JP2016070714A - Device for measuring particle size distribution of construction material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily and surely make a construction material to be uniformly distributed when particle size distribution of the construction material is measured so as to improve accuracy of particle size distribution measurement.SOLUTION: The device is provided with: supply means 10 that supplies the construction material; cylindrical accommodation means 20 provided directly under the supply means 10; diffusion means 30 accommodated in the accommodation means 20 and having a cone shape the diameter of which expands downwardly, the diffusion means 30 diffusing the construction material supplied from the supply means 10 in a cylindrical manner; diffusion regulation means 40 provided at a lower part of the diffusion means 30 so as to be continued from the diffusion means 30; imaging means 50 that images the construction material uniformly diffused by the diffusion means 30; and particle size distribution analysis means 60 that performs image analysis of image data imaged by the imaging means 50 to analyze the particle size distribution of the construction material. An inner surface of the accommodation means 20 and an outer surface of the diffusion regulation means 40 restrict a spreading width of the construction material flowing down from increasing.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a construction material particle size distribution measuring apparatus, and more particularly, to disperse and flow down the construction material to be measured for particle size distribution, and to perform image processing by photographing the flowing construction material. The invention relates to an apparatus for measuring the particle size distribution.

  In fill dams and CSG (Cemented Sand and Gravel) dam construction, it is important to manage the particle size distribution of the construction materials used in order to improve construction quality. The conventional particle size measurement methods are mainly screening tests and sedimentation analysis. Especially when the amount of construction materials to be managed is huge, such as fill dam construction, the conventional particle size measurement method takes a lot of time. There was a problem of requiring labor. For this reason, development of a technique for capturing construction material and performing image processing on the image data to grasp the particle size distribution is underway (see, for example, Patent Document 1 and Patent Document 2).

  The technique described in Patent Document 1 is a technique for creating a particle size accumulation curve using an image of a granular material. In this granular material particle size distribution measuring method, a granular material in which granular materials having different particle diameters are mixed is taken out and an entire image and a partial image at a predetermined magnification are taken. Then, for a plurality of predetermined coarse particle diameters that are equal to or greater than the detection lower limit particle diameter from the entire image, a particle size index that is an area ratio with respect to the entire image of the detected granular material that is equal to or greater than the predetermined coarse particle diameter is calculated, And a coarse particle size accumulation curve having a predetermined coarse particle size or more is created.

  Subsequently, a granular material is detected from a partial image for a predetermined fine particle size equal to or less than the predetermined coarse particle size, a particle size index of the predetermined fine particle size is calculated, and the particle size index is converted into a cumulative passage rate to obtain the predetermined coarse particle size. The following fine particle size accumulation curve is created. A particle diameter accumulation curve is created by synthesizing the created accumulation curve of the coarse particle diameter and the fine particle diameter.

  The technique described in Patent Document 2 is a technique related to an image capturing apparatus for measuring the particle size distribution of a material. This image capturing device for particle size distribution measurement includes an inclined plate having a surface from which material flows down from the upstream side toward the downstream side, a downflow direction conversion unit provided on the downstream side of the inclined plate, and a downflow direction conversion unit. A screen provided on the downstream side, an illuminating unit that illuminates the screen, and a photographing unit that photographs the material passing through the space on the front side of the screen from the horizontal direction are provided.

  The flow direction conversion section has two vertical plates, front and rear, so that the material flowing down from the inclined plate toward the front passes between the two vertical plates. Further, the screen is offset to the rear side with respect to the flow direction changing portion.

JP2013-257188A JP 2014-62875 A

  However, with the above-described conventional technology, sufficient accuracy has not been obtained for the particle size distribution measurement. The reason why sufficient accuracy cannot be obtained is as follows.

  First, since it is difficult to disperse uniformly so that granular bodies (for example, soil particles) to be imaged do not overlap, the boundaries of the granular bodies become unclear. Second, it is difficult to discriminate individual granules having a relatively small particle size. Thirdly, the relatively small granular materials may be recognized as one large granular material, and the coarse particles are overestimated. Fourth, it is because the presence of a granular material with a small particle size hidden behind a granular material with a relatively large particle size cannot be recognized. Fifth, the protrusions are used to separate the construction material to be measured. However, if there are protrusions in the flow path of the construction material, there is a possibility that the flow path may be clogged with particulate matter.

