JP2010271159A - Particle size distribution measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a particle size distribution measuring apparatus capable of accurately and quickly grasping a temporal change of a particle size distribution.
A storage unit 5 stores particle size distribution data composed of two axes of a particle diameter and a particle amount for each measurement time, and a plurality of particle size distribution data stored in the storage unit 5 The particle size distribution measuring apparatus 200 includes a three-dimensional graph display control unit 14 that displays a three-dimensional graph composed of three axes of a diameter, a particle amount, and a measurement time. The three-dimensional graph includes the same measurement time. A line connecting the amount of particles at the same time is displayed, and a line connecting the amount of particles at the same particle size is displayed. From the amount of particles at the first measuring time to the amount of particles at the second measuring time at the same particle size The color, thickness, and / or brightness of the line connecting the particle amount at the first measurement time and the particle amount at the second measurement time with the same particle diameter are changed as the degree of increase or decrease It is characterized by.
[Selection] Figure 1

Description

  The present invention relates to a particle size distribution measuring apparatus for measuring a particle size distribution, and more particularly to a particle size distribution measuring apparatus used in a powder process or the like that needs to grasp a temporal change in the particle size distribution.

Examples of the method for measuring the particle size distribution include a sedimentation method, a laser diffraction method, an electric resistance method, a light shielding method, a sieving method, and a microscope method. And the particle size distribution measuring apparatus which can measure a particle size distribution by utilizing any one of these methods has been put into practical use.
In addition, in the powder process and the like, it is necessary to know the temporal change in the particle size distribution of the produced powder, the powder used as a raw material, and the like. Therefore, in a powder process or the like, there is a particle size distribution measuring apparatus capable of measuring particle size distribution at every measurement time and storing particle size distribution data composed of two axes of particle diameter and particle amount at every measurement time. It has been put into practical use.

In order for the user to grasp the temporal change of the particle size distribution, a three-dimensional graph composed of the particle diameter, the particle amount, the measurement time, and the three axes is displayed based on the stored plurality of particle size distribution data. A particle size distribution measuring apparatus capable of performing the above is disclosed (for example, see Patent Document 1).
FIG. 8 is a diagram illustrating an example of a three-dimensional graph showing temporal changes in the particle size distribution displayed by a conventional particle size distribution measuring apparatus. The X axis extends upward, the Y axis extends in the upper right diagonal direction, and the Z axis extends in the upper left diagonal direction. The particle amount (μm) is taken on the X axis, the particle diameter (%) is taken on the Y axis, and the measurement time is taken on the Z axis. Furthermore, in the three-dimensional graph, a line connecting the amount of particles at the same measurement time is displayed for each set time (0, 1, 2,... 13), and the amount of particles at the same particle diameter is connected. An elliptic line is displayed for each set particle diameter (0.01, 0.02,..., 500).
Thereby, the user can grasp | ascertain the temporal change of a particle size distribution by observing a three-dimensional graph. For example, it has been identified how the particle amount at the measurement time 4 increases or decreases from the particle amount at the measurement time 3 for a particle size of 0.1 μm.

Japanese Patent No. 2722866

However, the user may not be able to quickly and accurately grasp the temporal change in the particle size distribution simply by observing the three-dimensional graph shown in FIG. That is, since the three-dimensional graph is a perspective view, the slope of the line connecting the particle amount at the measurement time 3 and the particle amount at the measurement time 4 with a particle diameter of 0.1 μm is positive or negative. Sometimes it was difficult to identify.
Further, the slope of the line connecting the particle amount at the measurement time 3 and the particle amount at the measurement time 4 at a particle size of 5 μm is the particle amount at the measurement time 3 and the measurement time 4 at a particle size of 0.1 μm. It was difficult to identify because it was hidden by a line connecting the amount of particles at.
Therefore, an object of the present invention is to provide a particle size distribution measuring apparatus capable of accurately and quickly grasping a temporal change in the particle size distribution.

