JP2001208666A - Method and device for measuring water content of fresh concrete - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate the drawback of conventional techniques for measuring the water content of fresh concrete that simple and accurate measurements are difficult to make with these techniques. SOLUTION: The unit volume mass of fresh concrete is measured after the amount of air in the fresh concrete is reduced and stabilized. Using the proportional relationship between a predetermined unit volume mass and a unit amount of water, the unit amount of water in the fresh concrete is determined from the measured unit volume mass, whereby the water content of the fresh concrete can be easily and accurately measured.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moisture measuring method and a moisture measuring device for measuring the moisture of fresh concrete (concrete that has not yet set).

[0002]

2. Description of the Related Art The moisture content of fresh concrete has a great influence on the quality of hardened concrete. For this reason, it is important to measure the moisture of fresh concrete. Techniques for measuring the moisture in fresh concrete include, for example, drying the fresh concrete using a microwave oven and weighing the amount of evaporated water with a scale, or removing the coarse aggregate from the fresh concrete to form a mortar, Is measured using microwaves.

[0003]

However, in the former method in which the amount of evaporated water is measured with a balance, it takes time to evaporate the water, and the amount of evaporated water changes as the hydration reaction of cement proceeds. Therefore, it is necessary to perform a correction calculation for the change, and there is a problem that accuracy is lost. In addition, even in the latter method using microwaves, the number of variables required for measurement increases, and errors of each variable are accumulated, so that accurate measurement cannot be performed.
In particular, when measuring the amount of air in fresh concrete separately, sampling errors also had an adverse effect on measurement accuracy. Other methods for measuring the moisture content of fresh concrete include those using neutron beams and those using salt water. However, when neutron beams are used, the equipment required for measurement is complicated and expensive, and salt water is also used. When used, there is a problem that the preparation is troublesome and it is difficult to discard the concrete mixed with the salt water after the measurement. As described above, it is difficult to perform simple and accurate measurement with the conventional method for measuring moisture in fresh concrete.
There was a lack of on-site implementation effectiveness. In order to solve the problems in the conventional technology, the present invention has improved a method and a device for measuring the moisture of fresh concrete, stabilizing the fresh concrete while suppressing the amount of air, and then increasing the unit of fresh concrete. The volume of the fresh concrete is measured simply and accurately by measuring the volume mass and obtaining the unit water volume of the fresh concrete from the measured unit volume mass using the proportional relationship between the predetermined unit volume mass and the unit water volume. It is an object of the present invention to provide a method and a device for measuring the moisture of fresh concrete which can be performed.

[0004]

In order to achieve the above object, the invention according to claim 1 is to stabilize the fresh concrete while suppressing the air amount, measure the unit volume mass of the fresh concrete, and measure the unit volume of the fresh concrete. The method is configured as a moisture measurement method for fresh concrete in which a unit water amount of fresh concrete is obtained from the measured unit volume mass by using a proportional relationship between a volume mass and a unit water amount. According to the first aspect of the invention, after the amount of air in the fresh concrete is stabilized while being suppressed,
The unit mass of fresh concrete is measured.
If the amount of air in the fresh concrete is stable, a suitable proportional relationship can be obtained between the unit volume mass and the unit water volume. From the mass, the unit water amount of fresh concrete is obtained. When measuring the unit water volume, basically only the unit volume mass is required, there are few parameters to be transferred, and the process is simple. According to the first aspect of the present invention, it is possible to provide a method for measuring the moisture of fresh concrete, which can easily and accurately measure the moisture of fresh concrete.

