation method of the concrete intensity | strength which can estimate the intensity | strength after hardening from the fresh concrete after kneading in a short period is disclosed. According to the present invention, an estimated cement water ratio is obtained from a sample collected from fresh concrete, and the strength can be estimated by a regression equation showing the correlation between the cement water ratios of various blends of concrete calculated in advance and the concrete strength.
Japanese Industrial Standards JIS A 1805: 2001 JP-A-8-304384

  However, in the test method described in Non-Patent Document 1, it takes 7 days at the shortest to confirm the compressive strength, and the placed concrete is already hardened. Therefore, it is preferable that the concrete compressive strength of a predetermined age can be determined earlier. Moreover, when the invention of Patent Document 2 is used, the early strength can be estimated at a desired time, but the compressive strength is estimated only by the water cement ratio obtained from the collected concrete sample. The compressive strength of concrete is basically linearly related to the cement water ratio (C / W), but other factors (eg, slump, air volume, concrete temperature, etc.) also affect the concrete strength. ing.

  The present invention has been made in order to solve such problems, and provides a method for estimating the compressive strength of concrete that can estimate the compressive strength of concrete earlier and more accurately than the prior art. The purpose is to provide.

  In order to achieve the above object, the compressive strength estimation method for concrete according to the present invention includes a strength estimation formula blending data for a strength estimation formula concrete material, and a strength estimation formula produced by mixing the strength estimation formula concrete material. The strength estimation formula quality data of the concrete, and after preparing a specimen from the strength estimation formula concrete and curing for a predetermined period, the compressive strength for the strength estimation formula obtained by the compressive strength test of the specimen, Build the strength estimation formula to be associated in advance, and substitute the blending data for construction of the concrete material for construction and the construction quality data of the concrete for construction manufactured by mixing the concrete material for construction into the strength estimation formula. The concrete compressive strength for construction after the predetermined period is estimated.

  Further, the cement water ratio of the concrete for strength estimation formula may be calculated from the blending data for strength estimation formula, and the cement water ratio of the concrete for construction may be calculated from the blending data for construction.

  The strength estimation formula quality data and the construction quality data may be configured to be at least one measurement data of concrete temperature, air volume, slump or slump flow measurement data.

  In addition, the strength estimation formula is a multiple regression formula obtained from a plurality of related formulas that associate the compressive strength for the strength estimation formula with the blending data for the strength estimation formula and the quality data for the strength estimation formula. It may be configured.

  As described above, according to the present invention, the concrete compressive strength at a predetermined age is immediately estimated by measuring the concrete temperature, the air amount, the slump or the slump flow by the acceptance inspection of the manufactured concrete. It becomes possible. Therefore, even if concrete having a problem in quality is delivered, there is an effect that it is possible to immediately cope with it. In addition, it is possible to eliminate defects caused when the specimen is collected (for example, filling failure, leaving the specimen under the hot sun, etc.) and human error due to the specimen being misplaced. Even for concrete that has not been examined in the conventional sampling test, it is possible to grasp the estimated compressive strength of the concrete. In addition, the cement water ratio can be used to estimate the compressive strength of the concrete, and the temperature, air volume, slump or slump flow of the concrete delivered to the site can be taken into account, so the compressive strength can be estimated with higher accuracy. . In particular, there is an effect that the change in the quality of concrete due to transportation from the ready-mix factory can be reflected in the estimation of the compressive strength.

  Hereinafter, the best mode for carrying out the concrete compressive strength estimation method according to the present invention will be described with reference to the drawings.

  FIG. 1 shows a flowchart of a concrete compressive strength estimation method according to an embodiment of the present invention. This flowchart is composed of operations (S111 to S114) in a concrete manufacturing process performed before concrete construction and operations (S115 to S118) performed at the time of receiving inspection of the manufactured concrete.

  Concrete is usually manufactured at a concrete factory or a concrete production plant installed in a construction site, and loaded into an agitator car or the like to a concrete placement site. These manufacturing factories (plants) accurately measure and measure each material using appropriate measuring methods and measuring methods using measuring devices and measuring devices that comply with JIS, JASS, and other standards. The concrete quality is ensured. Various data measured or measured at the time of concrete production are recorded through a measuring instrument, a system that can collect data directly from the measuring instrument, or in a data logger that is input by the worker during work, and is usually stored in the factory office. The data can be output as data on various media that are managed by a personal computer or the like installed on the computer and the measurement / measurement values are described (in the present invention, these data are referred to as “print data”) (S111). These data are the measured values of concrete materials such as cement, mixing water, fine / coarse aggregates, admixtures, etc. (both mass), and fine / coarse It indicates the actual measured value of the surface water content of the aggregate (including estimated values from lasers and sensors). The surface water content was measured for each extraction batch, and for batches that were not measured, a value based on the set value was used for strength estimation from the relationship between the measured value and the set value.

  The concrete weighed in this way is put into a mixer and kneaded for a predetermined time until the concrete material becomes uniform. The fresh concrete produced in this way is measured for concrete kneading temperature, air volume, slump or slump flow as production data (S112).

