Fig.2- Richard Dam overflow in America

FLOW-3D 수치 모델을 이용하여 미로 위어 평면도의 형상 변화가 유량 계수 증가에 미치는 영향 연구

E. Zamiri 1
, H. Karami 2*
and S. Farzin3
1- M.S. Student, Department of Civil Engineering, Semnan University, Semnan, Iran.
2
*

  • Corresponding Author, Assistant Professor, Department of Civil Engineering, Semnan
    University, Semnan, Iran. (hkarami@semnan.ac.ir).
    3- Assistant Professor, Department of Civil Engineering, Semnan University, Semnan, Iran.

Keywords: : Flood control, Sidewall angle, Predicting discharge coefficient, Computational hydraulic,

Introduction

Weirs are hydraulic structures used to measure, regulate and control the water levels and are
fixed upon open channels and rivers width. Growing magnitude of probable maximum flood
events (PMF) has highlighted the demand for increasing discharge capacity. Application of
labyrinth weir has been suggested as a solution for increasing discharge capacity.
Tullis et al. (1995) evaluated the effective parameters in determining the capacity of a labyrinth
weir. They introduced total head, the effective crest length and the discharge coefficient as
parameters influencing the discharge capacity of a labyrinth weir. Khode et al. (2011)
experimentally studied the parameters of a flow-over labyrinth weir for different side wall angles
(α) from 8 to 30°. They found that discharge coefficient increases by growing side wall angle
values.
Crookston and Tullis (2012a) studied performance of different labyrinth weirs by making
differences between geometric shapes of weirs in plan. The results indicated that discharge
capacity of the arced labyrinth weirs is more than the discharge capacity of horseshoe weirs.
Seo et al. (2016) investigated the effect of weir shapes on discharge of weirs. It was shown that
the discharge of the labyrinth weir had an increase of approximately 71% in comparison with the
linear ogee weir.
In this research, labyrinth weir with sidewall angle equal to 6° was simulated through Flow3D model, using experimental results of previous researchers. After validation, the changes of
discharge coefficient of weir with angles of 45° and 85° and apex shapes of triangular and halfcircular shapes were analyzed.

Weirs는 수위를 측정, 조절 및 제어하는 ​​데 사용되는 수력 구조물이며 열린 수로 및 강 폭에 고정됩니다. 예상되는 최대 홍수 사건 (PMF)의 규모가 커짐에 따라 배출 용량 증가에 대한 요구가 강조되었습니다. 미로 위어 (labyrinth weir)의 적용은 배출 용량을 증가시키기 위한 해결책으로 제안 되었습니다.

Tullis et al. (1995)는 미로 위어의 용량을 결정하는데 효과적인 매개 변수를 평가했습니다. 그들은 미로 위어의 배출 용량에 영향을 미치는 매개 변수로 총 수두, 유효 문장 길이 및 배출 계수를 도입했습니다.

Khode et al. (2011)은 8 ~ 30 °의 다양한 측벽 각도 (α)에 대한 유동-오버 래비 린스 위어의 매개 변수를 실험적으로 연구했습니다.

그들은 측벽 각도 값이 증가함에 따라 방전 계수가 증가한다는 것을 발견했습니다. Crookston과 Tullis (2012a)는 평면에서 위어의 기하학적 모양을 차이를 만들어 서로 다른 미로 위어의 성능을 연구했습니다.

결과는 호형 미로 위어의 배출 용량이 말굽 위어의 배출 용량보다 더 많다는 것을 나타냅니다. Seo et al. (2016)은 위어의 배출에 대한 위어 모양의 영향을 조사했습니다. 미로 위어의 배출량은 선형 오지 위어에 비해 약 71 % 증가한 것으로 나타났습니다.

이 연구에서는 이전 연구자들의 실험 결과를 사용하여 Flow3D 모델을 통해 측벽 각도가 6 ° 인 미로 위어를 시뮬레이션했습니다. 검증 후 각 45 °, 85 °의 위어의 배출 계수 변화와 삼각형 및 반원 형태의 정점 형태를 분석 하였다.