[0005] Further, the invention according to claim 2 is an air amount stabilizing means for stabilizing the fresh air while suppressing the air amount, and a unit of the fresh concrete in which the air amount is suppressed and stabilized by the air amount stabilizing means. The unit water mass of the fresh concrete is calculated from the unit volume mass measured by the unit volume mass measuring unit by using a unit volume mass measuring unit for measuring the volume mass and a proportional relationship between the unit volume mass and the unit water amount determined in advance. And a unit for calculating the amount of water in the fresh concrete. According to a third aspect of the invention, in the fresh concrete moisture measuring apparatus according to the second aspect, the unit volume mass measuring means is a gamma ray transmission type density meter. According to a fourth aspect of the present invention, in the fresh concrete moisture measuring apparatus according to the second or third aspect, the air amount stabilizing means pressurizes the fresh concrete filled in the closed container. That is the gist.
According to a fifth aspect of the present invention, in the fresh concrete moisture measuring apparatus according to any one of the second to fourth aspects, the air amount stabilizing means applies vibration to the fresh concrete filled in the container. The gist is to give. In the invention according to any one of claims 2 to 5, the amount of air in the fresh concrete is stabilized while being suppressed by the air amount stabilizing means, and is measured by a unit volume mass measuring means such as a transmission type gamma ray density meter. The unit mass of fresh concrete is measured. If the amount of air in the fresh concrete is stable, a favorable proportional relationship can be obtained between the unit volume mass and the unit water amount. This proportional relationship is predetermined and held in the unit water amount calculating means. The unit water amount of the fresh concrete is obtained from the unit volume mass measured by the unit volume product mass measuring unit using the proportional relationship by the unit water amount calculating unit. When measuring the unit water volume, basically only the unit volume mass is required. Since there are few parameters to be interposed, high measurement accuracy can be ensured, and the steps required for measurement are simple.
According to the invention as described in any one of the second to fifth aspects, it is possible to provide a fresh concrete moisture measuring device capable of simply and accurately measuring the moisture of fresh concrete. Moreover, in the fresh concrete moisture measuring device according to the third aspect, since a transmission type gamma ray density meter is used for measuring the unit volume mass, it is possible to easily measure a large number of samples.

[0006]

Embodiments of the present invention will be described below with reference to the accompanying drawings to provide an understanding of the present invention.
The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention. The moisture measuring device for fresh concrete according to the embodiment of the present invention is a suitable device for performing the moisture measuring method for fresh concrete according to the embodiment of the present invention,
As shown in FIG. 1, a pressure vessel (corresponding to air stabilizing means) 1 capable of pressurizing an air chamber 12 and a transmission type gamma ray density meter (unit volume) installed on the outer surface of the pressure vessel 1 A unit water amount calculation for obtaining a unit water amount of fresh concrete from the unit volume mass measured by the unit volume mass measuring unit, using a proportional relationship between the unit volume mass and the unit water amount determined in advance, 2) Means 3. In the device for measuring the moisture content of fresh concrete, the pressure vessel 1 includes a cylindrical vessel 11 for filling fresh concrete F, a lid 15 provided with an air chamber 12 and having a piston 13 for pressurization and a pressure gauge 14. . A flange is provided on the contact surface between the cylindrical container 11 and the lid 15, and when the lid 15 is closed, the inner chamber 16 of the cylindrical container 11 is sealed while being connected to the air chamber 12. . When measuring the moisture of the fresh concrete, first, the fresh concrete F is filled in the cylindrical container 11 while pushing it with a stick according to a method such as JIS or the like, and is poured so as to fill the cylindrical container 11 approximately.
At this time, the fresh concrete F is in the cylindrical container 1
You only need to satisfy 1 approximately, and there is no need to polish carefully.
Next, the open port of the cylindrical container 11 is closed by the lid 15, and air is injected into the air chamber 12 by moving the pressurizing piston 13 for air injection, and while watching the pressure gauge 14, for example, 98 to 490 kN / m ^2. Pressurized with appropriate pressure
Crush bubbles in fresh concrete F.

