JP2003114189A - Method and instrument for measuring water-cement ratio - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and instrument for measuring water-cement ratio by which the water-cement ratio of an unset cement-based material can be measured quickly and accurately at a construction site. SOLUTION: In this method, a filtrate is extracted from fresh concrete which is the unset cement-based material and the concentration of chromium contained in the infiltrate is measured at the construction site (step 101). In addition, the correlation between the concentration of the chromium contained in the filtrate and the water-cement ratio of the fresh concrete is also found (step 102). Then the water-cement ratio is evaluated by applying the concentration of the chromium to the found correlation (step 103).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for measuring a water-cement ratio of a cement-based material that has not yet solidified, mainly at a construction site, and a measuring apparatus used therefor.

[0002]

2. Description of the Related Art Regarding cement-based materials such as concrete, mortar, and cement paste, it goes without saying that their water-cement ratio has a great influence on compressive strength and durability. When performing construction, it is strongly desired in quality control to measure and control the water-cement ratio of the cement-based material that has not yet solidified.

On the other hand, the cement-based material is usually manufactured in a batcher plant and conveyed to the site by a mixer truck. For example, cement can be managed in the plant within an error range of about 1%. On the other hand, regarding the amount of water, it is often difficult to accurately grasp the amount of surface water of the fine aggregate, and therefore, the value is often not the value as indicated by the formulation at the time of shipment.

Therefore, regarding the water-cement ratio, it is necessary to confirm the water-cement ratio on site immediately before using the cement-based material, that is, when receiving the cement-based material that has not solidified yet from the mixer truck. Methods such as the heat of solution method, washing test method, centrifugal dehydration method, back titration method, and hydrometer method have been developed.

[0005]

However, each of these methods requires several tens of minutes for measurement and lacks promptness, and the apparatus used for measurement is large and laborious for testing. The problem was that the machine was expensive and expensive.

Further, since the analytical devices necessary for measuring the amount of water according to the back titration method are made for the laboratory, it is not possible to bring these devices into the field, and the accuracy is high in the field. There was also a problem that it was difficult to measure the water-cement ratio.

The present invention has been made in consideration of the above-mentioned circumstances, and a method for measuring a water-cement ratio capable of quickly and accurately measuring a water-cement ratio of a cement-based material that does not solidify on site and An object is to provide a measuring device to be used.

[0008]

In order to achieve the above object, the method for measuring the water-cement ratio according to the present invention is characterized in that, as described in claim 1, the filtrate is extracted from a cement-based material which is not yet set. While measuring the concentration of chromium contained in the filtrate, the correlation between the chromium concentration and the water-cement ratio is obtained in advance, and the cement system that has not yet solidified by applying the measured concentration of chromium to the correlation This is to evaluate the water cement ratio of the material.

The method for measuring the water-cement ratio according to the present invention comprises irradiating the filtrate with light having a wavelength of 360 to 400 nm,
The absorbance at that time is used to measure the chromium concentration.

The water-cement ratio measuring method according to the present invention obtains the correlation between the chromium concentration and the water-cement ratio for each type of cement contained in the cement-based material.

The water-cement ratio measuring device according to the present invention is, as described in claim 4, a filtrate extracting device for extracting a filtrate from a cement-based material which is not yet solidified, and an absorbance of chromium contained in the filtrate. Measuring device, a storage device in which the correlation data of the previously determined chromium concentration and water cement ratio is stored, and a computing device that performs a predetermined computation, and the computing device converts the absorbance. Using the obtained concentration of chromium, the water-cement ratio of the cement material that has not solidified is calculated from the correlation data stored in the storage device.

In the water-cement ratio measuring device according to the present invention, the measuring device is used in the filtrate so as to have a wavelength of 360 to 400 nm.
The light is irradiated and the absorbance at that time is measured.

Further, in the water cement ratio measuring device according to the present invention, the storage device obtains and stores the correlation data between the chromium concentration and the water cement ratio for each type of cement contained in the water cement-based material. It is configured to do.

