JP2004069363A - Concrete testing method and device therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a testing method and a testing device capable of properly and efficiently evaluating the behavior of semi-high fluidity concrete or soft milling fresh concrete. <P>SOLUTION: A slope flow tester 1 comprises a cylindrical tank part 2 and a slope flow part 3 of a prescribed slope divided from the lower part of the tank part 2 with a partition plate 4. Fresh concrete is put in the tank part 2 of the slope flow tester 1 as a sample, By opening the partition plate 4, the sample is made to flow down to the slope flow part 3. By measuring the speed of the sample with a sensor 9 of a speed measurement device 8, mainly the plastic viscosity or the like associated with workability can be evaluated. <P>COPYRIGHT: (C)2004,JPO

Description

【００３８】
コンクリートの練り混ぜは、容量１００リットルのパン型強制練りミキサを用いて行った。練混ぜ方法は、粗骨材、細骨材（１／２）、セメント、細骨材（１／２）の順に投入し、１分間攪拌した後、水および混和剤を投入した。これを１分３０秒攪拌してから排出した。
【００３９】
試験方法としては、上述した図１の傾斜フロー試験器１を用い、タンク部２のコンクリート投入口に１０リットルのコンクリート試料を３層１０回突き詰めてから静かに仕切板４のゲートを開き、流下速度を測定した。また、並行して従来法によるスランプ値およびスランプフロー値を測定した。
【００４０】
実験結果は、表１に併記した通りである。また、図２に水セメント比と流下速度（傾斜フロー速度）の関係を示した。
【００４１】
傾斜角度が２６°の時の流下速度は高速のため、実験に用いた装置では測定不可能であった。
【００４２】
一般に、水セメント比（Ｗ／Ｃ）が小さくなると粘性が大きくなり、流動性は低下する傾向にある。図２において、水セメント比（Ｗ／Ｃ）が小さくなるにつれて流下速度が小さくなっていることから、傾斜フロー試験が流動性の一般的傾向を示していることが確認できる。
【００４３】
傾斜角度については、スランプ値と傾斜フローとの単回帰分析を行った結果、水セメント比（Ｗ／Ｃ）およびスランプに関係なく、傾斜角度が２０°の場合は、相関が低いことが分かる。一方、傾斜角度が２３°の場合は、決定係数Ｒ^２が０．９８９および０．９５８３となり、流下速度１５〜４０ｃｍ／ｓｅｃにおいて高い相関が確認できる。
【００４４】
この実験結果においては、傾斜フロー試験によりフレッシュコンクリートの粘性の評価が可能であり、上記の条件の下、傾斜角度については２３°が適していることが分かった。
【００４５】
【発明の効果】
本願発明の試験方法、試験装置によれば、従来のスランプ試験やスランプフロー試験では的確な評価ができなかった準高流動コンクリートや軟練りのコンクリートのワーカビリティーの評価を、傾斜フローの適用により効率よく、より適正によく行うことができる。
【図面の簡単な説明】
【図１】本願発明に係る傾斜フロー試験器の一実施形態を示す側面図である。
【図２】実験結果における水セメント比と流下速度（傾斜フロー速度）との関係を示すグラフである。
【図３】従来例としてのＬ形フロー試験器を示す斜視図である。
【符号の説明】
１…傾斜フロー試験器、２…タンク部、３…傾斜フロー部、４…仕切板、５…支柱、６…上部支持部、６ａ…固定ねじ、７…下端支持部、７ａ…固定ねじ、８…フロー速度測定器、９…センサ、２１…Ｌ形フロー試験器、２２…鉛直部、２３…水平部、２４…仕切板[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a test method and a test apparatus for uncured fresh concrete, and is particularly suitable for an evaluation test of semi-high-flow concrete or soft-mixed concrete.
[0002]
[Prior art]
As a test method for evaluating the workability of uncured fresh concrete, a slump test method of JIS A 1101 using a slump cone is most widely used.
[0003]
On the other hand, in recent years, the construction performance of high fluidity concrete with high fluidity using a fine powder having a large specific surface area and excellent self-filling property has been increasing, but high fluidity concrete has too high fluidity and the conventional slump test Because it cannot be handled, slump flow test method is used for high fluidity concrete.
[0004]
The slump flow test uses a slump cone in the slump test method of JIS A 1101 described above, and measures a slump flow value (mm) based on the diameter of the spread of the sample and a 500 mm arrival time (t-500) using a stopwatch. Is done.
[0005]
Further, as an improved type of the slump flow test method, there is an L-shaped flow test method, which has been standardized as a test method for high fluidity concrete together with the slump flow test method.
