KR101064965B1 - Flow measurement system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of hydraulic engineering, and more particularly, to a flow rate measuring system for measuring the flow velocity of water bodies such as rivers and rivers. The present invention floats in the water body 10, the rich (20) and behaves together with the water body (10); It is installed at a measuring point that can measure the rich man 20 that works with the water body 10 so as to obtain the moving time and the moving distance information of the rich man 20 to calculate the flow rate of the water body 10. Presents a flow rate measuring system comprising a; photographing equipment 30 for continuously photographing the rich (20) to move with the water body (10).

Description

Flow rate measurement system {MEASUREMENT SYSTEM FOR VELOCITY OF FLUID}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of hydraulic engineering, and more particularly, to a flow rate measuring system for measuring the flow velocity of water bodies such as rivers and rivers.

The flow rate data of water bodies such as rivers and rivers are the most important among various hydrologic observation data because they are widely used for the purpose of water, water, and water quality management.

Common flow rate measurement methods include flowmeters, electromagnetic surface flowmeters, ultrasonic flowmeters, sealers, and concentration dilution methods. However, the flow rate data measured by this method has various limitations and is not properly used as hydrologic data.

In particular, the flow data calculated by the flood flow measurement method has very low accuracy due to limitations of measurement conditions, methods, and equipment.

Therefore, for the quantitative analysis of flood damage or disaster prevention design of water structures such as rivers, there is an urgent need for a flow measurement method that can acquire flow rate data with high accuracy.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a flow rate measurement system that can obtain the flow rate data very quickly and accurately even during the flood period.

In order to solve the above problems, the present invention floats in the water body 10, the rich body 20 is behaving together with the water body 10; It is installed at a measuring point that can measure the rich man 20 that works with the water body 10 so as to obtain the moving time and the moving distance information of the rich man 20 to calculate the flow rate of the water body 10. Presents a flow rate measuring system comprising a; photographing equipment 30 for continuously photographing the rich (20) to move with the water body (10).

The rich man 20 floats on the water body 10 and is buoyed to be a buoy for photographing the photographing equipment 30, and is connected to the buoy 22 and is locked to the water body 10 so that the It may include a draft portion 24 for supporting the buoy portion (22).

The buoy portion 22 may be spherical.

The draft portion 24 may have a rod shape.

The lower portion of the main body portion may be provided with a weight portion 26 so that the weight is larger than the upper portion of the main body portion.

The weight part 26 may be embedded in the draft part 24.

The photographing equipment 30 may include an ultra-high speed camera that performs continuous shooting at regular time intervals.

It may further include a guide member 50 for inducing the rich man 20 to move along with the water body 10 in a straight direction along the flow direction of the water body (10).

The guide member 50 may be attached to the draft part 24.

The guide member 50 may have a flat or curved shape.

The present invention can obtain the flow rate data quickly and accurately by floating the rich in the water body, by observing the behavior of the actual rich by the imaging equipment instead of the naked eye. Especially in the case of deep water, high flow rate, and high flow rate such as flooding, both the speed and the accuracy of the flow rate measurement are excellent.

1 is a plan view of the flow rate measuring system according to the present invention.
2 and 3 are examples of photographing data obtained by FIG. 1.
4 is a rich perspective view of the flow rate measuring system according to the present invention.
5 is a rich cross-sectional view of a flow rate measuring system according to the present invention.
Figure 6 is a rich cross-sectional view attached to the guide member of the flow rate measuring system according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, the flow rate measuring system according to the present invention includes: a rich man 20 floating in the water body 10 and behaving together with the water body 10; In order to obtain the moving time and the moving distance information of the rich 20 for calculating the flow rate of the water body 10, the water body 10 is installed at a measuring point capable of measuring the rich 20 that moves along with the water body 10. 10) and the shooting equipment 30 for continuous shooting of the rich man 20 is behaving together; may include.

That is, the rich man 20 is dropped into the water body 10, and the rich man 20 dropped into the water body 10 is photographed with the photographing equipment 30 to obtain image data.

