The Development Study of the Drag Coefficient of Solid Cylinder on Inclined Plane in Water

Authors

  • Reza Ariefka STKIP Muhammadiyah OKU Timur, Sumatera Selatan 32382, Indonesia
  • Yudhiakto Pramudya Program Studi Magister Pendidikan Fisika, Universitas Ahmad Dahlan, Yogyakarta 55166, Indonesia

DOI:

https://doi.org/10.48048/tis.2022.6179

Keywords:

Drag coefficients, Rolling cylinder, Mass coefficients, Reynolds number, Logger pro

Abstract

The dynamic resistance of a fluid to a cylinder rolling on an inclined plane in water has been experimentally studied. This creates problems in the form of solid-liquid interactions, which include landslides on the seabed and debris flows on the seabed that cause Tsunamis. The development of flow around a rolling cylinder is described to highlight the implications on the nature of the hydrodynamic force coefficient acting on the cylinder as resistance. The coefficient of drag on the cylinder when rolling on an inclined plane in water is the coefficient of drag that prevents the cylinder from rolling. In addition, other external force coefficients (besides the drag coefficient) also impede the cylinder motion. The equation of motion of the cylinder is solved with experimental data which is used as the most suitable solution to get the drag coefficient value. The movement of the cylinder is also not perfectly linear because there is a force from the side of the track and the cylinder moves slightly zigzag in 1-D motion.

HIGHLIGHTS

  • In this study, we present the experimental results of cylindrical drag coefficients of various materials on inclined planes in water as modeling of broader scientific problems, especially the potential for hydrometeorological and sedimentation disasters
  • Fluid dynamics of the cylinder drag force on an inclined plane in water were measured experimentally
  • The motion of the cylinder on an inclined plane in water is recorded, then the recorded video is processed using Logger Pro to obtain experimental time, speed, and position data which is processed using the appropriate mathematical equations


GRAPHICAL ABSTRACT 

Downloads

Download data is not yet available.

References

RP Chhabra, M Kumar and P Rishitosh. Drag on spheres in rolling motion in inclined smooth tubes filled with incompressible liquids. Powder Tech. 2000; 113, 114-8.

R Clift, J Grace and ME Weber. Drops and particles. Academic, New York, 1978.

R Martino, A Paterson and MF Piva. Experimental and analytical study of themotion of a sphere falling along an inclined plane in still water. Powder Tech. 2015; 283, 227-33.

RP Chhabra. Bubbles, drops and particles, in non-newtonian fluids. CRC Press, Florida,1993.

RP Chhabra and JM Ferreira. An analytical study of the motion of a sphere rolling down a smooth inclined plane in an incompressible Newtonian fluid. Powder Tech. 1999; 104, 130-8.

B Zeinali and J Ghazanfarian. Turbulent flow over partially superhydrophobic underwater structures: The case of flow over sphere and step. Ocean Eng. 2020; 195, 106688.

EA Ashmawy. Wall effects on a rigid sphere moving perpendicular to a plane wall in a couple stress fluid filling a half-space. Eur. J. Mech. B Fluid 2019; 74, 380-8.

JT Jeong. Axisymmetric stokes flow around a sphere translating along the axis of a circular cylinder. Eur. J. Mech. B Fluid 2019; 77, 252-8.

G Mishra, SA Patel and RP Chhabra. Pulsatile flow of power-law fluids over a sphere: Momentum and heat transfer characteristics. Powder Tech. 2020; 360, 789-817.

TH Shehadeh and EA Ashmawy. Interaction of two rigid spheres translating collinearly in a couple stress fluid. Eur. J. Mech. B Fluid 2019; 78, 284-90.

Z Peng, K Galvin and E Doroodchi. Influence of inclined plates on flow characteristics of a liquid-solid fluidised bed: A CFD-DEM study. Powder Tech. 2019; 343, 170-84.

SS Tiwari, E Pal, S Bale, N Minocha, AW Patwardhan, K Nandakumar and JB Joshi. Flow past a single stationary sphere, 2. Regime mapping and effect of external disturbances. Powder Tech. 2020; 365, 215-43.

AT Sholagberu, MR Mustafa, KW Yusof and AM Hashim. Geostatistical based susceptibility mapping of soil erosion and optimization of its causative factors: a conceptual framework. J. Eng. Sci. Tech. 2017; 12, 2880-95.

GG Dogan, A Annunziato, R Hidayat, S Husrin, G Prasetya, W Kongko, A Zaytsev, E Pelinovsky, F Imamura and AC Yalciner. Numerical simulations of December 22, 2018 Anak Krakatau Tsunami and examination of possible submarine landslide scenarios. Pure Appl. Geophys. 2021; 178, 1-20.

T Zengaffinen, F Løvholt, GK Pedersen and A Muhari. Modelling 2018 Anak Krakatoa flank collapse and Tsunami: Effect of landslide failure mechanism and dynamics on Tsunami generation. Pure Appl. Geophys. 2020; 177, 2493-516.

