بررسی عددی توزیع سرعت در جریان بر روی سرریزهای جانبی مستطیلی

نوع مقاله : پژوهشی اصیل (کامل)

نویسندگان
امیرعلی محمدعلی پوراهری 1
عباس بختیاری ارکسی 2
محمدرضا جلیلی قاضی زاده 1
1 دانشگاه شهید بهشتی
2 کارشناسی ارشد
چکیده
سرریزهای جانبی، کاربردگسترده­ای در سیستم­های انتقال آب و فاضلاب دارند. جریان بر روی این سازه­ ها از نوع متغیر مکانی و سه بعدی است. برای تحلیل این جریان لازم است توزیع سرعت و مقادیر ضرایب تصحیح انرژی جنبشی (α) و اندازه حرکت (β) شناخته شده باشند اما پیچیدگی ­های موجود در این جریان از یک طرف و محدودیت­های آزمایشگاهی از طرف دیگر، باعث شده است تا توزیع سرعت در این نوع از جریان، کمتر مورد مطالعه قرار گیرد. در تحقیق حاضر توزیع سرعت در سرریز جانبی مستطیلی توسط نرم افزار FLOW-3D در دو حالت جریان زیر بحرانی و فوق بحرانی مورد بررسی قرار گرفته است. ابتدا صحت­ سنجی نرم ­افزار با استفاده از داده­ های آزمایشگاهی انجام شد. پس از اطمینان از عملکرد مدل عددی در تحلیل جریان، توزیع سرعت، ضرایب تصحیح انرژی جنبشی و اندازه حرکت و نواحی جداشدگی مورد مطالعه قرار گرفتند. براساس نتایج شبیه­ سازی موجود، روابط جدیدی بین ضرایب αوβ برای جریان زیربحرانی و فوق بحرانی ارائه شد و همچنین روابطی برای کمی ­سازی ناحیه جداشدگی، ارائه گردید. نتایج این تحقیق می­تواند به طراحان سرریزهای جانبی برای شناخت بهتر از جریان سه بعدی و پیچیده آن کمک نماید.

کلیدواژه‌ها

موضوعات

عنوان مقاله English

Numerical Study of the Flow Velocity Distribution over Rectangular Side Weirs

نویسندگان English

amirali mohamadalipourahari 1
abbas Bakhtiari arkasi 2
mohamadreza jalilighazizadeh 1
1 Master student of Shahid Beheshti University
2 Masters of Water
چکیده English

Side weirs are a type of hydraulic structures used for different purposes in water transition systems, water supply, flow diversion and flood control important. Side weir, is a key structure in transition of urban sewage; the advantage of this structure in urban sewage is the pre treatment of the diverted flow due to side weir height which is in environmental engineering. The flow on these structures is spatially varied flow type with decreasing discharge. Spatially varied flow is a type of steady flow with decreasing or increasing discharge along the channel. To analyze this flow, its necessary to know the velocity distribution and the values of the kinetic energy correction factor (α) and the momentum correction factor (β).However due to complexities concerned with this type of flow and experimental limitations there hasn't been enough study on the velocity distribution for this kind of flow . In this research the velocity distribution in a rectangular side weir has been investigated using a commercial software. Before performing the numerical analysis it's necessary to check the software's ability in modeling the 3D flow on the side weir. Experimental data of Jalili Ghazizadeh (1994) has been used for verification. In these experiments side weir lengths 20,30,45,75 (cm) and side weir heights 1, 10, 19 (cm) has been used while discharge in the main channel varied from 43 to 90 (lit/s). The simulation boundary conditions are volume flow rate discharge for upstream boundary,the "wall" for wall and "symmetry" boundary conditions for water surface. The only difference in boundary conditions for subcritical and supercritical flow is in downstream boundary condition which is "specified pressure" for supercritical flow and "specified velocity" for subcritical flow used respectively. Turbulence model is RNG in all simulations. Comparing the results shows that the software is capable of calculating the discharge passing the rectangular side weir with a good accuracy for both subcritical and supercritical flows. Therefore, based on obtained results we can conclude that the commercial software is capable of simulating 3D flow on rectangular side weir and the results obtained from performing analysis with this software can be cited. Velocity distribution, correction factors for kinetic energy and momentum were studied in detail . In the case of subcritical flow on the side weirs, water in the main channel and downstream area of the side weir has been observed to seperate in the opposite direction of the main channels, there for it is important to study these areas. A noticeable point is that although large amounts of simulation points have (α) and (β) close to one, simulation results show that (α) and (β) can not be considered equal to one for the whole cases. The variation of (α) and (β) in side weirs length in this research were ascending. Based on existing simulation results, new equation between (α) and (β) for subcritical and supercritical flow and quantification of separating area were proposed. Results of this research can help side weir designers to have a better understanding of the complex 3D flow on side weirs.