At this time, since the rich man 20 moves with the water body 10 and moves away from the photographing device 30, the size of the rich man 20 in the image photographed on the photographing device 30 is rich. It becomes small in inverse proportion to distance (L1, L2) away from 30). For example, as described later, if the buoy portion 22 of the rich man 20 is spherical, the buoy portion 22 of the rich man 20, which is the photographing object 34a captured in the photographed image 34 according to the shooting time elapsed, may be used. The diameters d1, d2, d3, d4 become small (see FIG. 2).

Therefore, the recording time of the recording device 30 becomes the moving time information of the rich 20, the rich 20 from the recording device 30 through the image size of the rich 20 photographed on the recording device 30 It is possible to obtain a distance away, that is, moving distance information of the rich (20).

As such, the flow velocity of the water body 10 may be calculated by combining the moving time information of the rich man 20 and the moving distance information of the rich man 20. Furthermore, the cross-sectional area of the water body 10 is obtained from the cross section of the water body 10 measured in advance, and the water body 10 is obtained by multiplying the cross-sectional area of the water body 10 previously obtained and the flow rate (or average flow rate) calculated as described above. The flow rate of can also be calculated.

The flow rate measuring method according to the present invention may have the following effects.

First, by observing the behavior of the rich man 20 through the photographing equipment 30 instead of visual observation, it is possible to prevent the error of the moving time information of the rich man 20 and the moving distance information of the rich man 20.

Particularly, the rich man 20 may not only go straight along the flow of the water body 10 (arrow A) but may be inclined downward according to the flow of the water body 10, and may swing according to the depth of water. However, since the relative setting behavior of the rich man 20 can be continuously photographed based on the photographing equipment 30 while the photographing setting conditions (for example, photographing point, photographing angle, photographing time interval, etc.) of the photographing equipment 30 are not changed. , It is possible to observe the actual behavior of the rich (20). That is, when the rich man 20 moves straight, the focal point 34b of the photographed image 34 and the center of the photographed object 34a photographed in the photographed image 34 coincide with each other, and the rich man 20 moves obliquely or moves to a depth of water. As a result, the center of the photographing object 34a captured in the photographing image 34 is eccentric from the photographing focus 34b.

Therefore, the movement time information of the rich man 20 and the moving distance information of the rich man 20 according to the present invention are not obtained on the premise that the rich man 20 goes straight. Since the actual behavior of the rich man 20 is reflected, the accuracy is very excellent.

Secondly, since the photographing equipment 30 continuously photographs at very short time intervals and immediately checks the photographed image 34, a rapid and accurate flow rate measurement is possible even when the flow rate is high or the flow rate is high. Therefore, it is possible to respond quickly to changes in the flood.

Third, since the photographing equipment 30 can be installed on the bridge 40 without being photographed in the water body 10, the photographing equipment 30 can be safely photographed at night or during flooding.

Fourth, the observation using the photographing equipment 30 does not require a large number of personnel.

Hereinafter, the rich man 20 according to the present invention will be described in more detail.

The rich man 20 floats on the water body 10 and is connected to the buoy part 22 and the buoy part 22 which becomes a buoy for photographing the photographing equipment 30, and is buried in the water body 10 so that the buoy part 22 is closed. It may be configured to include a draft portion 24 for supporting.

The buoy portion 22 may be formed in various shapes. However, it is a part for acquiring the moving distance information of the rich man 20 relative to the photographing equipment 30 as the shooting object 34a, and the moving distance of the rich man 20 using the size of the shooting object 34a. It is more preferable to take a rectangle so that information can be easily interpreted.

The buoy portion 22 may take any material and structure as long as it can float in the water body 10 while being supported by the draft portion 24.

The draft part 24 is a part which is submerged in the water body 10 and may be formed in various shapes. However, the draft part 24 prevents the buoy portion 22 from being rotated or inverted under the influence of wind, and supports the buoy portion 22 to always float on the water body 10 so that the water body 10 can be measured during the flow rate measurement. It is more preferable to take the rod shape so that the velocity distribution along the water depth can be reflected. At this time, the rod-shaped draft part 24 may be a hollow structure, or may be a solid (solid) structure is full inside.