In the method for measuring the water-cement ratio according to the present invention, first, the filtrate is extracted from the cement-based material which is not yet solidified and the chromium concentration contained in the filtrate is measured. Is obtained in advance, and then the water-cement ratio of the cement-based material that is not yet solidified is measured by applying the measured chromium concentration to the correlation.

In this way, by utilizing the correlation between the chromium concentration and the water-cement ratio, which has been obtained in advance,
It is possible to quickly obtain the water-cement ratio simply by measuring the chromium concentration without directly measuring the water-cement ratio on site.

Further, since it is sufficient to have a device for extracting the filtrate from the cement-based material and a device for measuring the chromium concentration, there is no need for an expensive and large measuring device or analysis device used in a laboratory, Can be easily measured in.

The method of obtaining the correlation between the chromium concentration and the water-cement ratio is arbitrary. For example, fresh concrete is produced so that the water-cement ratio has various values, and the chromium concentration for each of the fresh concretes is changed. After the measurement, the correlation can be obtained from the measured value as an approximate expression or a regression expression by using, for example, the least squares method. In such a case, accurate measurement should be performed during compounding so that the water-cement ratio can be obtained with sufficient accuracy.

[0018] When determining the correlation between the chromium concentration and the water-cement ratio, how to measure the chromium concentration is arbitrary. For example, a method for quantifying hexavalent chromium using diphenylcarbazide described in JIS. May be used.

When such a method is used, first, the filtrate containing hexavalent chromium is reacted with diphenylcarbazide to develop a reddish purple color, and then the filtrate is irradiated with light having a wavelength of about 540 nm. The absorbance at that time may be measured, and then the absorbance may be converted to the chromium concentration using a calibration curve showing the relationship between the chromium concentration and the absorbance.

Here, instead of the above-mentioned known method, the filtrate may be irradiated with light having a wavelength of 360 to 400 nm, and the chromium concentration may be measured from the absorbance at that time.

In such a case, the chromium concentration of the filtrate can be directly measured without reacting the filtrate with a specific substance such as diphenylcarbazide, and the reaction process with the specific substance can be omitted. As much as possible, it becomes possible to easily and quickly measure the chromium concentration.

Since the chromium concentration is considered to be influenced by the type of cement, it is desirable to determine the correlation between the chromium concentration and the water cement ratio for each type of cement contained in the cement material.

In order to measure the water-cement ratio using the water-cement ratio measuring device according to the present invention, first, the filtrate is extracted from the cement-based material which is not yet solidified by the filtrate extracting device and contained in the filtrate. The absorbance of chromium is measured by a measuring device, and the correlation between the chromium concentration and the water-cement ratio is obtained in advance and the correlation data is stored in the storage device.

Next, by using the chromium concentration obtained by converting the above-mentioned absorbance, the water-cement ratio of the cement material which has not yet solidified is calculated by the arithmetic unit from the correlation data stored in the storage device. Calculate

In this way, by utilizing the correlation between the chromium concentration and the water-cement ratio, which has been obtained in advance,
It is possible to quickly obtain the water-cement ratio simply by measuring the chromium concentration on site.

Further, a filtrate extraction device for extracting the filtrate from the cement-based material, a measuring device for measuring the absorbance of chromium, a memory device, and a computing device are sufficient, so an expensive and large-scale measurement such as used in a laboratory is required. Measurements can be easily performed on site without the need for a device or analysis device.

Further, since the arithmetic unit automatically calculates the water-cement ratio from the chromium concentration, the water-cement ratio can be measured more quickly and accurately.

The filtrate extraction device may be constructed in any manner as long as it can extract the filtrate from the cement-based material that has not solidified yet, but it is desirable that the device be capable of extracting in the shortest possible time. For example, a vacuum suction filter for extracting using a vacuum pump may be used.

The measuring device may be constructed in any manner as long as it can measure the absorbance of chromium contained in the filtrate, but a portable device is preferable in consideration of use at the site. For example, it is conceivable to use a portable colorimeter that measures the absorbance of a solution at a specific wavelength.