[0006]
In the L-shaped flow test method, an L-shaped tester 21 having a vertical portion 22 and a horizontal portion 23 as shown in FIG. 3 is used. After filling, the partition plate 24 that separates the vertical portion 22 and the horizontal portion 23 is pulled up, and the passage time of 5 cm and 10 cm sections from the opening is measured by a sensor, and the sinking amount of the vertical portion 22 when the flow is stopped and Measure the amount of movement to the tip.
[0007]
In addition, as an improved type of the slump flow test method, a plurality of concentric barriers are provided on a flat plate in a slump flow test as in a method for evaluating fresh concrete described in Japanese Patent Application Laid-Open No. 9-218196, for example. There has been invented one that measures a flow value and an arrival time to each barrier.
[0008]
Japanese Patent Application Laid-Open No. 9-250980 discloses a conventional slump flow test described above and a vertical leg at the outer circumferential position of a slump cone for each circumferentially equal position of a belt ring as a consistency test method for high fluidity concrete. A method is described in which a barrier slump flow test performed by installing a barrier provided with is also used, and a consistency related to workability is evaluated from a comparison thereof.
[0009]
When the behavior of fresh concrete is modeled as the behavior of a Bingham fluid, the slump value and the slump flow value are mainly used to evaluate the yield value τf, and the 500 mm arrival time in the slump flow test including the time element and the V funnel test Is used to evaluate the plastic viscosity ηpl.
[0010]
[Problems to be solved by the invention]
In recent years, as the performance required of concrete is becoming increasingly sophisticated and diversified, problems with the above-mentioned high fluidity concrete, such as cost increase due to increase in the amount of powder and increase in shrinkage, have been pointed out. Management is required.
[0011]
The quasi-high-fluidity concrete with a slump flow of about 450 ± 50 mm, which seems to be able to reduce these problems, has no self-compacting property, but has good fluidity due to slight vibration by vibrator etc. Also, excellent material separation resistance is expected even under vibration conditions.
[0012]
However, the conventional slump test method is said to be suitable for the evaluation of concrete with a slump of 21 cm or less, and the slump flow test method and the L-shaped flow test method, and their improved methods are used for slump flow of high-fluid concrete with a slump flow of 600 mm or more. It is considered to be suitable for evaluation, but the above-mentioned slump flow located in between does not reach approximately 450 ± 50 mm quasi-high-fluidity concrete (usually having a slump value of about 21 to 25 cm) or quasi-high-fluidity concrete For soft-mixed concrete with a relatively large slump (slump value 15 cm or more), there was no test method capable of properly evaluating the properties of fresh concrete.
[0013]
That is, in the conventional slump test method, as in the case of the high fluidity concrete, the fluidity is too high, and it is difficult or impossible to measure the slump value.
[0014]
In addition, in the slump flow test method, for example, the measurement itself of t-500 cannot be performed unless the flow reaches 500 mm. In addition, the accuracy falls extremely in the range where the flow finally reaches 500 mm. In contrast, a slight difference in performance is sensitive to slump flow, whereas in the case of semi-high fluidity concrete with a slump flow of about 450 ± 50 mm, the difference in performance is not remarkable as a difference in slump flow value, but also extremely There is a problem that accuracy is reduced.
[0015]
The present invention relates to a test method and a test apparatus capable of appropriately and efficiently evaluating properties of fresh concrete such as workability or consistency of quasi-high fluidity concrete and soft-mixed concrete, for which there was no test method that can be appropriately evaluated. It is intended to provide.
[0016]
[Means for Solving the Problems]
The method for testing concrete according to claim 1 of the present application is directed to the tank of the inclined flow tester including a cylindrical tank portion and an inclined flow portion having a predetermined inclination defined by a partition plate and a lower portion of the tank portion. To the portion, a sample of uncured fresh concrete is packed to a predetermined height, and by opening the partition plate, the sample is caused to flow down to the inclined flow portion, and the flowing speed of the sample at that time is measured. And evaluating the workability of the sample.
[0017]
Although the basic principle is the same as the L-shaped flow test method, the L-shaped flow test method measures the flow and spread of concrete on a horizontal surface in the same manner as the normal slump flow test method, whereas the test of the present invention The method evaluates workability mainly by measuring the flow velocity on an inclined surface.
[0018]
This is related to the fact that the target of the sample to be evaluated is soft-mixed concrete or semi-high-fluidity concrete, which has been difficult to properly evaluate in the past. For these concrete samples having low fluidity, measurement is performed with the apparently amplified fluidity by using the inclined surface. According to this test method, the evaluation of plastic viscosity (ηpl), which is one of the elements of workability evaluation, can be performed more accurately than the conventional V-funnel test or slump flow test method.