In this state, the transmission type gamma ray density meter 2 is operated to measure the density of the fresh concrete F.
When a transmission type gamma ray densitometer is used, measurement can be easily performed even when a large amount of sample is used. In addition, a stabilized scintillation detector method can be used to perform accurate measurement with very little drift. . Further, the shape of the container is not limited. The density measured by the transmission-type gamma-ray densitometer 2 is converted into a unit volume mass by a calculation device built in the transmission-type gamma-ray density meter 2, and then supplied to the unit water amount calculation means 3. As the unit water amount calculating means 3, a calculating device built in the transmission type gamma ray densitometer 2 can be used, but in this embodiment, a separate calculating device is prepared. A storage medium such as a ROM or a hard disk connectable to the arithmetic unit holds a table value of a proportional relationship between a predetermined unit volume mass and a unit water amount, or a coefficient for determining a proportional relationship, and stores the transmission type of the transmission type. When a unit volume mass is supplied from the gamma ray densitometer 2, a table value or a coefficient is read from the storage medium, and a unit water amount of fresh concrete is obtained from the unit volume mass. The proportional relationship between the unit volume mass and the unit water amount is a principle feature of the present invention. Generally, "coarse aggregate density" and "cement +
The "sand mixing density" is a close value. Even if the ratio of “coarse aggregate” and “cement + sand” is changed, water and solid content have a linear relationship because the density of solid content in the formulation is small as a whole. Also, when the coarse aggregate is removed and only mortar is used, the inclination changes, but the proportional relationship can be similarly determined. The method of identifying the proportional relationship can be roughly classified into the following three cases, and which one to use is arbitrary and may be determined as needed. (1) Determine the relationship based on the blending system and the blending row. (2) Determine the relationship when the amount of air is simply adjusted at a constant air volume in the specific blend. (3) In the mortar part where coarse aggregate is removed from the specific blend. Determining the relationship when simply adding or subtracting water with a constant air volume

A detailed description will be given using a combination list, taking as an example the relationship based on the combination system and the combination sequence in (1). Here, an example of the combination list is shown in FIG. The blending list in FIG. 2 shows the total blending of the blending system of the example plant with ordinary Portland cement, coarse aggregate size of 20 mm and air volume of 4.5%. Here, the compounding system is a collective term for the same compounding group in which three of cement used / coarse aggregate size / air volume are the same. A compound group that differs in any one of cement used / coarse aggregate size / air amount is another compound system. Also,
Mixing columns A to H, which further classify one compounding system, are generic names of compounding groups having the same compounding strength and the same compounding system. Mixing groups having different mixing strengths form different mixing columns. FIG. 3 is a graph plotting the unit water amount and the unit volume mass of fresh concrete for all the formulations in rows A to H based on the above-mentioned formulation list.
It is shown in FIG. In the graph of Fig. 3, a straight line (proportional relationship) determined using the least squares method for each plot
Is represented by the following equation (A1). y = -1.5084x + 2538.1845 (A1) Here, y is unit mass of fresh concrete (kg / m ³ ), and x is unit water (kg / m ³ ).
In addition, a straight line determined by using the least squares method for five combinations in column A of all plots is as shown in the following equation (A2). y = −1.4990x + 253.5952 (A2) Further, a straight line determined by using the least squares method with respect to five combinations in column H of all plots is as in the following equation (A3). y = -1.4592x + 2537.2969 (A3) The slopes of the straight lines (A1) to (A3) are almost the same,
The intercept of the straight line (A2) corresponding to the row A having the smallest blending strength is the smallest, and the intercept of the straight line (A3) corresponding to the H row having the largest blending strength is the largest. The intercept of the straight line (A1) corresponding to all the blends of this blending system is between them.

