Effective Analysis by Arrangement of Multi-Baffle at Weir Downstream ()
1. Introduction
In general, a weir is a structure installed for the purpose of irrigation and flood control. However, the river design standard only presents the design standard for the general weir, so technical limitations are shown for designing medium size weir structure (fixed weir, movable weir, etc). Especially, the weir under the river design standard is defined as a small-scale structure constructed at the maximum height of 2 - 3 m, so the design standards and methods for dissipation structure in downstream according to the scale are insufficient currently. Also, weir structures installed recently have a height over 5 m but the river design standard and the dam design standard only discuss the function and installation method of energy dissipater according to the installation of spillway, studies on the placement and verification according to the dissipation effect should be carried out additionally.
The analysis result of domestic and overseas researches related to scouring shows that those researches focused on the numerical simulation on local scouring occurred due to hydraulic structures and the simulation on the scouring estimation according to flow velocity is being carried out currently [1] [2] [3] [4] [5] . The study on the effect of waterway at the downstream of weirs was also carried out but only the improvement of calculation formula for riverbed material according to the turbulence intensity at the downstream of waterway was suggested [6] . Kim et al. carried out the hydraulic model experiment for scouring at the downstream drain pan of the structure and the amount of settlement occurred after riprap protection was installed and suggested the empirical equation to quantify the dimensionless subsidence of Riprap Scour Protection but only the standard was suggested due to insufficient verification [7] .
McLaughlin Water Engineers investigated the advantages and disadvantages of transverse structure in various shapes and suggested an appropriate structure for each area [8] and Agricultural research service and Little carried out the studies on scour depth changes for each condition through the hydraulic experiments [9] [10] . Also, the experiment on the development and effect of stepped drop structure for dissipation was carried out [11] and the effect of energy dissipater was also analyzed quantitatively through the hydraulic model experiment in a reservoir where the energy dissipater was installed [12] . Cho installed a movable weir and a dissipation block in the indoor open channel experimental equipment, carried out the hydraulic experiment and analyzed the impact on dissipation changes according to the hydraulic conditions [13] and Cho also carried out a study to increase the dissipation rate in a jump basin and analyze the characteristics of hydraulic jump by installing a block [14] .
However, most studies were based on the numerical analysis and the purpose of such studies was to analyze the scour depth. Also, most studies were experimental studies on the analysis of effects according to the installation of energy dissipater. Therefore, baffles, which were energy dissipaters, were installed in the downstream of fixed weir and movable weir in multiple directions and the hydraulic experiment was carried out in this study, and the placement with the highest dissipation effect was presented.
2. Method of Study
2.1. Composition of Hydraulic Experiment and Measurement
The experimental equipment used in the hydraulic experiment was classified into the waterway and the flow supply unit. The flow supply unit consisted of underground storage facility and the pump, and the experimental equipment consisted of baffle, model waterway and water collecting well at the downstream. The open channel used as the experiment equipment was installed to enable the maximum flow of 0.3 m3/s. The stationary hydraulic experiment was carried out at the straight waterway which had a rectangular section, and the width, length and height of waterway were 2.0 m, 50.0 m and 1.2 m respectively.
The movable weir on the target structure for experiment was sliding water gate type with the width of 0.3 m and two water gates were produced and the fixed weir was produced in a basic shape with the width of 0.5 m (left bank), 0.4 m (middle back) and 0.5 m (right bank) (Figure 1). All baffles were produced in the same square shape (width: 0.03 m, length: 0.03 m, height: 0.08 m).
In order to measure flow change occurred due to the installation of baffle, a 1.0 m section at the downstream of baffle installation section was set as the zone for experimental measurement. The measurement interval was a 0.1 m interval in the longitudinal and transverse directions and the total number of measuring points is 190 points.
2.2. Experimental Method
The flow in the downstream direction of weir after passing through 2 movable weirs creates a crossing wave with the flow in multiple directions unlike the flow in the upper stream. In order to facilitate the measurement of flow velocity for such hydraulic behavior in case of baffle installation and no baffle installation, a 2.4 m × 0.4 m-sized carriage was installed and a velocity meter was attached to move to the measuring points. For the attached velocity meter, VO1000 produced by KENEK in Japan, a 1-dimen- sional propeller-type velocity meter that could be utilized in shallow water was used. VO1000 can measure one-directional flow velocity with the measurement range of ±3 - ±200 cm/s and the measurement error of ±3 cm/s according to the range of flow velocity. The average flow velocity at the measurement interval of 1, 5, 10, 20, 40 and 60 seconds can be measured. The average flow velocity was measured in this experiment at the time interval of 20 seconds. The flow velocity was measured using the one point method that the measurement was taken at the position of 60% from the surface of the water.