  The construction material particle size distribution measuring apparatus according to the present invention has been proposed in view of the above-described circumstances, and when measuring the particle size distribution of the construction material, the construction material is easily and surely dispersed uniformly to thereby obtain the particle size distribution. It is an object of the present invention to provide a construction material particle size distribution measuring apparatus capable of increasing the accuracy of distribution measurement.

  The construction material particle size distribution measuring apparatus according to the present invention has the following features in order to achieve the above-described object. In other words, the construction material particle size distribution measuring apparatus according to the present invention is an apparatus for measuring the particle size distribution by uniformly dispersing and flowing down the construction material and photographing the flowing construction material. And an accommodation unit, a diffusion unit, a diffusion regulation unit, an imaging unit, and a particle size distribution analysis unit.

  A supply means is a means for supplying construction material, for example, is comprised by a belt conveyor, a hopper, etc. The accommodating means is made of a cylindrical member provided immediately below the supply means, and has, for example, a cylindrical shape, a rectangular tube shape, or a combination thereof. The diffusing means is a cone which is accommodated in the accommodating means and has a diameter expanded downward, and is a means for uniformly diffusing the construction material supplied from the supplying means.

  The diffusion regulating means is a means for regulating the width of the construction material flowing down in the thickness direction by providing the diffusion regulating means continuously in the lower part of the diffusing means. For example, the diffusion regulating means is formed of a cylindrical member continuously provided at the lower part of the diffusing means. When the lower part of the diffusing means is a quadrangular pyramid, the diffusion regulating means has a quadrangular prism shape in cross section. When the lower part of the diffusion means is a triangular pyramid, the cross section of the diffusion restricting means is triangular, and when the lower part of the diffusion means is conical, the cross section of the diffusion restricting means is cylindrical. In particular, it is preferable that the diffusion restricting means integrated with the diffusing means is a rectangular tube.

  The imaging means is means for photographing the construction material uniformly diffused by the diffusing means, and includes an imaging lens system, an imaging element, an image data transmission interface, and the like. Moreover, you may include the illuminating device for illuminating the construction material used as imaging object as a component of an imaging means.

  The particle size distribution analyzing unit is a unit for analyzing the particle size distribution of the construction material by analyzing the image data captured by the image capturing unit. For example, the particle size distribution analysis means is composed of a personal computer and image analysis software, and by performing image analysis based on image data received from the image pickup means by the function of image analysis software installed in the personal computer, Analyze the particle size distribution of construction materials.

  In the above-described construction material particle size distribution measuring apparatus, the lower part of the diffusion regulating means protrudes below the accommodating means, and the outer periphery of the diffusion regulating means protruding from the accommodating means when photographing the construction material by the imaging means The surface can be a shooting background screen.

  Further, in the above-described construction material particle size distribution measuring apparatus, the diffusing means can be in the form of a mesh that allows passage of granules having a predetermined particle size or less. The granular material may be any material as long as it is a construction material. For example, soil particles correspond to the granular material.

  Further, in the above-described construction material particle size distribution measuring apparatus, the passing weight measuring apparatus for collecting and weighing the construction material having a predetermined particle diameter or less that has passed through the diffusion means, and the total weight of the construction material supplied from the supply means are measured. An overall weighing device, and based on the difference between the total weight of the construction material weighed by the overall weighing device and the passing weight of the construction material weighed by the passage weighing device, the object to be photographed without passing through the diffusion means It is possible to determine the weight of the construction material.

  According to the construction material particle size distribution measuring apparatus of the present invention, the construction material to be measured is uniformly diffused by the function of the diffusion means, and further, the spread width in the thickness direction is regulated by the function of the diffusion regulation means. Therefore, the construction material that has reached the imaging position of the imaging means is in a uniformly distributed state, and since it has a uniform thickness, it is possible to appropriately photograph the construction material to be imaged, It becomes possible to improve the accuracy of the particle size distribution measurement of construction materials.