These proportional relationships may be determined for each blending system or blending row and stored in the storage medium so that the user can appropriately select them. Further, it is also possible to determine a proportional relationship with respect to a blend including a blend system other than this blend system, and the straight lines (A1), (A2),
Using (A3) and the like, it is also possible to determine the proportional relationship of one individual composition. In order to determine the proportional relationship of an individual composition, for example, as shown in FIG.
The intercept may be determined so that a straight line having the same slope as the above passes through the plot P4 of the composition. The straight line (proportional relationship) defined for the plot P4 is as shown in the following equation (A4). y = -1.5804 + 2528.200 (A4) In addition, unit water amount 158,166,172,180,192
At kg / m ³ , the plots are arranged in the direction of the vertical axis, which is consistent with the line according to the law of constant slump in the formulation, resulting in 8, 12, 15, 18, and 21 slumps, respectively. Further, as described in (2) above, in the specific blend (for example, blend A-3), when the water content is simply adjusted at a constant air amount (that is, when the solid content is constant), as described in (3), the specific blend ( For example, FIG. 5 shows graphs in which the mortar portion obtained by removing the coarse aggregate from the formulation A-3) is simply plotted with the case where the water content is simply adjusted with a constant air amount. FIG.
In the graph, the straight line corresponding to the above (2) is represented by the following equation (B). y = −1.6845x + 2563.6675 (B) Further, the straight line corresponding to the above (3) is represented by the following equation (C). y = −2.1392x + 2424.0931 (C) If these straight lines are used, the unit water amount can be uniquely determined from the unit volume mass of the fresh concrete.
FIG. 5 also shows the straight line (A2) for comparison. In FIG. 5 and the following FIG. 6, the unit water amount when the mortar is used alone is converted into the unit water amount when the coarse mortar is included and displayed.

Each of the straight lines (A2), (B),
Comparing (C) with (A2), (B),
The inclination becomes steep in the order of (C). That is, the water measurement becomes more accurate in this order. Each straight line (A2), (B),
Considering (C), that is, the features of the above cases (1), (2), and (3), in the case of the above (1), since the formulation is not specified as one, a versatile proportional relationship is obtained. It is suitable for observing trends such as when multiple blends are produced in a plant. The case (2) is desirable in that the accuracy of the unit water amount is improved. In the case of (3), it takes time and effort to separate the coarse aggregate, but the unit water amount can be measured with the highest accuracy. Next, (1),
The influence of the peripheral conditions on each straight line corresponding to (2) and (3) will be considered. Specifically, it is the influence of the unevenness of the coarse aggregate, the fluctuation of the air amount, and the fluctuation of the air amount in the mortar from which the coarse aggregate is removed, on the unit volume mass. FIG. 6 shows the influence of the unevenness of the coarse aggregate (I1), the change of the air amount (I2), and the change of the air amount in the mortar (I3) with respect to the example of FIG. As shown in FIG. 6, the influence of the unevenness of the coarse aggregate is small, and the influence of the fluctuation of the air amount is the largest. For this reason, it is necessary to measure the unit volume mass after stabilizing fresh concrete while suppressing the air volume.
In addition, if the fresh concrete is stabilized while suppressing the amount of air, the sampling error can be reduced.
In addition, since the influence of the unevenness of the coarse aggregate is small but cannot be eliminated, it is necessary to pay close attention to the separation of the coarse aggregate when sampling the fresh concrete containing the coarse aggregate. Especially when precision is required, it is preferable to remove coarse aggregate. As described above, in the method and the apparatus for measuring the moisture of fresh concrete according to the embodiment of the present invention, after stabilizing the amount of air in the fresh concrete while suppressing the amount of air, the unit mass of the fresh concrete is measured and predetermined. Since the unit water amount of fresh concrete is determined from the unit volume mass using the proportional relationship between the unit volume mass and the unit water amount, the water content of the fresh concrete can be measured simply and accurately.

