KR101125028B1 - Annular Flume using Angle adjustable side walls and lid - Google Patents

Abstract

The present invention relates to an annular tank having a velocity gradient fluctuating flow section, comprising: a main body having an inner flow section partitioned into an inner wall, an outer wall, a bottom, and a lid, wherein the angle of the outer wall and the lid of the main body is adjusted. By reducing the secondary flow to achieve the same result without the rotation of the main body, by adjusting the angle of the outer wall and the lid of the tank body to reduce the secondary flow, the same result can be obtained without the rotation of the main body. .

Annular water tank, velocity gradient fluctuation flow part, outer wall, lead, slope

Description

Annular Flume using Angle adjustable side walls and lid}

The present invention relates to an annular water tank equipped with a velocity gradient fluctuation flow part, and more particularly, to an annular water tank configured to achieve the same result without rotation of the main body by reducing the secondary flow by adjusting the angle of the outer wall of the water tank body and the lid. will be.

In general, the research for investigation of sediment erosion and sedimentation characteristics has mainly been carried out experimental methods using waterways. The first experimental studies were conducted mainly in straight tanks (Alishahi and Krone, 1964: Thom and Parsons, 1980).

However, this straight water tank has been questioned for its feasibility because sediment agglomerated by the recirculation pump can be easily separated. Therefore, an annular water tank that does not require a recirculation pump and can make flow conditions the same without restriction of time is required. Designed. In addition, race-track flume and rocking flume have been tried, but the annular bath is known as the most preferred experimental device in terms of the validity of the experimental method and the results.

1 is a diagram illustrating an example of the annular water tank described above.

1 is an experimental device for erosion and deposition experiments, the flow is generated by the friction of the top ring (rotating top ring) in contact with the water surface of the tank, and makes a uniform flow circulating endlessly.

FIG. 2 is a schematic diagram schematically illustrating a secondary circulation flow in the annular water tank of the upper lid rotation type as shown in FIG. 1.

As can be seen in Figure 2, such an annular tank of the upper lead rotation drive system forms a secondary circulation flow due to the velocity gradient according to the centrifugal force and the radius to make the bottom shear stress uneven.

However, in order to reduce the occurrence of such secondary circulation flow, the method of rotating the body of the annular water tank in the direction opposite to the rotational direction of the upper ring complicates the structure of the annular water tank itself, and has the disadvantage that the field application is impossible. have.

In other words, this method complicates the structure of the experimental apparatus, and its application becomes very limited because the main body cannot be rotated in the field application.

In addition, it is also a problem to calculate the bottom shear stress that varies in accordance with the rotational speed of the upper lead and the main body.

In the present invention, by adjusting the angle of the side wall and the lead of the annular tank body to reduce the secondary flow, the main technical object of the present invention is to present a device that can achieve the same result without the rotation of the body.

In order to achieve the above object, the present invention, in the annular water tank including a main body having an inner flow portion partitioned into an inner wall, an outer wall, a bottom and a lid, by adjusting the angle of the outer wall and the lid of the main body secondary flow By reducing the, the main technical solution is to present an annular bath, characterized in that configured to achieve the same result without the rotation of the main body.

According to the present invention, by reducing the secondary flow by adjusting the angle of the outer wall and the lid of the tank body, there is an advantage that the same result can be obtained without the rotation of the body.

Hereinafter, with reference to the accompanying drawings the configuration of the present invention, Figure 3 is a perspective structural diagram showing an annular water tank employing a velocity gradient variable flow portion according to the present invention, Figure 4 is a longitudinal cross-sectional structure of the annular water tank of FIG. Fig. 1 is a fluid flow diagram illustrating a state in which the velocity gradient according to the centrifugal force and the radius under the rotational motion of the upper lead of the is reduced.

The annular water tank 100 of the present invention is an annular water tank 100 including a main body having an inner flow portion 10 partitioned into an inner wall 101, an outer wall 103, a bottom 105, and a lid 107. It is derived as part of.

In addition, the annular water tank 100 according to an embodiment of the present invention, by reducing the secondary flow by adjusting the angle of the outer wall 103 and the lid 107 of the main body, it is possible to obtain the same result without the rotation of the main body It is configured to.

In addition, the outer side wall 103, the outer side wall 103 includes a first speed gradient fluctuation flow portion 21, which is formed by inclining at a predetermined angle in the outward direction on the virtual vertical line of the outer end of the bottom 105. It becomes the structure to say.

In addition, on the side of the said lead 107, the said lead 107 is comprised by the structure which includes the 2nd speed gradient fluctuation | fluctuation flow part 23 formed inclined upward by the set angle upward from the virtual horizontal line of the said inner wall 101. It is.

In addition, on the outer side wall 103 and the lead 107 side, the V-shaped third speed gradient fluctuation flow part 20 formed inside is formed while the ends of the outer inclined lead 107 and the outer wall 103 meet. It is configured to be provided.

Meanwhile, reference numeral P denotes a channel in which a circulation flow including the flow part and the first, second and third speed gradient varying flow parts 21, 23, and 20 occurs.

Thus, in the present invention, unlike the conventional annular water tank 100 having a rectangular or rectangular longitudinal section shape, by adjusting the angle of the outer wall 103 and the lead 107 of the body of the annular water tank 100 without the rotation of the body 2 It will provide a way to reduce the vehicle.

Since it does not require the rotation of the body, the structure of the annular water tank 100 experimental apparatus is simplified, and as a result it is possible to reduce the manufacturing cost of the experimental apparatus.