Such buoy portion 22 and the draft portion 24 may be integrally manufactured from the beginning, or may be separately manufactured and then combined. In the latter case, the buoy part 22 and the draft part 24 may be mutually coupled in various ways, for example, as shown, the groove 22a into which the draft part 24 is inserted into the buoy part 22 is formed. In addition, a screw for screwing may be formed in the upper portion of the groove 22a and the draft portion 24 of the buoy portion 22, respectively.

Meanwhile, the rich man 20 may further include a weight part 26 so that the lower part of the draft part 24 has a larger weight than the upper part of the draft part 24 in order to maintain the posture and the draft of the rich man 20. Can be.

The weight part 26 may be any medium such as sand as long as the weight of the lower part of the draft part 24 can be relatively large. As shown, the weight part 26 is inserted into the hollow 24h of the draft part 24 so that the weight part ( It may be embedded in the 24, it may be installed on the outside of the draft portion 24, although not shown.

Here, when the weight part 26 is built in the draft part 24, the draft part 24 covers the main body part 24a formed so as to have the hollow 24h, and the hollow part 24h of the main body part 24a. It may be configured to include a lid (24b).

Hereinafter, the photographing equipment 30 according to the present invention will be described in detail.

The photographing equipment 30 may be any device that can acquire a photographing image 34 such as a camera or a video. However, it is possible to obtain the captured image 34 more easily in terms of cost, and to continuously shoot at a very short time interval so that shooting can be performed quickly and accurately even when the behavior of the water body 10 such as a flooding period changes drastically. It may include a high speed camera capable of shooting.

Such photographing equipment 30 may be installed anywhere, including the bridge 40 crossing the water body 10 to photograph the behavior of the rich 20. At this time, in order to relatively observe the behavior of the rich man 20 floating in the water body 10 with respect to the photographing equipment 30, the photographing point of the photographing equipment 30, photographing angle (30 '), photographing time interval, etc. It can be set to a fixed value.

On the other hand, in the flow rate measuring system according to the present invention, as shown in Figure 6, if you want to induce the movement of the rich 20, if necessary, the movement of the rich 20 in the water body 10 to the flow direction It may further include a guide member 50 to guide to follow. The guide member 50 may be integrally manufactured from the beginning of the draft part 24 or may be separately manufactured and then combined. In the latter case, the guide member 50 and the draft portion 24 may be coupled to each other in various ways. The guide member 50 may have various shapes as a flat or curved shape.

10; Body 20; Wealthy
22; Buoy 24; Draft
26; Parts by weight 30; Shooting equipment
50; Guide member

Claims (8)

A rich man 20 that behaves together with the water body 10 in a part submerged in the water body 10;
It is installed at a measuring point that can measure the rich man 20 that works with the water body 10 so as to obtain the moving time and the moving distance information of the rich man 20 to calculate the flow rate of the water body 10. Photographing equipment (30) for continuously photographing the rich (20) that is behaving together with the body (10);
It includes;
The rich man 20 floats on the water body 10 and is buoyed to be a buoy for photographing the photographing equipment 30, and is connected to the buoy 22 and is locked to the water body 10 so that the A draft portion 24 supporting the buoy portion 22;
The buoy portion 22 is spherical, and the draft portion 24 is rod-shaped. delete delete delete The method according to claim 1,
The lower portion of the draft portion (24) is a flow rate measuring system, characterized in that the weight portion 26 is provided so that the weight is greater than the upper portion of the draft portion (24). The method according to claim 5,
The weight part (26) is a flow rate measuring system, characterized in that embedded in the draft part (24). The method according to any one of claims 1,5,6,
The photographing equipment (30) is a flow rate measuring system, characterized in that it comprises a high-speed camera for continuous shooting at a predetermined time interval. The method according to any one of claims 1,5,6,
And a guide member (50) for guiding the rich (20) moving together with the water body (10) to go straight along the flow direction of the water body (10).

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