[0011]

EXAMPLE In the above embodiment, if fresh concrete is capable of crushing air bubbles by applying a pressure of about 98 kN / m ^2, it is used for an air volume test without preparing a separate pressure vessel. A container of the air chamber pressure method may be used as it is, and a transmission type gamma ray densitometer may be attached to the container or disposed so as to sandwich it. In this way, the normal air volume test and moisture measurement can be performed simultaneously. In the above embodiment, the pressure vessel 1 as shown in FIG. 1 is used to stabilize the fresh concrete while suppressing the air volume. Instead, for example, a pressure vessel as shown in FIG. It is also possible to use 71. As shown in FIG. 7, the pressure vessel 71 is formed into a bag shape by attaching a blind lid 73 to one end of a cylindrical container 72 having flanges at both ends and attaching two disc-shaped towable membranes to the other end. It is provided with a pressurized towable membrane 74 provided with an inlet, and a lid 75 having a hole through which an oil inlet is passed. When using the pressure vessel, for example,
The fresh mortar F ′ obtained by removing the coarse aggregate from the fresh concrete in row-3 is put into the cylindrical container 72, and if necessary, is pierced with a piercing rod to be filled firmly.
At this time, the fresh mortar F 'is
It only needs to be approximately 2 and does not need to be carefully polished.
Next, after closing the open end of the cylindrical container 72 using the lid 75, the hose 7 is connected to the hydraulic pump 76 with a pressure gauge.
Oil is sent between the bag-shaped towable membranes 74 via 7 to increase the volume occupied by the bag-shaped towable membrane 74. Thereby, the fresh mortar F 'in the cylindrical container is pressurized. The pressure at this time is 98-4 per square meter.
It is about 90 kN. By this pressurization, bubbles in the fresh mortar F 'are crushed. In this state, the transmission type gamma ray densitometer 20 is operated, and the fresh mortar F '
Measure the density of This density is converted into a unit volume mass by a calculation device built in the transmission type gamma ray density meter 2, and then supplied to the unit water amount calculation means 3, where the unit water amount is calculated in the same manner as in the embodiment. Can be When fresh mortar is used, it takes time and effort to separate coarse aggregate, but as described above, the accuracy of the required unit water volume can be improved.

The fresh mortar can be directly pressurized by a plunger or the like. In this case, although simple, water may escape due to wear of the cylinder. As described above, it is preferable to pressurize the gas using the towable film to crush the bubbles, so that accurate measurement can be performed without leaking water. In addition, in the above-described embodiment and examples, the pressure vessel was filled with fresh concrete or fresh mortar, and the unit water amount was measured. However, as shown in FIG. 8, the pressure vessel 80 was connected to a fresh concrete pressure pump. It is also possible to mount a transmission type gamma ray density meter 2 to measure the unit water volume. In this case, first, for example, the pumping of fresh concrete of the composition A row-3 is started from the ready-mixed concrete pumping pump. The fresh concrete, which is a Bingham body, exists in a pressurized state not only during movement in the pipe 80 but also during stoppage. For example, in the above-mentioned pressurized state of about 98 to 490 kN, the bubbles in the fresh concrete are crushed. In this pressurized state, as in the other examples, the transmission type gamma ray densitometer 2 is operated to determine the unit volume mass from the density, and then determine the unit water amount from the proportional relationship. A pressure gauge may be attached to the pressure feed pipe 80 to check the pressurized state. In the case of measurement using a pressure pump, it is preferable to take a long moving average since the volume of the measurement object increases and the unevenness of the coarse aggregate is naturally averaged and virtually eliminated. Also, the unit water amount can be obtained by using a scale 91 and a vibration device 92 as shown in FIG. 9 without using a transmission type gamma ray density meter. By applying vibration to the fresh concrete F by the vibrating device 92, bubbles in the fresh concrete are eliminated. First, the cylindrical container 93 is weighed on a scale 91. Then, the cylindrical container 9
For example, fresh concrete F having a composition A row-3 and coarse aggregate size of 20 mm was added to the cylindrical container 93 having a volume of about 2
About / 3. Next, the cylindrical container 93 and the fresh concrete F are weighed by a scale, and then the cylindrical container 93 into which the fresh concrete F has been put is placed on the vibration device 92. Then, when the cylindrical container 93 is vibrated by the vibrating device 92 for several tens of seconds to several minutes, the air amount is reduced, and regardless of the slump,
For example, it converges cleanly to a certain amount of about 1.3%. When the amount of air converges, water is gently poured into the remaining portion of the cylindrical container 93 to fill the cylindrical container 93. At this time, the amount of water required for filling was measured by a scale 91, and the volume of the filled water was subtracted from the volume of the cylindrical container 93 to obtain the volume of the fresh concrete F whose vibration reduced the amount of air. Then, the unit mass at the planned air amount is calculated from the volume of the fresh concrete after the vibration, the weight of the fresh concrete, and the converged air amount.
The unit water amount of the fresh concrete is obtained from the unit volume mass obtained in this manner, using the proportional relationship between the unit volume mass and the unit water amount in the same manner as in the embodiment and the examples.