[0019]
According to a second aspect of the present invention, in the concrete testing method according to the first aspect, a sensor provided in the inclined flow section measures a moving time of the flowing sample in a predetermined section to obtain the falling speed. Is what you do.
[0020]
In the concrete test method according to claim 1, the method of measuring the flow velocity is not particularly limited, but the measurement by the stopwatch used in the slump flow test method has low reliability, and is conventionally mounted on an L-shaped flow tester. By using such a speed sensor, a highly accurate measurement result can be obtained.
[0021]
Such a sensor generally determines the speed based on the time difference between when concrete passes two or several points apart (usually measured at the tip of the falling concrete).
[0022]
The inclined flow tester according to claim 3 of the present application is divided by a cylindrical tank portion into which a sample is charged, a lower portion of the tank portion and a partition plate, and is charged into the tank portion by opening the partition plate. It is characterized by comprising an inclined flow part with a predetermined inclination in which the sample flows down, and a sensor for measuring the flow velocity of the sample in the inclined flow part.
[0023]
The basic principle is the same as that of the L-shaped flow tester, but the L-shaped flow tester has a form in which a predetermined inclination is provided in a horizontal portion.
[0024]
That is, the sample is put into a cylindrical tank portion corresponding to the vertical portion of the L-shaped flow tester, and the sample flows down the inclined flow portion by lifting the partition plate. For samples of soft-mixed concrete or semi-high-flowable concrete, the flow is promoted by tilting, so that the sensitivity can be increased as compared with the L-type flow tester, and the workability of concrete can be evaluated with higher accuracy.
[0025]
According to a fourth aspect of the present invention, in the inclined flow tester according to the third aspect, the inclination of the inclined flow portion from horizontal is 20 ° to 26 °.
[0026]
Regarding the evaluation of workability, in addition to the plastic viscosity, the concrete yield value (τf) and the like are also important factors, and there are some aspects that cannot be determined unconditionally. However, the slump flow mainly targeted by the present invention is about 450 ± 50 mm. In the case of semi-high fluidity concrete or soft-mixed concrete having a large slump value, if the slope is less than 20 °, the falling speed is not sufficient because the flow rate is not enough, and the sensitivity becomes poor (variation of the measurement results becomes large). If it is large, the flow speed is too fast, and accurate measurement may be difficult.
[0027]
According to a fifth aspect, in the inclined flow tester according to the third or fourth aspect, the inclination of the inclined flow section is variable.
[0028]
When semi-high-fluidity concrete or soft-mixed concrete is targeted, it is considered that it is desirable to select the inclination of the inclined flow portion from the horizontal in the range of 20 ° to 26 ° limited by claim 4. If the inclination of the inclined flow section is made variable, for example, by making the joint between the tank section into which the liquid is injected and the inclined flow section have a pin structure, for example, the object to be applied is further finely limited and the measurement at the optimal inclination is performed. And so on.
[0029]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows an embodiment of an inclined flow tester 1 of the present invention, which has a cylindrical tank portion 2 and an inclined flow portion 3 inclined at a predetermined angle θ. The sample is divided into several layers and injected while being squeezed, and the sample flows down the inclined flow section 3 by grasping the handle 4a and pulling up the partition plate 4.
[0030]
In the present embodiment, the inclined flow portion 3 has a groove-shaped cross section with an open upper surface, and a flow speed measuring device 8 for measuring the flow speed of concrete is detachably mounted at an intermediate position. Further, the tip of the inclined flow part 3 is closed, and the concrete that has flowed down is accumulated inside, but the tip may be open.
[0031]
The flow velocity measuring device 8 is the same as that used in the conventional L-shaped flow tester, and passes through the tip position of the concrete flowing down by the plurality of non-contact objective sensors 9 arranged at predetermined intervals. By catching the time, the flow velocity can be measured based on the distance between the sensors 9 and the time difference.
[0032]
In the drawing, reference numeral 5 denotes a column for supporting the tank portion 2 and the inclined flow portion 3, and a cylindrical upper support portion 6 welded to both side surfaces of the tank portion 2 is screwed to the column 5 with fixing screws 6a. The lower end support portion 7 having a cylindrical shape is fixed to the column 5 by a fixing screw 7a below the lower end portion, and supports the lower surface of the inclined flow portion 3 at the start end. By adjusting these supporting heights, the inclination θ of the inclined flow section 3 can be changed.
[0033]
Next, an experimental example using the inclined flow tester will be described.