  In addition, since the apparatus for uniformly diffusing the construction material to be measured has a simple configuration, the downflow path is not clogged with the granular material (for example, earth particles) that is the construction material. The particle size distribution of construction materials can be measured simply and easily.

The schematic diagram which shows the structure of the principal part of a particle size distribution measuring apparatus. The block diagram which shows the component of a particle size distribution measuring apparatus. The perspective view which shows an example of a spreading | diffusion means and a spreading | diffusion regulation means. The schematic diagram which shows the state which makes the thickness of construction material uniform by a diffusion control means.

  DESCRIPTION OF EMBODIMENTS Hereinafter, an embodiment of a construction material particle size distribution measuring apparatus (hereinafter abbreviated as a particle size distribution measuring apparatus) according to the present invention will be described with reference to the drawings. 1 to 4 illustrate a particle size distribution measuring apparatus according to an embodiment of the present invention. FIG. 1 is a schematic diagram showing a configuration of a main part of the particle size distribution measuring apparatus, and FIG. 2 is a block diagram of the particle size distribution measuring apparatus. 3 is a perspective view showing an example of the diffusing means and the diffusion regulating means, and FIG. 4 is a schematic diagram showing a state in which the thickness of the construction material is made uniform by the diffusion regulating means.

  As shown in FIGS. 1 and 2, the particle size distribution measuring apparatus 100 according to the embodiment of the present invention measures the particle size distribution by uniformly dispersing and flowing down the construction material and photographing the flowing construction material. The apparatus includes a supply unit 10, a storage unit 20, a diffusion unit 30, a diffusion regulation unit 40, an imaging unit 50, and a particle size distribution analysis unit 60 as main components. In addition, each means is comprised from the logic circuit which has the software which exhibits the function, or the logic circuit which has an equivalent function by being performed by hardware, such as a single or several member for exhibiting each function, or CPU etc. Is done.

<Supply means>
The supply means 10 is a means for supplying construction materials. In the present embodiment, as shown in FIG. 1, in order to supply the construction material directly above the center of the diffusion means 30, the belt conveyor 11 for conveying the construction material and the construction material conveyed by the belt conveyor 11 are used. The supply means 10 is constituted by a hopper 12 for dropping directly above the center of the diffusion means 30. The supply means 10 is not limited to the belt conveyor 11 and the hopper 12 and may be any member as long as the construction material can be supplied directly above the center of the diffusion means 30. A backhoe or a power shovel may be used.

<Accommodating means>
The accommodating means 20 is composed of a cylindrical member provided directly below the supply means 10. The cross-sectional shape of the accommodating means 20 is a shape that matches the outer shape of the lower portion of the diffusing means 30. When the outer shape of the lower portion of the diffusing means 30 is a pyramid, it is a rectangular tube shape. When the lower outer shape is a conical shape, the shape is cylindrical.

  Further, the accommodating means 20 of the present embodiment has a height for accommodating the upper portions of the diffusing means 30 and the diffusion regulating means 40. In addition, a square tube shape means a polygon whose cross section is a triangle, a quadrangle, or a pentagon or more. In this embodiment, as shown in FIG. 3, since the outer shape of the lower part of the diffusing means 30 is a quadrangular pyramid, the diffusion regulating means 40 is a square cylinder.

<Diffusion means>
The diffusing means 30 is a cone that is accommodated inside the accommodating means 20 and has a diameter that is expanded downward, and is a means for uniformly diffusing the construction material supplied from the supplying means 10. As shown in FIG. 3, the diffusing unit 30 of the present embodiment has a conical shape in which the upper part protrudes upward, and the lower part has a quadrangular pyramid shape whose diameter expands downward. By dropping the construction material onto the surface, the construction material can be uniformly diffused around the top. The shape of the diffusing means 30 is not limited to the mode shown in FIG. 3. If the construction material supplied from the supplying means 10 can be uniformly diffused, a triangular pyramid shape, a quadrangular pyramid shape, a conical shape, or these Any shape such as a combination may be used.