In this example, the fresh concrete is vibrated by placing the cylindrical container 93 on the vibrating device 92. However, for example, vibration is applied by using ultrasonic waves or the cylindrical container 93 is vibrated. Vibration may be applied to the fresh concrete by, for example, vibrating while rotating, or inserting a vibrator into the cylindrical container 93. When a vibrator is inserted inside, the amount of the sample adhering to the vibrator can be corrected by wiping it with a rag and weighing it with a weighing scale. When inserting the vibrating part inside the container, set the vibrating rod etc. in the container in advance or use a separate type vibrating rod etc. to supply energy by electromagnetic force etc. and vibrate. , Including a vibrating rod, etc., can be measured with a scale, thereby increasing the accuracy and shortening the time required for the entire measurement process. In addition, in the above-mentioned example, the volume of fresh concrete after vibration was measured using a scale with water added thereto. However, the volume may be measured using a graduated cylinder or the like. Alternatively, the volume of the fresh concrete may be obtained directly from the scale. In this case, the use of a container with a smaller diameter at the top enables the water to be injected more accurately than a cylindrical container with the same diameter in the vertical direction, and reduces the volume of fresh concrete after vibration. This is preferable because it can be determined accurately. Also,
When the air amount is converged by vibration as in the above example, the proportional relationship may be slightly different for each plant due to the relationship between the cement used, the aggregate, the AE agent, and other additives. For example, an air amount of about 1.3% may be determined for each plant or material used, and once calculated based on the air amount, the unit water amount may be measured. Further, when it is necessary to converge the air amount to a smaller value, an antifoaming agent or a defoaming agent may be added to the fresh concrete. Further, in the above-described embodiment, the measurement is performed by filling the container for fresh water measurement with the fresh concrete, but it is also possible to measure the unit water amount of the fresh concrete filled in the air amount test instrument.

The weight of the fresh concrete filled in a predetermined amount into the tube of the test device is measured by a scale, and the air amount is measured by a predetermined procedure such as JIS, and the volume, weight, and air amount of the fresh concrete are measured. A unit volume mass at a predetermined air amount is calculated to measure a unit moisture amount. The air volume is preferably measured by an air chamber pressure method. The reason is that the measurement can be performed in a short time, and the method can be combined with the method of the above-described embodiment by changing the pressing force in addition to the standard measurement by the same method. The method of weighing is not particularly limited, whether it is weighed including the lid of the air amount measuring device of the air amount test device or the container portion alone. The means for measuring the unit mass is not limited to any of a method using a balance and a container, a method using a gamma ray densitometer, and a method for measuring other masses. The load cell is preferably of a load cell type because of its high performance and small size. If the air volume is stabilized by suppressing the air volume by pressurization or vibration, the difference in the unit volume / mass is more apparent than when the unit water volume is measured as it is, so that accurate measurement can be achieved. For example, the densities of the blends A-1 and A-5 are A-1 (2.28753) and A-5 (2.2426
In 2), the difference is 0.04491, whereas when the air volume is 0%, the difference is A-1 (2.39531) and A-5 (2.34830).
0.04701 and the difference in mass per unit volume increases, making measurement easier. When mortar is used, air content is 4.5% A-
1 (2.05657) and A-5 (2.04728), the difference of which is 0.00929, whereas A-1 (2.21531) and A-5 (2.190
In (12), the difference is 0.02519, and the difference in mass per unit volume is even larger, making measurement easier. Further, the material of the container for filling the fresh concrete is not limited to any material such as iron, aluminum, vinyl chloride, and PP.
Further, the shape of the container is not limited to a cylinder or a square tube, but may be any shape. The tube may be long and used as a tube, or a cylindrical container having one end or both ends closed may be used, and the shape of the tube may be enlarged or reduced in diameter, and is not limited. Further, it may be used as a curved tube or a curved tube. The arrangement of the gamma ray densitometer and the container may be measured by directly attaching the gamma ray density meter to the container, or the gamma ray density meter and the container may be arranged separately. Furthermore, it does not matter which way the gamma ray beam is passed in the length direction of the container or the beam is passed in the cross-sectional direction of the container.