کلیدواژه‌ها English

Rectangular Side Weir
Energy Flux Correction Factor
Momentum Flux Correction Factor
separation zone
Numerical simulation
FLOW-3D software
Energy Correction Factor
Momentum Correction Factor
1. Chow,V.T.(1959).Open-channel hydraulics, McGraw-Hill, New York.
2. DeMarchi,G.(1934).“Theoretical knowledge on the functioning of side weir. ” L’Energia Elettrica, 11, 849–860 (in Italian).
3. Borghei, S. M., Jalili, M.R., Ghodsian, M., (1999).“Discharge coefficient for sharp crested side weirs in subcritical flow.” ASCE, Journal of Hydraulic Engineering; 125:10516.
4. Das,A.(1997). “Spatialy varied flow over an embankment side weir.”ASCE Journal of Irrigation and Drainage Engineering, 123(4), 314-317.
5. Ghodsian,M.(2004).“Flowovertriangular side weir.” ScientiaIranica,Vol. 11, No. 1&2, pp.114-120.
6. Kesshavarzi, A. and Fararooi, A. R. and Honar,T.(2001).“Hydraulic of flow over side weir in open-end and close-end conditions”. Irrig Sci.
7. Parhizgari,m.(2006).“Providedesign relationshipson rectangular lateral overflows in combined sewage pipes using laboratory results”.Master thesis, Power and water university of technology, Tehran, Iran "(In Persian)".
8. Ghodsian,M.(2003).“Supercritical flow over a rectangular side weir”. Can, Journal of Civil Engineering, Vol. 30, No. 3, pp. 596-600.
9. Swamee, P.K., Pathak, S.K., Mohan, M., and Ali, M.S.,(1994).“Side weir analysis using elementary discharge coefficient”.Journal of Irrigation and Drainage Engineering, ASCE, Vol. 120, No. 4.,pp. 742-755.
10. Ackers,p.(1957).“Atheoretical consideration of side weirs onstorm water over floes”.Proc, Institution of civil Engineers, London, England, 6, 305-328.
11. El-Khashab, A. M. M., (1975).“Hydraulics of flow over side-weirs”.Ph.D. thesis, Univ. of Southampton, Southampton, U.K.
12. El-Khashab,A.,Smith,K.V.H.,(1976) .“Experimental investigation of flow over side weirs.” ASCE Journal of Hydraulic Engineering; 102(9), 1255-1268.
13. Hager, W., (1982). Hydraulic of Distribution channels, Internationl Association for Hydraulic of Research 20th IAHR congress, vol.6, Moscow.
14. Tynes, K.A., (1989).“Hydraulics of side-channel weirs for regional detention basins”.M.SThesis,Dep.OfCivilEngineering, University of Texas, Austin, 128pp.
15. Venutelli, M., (2008).“Method of solution of nonuniform flow with the presence of rectangular side weir”.Journal of Irrigation and Drainage Engineering, ASCE, Vol. 134, No. 6, pp. 840-8.
16. Novak, G.“Steinman, F., and Muller, M., (2012). Study of velocity field at model Side weir using visualization method”. Journal of Hydraulic Research, Vol. 50, No. 1.,pp. 129-133.
17. Castro-Orgaz, O. and Hager, W.H.,(2012).“ Subcritical Side-Weir Flow at High Lateral Discharge”.JournalofHydraulic Engineering ,ASCE, Vol. 138, No. 9, pp. 777-787.
18. FLOW-3D Help, 2017, Ver 11.2.2, Flow science Inc.
19. JaliliGhazizadeh,M,(1994).“Laboratory examination of lateral overflows”.Master thesis, Sharif university of technology, Tehran, Iran "(In Persian)".
20. Michelazzo,G.Oumeraci,H.Paris,E.,(2017). “Laboratory Study on 3D Flow Structures Induced by Zero-Height Side Weir and Implications for 1D Modeling”.Journal of Hydraulic Engineering, 141(10).
مهندسی عمران مدرس
دوره 21، شماره 4
مهر و آبان 1400
صفحه 113-126