In addition, by reducing the tangential velocity in the vertical direction of the circumferential velocity of the water tank to reduce the secondary flow, the existing non-uniform bottom 105 shear stress is distributed evenly, thereby causing the channel during erosion and deposition experiments. (P) It becomes possible to provide uniform flow on a cross section.

5 to 7 show the results of analyzing the speed while changing the angle of the upper lead 107 that rotates to generate the flow inside the channel P. FIG. 5 shows the rotation of the upper lead 107. 6 shows the results when the speed is 2 rpm, FIG. 6 is 5 rpm, and FIG. 7 is 10 rpm. The velocity shown in the transverse direction represents the radial velocity distribution along the height at the center of the channel P. Since the height of the channel P varies with the angle, it is normalized using the height of each channel P.

Here, it can be seen that the magnitude of the velocity near the bottom 105 decreases as the angle of the top lead 107 increases, which is expected to have a significant effect on the bottom 105 shear stress. In addition, it can be seen that as the angle of the upper lead 107 increases, the magnitude of the velocity near the center portion of the channel P, that is, the dimensionless height of 0.4 to 0.7, is reduced.

In other words, it can be seen that the secondary flow, which is the rotational flow in the cross section of the channel P, decreases. In the vicinity of height 1, which is part of the upper lid 107, the rapid decrease in speed only at the zero degree indicated by the solid line is the radial velocity in the upper lid 107 at zero degrees, but radial in the case of an angle. This is because the velocity component appears.

8 to 10 illustrate the distribution of shear stresses on the bottom 105 surface while increasing the angle of the upper lead 107. FIG. 8 is a rotational speed of 2 rpm, FIG. 9 is 5 rpm, and FIG. 10 is 10 rpm. Indicates the result. It can be seen that the radial shear stress distribution becomes uniform as the angle of the upper rotary lead 107 increases regardless of the rotational speed.

In this experiment, the annular water tank 100 can eliminate the end effect of the existing straight water tank and can maintain the proper flow continuously, thereby maintaining the physical dynamics between the sediment-water. In order to study, the upper lead 107 was introduced as part of an experimental device having a rotating means 200 which allows the angle to be set and rotated.

In addition, the rotation means 200 is configured to include a drive motor 210, a rotational force transmission member 220 such as a bearing, and an arm portion 230 having a plurality of joint links (see Fig. 4). )

However, in the existing tank, the velocity gradient is generated by the centrifugal force, which causes the bottom shear stress to be uneven. Therefore, in order to reduce the circulation of the secondary flow and the change of the bottom shear stress, the counter's bidirectional rotation (counter) Types such as the -rotating method find the optimal rotation ratio where the secondary flow and the bottom shear stress are minimized, such as the value of the bottom shear stress varies depending on the rotational speed of the tank body. In order to solve the problem of causing such a problem, in the present invention, the outer wall 103 and the lead 107 of the main body, when viewed on the longitudinal section of the annular water tank 100 without the rotation of the conventional annular water tank 100 body By reducing the secondary flow by adjusting the angle of the, due to the annular water tank 100 that does not require the rotation of the body, while simplifying the experimental apparatus, while reducing the production cost of the experimental apparatus Would that have excellent effects such as being able.

In other words, the method of applying the speed gradient fluctuation structure according to the embodiment of the present invention further simplifies the structure of the experimental apparatus, so that the application thereof is limited even where there is no facility space of the apparatus for rotating the main body in the field application. There is a very good advantage, such as being made without a wide range.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 is a perspective structural diagram showing an annular water tank 100 employing a conventional upper lead rotation drive method,

2 is a fluid flow diagram illustrating a state of generation of secondary circulation flow due to a velocity gradient according to a centrifugal force and a radius according to a rotational motion of the upper lid in the longitudinal cross-sectional structure of the annular water tank of FIG. 1;

3 is a perspective structural diagram showing an annular water tank employing a velocity gradient variable flow unit according to the present invention;

4 is a fluid flow diagram illustrating a state in which the velocity gradient according to the centrifugal force and the radius under the rotational motion of the upper lid in the longitudinal cross-sectional structure of the annular water tank of FIG. 3 is reduced;

5 to 7 are graphs showing the results of analyzing the speed while varying the angle of the upper lead 107 which rotates to generate the flow in the channel, and

8 to 10 are graphs showing the shear stress of the bottom surface while increasing the angle of the upper lead.

※ Explanation of symbols for main part of drawing.

100: annular water tank 101: inner wall

103: outer wall 105: floor

107: upper lead

Claims (4)

An annular water tank comprising a main body having an inner flow portion partitioned into an inner wall, an outer wall, a bottom, and a lid, And an rotating means for adjusting the angle of the outer wall and the lid. The method of claim 1, An annular tank further comprising a first velocity gradient fluctuating flow portion formed by being inclined at a predetermined angle in an outward direction of the annular water tank with respect to the point where the outer wall is in contact with the bottom of the annular water tank. The method of claim 1, And a second velocity gradient fluctuating flow portion formed by being inclined at a predetermined angle toward the upper side of the annular water tank with respect to the point where the lead is in contact with the inner wall of the annular water tank. The method of claim 1, The outer wall is formed to be inclined at a predetermined angle in the outward direction of the annular tank with respect to the point of contact with the bottom of the annular tank, The lead is formed by inclining at a predetermined angle toward the upper side of the annular tank with respect to the point of contact with the inner wall of the annular tank, And the third speed gradient fluctuating flow part formed inside the annular water tank by extending the outer wall and each end of the lead in contact with each other.

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