[0015]

As described above, according to the first aspect of the present invention, it is possible to provide a method for measuring the moisture of fresh concrete, which can easily and accurately measure the moisture of fresh concrete. According to the invention described in any one of claims 2 to 5,
A fresh concrete moisture measuring device capable of simply and accurately measuring the moisture of fresh concrete can be provided. Moreover, in the fresh concrete moisture measuring device according to the third aspect, since a transmission type gamma ray density meter is used for measuring the unit volume mass, it is possible to easily measure a large number of samples.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a schematic configuration of a moisture measuring device for fresh concrete according to an embodiment of the present invention.

FIG. 2 is a view showing a mixing list of fresh concrete.

FIG. 3 is a diagram showing a proportional relationship between a unit volume mass and a unit water amount of fresh concrete determined based on a mixing system and a mixing row.

FIG. 4 is a view showing a proportional relationship between a unit volume mass and a unit water amount determined for a single blend.

FIG. 5 is a diagram for comparing how to determine a proportional relationship between a unit volume mass and a unit water amount.

FIG. 6 is a view showing the influence of a change in air amount and a bias of coarse aggregate on the proportional relationship.

FIG. 7 is a diagram showing a schematic configuration of a moisture measuring device for fresh concrete according to an embodiment of the present invention.

FIG. 8 is a view for explaining another embodiment of the fresh concrete moisture measuring device.

FIG. 9 is a view for explaining still another embodiment of the moisture measuring device for fresh concrete.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Pressure vessel 2 ... Gamma-ray density meter of transmission type 3 ... Unit water amount calculation means

Claims (5)

[Claims] 1. stabilize the fresh concrete while suppressing the air volume, measure the unit volume mass of the fresh concrete, and use the proportional relationship between the predetermined unit volume mass and the unit water volume to calculate the unit volume mass from the measured unit volume mass. A method for measuring the water content of fresh concrete, which determines the unit water content of fresh concrete. 2. An air amount stabilizing means for stabilizing a fresh concrete while suppressing an air amount, and a unit for measuring a unit volume mass of the fresh concrete in which an air amount is suppressed and stabilized by said air amount stabilizing means. The volume mass measuring means and the unit water amount calculating means for obtaining the unit water amount of fresh concrete from the unit volume mass measured by the unit volume mass measuring means using a predetermined proportional relationship between the unit volume mass and the unit water amount. Moisture measuring device for fresh concrete. 3. The fresh concrete moisture measuring device according to claim 2, wherein the unit volume mass measuring means is a gamma ray transmission type density meter. 4. The fresh concrete moisture measuring device according to claim 2, wherein the air amount stabilizing means presses the fresh concrete filled in the closed container. 5. The fresh concrete moisture measuring device according to claim 2, wherein the air amount stabilizing means applies vibration to the fresh concrete filled in the container.