Experimental and Numerical Investigation of the Loss Coefficient of a 90° Pipe Bend for Power-Law Fluid

Bíbok, Máté; Csizmadia, Péter; Till, Sára

doi:10.3311/ppch.14346

Cited by 8 publications

(3 citation statements)

References 31 publications

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“…The number of fittings or bends in the pipeline is another element that affects head loss [52]. A straight-line pipeline will have less head loss than a pipeline with fittings or bends of the same length.…”

Section: Losses In Pipementioning

confidence: 99%

Evaluating the Pressure and Loss Behavior in Water Pipes Using Smart Mathematical Modelling

Altowayti

Othman

Tajarudin

et al. 2021

Water

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Due to the constant need to enhance water supply sources, water operators are searching for solutions to maintain water quality through leakage protection. The capability to monitor the day-to-day water supply management is one of the most significant operational challenges for water companies. These companies are looking for ways to predict how to improve their supply operations in order to remain competitive, given the rising demand. This work focuses on the mathematical modeling of water flow and losses through leak openings in the smart pipe system. The research introduces smart mathematical models that water companies may use to predict water flow, losses, and performance, thereby allowing issues and challenges to be effectively managed. So far, most of the modeling work in water operations has been based on empirical data rather than mathematically described process relationships, which is addressed in this study. Moreover, partial submersion had a power relationship, but a total immersion was more likely to have a linear power relationship. It was discovered in the experiment that the laminar flows had Reynolds numbers smaller than 2000. However, when testing with transitional flows, Reynolds numbers were in the range of 2000 to 4000. Furthermore, tests with turbulent flow revealed that the Reynolds number was more than 4000. Consequently, the main loss in a 30 mm diameter pipe was 0.25 m, whereas it was 0.01 m in a 20 mm diameter pipe. However, the fitting pipe had a minor loss of 0.005 m, whereas the bending pipe had a loss of 0.015 m. Consequently, mathematical models are required to describe, forecast, and regulate the complex relationships between water flow and losses, which is a concept that water supply companies are familiar with. Therefore, these models can assist in designing and operating water processes, allowing for improved day-to-day performance management.

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Section: Losses In Pipementioning

confidence: 99%

Evaluating the Pressure and Loss Behavior in Water Pipes Using Smart Mathematical Modelling

Altowayti

Othman

Tajarudin

et al. 2021

Water

View full text Add to dashboard Cite

show abstract

“…In recent years, Computational Fluid Dynamics (CFD) computations proved to be an accurate and affordable way of modelling industrial problems [23], and non-Newtonian flows [24][25][26]. Bartosik [27] modelled the turbulent flow of Herschel-Bulkley fluids in a smooth horizontal tube.…”

Section: Introductionmentioning

confidence: 99%

CFD-based Estimation of Friction Factor in Rough Pipes with Herschel-Bulkley Fluids

Csizmadia

Dombóvári

Till

et al. 2023

Period. Polytech. Chem. Eng.

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The appropriate estimation of frictional losses in a pipeline system is essential. So far, little attention has been paid to determining the friction factors with non-Newtonian fluids, especially in rough pipes. This study aims at calculating the friction factor using validated three-dimensional Computational Fluid Dynamics models in Ansys CFX. Steady-state computations are performed with three different incompressible Herschel-Bulkley fluids in rough pipes with relative roughness of the inner pipe surface ε = 0.0005 – 0.01. A power-law type bath gel as a test fluid is used for experiments to validate our numerical model. The numerical results are compared with the measured values and also with numerous existing friction factor estimation models with the help of generalization of the Reynolds number in the relevant engineering range of Regen = 100 – 40,000. This paper shows that the existing approximations can not accurately describe the friction factor with pseudoplastic fluids in rough pipes. On the contrary, in the case of Bingham plastic fluid, a new, explicit calculation relation is found in a unified form accepted by the literature.

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“…They reported that reverse flow was one of the major causes for the reduction in flow efficiency. Similarly, Bíbok et al (2020) postulated that low flow performance in curved open channels comes because of friction between the fluid and pipe internal surface, hydraulic head, and flow transition. However, mitigation means were not proposed in their work to curb the physics governing the reported reduction in flow efficiency.…”

Section: Introductionmentioning

confidence: 99%

Improving flow efficiency in curved pipes during multi-phase, immiscible fluid flow using edge-tailored guide vanes

Ejeh

Alawwa

Kofi

et al. 2021

Exp. Comput. Multiph. Flow

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High static pressure due to flow transitioning associated with recirculation, mixing, and separation around a pipe bend is a possible cause for a decrease in flow efficiency. This paper aims to use edge-tailored guide vanes to ease flow transition and improve flow efficiency, numerically. Here, flow efficiency serves the purpose for qualifying the effectiveness of the proposed technology.Sensitivity studies were performed on the influence of number of guide vane and guide vane thickness in a 45° pipe elbow. In setting up the numerical model for the assumed two-phase flow system (crude oil and water), the volume of fluid model was activated to model time-dependent fluctuations of each interacting phase volume fraction throughout the flow period. Furthermore, the improved delayed detached-eddy simulation turbulence model is employed to resolve the flow features in and outside the wall boundary layer. From the findings, an improvement in flow performance was witnessed using guide vanes. Furthermore, three thin and non-contacting guide vanes were strategically positioned at the center and towards the circumference of the pipe within the bend area, causing an increase in flow efficiency by 78.87%. In addition, the guide vanes played a significant role in limiting turbulence effect to effective flow of the primary phase.

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Experimental and Numerical Investigation of the Loss Coefficient of a 90° Pipe Bend for Power-Law Fluid

Cited by 8 publications

References 31 publications

Evaluating the Pressure and Loss Behavior in Water Pipes Using Smart Mathematical Modelling

Evaluating the Pressure and Loss Behavior in Water Pipes Using Smart Mathematical Modelling

CFD-based Estimation of Friction Factor in Rough Pipes with Herschel-Bulkley Fluids

Improving flow efficiency in curved pipes during multi-phase, immiscible fluid flow using edge-tailored guide vanes

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