Syamsidika, Benazira, M Umara, G Margaglio and A Fitrayansyaha. Post-tsunami survey of the 28 September 2018 tsunami near Palu Bay in Central Sulawesi, Indonesia: Impacts and challenges to coastal communities. Int. J. Disast. Risk Reduction 2019; 38, 101229.

J Wanga, SN Ward and L Xiaoa. Tsunami squares modeling of landslide generated impulsive waves and its application to the 1792 Unzen-Mayuyama mega-slide in Japan. Eng. Geol. 2019; 256, 121-37.

R Brackenridge, U Nicholson, B Sapiie, D Stow and DR Tappin. Indonesian throughflow as a preconditioning mechanism for submarine landslides in the Makassar Strait. Geol. Soc. Spec. Publ. 2020; 500, 195-217.

T Giachetti, R Paris, K Kelfoun and B Ontowirjo. Tsunami hazard related to a flank collapse of Anak Krakatau Volcano, Sunda Strait, Indonesia. Geol. Soc. Spec. Publ. 2012; 361, 79-90.

FD Traglia, T Nolesinia, L Solaria, A Ciampalini, W Frodella, D Steria, B Allotta, A Rindi, L Marini, N Monni, E Galardi and N Casaglia. Lava delta deformation as a proxy for submarine slope instability. Earth Planet. Sci. Lett. 2018; 488, 46-58.

J Karstens, C Berndt, M Urlaub, SFL Watt, A Micallef, M Ray, I Klaucke, S Muff, D Klaeschen, M Kühn, T Roth, C Böttner, B Schramm, J Elger and S Brune. From gradual spreading to catastrophic collapse-Reconstruction of the 1888 Ritter Island volcanic sector collapse from high-resolution 3D seismic data. Earth Planet. Sci. Lett. 2019; 517, 1-13.

M Carvajal, C Araya‐Cornejo, I Sepúlveda, D Melnick and JS Haase. Nearly instantaneous tsunamis following the MW 7.5 2018 Palu earthquake. Geophys. Res. Lett. 2019; 46, 5117-26.

H Takagi, MB Pratama, S Kurobe, M Esteban and R Aránguiz. Analysis of generation and arrival time of landslide tsunami to Palu City due to the 2018 Sulawesi Earthquake. Landslides 2019; 16, 983-91.

R Williams, P Rowley and MC Garthwaite. Reconstructing the Anak Krakatau flank collapse that caused the December 2018 Indonesian tsunami. Geology 2019; 47, 973-6.

A Perttu, C Caudron, D Assink J, D Metz, D Tailpied, B Perttu, C Hibert, D Nurfiani, C Pilger, M Muzli, D Fee, L Andersen O and B Taisne. Reconstruction of the 2018 tsunamigenic flank collapse and eruptive activity at Anak Krakatau based on eyewitness reports, seismo-acoustic and satellite observations. Earth Planet. Sci. Lett. 2020; 541, 116268.

S Viroulet, A Sauret and O Kimmoun. Tsunami generated by a granular collapse down a rough inclined plane. Europhys. Lett. 2014; 105, 34004.

R Delannay, A Valance, A Mangeney, O Roche and P Richard. Granular and particle-laden flows: From laboratory experiments to field observations. J. Phys. Appl. Phys. 2017; 50, 053001.

M Bursik, A Patra, EB Pitman, C Nichita, JL Macias, R Saucedo and O Girina. Advances in studies of dense volcanic granular flows. Rep. Progr. Phys. 2005; 68, 271-301.

S Abadie, J Harris, S Grilli and R Fabre. Numerical modeling of tsunami waves generated by the ank collapse of the Cumbre Vieja Volcano (La Palma, Canary Islands): Tsunami source and near field effects. J. Geophys. Res. 2012; 117, C05030.

L Verrucci, P Tommasi, D Boldini, A Graziani and T Rotonda. Modelling the instability phenomena on the NWflank of Stromboli Volcano (Italy) due to lateral dyke intrusion. J. Volcanol. Geoth. Res. 2019; 371, 245-62.

R Omira, GG Dogan, R Hidayat, S Husrin, G Prasetya, A Annunziato, C Proietti, P Probst, MA Paparo, M Wronna, A Zaytsev, P Pronin, A Giniyatullin, PS Putra, D Hartanto, G Ginanjar, W Kongko, E Pelinovsky and AC Yalciner. The September 28th, 2018, Tsunami in Palu-Sulawesi, Indonesia: A post-event field survey. Pure Appl. Geophys. 2019; 176, 1379-95.

HW Lewis. Calibration of rolling ball viscometer. Anal. Chem. 1953; 25, 507-8.

MS Medania and MA Hasan. Viscosity of organic liquids at elevated temperatures and the corresponding vapour pressures. Can. J. Chem. Eng. 1977; 55; 203-9.

MA Hasan. Wall effects on the motion of a rolling sphere in a closely fitting tube. Chem. Eng. J. 1986; 33, 97-101.

RJ Garde, S Sethuraman and LH Blanche. Variation of the drag coefficient of a sphere rolling along a boundary. Houille Blanche, La 1969; 7, 727-32.