  Further, the diffusing means 30 can be mesh-shaped. That is, the diffusing means 30 is formed of a mesh having a predetermined mesh, and construction material exceeding a predetermined particle size flows down on the outer surface of the mesh, and construction material having a predetermined particle size or less passes through the mesh and is collected. Note that the mesh opening can be appropriately set according to the construction material to be measured, and is set to, for example, about 2.0 mm.

  When the diffusing means 30 has a mesh shape as described above, as shown in FIGS. 1 and 2, a passing weight measuring device 70 that collects and measures the construction material having a predetermined particle diameter or less that has passed through the diffusing means 30. And an overall weighing device 80 for measuring the total weight of the construction material supplied from the supply means 10. In this case, in order to prevent clogging of the mesh, it is preferable to provide a vibration device 90 that applies vibration to the diffusing means 30. For example, a known vibrator can be used as the vibration device 90.

  The passage weighing device 70 and the entire weighing device 80 can be configured by a general electronic balance. Since the construction material to be weighed by the whole weighing device 80 is a large amount, it is preferable to weigh in small amounts when it is put into the belt conveyor 11 or when it is put into the hopper 12. Similarly, when there is a large amount of construction material to be weighed by the passage measuring device 70, the collected construction material may be subdivided and weighed.

  In the case of the configuration including the passage measuring device 70 and the overall weighing device 80, the total weight of the construction material measured by the overall weighing device 80 and the passing weight of the construction material measured by the passage measuring device 70. Based on the difference, it is possible to obtain the weight of the construction material that has been photographed without passing through the diffusion means 30. Thus, the granular material which exceeds the predetermined particle size can be accurately determined by separating the granular material having the predetermined particle size or less that has passed through the mesh.

<Diffusion regulation means>
The diffusion regulating means 40 is a means for regulating the spreading width of the construction material flowing down in the thickness direction by being continuously provided in the lower part of the diffusing means 30 in the housing means 20. The diffusion regulating means 40 is made of, for example, a cylindrical or rectangular tube member. Since the diffusion regulating means 40 is provided continuously below the diffusing means 30, when the lower part of the diffusing means 30 has a quadrangular pyramid shape, the diffusion regulating means 40 has a square cylindrical shape, and the lower part of the diffusing means 30. Is triangular pyramid, the diffusion restricting means 40 is triangular, and when the lower part of the diffusing means 30 is conical, the diffusion restricting means 40 is cylindrical.

  The diffusion regulating means 40 may have any cross-sectional shape, but in order to diffuse the construction material into a flat plate shape (so that the curvature is “0”), the outer peripheral surface is a combination of planes. It is preferable that the shape is formed (for example, a quadrangular prism shape or a triangular prism shape). As shown in FIG. 4, the construction material diffused by the diffusing unit 30 is regulated in the flow direction between the inner peripheral surface of the housing unit 20 and the outer peripheral surface of the diffusion regulating unit 40 and has a uniform thickness. It flows down as a plate.

  In addition, as shown in FIG. 1, by allowing the lower part of the diffusion regulating means 40 to protrude below the accommodation means 20, the diffusion regulation that protrudes from the accommodation means 20 when photographing the construction material using the imaging means 50. The outer peripheral surface of the means 40 can be used as a photographing background screen.

<Imaging means>
The imaging means 50 is a means for photographing the construction material uniformly diffused by the diffusing means 30. Although not shown, the imaging unit 50 of the present embodiment is configured by a digital camera including an imaging lens system, an imaging element, an image data transmission interface, and the like. Moreover, the illuminating device for illuminating the construction material used as imaging object may be included as a component of the imaging means 50. FIG. As the illumination device, for example, an LED light capable of adjusting the light amount and the color temperature can be used.

  The imaging lens system of the imaging means (digital camera) 50 may be a single focal point, but may have a focusing mechanism, and may further have a pan / tilt mechanism and a zoom mechanism. Further, the imaging means (digital camera) 50 may be a camera that captures a still image or a camera that captures a moving image.