  Then, a sample is collected from the fresh concrete, and it is driven into a predetermined test body form defined by JIS or the like and compacted to produce a plurality of specimens. In this example, three specimens were prepared for each nominal strength at each age and in the same curing method. The prepared specimen is subjected to standard curing until a predetermined age. The predetermined age is the age of the compressive strength of concrete to be estimated at an early stage. For example, when it is desired to estimate the strength at 28 days, standard curing for 28 days is performed. The specimen subjected to the standard curing is required to have a compressive strength by a predetermined compression test method (S113). When concrete having a plurality of nominal strengths is constructed, a specimen having a composition based on each nominal strength is prepared and the compressive strength is obtained. Moreover, even if it is a test body in which the curing methods other than standard curing were performed, compressive strength can be calculated | required by the method similar to this invention.

Next, a strength estimation formula is constructed using the various data obtained in steps S111 and S112 and the concrete age strength obtained in step S113 (S114). The required strength estimation formula (Formula 1) is shown below.

σ _d = a + b · (C / W) −c · Sd · (Va / V) −e · t (Formula 1)

Here, σ _d is the age strength of concrete to be obtained (N / mm ² ), C / W is the water cement ratio (C: cement mass (kg), W: water mass (kg)), and S is slump (cm ), Va / V is the amount of air (%), t is the concrete temperature (° C.), a, b, c, d, and e are the coefficients. The compressive strength of concrete is roughly proportional to the cement water ratio (C / W). growing. Also, the larger the slump, the higher the concrete kneading temperature, and the greater the amount of air, the lower the compressive strength of the concrete. (Formula 1) is formulated based on such factors that affect the compressive strength of concrete.

  Here, various data (C, W (total water mass (mixed water amount + aggregate surface water amount)), S, Va / V, t) obtained in S111 and S112, and the predetermined age determined in S113. The compressive strength (σd) of concrete is substituted into (Equation 1). The coefficients a, b, c, d, and e can be obtained by performing multiple regression analysis on the obtained plurality of (Expression 1).

  The procedure described above is performed in a concrete manufacturing plant installed in a ready-mix factory or construction site before concrete construction. In constructing the concrete strength estimation formula, the concrete strength estimation formula is constructed using the concrete material and manufacturing equipment actually used at the construction site. By doing so, it is possible to construct a concrete compressive strength estimation formula that incorporates the concrete material and characteristics of the manufacturing equipment that are actually used, and therefore it is possible to estimate the compressive strength with higher accuracy.

  Next, the procedure (S115-S118) at the time of receiving the manufactured fresh concrete on the spot is demonstrated.

  Concrete for construction site construction is manufactured at a ready-mix factory or a concrete manufacturing factory installed in the construction site. And various data measured or measured at the time of concrete manufacture are obtained from printing data (S115). As in step S111, these data are the measured values (both masses) of concrete materials such as mixed water, fine / coarse aggregate, and admixture, and the surface water ratio of the fine / coarse aggregate. It refers to actual measurement values (including estimated values from lasers and sensors).

  When the manufactured fresh concrete arrives at the construction site, product inspection is performed to confirm the quality of the concrete. In the product inspection, a sample is collected from the manufactured fresh concrete, and the concrete temperature, air amount, slump or slump flow is measured (S116).

  The various data (C, W, S, Va / V, t) obtained in steps S115 and 116 are substituted into a pre-constructed compressive strength estimation formula (formula 1) to be estimated for a predetermined material age Strength σd (hereinafter referred to as estimated age strength) is obtained (S117).

  In order to verify the estimated material age strength obtained in this way, it is desirable to prepare a specimen from an arbitrarily sampled concrete sample, cure it to a predetermined age, and then check the compressive strength (S118).

FIG. 2 is a graph showing the relationship between the estimated value obtained by the concrete compressive strength estimation method according to Example 1 of the present invention and the measured value of the concrete compressive strength. This figure is based on a standard period (assuming spring and autumn temperatures around 20 ° C) for concrete with nominal strength 33 and slump 18cm medium temperature hot Portland cement. Has been created.
The vertical axis represents the actually measured 56-day intensity (N / mm ² ) obtained in step S113 of FIG. 1, and the horizontal axis represents the estimated intensity value (N / N) obtained from the intensity estimation formula obtained in step S114 of FIG. mm ² ). Therefore, the most ideal graph is plotted on a straight line y (vertical axis) = x (horizontal axis) (a straight line indicated by dots). The intensity estimation formula obtained from 681 measurement counts (data count) is as the following formula (Formula 2).

σ ₅₆ = 48.043 + 2.297 (C / W) −0.585 (Va / V) −0.473t (Formula 2)

Here, σ ₅₆ is the estimated 56-day intensity, and C / W, Va / V, and t are as described above. In this embodiment, the influence of the slump S shown by the general formula (Formula 1) is not taken into consideration.