If the storage device stores the correlation data between the chromium concentration and the water-cement ratio obtained in advance, the storage device may be constructed in any manner, and the arithmetic device may also be used in the filtrate. If it is configured to calculate the water-cement ratio of a cementitious material that has not yet solidified by applying the concentration of chromium contained to the correlation data stored in the storage device, how is it configured? It is conceivable that these arithmetic device and storage device may be configured by computer equipment that can be brought into the field, such as a notebook computer and a personal digital assistant (PDA).

The method of obtaining the correlation data between the chromium concentration and the water-cement ratio stored in the storage device is arbitrary,
For example, it is possible to obtain the correlation data as an approximate expression or a regression expression by measuring the chromium concentrations for various water-cement ratios and then using the least squares method from the measured values.

How to measure the absorbance of chromium using a measuring device is arbitrary, and for example, a method for quantifying hexavalent chromium using diphenylcarbazide described in JIS may be used.

Here, instead of the above-mentioned known method, the measuring device may be configured to irradiate the filtrate with light having a wavelength of 360 to 400 nm and measure the absorbance at that time.

In such a case, the concentration of chromium contained in the filtrate can be directly measured without reacting the hexavalent chromium contained in the filtrate with the specific substance such as diphenylcarbazide. Since the reaction process with and can be omitted, the chromium concentration can be measured easily and quickly.

Since the chromium concentration is considered to be influenced by the type of cement, the correlation data between the chromium concentration and the water-cement ratio should be obtained and stored for each type of cement contained in the cement-based material. It is desirable to configure the storage device.

The cement-based material according to the present invention may be any material as long as it is a material containing cement and water, and in addition to fresh concrete, materials such as mortar and cement paste can be considered.

[0037]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a method for measuring a water cement ratio and a measuring apparatus used therefor according to the present invention will be described below with reference to the accompanying drawings. It should be noted that parts and the like which are substantially the same as those of the conventional technique are designated by the same reference numerals and the description thereof will be omitted.

(First Embodiment)

FIG. 1 is a flow chart showing a method for measuring a water cement ratio according to this embodiment. As shown in the figure, the method for measuring the water-cement ratio according to the present embodiment, first, extracts the filtrate from fresh concrete, which is a cement-based material that does not solidify in the field, to determine the concentration of chromium contained in the filtrate. Measure (Step 10
1).

Here, in order to extract the filtrate from the fresh concrete, for example, a vacuum suction filter equipped with a vacuum pump may be used. Further, in measuring the chromium concentration, the extracted filtrate is irradiated with light having a wavelength of 360 to 400 nm, preferably 380 nm to measure the absorbance of hexavalent chromium contained in the filtrate, and then the absorbance is predetermined. It may be converted to chromium concentration using the calibration curve of. The absorbance of hexavalent chromium can be measured using, for example, a colorimeter.

On the other hand, the correlation between the chromium concentration and the water cement ratio is obtained in advance (step 102). Note that it is desirable to accurately obtain such a correlation in a laboratory or the like even if it takes time, since it is not necessary to obtain the correlation once it is obtained.

Specifically, first, fresh concrete is produced so that the water-cement ratio becomes various values, and the concentrations of chromium contained in these fresh concretes are measured, respectively, and then, from the measured values. For example, the least-squares method is used to obtain the correlation as an approximate expression or a regression expression. In such a case, accurate measurement is performed during compounding so that the water-cement ratio can be obtained with sufficient accuracy.

In mixing the materials, in order to prevent fluctuations in the amount of water due to the surface water of the aggregate, especially the fine aggregate, the fine aggregate is once moistened and then dried with a dryer such as a dryer. It is desirable to confirm the change in the wet state and repeat this operation until the fine aggregate reaches the surface dry state.

Regarding the measurement of the chromium concentration when the correlation between the water cement ratio and the chromium concentration is obtained in advance, for example,
It is conceivable to use the method for quantifying hexavalent chromium using diphenylcarbazide described in JIS. When such a method is used, first, a filtrate containing hexavalent chromium is reacted with diphenylcarbazide to develop a reddish purple color, and then the filtrate is irradiated with light having a wavelength of about 540 nm. The absorbance is measured, and then the absorbance is converted to the chromium concentration using a calibration curve showing the relationship between the chromium concentration and the absorbance.