  The particle size distribution measuring apparatus of the present invention made to solve the above-mentioned problems is a storage unit that stores particle size distribution data composed of two axes of a particle size and a particle amount for each measurement time, and stores in the storage unit A particle size distribution measuring apparatus including a three-dimensional graph display control unit that displays a three-dimensional graph composed of three axes of a particle size, a particle amount, and a measurement time based on a plurality of particle size distribution data. In the three-dimensional graph, a line connecting the particle amounts at the same measurement time is displayed, and a line connecting the particle amounts at the same particle diameter is displayed. The color of the line connecting the particle amount at the first measurement time and the particle amount at the second measurement time with the same particle size, with the degree of increase or decrease in the particle amount at the second measurement time from the particle amount of Change thickness and / or brightness It has to.

Here, the “first measurement time” and the “second measurement time” are arbitrary measurement times, and are set in advance by the user or the like. For example, the first measurement time is set as the measurement time 0. In addition, the second measurement time is set to measurement time 1.
According to the particle size distribution measuring apparatus of the present invention, a three-dimensional graph composed of three axes of particle diameter, particle amount, and measurement time is displayed. In the three-dimensional graph, a line connecting the particle amounts at the same measurement time is displayed, and a line connecting the particle amounts at the same particle diameter is displayed. At this time, as the amount of particles at the second measurement time increases or decreases from the amount of particles at the first measurement time at the same particle size, the amount of particles at the first measurement time and the second measurement at the same particle size. The color, thickness, and / or luminance of the line connecting the amount of particles over time is changed. For example, when the particle amount at the measurement time 0 is increased from the particle amount at the measurement time 0 at a particle diameter of 0.1 μm, the color of the line is changed to green, whereas when it is decreased, the color of the line is changed. To red. Also, when the change is significant, the thickness of the line is changed to be thicker. On the other hand, when the change is a little, the thickness of the line is changed to be thinner.

  As described above, according to the particle size distribution measuring apparatus of the present invention, it is possible to quickly and accurately grasp the temporal change of the particle size distribution.

(Means and effects for solving other problems)
The particle size distribution measuring apparatus of the present invention includes a storage unit that stores particle size distribution data composed of two axes of a particle diameter and a particle amount for each measurement time, and a plurality of particle size distributions stored in the storage unit. A particle size distribution measuring apparatus including a three-dimensional graph display control unit that displays a three-dimensional graph composed of three axes of particle diameter, particle amount, and measurement time based on data, wherein the three-dimensional graph includes: A line connecting the particle amount at the same measurement time is displayed, and a line connecting the particle amount at the same particle size is displayed, and the second measurement is performed from the particle amount at the first measurement time at the first particle size. In accordance with the magnitude of the average value of the degree of increase / decrease in the amount of particles in time and the degree of increase / decrease in the amount of particles in the second measurement time from the amount of particles in the first measurement time in the second particle diameter, The amount of particles at the first measurement time and the number of particles A line connecting the particle amount at the measurement time, a line connecting the particle amount at the first measurement time and the particle amount at the second measurement time for the second particle diameter, and the first particle at the first measurement time The line connecting the particle amount at the diameter and the particle amount at the second particle diameter, and the line connecting the particle amount at the first particle diameter and the particle amount at the second particle diameter at the second measurement time The color and / or luminance of the surface to be surrounded is changed.

Here, the “first particle diameter” and the “second particle diameter” are arbitrary particle diameters and are set in advance by a user or the like. For example, the first particle diameter is 0.05 μm. And the second particle diameter is set to 0.06 μm.
According to the particle size distribution measuring apparatus of the present invention, a three-dimensional graph composed of three axes of particle diameter, particle amount, and measurement time is displayed. In the three-dimensional graph, a line connecting the particle amounts at the same measurement time is displayed, and a line connecting the particle amounts at the same particle diameter is displayed. At this time, in the first particle size, the degree of increase or decrease in the particle amount in the second measurement time from the particle amount in the first measurement time, and in the second measurement time from the particle amount in the first measurement time in the second particle size. A line connecting the particle amount at the first measurement time and the particle amount at the second measurement time in the first particle diameter with the magnitude of the average value of the degree of increase or decrease of the particle amount of the second particle, The line connecting the particle amount at the first measurement time and the particle amount at the second measurement time in the diameter, and the particle amount at the first particle size and the particle amount at the second particle size at the first measurement time The color and / or luminance of the surface surrounded by the connected line and the line connecting the particle amount at the first particle size and the particle amount at the second particle size in the second measurement time are changed. For example, when the particle size is 0.05 μm, the amount of change in the particle amount from the particle amount at the measurement time 3 at the measurement time 4 and at the measurement time 4 from the particle amount at the measurement time 3 at the particle size of 0.06 μm. When the average value of the change amount of the particle size is positive and large, it is indicated by red, when positive and small, it is indicated by orange, when negative and small, it is indicated by blue, and when negative and large, it is indicated by green.
As described above, according to the particle size distribution measuring apparatus of the present invention, it is possible to quickly and accurately grasp the temporal change of the particle size distribution.