Fig.1- Schematic of trapezoidal, triangular, and rectangular congressional overflow
Fig.1- Schematic of trapezoidal, triangular, and rectangular congressional overflow
Fig.2- Richard Dam overflow in America
Fig.2- Richard Dam overflow in America
Fig.3- Plan of geometric parameters of congressional overflow
Fig.3- Plan of geometric parameters of congressional overflow
Fig. 4- The boundary conditions of the congressional overflow model
Fig. 4- The boundary conditions of the congressional overflow model
Fig.5- View of a simulated congressional overflow
Fig.5- View of a simulated congressional overflow
Fig. 6- Comparison of discharge coefficients resulted from numerical and experimental models
Fig. 6- Comparison of discharge coefficients resulted from numerical and experimental models
Fig.7- The relationship between Cd and Q for different angles of the congressional overflow wall
Fig.7- The relationship between Cd and Q for different angles of the congressional overflow wall
Fig. 8- The relationship between Cd and HT/p for different angles of the congressional overflow wall
Fig. 8- The relationship between Cd and HT/p for different angles of the congressional overflow wall
Table 3- The correlation of Q and HT/p with Cd for different angles of the overflow wall
Table 3- The correlation of Q and HT/p with Cd for different angles of the overflow wall
Fig. 9- The congressional overflow with linear, semicircular and triangular spans
Fig. 9- The congressional overflow with linear, semicircular and triangular spans
Fig. 10- The relationship between Cd and Q for different forms of congressional overflow
Fig. 10- The relationship between Cd and Q for different forms of congressional overflow
Fig. 11- The relationship of Cd and HT/p under different forms of congressional overflow
Fig. 11- The relationship of Cd and HT/p under different forms of congressional overflow
Fig. 12- The relationship Cd other/Cd simple and HT/p in a congressional overflow
Fig. 12- The relationship Cd other/Cd simple and HT/p in a congressional overflow
Fig. 13- Comparison of discharge coefficients resulted from a numerical model and proposed relation
Fig. 13- Comparison of discharge coefficients resulted from a numerical model and proposed relation
Fig. 14- Comparison of Cd from the present study and other studies for 6 angle congressional overflow
Fig. 14- Comparison of Cd from the present study and other studies for 6 angle congressional overflow
Fig. 15- The relationship between the discharge coefficient and HT/p for 6 ◦ angle congressional overflow
Fig. 15- The relationship between the discharge coefficient and HT/p for 6 ◦ angle congressional overflow

Results

오버행의 넘침 흐름을 증가시키는 것이 중요하기 때문에 본 연구에서는 넘침 벽의 돌출부에 6, 45 및 85 도의 세 가지 값을 채점하고 넘침 개구부에 삼각형 및 반원 모양을 제안함으로써 , 오버 플로우의 오버 플로우 계수를 변경하여 3D 숫자 래치를 사용하십시오.

Irene Par Vahsh Bareh에서 얻은 결과는 다음과 같습니다.

1- 흐름을 따라 포병의 범람 벽 각도를 늘리면 방출 계수가 증가합니다. 벽 각도가 85도 및 45 도인 포병의 범람 계수는 벽 각도가 6 도인 범람 계수 평균의 2.28 및 1.24 배입니다.

2-구부러진 양고기를 먹은 상태에서 배수로 모양의 변화는 배출 계수를 증가시킨다. 삼각형과 비 삼각형 개구부가있는 오버플로의 배출 계수는 온대 개구부가있는 오버플로의 배출 계수에 비해 양고기가 50.29 및 4.16 % 증가했습니다.

3- 오버플로 양 (p / HT)의 부하와 함께 부하 부하의 무 차원 비율 값을 늘리면 혼잡 한 오버플로의 방전 계수가 감소합니다. 또한 p <HT / 0.5의 값에서 세 가지 형태의 오버플로 개구에 대한 배출 계수의 값은 서로 가깝고 오버플로 모양의 각 끝은 값에서 동일한 기능을 갖습니다. p / HT <0.5. 4-유량이 증가함에 따라 유량 계수가 감소합니다.

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