From FIG. 2, the measured compressive strength has an error of about +7 (N / mm ² ) in the upper limit and about −4 (N / mm ² ) in the lower limit with respect to the estimated strength estimated by the compressive strength estimation method. . In the figure, broken lines representing a straight line y = x + 7 and a straight line y = x−4 are shown. Thus, although there is some variation between the estimated strength and the measured strength, this variation does not cause a problem in practice if the compressive strength is managed by the lower limit value.

FIG. 3 is a graph showing the relationship between the estimated value obtained by the concrete compressive strength estimation method according to Example 2 of the present invention and the measured value of the concrete compressive strength. This figure is based on a predetermined number of measurements, assuming a full year (assuming full year) for concrete using normal Portland cement with nominal strength 24 and slump 18cm. The vertical axis represents the actually measured 28-day intensity (N / mm ² ) obtained in step S113 of FIG. 1, and the horizontal axis represents the estimated intensity value (N / N) obtained from the intensity estimation formula obtained in step S114 of FIG. mm ² ). The intensity estimation formula obtained from the 51 measurement numbers (data counts) is as shown in the following formula (Formula 3).

σ ₂₈ = 50.942 + 2.906 (C / W) −0.524S−1.951 (Va / V) −0.192t (Formula 3)

Here, σ ₂₈ is the estimated 28-day intensity, and C / W, S, Va / V, and t are as described above.

From FIG. 3, the measured compressive strength has an error of about +2 (N / mm ² ) in the upper limit and about −2 (N / mm ² ) in the lower limit with respect to the estimated strength estimated by the compressive strength estimation method. . In the figure, broken lines representing a straight line y = x + 2 and a straight line y = x−2 are shown. Although the number of data is small, in the example shown in FIG. 3, the accuracy of the estimated intensity is improved compared to FIG. This is also due to the fact that the influence of the slump S is considered in (Equation 3).

  As described above, when the concrete compressive strength estimation method according to the present invention is used, the concrete temperature, air volume, slump or slump flow is measured by the acceptance inspection of the manufactured concrete, so that the predetermined age is immediately determined. It becomes possible to estimate the compressive strength of the concrete. Therefore, even if concrete with a problem in quality is delivered, it is possible to immediately take subsequent actions.

  In addition, it is possible to eliminate defects (for example, poor filling, leaving the specimen under the sun), and human error due to the specimen being misplaced.

  Moreover, the estimated compressive strength of concrete can be grasped also about the concrete which was not investigated by the sampling inspection by the conventional specimen. Therefore, it is an effective method in terms of guaranteeing the performance of concrete.

  In addition, the cement water ratio can be used to estimate the compressive strength of the concrete, and the temperature, air volume, slump or slump flow of the concrete delivered to the site can be taken into account, so the compressive strength can be estimated with higher accuracy. . In particular, there is an effect that the change in the quality of the concrete due to the transportation time from the ready-mix factory can be reflected in the estimation of the compressive strength.

  In the above-described embodiment, the factors of the concrete temperature, the air amount, and the slump are considered in addition to the cement water ratio in the estimation of the compressive strength of the concrete. However, the present invention is not limited to these. For example, as shown in the first embodiment, the present invention can be implemented without considering the influence of slump.

The flowchart of the compressive strength estimation method of the concrete which concerns on embodiment of this invention. The graph which showed the relationship between the intensity | strength estimated value obtained in Example 1, and an intensity | strength actual measurement value. The graph which showed the relationship between the intensity | strength estimated value obtained in Example 2, and an intensity | strength actual measurement value.

Explanation of symbols

  S111 to S118 Steps for carrying out the present invention

Claims (4)

Mixing data for strength estimation formula of concrete material for strength estimation formula,
Quality data for strength estimation formula of concrete for strength estimation formula produced by mixing the concrete material for strength estimation formula,
After preparing a specimen from the concrete for strength estimation formula and curing for a predetermined period of time, a strength estimation formula for associating the compressive strength for the strength estimation formula obtained by the compressive strength test of the specimen in advance is constructed,
The concrete data for construction of the concrete for construction and the quality data for construction of the concrete for construction produced by mixing the concrete for construction are substituted into the strength estimation formula, and the concrete compression for construction after the predetermined period is substituted. A method for estimating the compressive strength of concrete, characterized by estimating strength. Calculate the cement water ratio of the concrete for strength estimation formula from the blending data for strength estimation formula,
The method for estimating the compressive strength of concrete according to claim 1, wherein a cement water ratio of the concrete for construction is calculated from the blending data for construction.   The quality data for the strength estimation formula and the quality data for construction are at least one measurement data of concrete temperature, air volume, slump or slump flow measurement data. 2. A method for estimating the compressive strength of concrete according to 2.   The strength estimation formula is a multiple regression formula obtained from a plurality of related formulas associating the compressive strength for the strength estimation formula with the blending data for the strength estimation formula and the quality data for the strength estimation formula. The method for estimating the compressive strength of concrete according to any one of claims 1 to 3.

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