In the particle size distribution measuring apparatus of the present invention, in the three-dimensional graph, the line color, the line thickness, the line luminance, the surface color, and / or the set measurement time interval and the set particle diameter interval, and / or The brightness of the surface may be changed.
Here, the “set measurement time interval” is an arbitrary measurement time interval, and is set in advance by a user or the like. For example, in the three-dimensional graphs shown in FIGS. By setting the measurement time 13, the entire three-dimensional graph is executed.
Further, the “set particle diameter interval” is an arbitrary particle diameter interval and is set in advance by a user or the like. For example, in the three-dimensional graphs shown in FIGS. 3 to 6, the particle diameter is 0.01 μm. By setting the particle diameter to 100 μm, the entire three-dimensional graph is executed.

The particle size distribution measuring apparatus of the present invention includes an input device, and the three-dimensional graph display control unit changes a line-of-sight direction for displaying the three-dimensional graph based on an input signal from the input device. May be possible.
According to the particle size distribution measuring apparatus of the present invention, the line-of-sight direction for displaying a three-dimensional graph can be changed, so that an area to be observed is not hidden.

  Furthermore, in the particle size distribution measuring apparatus according to the present invention, the three-dimensional graph display control unit is arranged in the first line-of-sight direction, which is the axial direction of the particle amount, based on the first input signal from the first button of the input device. Based on the second input signal from the second button of the input device, it may be possible to change in the second viewing direction, which is the axial direction of the measurement time.

1 is a diagram showing a configuration of a laser beam diffraction / scattering particle size distribution measuring apparatus according to the present invention. FIG. It is a figure which shows the structure of the computer shown in FIG. It is a figure which shows an example of the three-dimensional graph displayed on the display apparatus in the particle size distribution measuring apparatus of this embodiment. It is a figure which shows an example of the three-dimensional graph displayed on the display apparatus in the particle size distribution measuring apparatus of this embodiment. It is a figure which shows an example of the three-dimensional graph displayed on the display apparatus in the particle size distribution measuring apparatus of this embodiment. It is a figure which shows an example of the three-dimensional graph displayed on the display apparatus in the particle size distribution measuring apparatus of this embodiment. It is a figure for demonstrating an example of the method of changing the color and brightness | luminance of each surface. It is a figure which shows an example of the three-dimensional graph displayed on the display apparatus in the conventional particle size distribution measuring apparatus.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, this invention is not limited to the following embodiment, It cannot be overemphasized that various aspects are included in the range which does not deviate from the meaning of this invention.

FIG. 1 is a diagram showing the configuration of a laser beam diffraction / scattering particle size distribution measuring apparatus according to the present invention. FIG. 2 is a diagram showing the configuration of the computer shown in FIG. 1 and 2, a schematic diagram showing a configuration of an optical system and a block diagram showing a configuration of a signal processing system including a data sampling circuit and a computer are shown together.
The dispersion tank 210 includes a stirrer 212 having a stirring blade and the like and an ultrasonic vibrator 213.
The liquid medium L is supplied from the liquid medium supply pump 211 into the dispersion tank 210, and the particle group P is also introduced into the dispersion tank 210. Furthermore, by driving the stirrer 212 and the ultrasonic vibrator 213, a sample S in which the particle group P is uniformly dispersed in the medium L in the dispersion tank 210 is generated.