Figure 2 shows the measuring points and the measuring points were marked both on the sideline on top of both walls of the waterway and the carriage to take a measurement at an accurate point.
2.3. Experiment Conditions
One flow velocity condition was set in order to analyze the flow dissipation effect from the baffle arrangement at the downstream of the weir. The water gates are completely open and the rate of inflow is 0.15 m3/s. The water level at the upper stream was 0.3 m and the water level at downstream was 0.12 m (Table 1). Figure 3 shows the type of baffle arrangement in the hydraulic experiment. The experiment was carried out for a total of 9 conditions and case 1 is the condition before baffle installation.
3. Experiment Result and Analysis
3.1. Flow Velocity and Water Level Measurement Result for Each Experiment Condition
In this experiment, water level difference between the upper stream and downstream was maximized in order to create strong flow velocity in the straight waterway. As a result of experiment, the maximum flow velocity at the downstream of the weir in Case 1 which was the case of no baffle installation was 2.068 m/s due to flow in multiple directions and crossing wave and since runoff flow was fast in the side walls of waterway,
Table 1. Condition of hydraulic model experiment.
a vortex occurred on the left and right sides. Since the maximum water level did not encounter flow resistance, the water level was lower than the water level in the case that the baffles were installed.
The maximum flow velocity at the downstream of weirs in cases 2 to 9 that the baffles were installed as shown in Table 2 was measured due to the flow dissipation effect of baffle arrangement, and the maximum water level was higher than the water level in Case 1 due to the flow resistance. A weak vortex occurred in the side walls of waterway due to flow dissipation at the downstream of weirs (Table 2, Figure 4). As a result of comparing the maximum flow velocity, case 5, case 6, case 7, case 8, and case 9 among the baffle arrangement types showed a decrease in the maximum flow velocity by more than 30 % in comparison to the case of no baffle installation and the range of flow velocity was between 36.992% and 45.841%.
3.2. Analysis of Flow Dissipation Effect for Each Baffle Arrangement
The flow dissipation effect was analyzed by comparing case 1 before baffle installation and case 2 - case 9 after baffle installation. Figure 5 shows the graph to compare baffle installation and no baffle installation for 190 measured flow velocity data and the overall flow dissipation trend showed that flow velocity decreased when the baffle were installed. For the case that the flow velocity increased after the baffles were installed, it is considered that a vortex occurred due to the side glass walls of waterway before the baffles were installed and flow velocity change occurred accordingly. Table 3 shows quantitative comparison of flow dissipation effects and it indicates the flow velocity (dimensionless) in the condition of baffle installation in comparison to the case of no baffle installation (case 1). For the flow dissipation effects, case 2, case 3 and case 4 showed 21.85%, 27.23% and 29.40% flow dissipation effects but the flow dissipation effect was less than 30%, so these cases were excluded (Table 2). As a result of analysis, the dissipation efficiency is inversely related since it is higher as the flow velocity is smaller after installation in comparison to before installation. Therefore, it is considered that case 9
Table 2. Maximum velocity and maximum depth on baffle arrangement type.
Table 3. Velocity after baffle installation.
has the highest flow velocity dissipation effect in comparison to the case of no baffle installation, and considering the number of baffles, case 6 was the low- cost and high efficiency case.
4. Conclusions
The flow dissipation effect from the arrangement types of energy dissipater in multiple directions was analyzed in this study in order to improve the scouring problem at the downstream of weirs combined with movable weirs and fixed weirs.
The maximum flow velocity at the downstream of the weir in Case 1 which was the case of no baffle installation was 2.068 m/s due to flow in multiple directions and crossing wave and since runoff flow was fast in the side walls of waterway, a vortex occurred on the left and right sides. Since the maximum water level did not encounter flow resistance, the water level was lower than the water level in the case that the baffles were installed. The maximum flow velocity at the downstream of weirs in case 2 - case 9 that were the cases of baffle installation decreased in comparison to the case of no baffle installation, and the maximum water level increased in comparison to the case of no baffle installation due to flow resistance.
As a result of analyzing the dissipation effects due to baffle arrangement, case 5 - case 9 showed the dissipation effect of 30% or higher and case 9 showed the highest flow velocity dissipation effect. Also, as a result of comparing the dissipation efficiency by considering the number of baffles, the “V-shaped” arrangement in case 6 could bring the most effective dissipation effect of flow velocity at the downstream with a less number of baffles when the number of baffles as shown in the experiment were installed.
The result of this study on the baffle installation and method for preventing scouring can be used as reference data for designing an energy dissipater in future. Also, the comparison between different number of baffles and relation analysis with the shape of baffle will be necessary additionally and the verification through full-scale experiment is also required.
Acknowledgements
This research was supported by the Internal Research Project (20160172-001) of the Korea Institute of Civil Engineering and Building Technology.