[0034]
The materials and physical properties used in the experiment are as follows.
[0035]
Cement: ordinary Portland cement (specific gravity ρ = 3.16)
Fine aggregate: mountain sand (specific gravity ρ = 2.62)
Coarse aggregate: calcareous crushed stone (specific gravity ρ = 2.70)
Admixture: Concrete Using the AE water-reducing agent experiment, a target slump and 15～21Cm, water-cement ratio (W / C) 40~55%, and the unit quantity of water is changed from 155~199kg / ^{m 3.}
[0036]
The composition is shown in Table 1.
[0037]
[Table 1]

[0038]
The kneading of the concrete was performed using a pan-type forced kneading mixer having a capacity of 100 liters. The kneading method was as follows: coarse aggregate, fine aggregate (1/2), cement, and fine aggregate (1/2) were added in this order, and after stirring for 1 minute, water and an admixture were added. This was stirred for 1 minute 30 seconds and then discharged.
[0039]
As a test method, using the inclined flow tester 1 shown in FIG. 1 described above, a 10-liter concrete sample is thrust into the concrete inlet of the tank 2 three times 10 times, and then the gate of the partition plate 4 is gently opened, and the flow is allowed to flow down. The speed was measured. In addition, a slump value and a slump flow value according to a conventional method were measured in parallel.
[0040]
The experimental results are as shown in Table 1. FIG. 2 shows the relationship between the water-cement ratio and the falling speed (inclined flow speed).
[0041]
When the inclination angle was 26 °, the falling speed was so high that it could not be measured by the apparatus used in the experiment.
[0042]
Generally, as the water-cement ratio (W / C) decreases, the viscosity increases and the fluidity tends to decrease. In FIG. 2, since the flow rate decreases as the water-cement ratio (W / C) decreases, it can be confirmed that the inclined flow test shows a general tendency of fluidity.
[0043]
As for the inclination angle, a simple regression analysis of the slump value and the inclination flow shows that the correlation is low when the inclination angle is 20 ° regardless of the water cement ratio (W / C) and the slump. On the other hand, when the inclination angle is 23 °, the coefficient of determination ^{R 2} is 0.989 and 0.9583, and the high correlation can be seen in falling speed 15~40cm / sec.
[0044]
In this experimental result, it was possible to evaluate the viscosity of the fresh concrete by the inclined flow test, and it was found that the inclination angle of 23 ° was suitable under the above conditions.
[0045]
【The invention's effect】
According to the test method and test apparatus of the present invention, the workability evaluation of semi-high-fluidity concrete and soft-mixed concrete, which could not be accurately evaluated by the conventional slump test and slump flow test, is efficiently performed by applying the inclined flow. Can be performed more properly.
[Brief description of the drawings]
FIG. 1 is a side view showing an embodiment of an inclined flow tester according to the present invention.
FIG. 2 is a graph showing a relationship between a water-cement ratio and a flow-down speed (inclined flow speed) in experimental results.
FIG. 3 is a perspective view showing an L-type flow tester as a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Inclined flow tester, 2 ... Tank part, 3 ... Inclined flow section, 4 ... Partition plate, 5 ... Prop, 6 ... Upper support part, 6a ... Fixing screw, 7 ... Lower end supporting part, 7a ... Fixing screw, 8 ... Flow velocity measuring device, 9 ... Sensor, 21 ... L-shaped flow tester, 22 ... Vertical part, 23 ... Horizontal part, 24 ... Partition plate

Claims (5)

A sample of uncured fresh concrete is placed in the tank section of the inclined flow tester having a cylindrical tank section and an inclined flow section having a predetermined inclination partitioned from the lower part of the tank section by a partition plate. By packing the sample to the height, by opening the partition plate, the sample is caused to flow down to the inclined flow portion, and by measuring the flow rate of the sample at that time, the workability of the sample is evaluated. Test method for concrete. 2. The concrete testing method according to claim 1, wherein the falling speed is obtained by measuring a moving time of the flowing sample in a predetermined section by a sensor provided in the inclined flow part. A cylindrical tank portion into which a sample is put, a lower portion of the tank portion and a partition plate, and an inclined flow portion having a predetermined inclination in which the sample put into the tank portion flows down by opening the partition plate, An inclined flow tester comprising a sensor for measuring a flow speed of the sample in the inclined flow section. The inclined flow tester according to claim 3, wherein an inclination of the inclined flow portion from the horizontal is 20 ° to 26 °. The tilt flow tester according to claim 3 or 4, wherein the tilt of the tilt flow section is variable.

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