The flow cell 230 has a lower connection port 230a at the lower end and an upper connection port 230b at the upper end. The lower connection port 230 a of the flow cell 230 is connected to the circulation pump 222 of the dispersion tank 210 via the pipe 221. Further, the upper connection port 230 b is connected to the dispersion tank 210 via the pipe 220.
In such a configuration, when the circulation pump 222 is driven, the sample S including the particle group P and the medium L in the dispersion tank 210 flows into the flow cell 230 from the lower connection port 230a, and the flow cell 230 flows from the bottom to the top and then flows out from the upper connection port 230b.

On the left side of the particle size distribution measuring apparatus 200, a laser light source 241, a condenser lens 242, a spatial filter 243, and a collimator 244 are arranged in this order from the left, and a flow cell 230 is arranged at the center of the particle size distribution measuring apparatus 200. Is done.
In such a configuration, the laser light generated by the laser light source 241 passes through the condenser lens 242, the spatial filter 243, and the collimator 244 to become parallel light, and flows in the forward direction (from left to right). 230 is irradiated. At this time, the sample S for measuring the particle size distribution is introduced into the flow cell 230 so as to flow from the bottom to the top.
As a result, the laser light is diffracted and scattered by the particle group P in the flow cell 230, and an intensity distribution pattern of the diffracted / scattered light is generated spatially.

On the right side of the particle size distribution measuring apparatus 200, a condenser lens 251 and a ring detector (forward scattered light sensor) 252 are arranged in this order from the left.
The ring detector 252 concentrically arranges a plurality of (for example, 64) photodetectors having ring-shaped or semi-ring-shaped light receiving surfaces having different radii so as to be centered on the optical axis of the condenser lens 251. It is arranged so that light having a diffraction / scattering angle corresponding to each position is incident on each light detection element. Therefore, the output signal of each light detection element represents the light intensity for each diffraction / scattering angle.
In such a configuration, the diffracted / scattered light within 60 ° with respect to the forward direction is condensed on the light receiving surface of the ring detector 252 via the condenser lens 251 to form a ring-shaped diffracted / scattered image. It becomes like this.

Further, the side scattered light sensor 253 detects the scattered light to the side (backward upward direction) exceeding 60 ° with respect to the front direction.
Further, the scattered light in the rear direction (rear and lower direction) exceeding 60 ° with respect to the front direction is detected by the plurality of back scattered light sensors 254.
The backscattered light sensor 254 has a plurality (for example, five) of light detection elements arranged in a straight line from left to right, and each light detection element has a diffraction / corresponding to each position. Light having a scattering angle is incident. Therefore, the output signal of each light detection element represents the light intensity for each diffraction / scattering angle.
The output signals of each of the ring detector 252, the side scattered light sensor 253, and the back scattered light sensor 254 are sequentially digitized by a data sampling circuit 260 including an amplifier, a multiplexer, and an A / D converter to obtain light intensity data. To the computer 270.

The computer 270 includes an input device 1 such as a keyboard, a touch panel, a mouse, and a stylus pen, a display device 2 such as a CRT (Cathode Ray Tube), an LCD (Liquid Crystal Display), and a plasma display, and various types of input from the input device 1. It is comprised by the control part 4 which performs a process according to a command, and the memory | storage part 5 which memorize | stores the data etc. which were produced by the control part 4. FIG.
The control unit 4 acquires the light intensity data received from the data sampling circuit 260 and stores it in the storage unit 5, and creates particle size distribution data from the light intensity data and stores it in the storage unit 5. A particle size distribution data creation unit 12, a 3D graph display control unit 14 that creates a 3D graph from the particle size distribution data and displays the 3D graph on the display device 2, and a pointer display that displays the pointer 31 on the display device 2 It has the control part 15 and the operation screen display control part 16 which displays the operation screen 30 on the display apparatus 2. FIG.
The storage unit 5 includes a light intensity data storage area 21 and a particle size distribution data storage area 22. In the light intensity data storage area 21, for example, as the light intensity data received from the data sampling circuit 260, the measured light intensity, the measurement position, and the measurement time (note that the measurement time is also called the measurement time, and the measurement time is the measurement time. Data that can be substituted in order) is stored. The particle size distribution data storage area 22 stores particle size distribution data composed of two axes of the particle diameter and the particle amount at the same measurement time.

