CFD Analysis of Sloshing in the Fuel Tank of a Heavy Vehicle with Emergency Braking System

ARSLAN, Turan Alp; BAYRAKÇEKEN, Hüseyin; YAVUZ, Hicri

doi:10.30939/ijastech..1360466

International Journal of Automotive Science and Technology

2023

DOI: 10.30939/ijastech..1360466

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CFD Analysis of Sloshing in the Fuel Tank of a Heavy Vehicle with Emergency Braking System

Turan Alp ARSLAN,

Hüseyin BAYRAKÇEKEN,

Hicri YAVUZ

Abstract: Liquid sloshing, which occurs in all accelerating and liquid-carrying vehicles, is of great importance, especially in the automotive and aerospace industries. Large-scale fluid sloshing causes both operational and safety problems in vehicles. In this study, the fuel tank of a heavy vehicle with an emergency braking system is designed in three dimensions, and liquid sloshing in the fuel tank is investigated by CFD analysis meth-od. VOF solution method, k-ԑ turbulence model, and PISO solution algorithm are used … Show more

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2024

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Cited by 2 publications

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Numerical Investigation of the Fuel Tank Sloshing Condition of a Commercial Vehicle

Yıldız,

Kibar,

Yiğit

2024

International Journal of Automotive Science and Technology

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This study investigates the impact of baffles on fuel sloshing behavior within truck fuel tanks using numerical simulations. The volume of the fluid multiphase model is employed to analyze the flow dynamics of 25% diesel fuel in a 250 L tank, modeled in a 3D domain. Two configurations were compared: a tank with baffles and one without. The primary focus is to analyze fuel distribution within the intake port region during vehicle acceleration and deceleration maneuvers. The simulated scenario mimics a realistic driving situation. The vehicle accelerates from 0 km/h to 60 km/h over 10 s, followed by a 3-s braking period to reach a complete stop (0 km/h) at the 13-s mark. The simulation then observes the fuel behavior within the tank for an addi-tional 7 s while the vehicle remains stationary. Results reveal significant differences in fuel behavior between baffled and unbaffled tanks. In the absence of baffles, the sloshing motion is substantial, leading to a complete depletion of fuel in the intake port region for a duration of 3 s during both the acceleration and deceleration phases (between 10 and 13 s). Compared to a standard tank, the presence of baffles significantly reduced the sloshing amplitude by approximately 70%. Furthermore, baffles led to a 50% decrease in pressure variations on the tank walls. Temporary fuel starvation can negatively impact engine performance and combustion efficiency. Conversely, the presence of baffles within the tank effectively mitigates sloshing and ensures continuous fuel presence at the intake port the entire simulation. This suggests that baffles play a crucial role in maintaining a stable and consistent fuel supply to the engine, even during dynamic vehicle maneuvers.

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Numerical Investigation of the Fuel Tank Sloshing Condition of a Commercial Vehicle

Yıldız,

Kibar,

Yiğit

2024

International Journal of Automotive Science and Technology

View full text Add to dashboard Cite

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Numerical Investigation of Flow Characteristics in Internally Flowing Pipes with Varying Roughness and Helical Angles of Vortex Generators

Tan,

Dede

2024

International Journal of Automotive Science and Technology

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In this study, the turbulent behavior inside a pipe containing an aluminum helical vortex generator plate was investigated using computational fluid dynamics (CFD) methods, considering different plate roughness and helical angle values. Accordingly, numerical analyses of velocity and pressure distributions for a liquid flow with a constant inlet velocity of 0.5 m/s and four different helical angles were performed and compared in a computer software. To observe the effects of the roughness values of the metal plate on flow behavior, analyses were conducted for three different roughness values for each helical angle and the results were compared and interpreted. As a result of the study, the combination of a roughness value of 0.04 and a helical angle of 0° led to the highest pressure and velocity values, while the same roughness value combined with a 270° helical angle resulted in the lowest pressure and velocity values. Detailed analysis showed that helical angles (90° and 180°) presented moderate pressure and velocity values, indicating a non-linear relationship between helical angle and flow characteristics. The results demonstrate that optimizing the helical angle and roughness is crucial for enhancing the efficiency of vortex generators. This way, a design will be developed to prevent performance degradation in industrial applications that require flow efficiency and pressure management.

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CFD Analysis of Sloshing in the Fuel Tank of a Heavy Vehicle with Emergency Braking System

Cited by 2 publications

References 39 publications

Numerical Investigation of the Fuel Tank Sloshing Condition of a Commercial Vehicle

Numerical Investigation of the Fuel Tank Sloshing Condition of a Commercial Vehicle

Numerical Investigation of Flow Characteristics in Internally Flowing Pipes with Varying Roughness and Helical Angles of Vortex Generators

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