Further, since the chromium concentration is considered to be influenced by the type of cement, the correlation between the chromium concentration and the water cement ratio is determined for each type of cement contained in fresh concrete.

FIG. 2 is an example of a graph showing the correlation between the water cement ratio and the chromium concentration. In such a case, the following regression equation was obtained. W / C = 1.633-0.188Cr + 0.007Cr ² W / C; Water cement ratio Cr; Chromium concentration

Next, the water-cement ratio of the fresh concrete is evaluated by applying the concentration of chromium contained in the filtrate of the fresh concrete to the above-mentioned correlation (step 103). In addition, when applying the correlation, it is applied to the correlation corresponding to the type of cement contained in fresh concrete.

Specifically, for example, the correlation between the chromium concentration and the water-cement ratio is obtained as a graph or a correlation formula from an experiment conducted in advance, and when the water-cement ratio is measured at the site, it is obtained at the site. Apply the chromium concentration to the graphed correlation to visually read the water-cement ratio corresponding to the chromium concentration, or substitute the chromium concentration obtained at the site into the correlation formula obtained in advance by experiment to determine the water-cement ratio. It is possible to calculate or use a computer to calculate.

As described above, according to the method for measuring the water-cement ratio according to the present embodiment, by utilizing the correlation between the chromium concentration and the water-cement ratio which is obtained in advance,
It is possible to quickly measure the water-cement ratio by simply determining the concentration of chromium contained in fresh concrete at the site, and it is possible to measure the water-cement ratio in minutes, which conventionally took several tens of minutes.

Further, since it is sufficient to have a device for extracting the filtrate from fresh concrete and a device for measuring the absorbance of chromium contained in the filtrate, an expensive and large measuring device or analyzer for use in a laboratory is required. Even if you do not, you can easily measure in the field.

Further, according to the method for measuring the water-cement ratio according to this embodiment, the filtrate is irradiated with light having a wavelength of 360 to 400 nm, and the chromium concentration is measured from the absorbance at that time. It is possible to directly measure the chromium concentration of the filtrate without reacting with a specific substance such as diphenylcarbazide, and the reaction process with the specific substance can be omitted, so that the chromium concentration can be easily measured. It can be done quickly.

Further, according to the method for measuring the water-cement ratio according to the present embodiment, the correlation between the chromium concentration and the water-cement ratio is obtained for each kind of cement contained in fresh concrete. It is possible to evaluate the water-cement ratio from the chromium concentration in consideration of the influence of the above, and it is possible to accurately measure the water-cement ratio.

Further, according to the method for measuring the water-cement ratio according to this embodiment, the absorbance of hexavalent chromium contained in the filtrate of fresh concrete is measured on-site, and this is converted into the chromium concentration using the calibration curve. , The correlation between the chromium concentration and the water-cement ratio is obtained in advance in a laboratory,
Since the water cement was measured by applying the above-mentioned chromium concentration to the correlation, the water-cement ratio can be determined by measuring or creating the absorbance measurement, the calibration curve and the correlation with sufficient accuracy. It is possible to measure with desired accuracy.

Further, according to the method for measuring the water-cement ratio according to the present embodiment, the water-cement ratio can be measured by a simple operation without requiring skilled skill.

In the present embodiment, the filtrate is directly irradiated with light in the field, and the chromium concentration is measured from the absorbance at that time. However, the method for measuring the chromium concentration is not limited to this. For example, JIS Chromium contained in the filtrate is reacted with a specific substance in advance, for example, by using the method for determining hexavalent chromium using diphenylcarbazide described in 1), and then the reaction product is irradiated with light of a wavelength suitable for the reaction product. Alternatively, the absorbance may be calculated.

Further, in the present embodiment, the correlation between the chromium concentration and the water-cement ratio is obtained for each type of cement contained in fresh concrete, but when only a specific cement is used, the type of cement The correlation does not have to be calculated for each.