The light intensity data acquisition unit 11 is a light intensity data (digital amplified signal) from each of the ring detector 252, the side scattered light sensor 253, and the back scattered light sensor 254, that is, the spatial intensity of the diffracted / scattered light. Control to store the distribution data in the light intensity data storage area 21 is performed.
The particle size distribution data creation unit 12 performs a known calculation based on Fraunhofer diffraction theory or Mie scattering theory using the spatial intensity distribution data of the diffracted / scattered light and the refractive indices of the particles and liquid medium stored in advance. By doing so, control is performed to calculate the particle size distribution of the particle group and to store the particle size distribution data in the particle size distribution data storage area 22. That is, the particle size distribution data composed of the two axes of the particle diameter and the particle amount at a certain measurement time is stored.

The three-dimensional graph display control unit 14 creates a three-dimensional graph composed of three axes of particle diameter, particle amount, and measurement time based on a plurality of particle size distribution data stored in the particle size distribution data storage area 22. Then, control for displaying the three-dimensional graph on the display device 2 is performed.
Here, FIGS. 3 to 6 are diagrams illustrating an example of a three-dimensional graph displayed on the display device. FIG. 3 is a three-dimensional graph viewed from any one direction. 4 is a three-dimensional graph viewed from the same direction as FIG. 3, and FIG. 5 is a view of the three-dimensional graph shown in FIG. 4 viewed from one different direction. Further, FIG. 6 is a view of the three-dimensional graphs shown in FIGS.
In FIG. 3, the X-axis extends upward, the Y-axis extends in the upper right diagonal direction, and the Z axis extends in the upper left diagonal direction. The particle amount (%) is taken on the X axis, the particle diameter (μm) is taken on the Y axis, and the measurement time is taken on the Z axis. Furthermore, in the three-dimensional graph, a line connecting the amount of particles at the same measurement time is displayed for each set time (0, 1, 2,... 13), and the amount of particles at the same particle diameter is connected. An elliptic line is displayed for each set particle diameter (0.01, 0.02,..., 500).
Then, in the particle size distribution measuring apparatus 200 of the present embodiment, the first particle size at the same particle size is increased as the particle amount at the second measurement time is increased or decreased from the particle amount at the first measurement time at the same particle size. The color and thickness of the line connecting the particle amount at the measurement time and the particle amount at the second measurement time are changed. It should be noted that such a change in line color and thickness is executed in almost the entire three-dimensional graph.

Specifically, when the particle amount at the second measurement time increases from the particle amount at the first measurement time at the same particle diameter, the color of the line is changed to green, while when the particle amount decreases. Changes the color of the line to red.
Further, the thickness of each line is changed based on the following formula (1).
Line thickness = (MAXw−MINw) × ABS (dy) / MAXdy (1)
Here, MAXw is the maximum value of the preset line thickness, MINw is the minimum value of the preset line thickness, and ABS (dy) is the first measurement time at the same particle diameter. Is the absolute value of the amount of change in particle amount and the amount of change in particle amount at the second measurement time, and MAXdy is the maximum value of the amount of change in particle amount in the entire three-dimensional graph.

In FIG. 4, the X axis extends upward, the Y axis extends in the upper right diagonal direction, and the Z axis extends in the upper left diagonal direction. The particle amount (%) is taken on the X axis, the particle diameter (μm) is taken on the Y axis, and the measurement time is taken on the Z axis. Furthermore, in the three-dimensional graph, a line connecting the amount of particles at the same measurement time is displayed for each set time (0, 1, 2,... 13), and the amount of particles at the same particle diameter is connected. An elliptic line is displayed for each set particle diameter (0.01, 0.02,..., 500).
And the degree to which the particle amount at the second measurement time increases or decreases from the particle amount at the first measurement time at the first particle size, and the particle amount at the second measurement time from the particle amount at the first measurement time at the second particle size. Along with the average value of the degree of increase or decrease of the particle amount, a line connecting the particle amount at the first measurement time and the particle amount at the second measurement time in the first particle size, and the second particle size The line connecting the amount of particles at the first measurement time and the amount of particles at the second measurement time and the amount of particles at the first particle size and the amount of particles at the second particle size at the first measurement time are connected. The color and brightness of the surface surrounded by the ellipse and the line connecting the particle amount at the first particle size and the particle amount at the second particle size in the second measurement time are changed. It should be noted that such a change in color and luminance of the surface is executed in almost the entire three-dimensional graph.