R Ariefka and Y Pramudya. The study of hollow cylinder on inclined plane to determine the cylinder moment of inertia. J. Phys. Conf. 2019; 1170, 012081.

S Zhao, HC Schneider and M Kamlah. An experimental method to measure the friction coefficients between a round particle and a flat plate. Powder Tech. 2020; 361, 983-9.

SK Samantaray, BK Rout, SS Mohapatra and B Munshi. Newtonian flow past a hollow frustum in vertical and inclined plane: An experimental observation for terminal velocity and drag coefficient. Powder Tech. 2018; 326, 114-22.

EA Molaei, AB Yu and ZY Zhou. Particle scale modelling of mixing of ellipsoids and spheres in gas-fluidized beds by a modified drag correlation. Powder Tech. 2019; 343, 619-28.

EA Molaei, AB Yu and ZY Zhou. Particle scale modelling of solid flow characteristics in liquid fluidizations of ellipsoidal particles. Powder Tech. 2018; 338, 677-91.

AA Zaidi. Granular drag force during immersion in dry quicksand. Powder Tech. 2020; 364, 986-93.

C Béguin, S Étienne and MJ Pettigrew. Effect of dispersed phase fraction on the drag coefficient of a droplet or a bubble in an idealized two-phase flow. Eur. J. Mech. B Fluid. 2017; 65; 339-49.

S Chamoli, T Tang, P Yu and R Lu. Effect of shape modification on heat transfer and drag for fluid flow past a cam-shaped cylinder. Int. J. Heat Mass Tran. 2019; 131, 1147-63.

L Qingling, T Shouceng, S Zhonghou, X Zhengming and P Zhaoyu. A new equation for predicting settling velocity of solid spheres in fiber containing power-law fluids. Powder Tech. 2018; 329, 270-81.

D Zhang, S Hua, R Zhanga, X Jianga, C Zhanga, H Yina, C Wange and X Qub. Development of an explicit formula for predicting the drag coefficients of equiaxed dendrites. Comput. Mater. Sci. 2020; 172, 109319.

TR Jayawickrama, NEL Haugen, MU Babler, MA Chishty and K Umeki. The effect of Stefan flow on the drag coefficient of spherical particles in a gas flow. Int. J. Multiphas. Flow 2019; 117, 130-37.

A Jetly, IU Vakarelski, Z Yang and ST Thoroddsen. Giant drag reduction on Leidenfrost spheres evaluated from extended freefall trajectories. Exp. Therm. Fluid Sci. 2019; 102, 181-8.

H Jin, H Wang, Z Wu, Z Ren and Z Ou. Numerical investigation on drag coefficient and flow characteristics of two biomass spherical particles in supercritical water. Renew. Energ. 2019; 138, 11-7.

W Kim, H Lee, J Lee, D Jung and H Choi. Flow over a ski jumper in flight: Prediction of the aerodynamic force and flight posture with higher lift-to-drag ratio. J. Biomech. 2019; 89, 78-84.

VA Shuvalov, NB Gorev, NA Tokmak and YP Kuchugurnyi. Drag on a spacecraft produced by the interaction of its magnetic field with the Earth’s ionosphere. Physical modelling. Acta Astronautica 2019; 166, 41-51.

S Li, J Yang and Q Wang. Large eddy simulation of flow and heat transfer past two side-by-side spheres. Appl. Therm. Eng. 2017; 121, 810-9.

WRA Goossens. Review of the empirical correlations for the drag coefficient of rigid spheres. Powder Tech. 2019; 352, 350-9.

DJ Tritton. Physical fluid dynamics. Springer Dordrecht, New York, 1977.

CA Ramírez. Summary of frictional drag coefficient relationships for spheres: Evolving solution strategies applied to an old problem. Chem. Eng. Sci. 2017; 168, 339-43.

Y Chen and CR Müller. Development of a drag force correlation for assemblies of cubic particles: The effect of solid volume fraction and reynolds number. Chem. Eng. Sci. 2018; 192, 1157-66.

VD Sarli, E Danzi, L Marmo, R Sanchirico and AD Benedetto. CFD simulation of turbulent flow field, feeding and dispersion of non-spherical dust particles in the standard 20 L sphere. J. Loss Prev. Process Indust. 2019; 62, 103983.

F Marchelli, Q Hou, B Bosio, E Arato and A Yu. Comparison of different drag models in CFD-DEM simulations of spouted beds. Powder Tech. 2020; 360, 1253-70.

A Bahatmaka and DJ Kim. Numerical approach for the traditional fishing vessel analysis of resistance by cfd. J. Eng. Sci. Tech. 2019; 14, 207-17.

BHMA Mahmoud. Particle dispersion and deposition in simulant nuclear waste slurries using novel ultrasonic techniques. Master Thesis. University of Leeds, England.

Downloads

Published

2022-10-03

Issue

Vol. 19 No. 19 (2022): Trends in Sciences, Volume 19, Number 19, 1 October 2022

Section

Research Articles

License

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.