Further, in the present embodiment, the present invention is applied when measuring the water-cement ratio of fresh concrete, but what kind of cement-based material is a material containing cement and water? It is optional and it is conceivable to apply the present invention to materials such as mortar and cement paste.

(Second Embodiment)

Next, an embodiment of the water cement ratio measuring device according to the second embodiment will be described with reference to the accompanying drawings. It should be noted that parts and the like which are substantially the same as those of the conventional technology and the first embodiment are designated by the same reference numerals and the description thereof will be omitted.

FIG. 3 is a block diagram showing a water cement ratio measuring device according to this embodiment. As shown in the figure,
The water-cement ratio measuring device 1 according to the present embodiment is a vacuum suction filter 2 which is a filtrate extracting device for extracting a filtrate from fresh concrete as a cement-based material which is not yet hardened, and the absorbance of hexavalent chromium contained in the filtrate. Colorimeter 3 which is a measuring device for measuring the water content, and a storage device 4 in which correlation data between the concentration of hexavalent chromium and the water cement ratio is stored in advance.
And an arithmetic unit 5 for performing a predetermined arithmetic operation.

The vacuum suction filter 2 is, as shown in FIG. 4, a container 15 into which fresh concrete 12 is put.
A filter paper 13 laid so as to vertically separate the space in the container, a filtrate storage pipe 16 airtightly connected to the lower end opening of the container 15, and a vacuum pump 11 connected to the filtrate storage pipe. The fresh concrete 12 is made by utilizing the difference in atmospheric pressure generated by the suction using the vacuum pump 11.
Thus, the filtrate 14 can be extracted through the filter paper 13 in a short time.

The colorimeter 3 may be appropriately selected from known portable colorimeters capable of measuring the absorbance of a solution at a specific wavelength, but in the present embodiment, the filtrate 14 has a wavelength of 360 to 400 nm. , Preferably wavelength 380nm
It is configured so that it can be irradiated with the light and the absorbance at that time can be measured.

The storage device 4 stores the correlation data between the chromium concentration and the water-cement ratio as described above. However, once such correlation data is obtained, it is not necessary to obtain it thereafter. Even if it takes time, it is desirable to obtain it accurately in the laboratory.

Specifically, first, water, cement and aggregate are accurately mixed to obtain a predetermined water-cement ratio to prepare concrete, and the chromium concentration at the predetermined water-cement ratio is measured. From these experimental results, the regression equation showing the correlation between the water cement ratio and the chromium concentration is obtained by using the least squares method.

In mixing the materials, in order to prevent fluctuations in the amount of water due to the surface water of the aggregate, particularly the fine aggregate, the fine aggregate is once in a wet state and then dried in a drier to obtain the wet state. It is desirable to confirm the change in the above condition and repeat this work until the fine aggregate reaches the surface dry state.

In measuring the chromium concentration when preparing the relative relationship data, it is conceivable to use, for example, the method for quantifying hexavalent chromium using diphenylcarbazide described in JIS. When such a method is used, first, a filtrate containing hexavalent chromium is reacted with diphenylcarbazide to develop a reddish purple color, and then the filtrate is irradiated with light having a wavelength of about 540 nm. The absorbance may be measured, and then the absorbance may be converted into the chromium concentration using a calibration curve showing the relationship between the chromium concentration and the absorbance.

Further, since it is considered that the chromium concentration is influenced by the type of cement, the correlation data between the chromium concentration and the water cement ratio is obtained for each type of cement contained in the fresh concrete 12, and Storage of correlation data for each type of cement 4
To memorize. The correlation data may be stored in the storage device 4 by programming the regression equation of FIG. 2 shown in the first embodiment.

The arithmetic unit 5 applies the concentration of chromium obtained by converting the absorbance measured by the colorimeter 3 to the correlation data stored in the storage unit 4 to apply the water cement of the fresh concrete 12. It is configured to calculate the ratio.

The arithmetic unit 5 and the storage unit 4 are
It is configured as a computer device that can be brought to the site, for example, a notebook computer 7, and the display 6 of the notebook computer can display the water-cement ratio calculated by the computing device 5.

