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Raindrop three-dimensional scale detection device and method for calculating raindrop volume using the device

A technology of raindrops and scales, applied in measuring devices, optical devices, rainfall/precipitation gauges, etc., can solve the problems of small number of detector pixels, inability to accurately respond to raindrops, and high labor intensity

Inactive Publication Date: 2016-11-23
KUNMING UNIV OF SCI & TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

The workload is heavy, the labor intensity is high, and the automatic classification and statistical measurement work cannot be completed automatically. It is not suitable for analyzing a large amount of data to find laws
Traditional rain gauges include tipping bucket rain gauges, siphon rain gauges, weighing rain gauges, etc. Although the structure and principle are simple, they cannot obtain the particle size and falling speed of raindrops, and cannot accurately reflect the start and stop time and time of rainfall. Obtain instant rainfall intensity information
[0003] Existing shielded optical rain gauges mostly use one-dimensional or two-dimensional detection in terms of product structure. The sampling area of ​​one-dimensional shielded optical rain gauges is small, and only the one-dimensional horizontal particle size of precipitation particles can be measured, and then according to the static wind state Under the assumption of vertical axis symmetry of the particles (small particles are assumed to be spheres, and when the particles are large, they are assumed to be horizontal prolate ellipsoids or lower flat round steamed buns, etc.) to establish a mathematical model for the conversion between the horizontal scale of precipitation particles and the particle volume, and calculate the precipitation particles The main problem of this method is that due to the one-dimensional scale detection and the small number of detector pixels, the amount of measured information is small
However, the axisymmetric calculation model deviates greatly from the actual situation under windy conditions, which may easily cause errors in rainfall calculations.
Moreover, when using the optical occlusion method to detect the volume of falling raindrops, it is necessary to know the diameter of the raindrops. Usually, the calculation of the volume of falling raindrops will use the longest line actually scanned as the equivalent diameter of the actual raindrops. Due to the limitation of frequency, especially when the size of raindrops is small, it is difficult to collect the longest line equal to the diameter of raindrops, resulting in errors;
When the falling raindrop is an ellipsoid, the volume calculation of the ellipsoid needs to know the three axis lengths of the ellipsoid, which cannot be satisfied by traditional one-dimensional or two-dimensional detection, and the data processing is relatively complicated, which affects the processing speed
When the diameter of the raindrop is large, the shape of the raindrop tends to be irregular due to the force in the vertical direction and the windward direction, so the traditional one-dimensional or two-dimensional detection cannot accurately reflect the information of the raindrop
In addition, there is mutual occlusion between raindrop particles in one-dimensional and two-dimensional detection, and the existing detection methods are difficult to further improve the detection accuracy

Method used

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  • Raindrop three-dimensional scale detection device and method for calculating raindrop volume using the device
  • Raindrop three-dimensional scale detection device and method for calculating raindrop volume using the device
  • Raindrop three-dimensional scale detection device and method for calculating raindrop volume using the device

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Experimental program
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Embodiment 1

[0047] Such as Figures 1 to 3 As shown, the raindrop three-dimensional scale detection device includes laser I1, beam shaping system I2, lower detection area 3, linear array photodetector I4, laser II5, beam shaping system II6, linear array photodetector II7, laser III8, laser Beam shaping system III9, upper detection area 10 and linear array photodetector III11, the divergent light emitted by the laser I1 is transformed by the beam shaping system I2 to be parallel to the xy plane and propagate along the x direction, with a width in the y direction and a width in the y direction. The parallel sheet light beam with a thickness of less than 1mm in the vertical direction is irradiated on the linear array photodetector Ⅰ4, and the divergent light emitted by the laser Ⅱ5 is transformed into parallel to the xy plane by the beam shaping system Ⅱ6, and propagates along the y direction, and in the x direction A parallel sheet light beam with a width and a thickness of less than 1mm in...

Embodiment 2

[0061] Such as Figures 1 to 3 As shown, the raindrop three-dimensional scale detection device includes laser I1, beam shaping system I2, lower detection area 3, linear array photodetector I4, laser II5, beam shaping system II6, linear array photodetector II7, laser III8, laser Beam shaping system III9, upper detection area 10 and linear array photodetector III11, the divergent light emitted by the laser I1 is transformed by the beam shaping system I2 to be parallel to the xy plane and propagate along the x direction, with a width in the y direction and a width in the y direction. The parallel sheet light beam with a thickness of less than 1mm in the vertical direction is irradiated on the linear array photodetector Ⅰ4, and the divergent light emitted by the laser Ⅱ5 is transformed into parallel to the xy plane by the beam shaping system Ⅱ6, and propagates along the y direction, and in the x direction A parallel sheet light beam with a width and a thickness of less than 1mm in...

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Abstract

The invention relates to a raindrop three-dimensional detection device and a method for calculating raindrop volume through the raindrop three-dimensional detection device, and belongs to the technical field of meteorological observation. The raindrop three-dimensional detection device comprises a first laser, a first beam shaping system, a lower-layer detection area, a first linear array photoelectric detector, a second laser, a second beam shaping system, a second linear array photoelectric detector, a third laser, a third beam shaping system, an upper-layer detection area and a third linear array photoelectric detector. The method for calculating the raindrop volume through the raindrop three-dimensional detection device comprises the steps that a raindrop is modeled to be in an ellipsoid shape or a steamed bun shape, and the approximate volume of the raindrop is obtained according to collected data. According to the raindrop three-dimensional detection device, a high-speed linear array scanning method in the three-dimensional direction is adopted, the raindrop dimension sampling accuracy and resolution ratio are improved, the recognition rate of tiny rainfall particles such as drizzles is increased, meanwhile, measurement, conducted by an existing optical rain gauge, of rainfall particle forms such as shapes and falling angles is improved, a more accurate mathematic model is established, and the error is small.

Description

technical field [0001] The invention relates to a raindrop three-dimensional scale detection device and a method for calculating the volume of raindrops by using the device, belonging to the technical field of meteorological observation. Background technique [0002] Traditional methods for measuring the diameter of raindrops include filter paper stain method, high-speed photography method, radar observation method, laser holography method, optical rain gauge method, flour ball method, etc. The workload is heavy, the labor intensity is high, and the automatic classification and statistical measurement work cannot be completed automatically. It is not suitable for analyzing a large amount of data to find laws. Traditional rain gauges include tipping bucket rain gauges, siphon rain gauges, weighing rain gauges, etc. Although the structure and principle are simple, they cannot obtain the particle size and falling speed of raindrops, and cannot accurately reflect the start and s...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G01W1/14G01B11/00G01B11/24
Inventor 吴尚谦刘爱英皇甫张棣薛拓
Owner KUNMING UNIV OF SCI & TECH
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