Specifically, when the average value is positive, the color of each surface is changed to green. On the other hand, when the average value is negative, the color of each surface is changed to red.
Moreover, the brightness | luminance of each surface is changed based on following formula (2) (refer FIG. 7).
Surface brightness = (MAXcol−MINcol) × ABS (E) / MAX-E (2)
Here, MAXcol is the maximum luminance value of the preset surface, MINcol is the minimum luminance value of the preset surface, and ABS (E) is the first measurement at the first particle diameter (R1). From the amount of particles (A) at time (T1) to the amount of change in the amount of particles (B) at the second measurement time (T2) and the amount of particles at the first measurement time (T1) in the second particle size (R2) (C) is the absolute value of the average value of the change amount of the particle amount (D) from the second measurement time (T2), and MAX-E is the average value of the change amount of the particle amount in the entire three-dimensional graph. Is the maximum value.

In FIG. 5, the X axis extends in a direction perpendicular to the paper surface, the Y axis extends in the right direction, and the Z axis extends in the upward direction. The particle amount (%) is taken on the X axis, the particle diameter (μm) is taken on the Y axis, and the measurement time is taken on the Z axis. Furthermore, in the three-dimensional graph, a line connecting the amount of particles at the same measurement time is displayed for each set time (0, 1, 2,... 13), and the amount of particles at the same particle diameter is connected. An elliptic line is displayed for each set particle diameter (0.01, 0.02,..., 500).
Then, in the same manner as in FIG. 4, the color and brightness of each surface are changed based on Expression (2). That is, FIG. 5 is a view of the three-dimensional graph shown in FIG. 4 as viewed from a different direction (first line-of-sight direction that is the axial direction of the particle amount).

Furthermore, in FIG. 6, the X axis extends upward in the drawing, the Y axis extends in the right direction, and the Z axis extends in a direction perpendicular to the drawing. The particle amount (%) is taken on the X axis, the particle diameter (μm) is taken on the Y axis, and the measurement time is taken on the Z axis. Furthermore, in the three-dimensional graph, a line connecting the amount of particles at the same measurement time is displayed for each set time (0, 1, 2,... 13), and the amount of particles at the same particle diameter is connected. An elliptic line is displayed for each set particle diameter (0.01, 0.02,..., 500).
Then, the color and thickness of each line are changed based on the formula (1) in the same manner as in FIG. 3, and the color of each surface based on the formula (2) in the same manner as in FIGS. And brightness.

Therefore, the three-dimensional graph display control unit 14 displays any one of the three-dimensional graphs as shown in FIGS. 3 to 6 on the display device 2. At this time, any one of three-dimensional graphs as shown in FIGS. 3 to 6 is selected by input signals from a pointer display control unit 15 and an operation screen display control unit 16 described later.
The pointer display control unit 15 displays the pointer 31 on the display device 2, moves the displayed pointer 31 based on an input signal output from a mouse or the like, and designates a position in the display screen with the pointer 31. Control.
The operation screen display control unit 16 displays the operation screen 30 on the display device 2 and designates a position in the operation screen 30 with the pointer 31, so that the three-dimensional graph display control unit is based on the designated position. 14 is controlled to output an input signal.