Water cement ratio measuring apparatus 1 according to the present embodiment
To measure the water-cement ratio on site using
Using vacuum suction filter 2, fresh concrete 12
The filtrate 14 is extracted from

Next, the absorbance of hexavalent chromium contained in the filtrate is measured by the colorimeter 3. Here, in measuring the chromium concentration, the filtrate 14 is irradiated with light having a wavelength of 360 to 400 nm, preferably 380 nm.

Next, the measured absorbance is converted into chromium concentration by a calibration curve, and the chromium concentration is applied to the correlation data obtained in advance as described above to determine the water-cement ratio of the fresh concrete 12. evaluate.

Specifically, the converted chromium concentration is transferred to the arithmetic unit 5 or input via a keyboard or the like, and then the correlation data stored in the storage unit 4 is loaded into the arithmetic unit 5, After that, the water-cement ratio of fresh concrete is calculated by the calculation device 5 from the input chromium concentration and the loaded regression equation. The type of cement may be appropriately input to the arithmetic unit 5 via a keyboard or the like. Next, the calculated water-cement ratio is displayed on the display 6.

As described above, according to the water-cement ratio measuring device 1 of the present embodiment, by utilizing the correlation data between the chromium concentration and the water-cement ratio which have been obtained in advance, the chromium concentration at the site can be improved. It becomes possible to quickly obtain the water-cement ratio simply by measuring, and it is possible to measure the water-cement ratio in minutes, which conventionally took several tens of minutes.

Further, since a vacuum suction filter 2 for extracting the filtrate 14 from the fresh concrete 12, a colorimeter 3 for measuring the absorbance and a notebook computer 7 are sufficient, they are expensive and large-sized as used in a laboratory. Measurement can be easily performed on-site without the need for a measuring device or an analyzing device.

Further, according to the water-cement ratio measuring device 1 of the present invention, the calculation of the water-cement ratio from the chromium concentration is automatically performed by the arithmetic device 5, so that the water-cement ratio can be measured more quickly and accurately. It becomes possible to do.

Further, according to the water-cement ratio measuring device 1 of the present embodiment, the absorbance of hexavalent chromium contained in the filtrate of fresh concrete is measured on the spot by the colorimeter 3, while the chromium concentration and the water cement are measured. Since the correlation data with the ratio is obtained in advance in a laboratory or the like, water cement is measured by applying the chromium concentration converted using the calibration curve from the above-described absorbance to the correlation data, By measuring or creating the absorbance measurement, the calibration curve and the correlation data with sufficient accuracy, the water-cement ratio can be measured with desired accuracy.

Further, according to the water-cement ratio measuring device 1 of the present embodiment, the water-cement ratio can be measured by a simple operation without requiring skilled skill.

In addition, according to the water-cement ratio measuring apparatus 1 of the present embodiment, the filtrate 14 is irradiated with light having a wavelength of 360 to 400 nm, and the chromium concentration is determined from the absorbance at that time. For example, it becomes possible to directly measure the chromium concentration of the filtrate without reacting with a specific substance such as diphenylcarbazide, and the reaction process with such a specific substance can be omitted, so that the chromium concentration can be easily measured. And it can be done quickly.

Further, according to the water-cement ratio measuring device 1 of the present embodiment, the correlation data between the chromium concentration and the water-cement ratio is obtained for each type of cement contained in the fresh concrete 12. It becomes possible to evaluate the water-cement ratio from the chromium concentration in consideration of the effect of the type, and it is possible to accurately measure the water-cement ratio.

In this embodiment, the filtrate 14
The chromium concentration was determined by directly irradiating the sample with light at that time, but the method for measuring the chromium concentration is not limited to this. For example, a hexavalent compound using diphenylcarbazide described in JIS can be used. The hexavalent chromium contained in the filtrate 14 may be reacted with a specific substance in advance, for example, by using a method for determining chromium, and then the absorbance may be determined by irradiating the reaction product with light of a wavelength suitable for the reaction product. .

