0 Contact Us

Flow Behavior on Elbow with Various Geometries of Nozzle

0*, M. Akhil Yuvaraj**
* Associate Professor, Department of Mechanical Engineering, Pragati Engineering College, Andhra Pradesh, India.
** UG Scholar, Department of Mechanical Engineering, Pragati Engineering College, Andhra Pradesh, India.
Periodicity:February - April'2019
DOI : https://doi.org/10.26634/jme.9.2.15851

Abstract

Elbow is one of the most common components in the pipe line system, where pressure difference occurs as a fluid flow.Due to the pressure difference, centrifugal force is developed. For this reason, the behaviour of the fluid flow in a 90° elbow for different geometries of nozzle have been studied using the FLUENT software. Ten different models were investigated based on the K-ɛ model of the energy equation. The analysis was simulated in terms of the velocity and pressure contours and comparison is done. The analysis has been done for 10 different models with changing the angle of convergence from 0° to 90° and found that the velocity gradients are increasing and pressure gradients are decreasing in an ascending order of the angles of convergence for nozzle geometry. The software values are compared to the regression values and found to yield good agreement with the simulated values.

Keywords

 k- Energy Equation, Fluent Software, 90° Elbows.

How to Cite this Article?

 Satish, G., and Yuvaraj, M. A. (2019). Flow Behavior on Elbow with Various Geometries of Nozzle. i-manager’s Journal on Mechanical Engineering, 9(2), 43-51. https://doi.org/10.26634/jme.9.2.15851

References
[1]. Adjei, R., & Mohsin, A. (2014). Simulation-driven design o optimization: A case study on a double 90 elbow bend. International Journal of Modeling and Optimization, 4(6), 426-432.
[2]. Crawford, N., Spence, S., Simpson, A., & Cunningham, G. (2009). A numerical investigation of the flow structures and losses for turbulent flow in 90o elbow bends. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 223(1), 27-44. DOI https://doi.org/10.1243/09544089JPME206
[3]. Homicz, G. F. (2004). Computational fluid dynamic simulations of pipe elbow flow (Technical Report). USA. DOI https:/doi.org/10.2172/919140
[4]. Kuan, B. T. (2005). CFD simulation of dilute gas-solid two-phase flows with different solid size distributions in a curved 90° duct bend. The Australian and New Zealand Industrial and Applied Mathematics Journal, 46, C744- C763. DOI https://doi.org/10.21914/anziamj.v46i0.988
[5]. Kumar, R. S., & Pentakota, A. K. (2017). Computational fluid dynamics simulations of pipe elbow flow. International Journal of Professional Engineering Studies, 9(2), 1-10.
[6]. Lu, X. Y., Zhou, Q. T., Huang, L. L., & Liu, J. M. (2013). Numerical simulation and parameter optimization of hot pushing elbow pipe bending process. Applied Mechanics and Materials, 432, 92-97. DOI https://doi.org/10.4028/ www.scientific.net/AMM.432.92
[7]. Mekhail, T. A., Aissa, W. A., Hassanein, S. A., & Hamdy, o O. (2011). CFD simulation of dilute gassolid flow in 90 square bend. Energy and power engineering, 3(3), 246- 252. DOI https://doi.org/10.4236/epe.2011.33031
[8]. Satish, G., Prasad, S. S., & Prasad, V. V. S. (2018). Experimental Studies on Mechanical Properties of Polymer Based Composites. i-manager's Journal on Mechanical Engineering, 8(4), 1-7.
[9]. Satish, G., Prasad, V. V. S., & Ramji, K. (2017a). Impact Carbon Nanotubes on Polymer Nano Composites. International Journal of Advanced Research in Basic Engineering Sciences and Technology (IJARBEST), 3(6), 46- 60.
[10]. Satish, G., Prasad, V. V. S., & Ramji, K. (2017). Manufacturing and characterization of CNT based polymer composites. Mathematical Models in Engineering, 3(2), 89-97. DOI https://doi.org/10.21595/ mme.2017.19121
[11]. Satish, G., Prasad, V. V. S., & Ramji, K. (2018). Effect on Mechanical Properties of Carbon Nanotube Based Hybrid Composites. Materials Today-Elsevier, 5(2), 7725–7734.
[12]. Sener, B. (2016). Parametric design of a surface combatant for simulation-driven design and hydrodynamic optimization. International Journal of Mechanical and Production Engineering, 4(12),125-129. Retrieved from http://www.iraj.in/journal/journal_ file/journal_pdf/2-324-1485753451125-129.pdf
[13]. Wang, L., Gao, D., & Zhang, Y. (2012). Numerical simulation of turbulent flow of hydraulic oil through 90° circular-sectional bend. Chinese Journal of Mechanical Engineering, 25(5), 905-910.
[14]. Yang, W., & Kuan, B. (2006). Experimental investigation of dilute turbulent particulate flow inside a o curved 90 bend. Chemical Engineering Science, 61(11), 3593-3601. DOI https://doi.org/10.1016/j.ces.2006.01.013
If you have access to this article please login to view the article or kindly login to purchase the article

Purchase Instant Access

Single Article

North Americas,UK,
Middle East,Europe 		India Rest of world
USD EUR INR USD-ROW
Pdf 35 35 200 20
Online 35 35 200 15
Pdf & Online 35 35 400 25
ADD TO CART

Options for accessing this content:
  • If you would like institutional access to this content, please recommend the title to your librarian.
    Library Recommendation Form
  • If you already have i-manager's user account: Login above and proceed to purchase the article.
  • New Users: Please register, then proceed to purchase the article.
Submit New Paper Track Paper Status Buy Journal Track Your Subscription Journal Archive
Authors Institutions/Librarians Agents Conferences
About Us Careers Contact FAQ Terms and Conditions Privacy Policy Refund & cancellation Policy