For example, as shown in FIGS. 3 to 6, an operation screen 30 is displayed on the lower right as a horizontal rotation control bar 30a, a vertical rotation control bar 30b, a change presence / absence display button (second button) 30c, and an overall image display. A button (first button) 30f, a green button 30d, and a fill button 30e are displayed.
Then, when the user designates the horizontal rotation control bar 30a with the pointer 31 and moves it left and right, the three-dimensional graph display control unit 14 horizontally rotates the three-dimensional graph according to the movement amount. Further, when the user designates the vertical rotation control bar 30b with the pointer 31 and moves it to the left and right, the three-dimensional graph display control unit 14 rotates the three-dimensional graph vertically according to the movement amount.
Further, when the user designates the change presence / absence display button 30c with the pointer 31, the three-dimensional graph display control unit 14 displays a three-dimensional graph as shown in FIG. That is, the three-dimensional graph is viewed from the second viewing direction that is the axial direction of the measurement time. On the other hand, when the user designates the whole image display button 30f with the pointer 31, the three-dimensional graph display control unit 14 displays a three-dimensional graph as shown in FIG. That is, the three-dimensional graph is viewed from the first line-of-sight direction which is the axial direction of the particle amount.
Further, when the user designates the green button 30d with the pointer 31, the three-dimensional graph display control unit 14 determines whether or not to change the color and thickness of each line. In other words, the three-dimensional graph may change the color and thickness of each line as shown in FIG. 3, or may not change the color and thickness of each line as in the prior art. On the other hand, when the user designates the fill button 30e with the pointer 31, the three-dimensional graph display control unit 14 determines whether or not to change the color and thickness of each surface. In other words, the three-dimensional graph may change the color and thickness of each surface as shown in FIG. 4 or may not change the color and thickness of each surface as in the prior art. Become.

  As described above, according to the particle size distribution measuring apparatus of the present invention, it is possible to quickly and accurately grasp the temporal change of the particle size distribution. Furthermore, since the line-of-sight direction for displaying the three-dimensional graph can be changed, the region to be observed is not hidden.

  The present invention can be used in a particle size distribution measuring apparatus for measuring a particle size distribution.

5: Storage unit 14: Three-dimensional graph display control unit 200: Particle size distribution measuring device

Claims (5)

A storage unit for storing particle size distribution data composed of two axes of particle diameter and particle amount for each measurement time;
A particle size distribution comprising a three-dimensional graph display control unit for displaying a three-dimensional graph composed of three axes of particle diameter, particle amount and measurement time based on a plurality of particle size distribution data stored in the storage unit A measuring device,
In the three-dimensional graph, a line connecting the particle amount at the same measurement time is displayed, and a line connecting the particle amount at the same particle diameter is displayed,
As the amount of particles at the second measurement time increases or decreases from the amount of particles at the first measurement time at the same particle size, the amount of particles at the first measurement time and the second measurement time at the same particle size A particle size distribution measuring apparatus characterized by changing the color, thickness and / or luminance of a line connecting the amount of particles. A storage unit for storing particle size distribution data composed of two axes of particle diameter and particle amount for each measurement time;
A particle size distribution comprising a three-dimensional graph display control unit for displaying a three-dimensional graph composed of three axes of particle diameter, particle amount and measurement time based on a plurality of particle size distribution data stored in the storage unit A measuring device,
In the three-dimensional graph, a line connecting the particle amount at the same measurement time is displayed, and a line connecting the particle amount at the same particle diameter is displayed,
The degree of increase or decrease of the particle amount at the second measurement time from the particle amount at the first measurement time at the first particle size, and the particle amount at the second measurement time from the particle amount at the first measurement time at the second particle size Along with the average value of the degree of increase or decrease, the line connecting the particle amount at the first measurement time and the particle amount at the second measurement time in the first particle size, and the second in the second particle size A line connecting the particle amount at one measurement time and the particle amount at the second measurement time, and a line connecting the particle amount at the first particle size and the particle amount at the second particle size at the first measurement time And / or changing the color and / or luminance of the surface surrounded by the line connecting the particle amount at the first particle size and the particle amount at the second particle size in the second measurement time. Particle size distribution measuring device.   In the three-dimensional graph, the color of the line, the thickness of the line, the luminance of the line, the color of the surface, and / or the luminance of the surface are changed between the set measurement time interval and the set particle size interval. The particle size distribution measuring apparatus according to claim 1 or 2. With input device,
The said three-dimensional graph display control part can change the gaze direction which displays the said three-dimensional graph based on the input signal from the said input device. The particle size distribution measuring apparatus according to any one of the above. Based on the first input signal from the first button of the input device, the three-dimensional graph display control unit changes the first line-of-sight direction, which is the axial direction of the particle amount,
5. The particle size distribution measurement according to claim 4, wherein the particle size distribution can be changed in a second line-of-sight direction, which is an axial direction of measurement time, based on a second input signal from the second button of the input device. apparatus.