Further, in the present embodiment, the correlation data between the chromium concentration and the water-cement ratio is obtained for each type of cement contained in the fresh concrete 12. However, when only a specific cement is used, the cement is used. It is not necessary to obtain the correlation or the correlation data for each type.

Further, in the present embodiment, the absorbance measured by the colorimeter 3 is converted into the concentration of hexavalent chromium using the calibration curve, and this is input to the arithmetic unit 5, but instead of this, Then, the storage device 4 is preliminarily stored with data relating to the calibration curve, and the absorbance measured by the colorimeter 3 is configured to be inputtable to the computing device 5, and the absorbance is stored in the storage device 4. The calculation device 5 may convert the chromium concentration into the chromium concentration by using the above data.

According to this structure, the conversion from the absorbance to the chromium concentration can be automated.

Further, in the present embodiment, the present invention is applied when measuring the water-cement ratio of the fresh concrete 12, but what kind of cement-based material is a material containing cement and water? Is optional, and the present invention can be applied to materials such as mortar and cement paste.

[0086]

As described above, according to the method for measuring the water-cement ratio and the measuring apparatus used therefor according to the present invention,
By using the correlation or the correlation data between the chromium concentration and the water-cement ratio obtained in advance, it is possible to quickly obtain the water-cement ratio simply by measuring the chromium concentration on site, and it has been possible to obtain dozens of times in the past. The water-cement ratio, which has taken minutes, can be measured in a few minutes.

Further, since it is sufficient to have a device for extracting the filtrate from the cement-based material which has not solidified yet and a device for measuring the chromium concentration, it is not necessary to use an expensive and large measuring device or analyzer which is used in a laboratory. Both can easily be measured on site.

[0088]

[Brief description of drawings]

FIG. 1 is a flowchart showing a method for measuring a water cement ratio according to a first embodiment.

FIG. 2 is a diagram showing an operation of the method for measuring a water cement ratio according to the first embodiment, and is a graph showing a correlation between the water cement ratio and the chromium concentration.

FIG. 3 is a block diagram showing a water cement ratio measuring device according to a second embodiment.

FIG. 4 is a sectional view showing a vacuum suction filter of a water cement ratio measuring device according to a second embodiment.

[Explanation of symbols]

1 Water-cement ratio measuring device 2 Vacuum suction filter (filtrate extracting device) 3 Colorimeter (measuring device) 4 Memory device 5 Computing device 12 Fresh concrete (cement-based material) 14 Filtrate

Claims (6)

[Claims] 1. The filtrate is extracted from a cement-based material that has not solidified yet, the concentration of chromium contained in the filtrate is measured, and the correlation between the chromium concentration and the water-cement ratio is obtained in advance and the measured value is measured. A method for measuring a water-cement ratio, characterized in that the water-cement ratio of the unhardened cementitious material is evaluated by applying the chromium concentration to the correlation. 2. The method for measuring the water-cement ratio according to claim 1, wherein the filtrate is irradiated with light having a wavelength of 360 to 400 nm, and the absorbance at that time is used to measure the chromium concentration. 3. The method for measuring the water-cement ratio according to claim 1, wherein the correlation between the chromium concentration and the water-cement ratio is determined for each type of cement contained in the cement-based material. 4. A filtrate extraction device for extracting a filtrate from a cement-based material that has not yet solidified, a measuring device for measuring the absorbance of chromium contained in the filtrate, and a correlation between a chromium concentration and a water-cement ratio determined in advance. The storage device stores data and a calculation device that performs a predetermined calculation, and the calculation device uses the concentration of chromium obtained by converting the absorbance to store the correlation stored in the storage device. A water-cement ratio measuring device for calculating a water-cement ratio of the cement-based material which has not yet solidified from data. 5. The measuring device is applied to the filtrate at a wavelength of 360.
The water-cement ratio measuring device according to claim 4, wherein the water-cement ratio measuring device is configured to irradiate light of ˜400 nm and measure the absorbance at that time. 6. The water according to claim 4, wherein the storage device is configured to obtain and store correlation data between the chromium concentration and the water cement ratio for each type of cement contained in the water cement-based material. Cement ratio measuring device.