  In the present embodiment, in order to perform imaging using the diffusion regulating means 40 as a background screen, the digital camera is installed at a position below the accommodating means 20 and at a position where the flowing construction material does not contact (collision). In order to increase the accuracy of the particle size distribution measurement, it is preferable to install imaging means (digital cameras) 50 at a plurality of locations as shown in FIG. For example, when the diffusion regulating means 40 serving as the background screen is a square cylinder, the imaging means (digital camera) 50 is installed at a position where two or four opposing faces can be photographed.

<Particle size distribution analysis means>
The particle size distribution analyzing unit 60 is a unit for analyzing the particle size distribution of the construction material by analyzing the image data captured by the image capturing unit 50. For example, the particle size distribution analysis unit 60 includes a personal computer and image analysis software, and performs image analysis based on the image data received from the imaging unit 50 by the function of the image analysis software installed in the personal computer. Analyze the particle size distribution of the construction materials. Any known method may be used as the image analysis method, but basically, a method of measuring the particle size of the granular material by recognizing the contour of the granular material based on the image data is used. It is done.

  Since the housing means 20, the diffusing means 30, and the diffusion regulating means 40 are members in contact with the construction material flowing down, they are materials that are not deformed or damaged by the collision of the construction material and are not worn by friction with the construction material. It is necessary to form with. For example, the accommodating means 20, the diffusing means 30, and the diffusion regulating means 40 can be formed of a steel plate. In the above-described embodiment, the diffusing unit 30 and the diffusion regulating unit 40 have been described as hollow members. However, if there is no problem with weight or the like, the diffusing unit 30 and the diffusion regulating unit 40 may be configured with solid members.

  Moreover, the space | interval of the inner wall face of the accommodating means 20 and the outer wall face of the spreading | diffusion means 30 and the spreading | diffusion regulation means 40 needs to have the width | variety which can make construction material flow down easily. The interval is defined by the maximum particle diameter of the construction material to be measured. Moreover, when the construction material supplied by the supply means 10 includes rocks or the like having a predetermined particle diameter or more that may block the flow path, it is preferable to remove them in advance.

DESCRIPTION OF SYMBOLS 10 Supply means 11 Belt conveyor 12 Hopper 20 Storage means 30 Diffusion means 40 Diffusion restriction means 50 Imaging means 60 Particle size distribution analysis means 70 Passage weighing device 80 Whole weighing device 90 Vibrating device 90 Vibrating device 100 Particle size distribution measuring device

Claims (5)

An apparatus for measuring the particle size distribution by uniformly flowing down the construction material and photographing the flowing construction material,
Supply means for supplying construction materials;
Cylindrical storage means provided directly below the supply means;
A conical body accommodated in the accommodating means and having a diameter expanded downward, and diffusing means for uniformly diffusing the construction material supplied from the supplying means;
Diffusion regulation means for regulating the spreading width in the thickness direction of the construction material flowing down by providing continuously in the lower part of the diffusion means inside the housing means;
Imaging means for photographing the construction material that is uniformly diffused by the diffusion means and whose spread width is regulated by the diffusion regulation means;
By analyzing the image data taken by the imaging means, a particle size distribution analyzing means for analyzing the particle size distribution of the construction material,
An apparatus for measuring the particle size distribution of construction materials, comprising:   2. The construction material particle size distribution measuring apparatus according to claim 1, wherein the diffusion regulating means has a rectangular tube shape.   The lower part of the diffusion restricting means protrudes below the accommodating means, and when photographing the construction material by the imaging means, the outer peripheral surface of the diffusion restricting means protruding from the accommodating means is used as a photographing background screen. The apparatus for measuring a particle size distribution of a construction material according to claim 1 or 2.   The particle size distribution measuring apparatus for a construction material according to any one of claims 1 to 3, wherein the diffusing means has a mesh shape that allows a granular material having a predetermined particle diameter or less to pass therethrough. A passage metering device that collects and weighs the construction material having a predetermined particle size or less that has passed through the diffusion means;
An overall weighing device for measuring the total weight of the construction material supplied from the supply means;
With
Based on the difference between the total weight of the construction material weighed by the total weighing device and the passage weight of the construction material weighed by the passage metering device, the construction material that was the subject of photography without passing through the diffusion means 5. The construction material particle size distribution measuring apparatus according to claim 4, wherein the weight of the construction material is determined.

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