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"This collection is dedicated to the 70th jubilee of Yu. N. Savchenko, and presents experimental, theoretical, and numerical investigations written by an international group of well-known authors. The contributions solve very important problems of the high-speed hydrodynamics,such as supersonic motion in water, drag diminishing, dynamics and stability of supercavitating vehicles, water entry and hydrodynamic performances of hydrofoils, ventilated cavities after a disc and under the ship bottom. "

"The book provides an easy way to understand the fundamentals of heat transfer. The reader will acquire the ability to design and analyze heat exchangers. Without extensive derivation of the fundamentals, the latest correlations for heat transfer coefficients and their application are discussed. The following topics are presented, steady state and transient heat conduction, free and forced convection, finned surfaces, condensation and boiling, radiation, heat exchanger design, problem-solving. After introducing the basic terminology, the reader is made familiar with the different mechanisms of heat transfer. Their practical application is demonstrated in examples, which are available in the Internet as MathCad files for further use. Tables of material properties and formulas for their use in programs are included in the appendix. "

"This book is the most comprehensive review of high-resolution schemes based on the principle of Flux-Corrected Transport (FCT). Book describe the development of the classical FCT methodology for convection-dominated transport problems, while the design philosophy behind modern FCT schemes is explained by S.T. Zalesak. The subsequent chapters present various improvements and generalizations proposed over the past three decades. In this new edition, recent results are integrated into existing chapters in order to describe significant advances since the publication of the first edition. Also, 3 new chapters were added in order to cover the following topics, algebraic flux correction for finite elements, iterative and linearized FCT schemes, TVD-like flux limiters, acceleration of explicit and implicit solvers, mesh adaptation, failsafe limiting for systems of conservation laws, flux-corrected interpolation (remapping), positivity preservation in RANS turbulence models, and the use of FCT as an implicit subgrid scale model for large eddy simulations."

"Fluid mechanics and thermodynamics of turbomachinery is the leading turbomachinery book due to its balanced coverage of theory and application. Starting with background principles in fluid mechanics and thermodynamics, the authors go on to discuss axial flow turbines and compressors, centrifugal pumps, fans, and compressors, and radial flow gas turbines, hydraulic turbines, and wind turbines. In this new edition,more coverage is devoted to modern approaches to analysis and design, including CFD and FEA techniques. Used as a core text in senior undergraduate and graduate level courses this book will also appeal to professional engineers in the aerospace, global power, oil & gas and other industries who are involved in the design and operation of turbomachines."

"Flow control and optimization has been an important part of experimental flow science throughout the last century. As research in computational fluid dynamics (CFD) matured, CFD codes were routinely used for the simulation of fluid flows. Subsequently, mathematicians and engineers began examining the use of CFD algorithms and codes for optimization and control problems for fluid flows. The marriage of mature CFD methodologies with state-of-the-art optimization methods has become the center of activity in computational flow control and optimization.Perspectives in Flow Control and Optimization presents flow control and optimization as a subdiscipline of computational mathematics and computational engineering. It introduces the development and analysis of several approaches for solving flow control and optimization problems through the use of modern CFD and optimization methods. The author discusses many of the issues that arise in the practical implementation of algorithms for flow control and optimization, such as choices to be made and difficulties to overcome. He provides the reader with a clear idea of what types of flow control and optimization problems can be solved, how to develop effective algorithms for solving such problems, and potential problems to be aware of when implementing the algorithms.This book is written for both those new to the field of control and optimization as well as experienced practitioners, including engineers, applied mathematicians, and scientists interested in computational methods for flow control and optimization. Both those interested in developing new algorithms and those interested in the application of existing algorithms should find useful information in this book."

"The emergence of complex enhanced recovery procedures in the field of hydrocarbon extraction techniques has emphasized the need for sophisticated mathematical tools, capable of modeling intricate chemical and physical phenomena and sharply changing fluid interfaces. This volume explains which problems need to be addressed, why they are difficult, what has been done previously to treat these difficulties, and which new techniques appear to possess potential for obtaining good simulation results."

"ABSTRAKMikroalga menghasilkan biomassa yang digunakan sebagai salah satu sumber energi terbarukan. Budidaya mikroalga dilakukan pada suatu wadah tertutup yang disebut sebagai fotobioreaktor. Penggunaan fotobioreaktor berguna untuk mengatur parameter-parameter yang berpengaruh pada pertumbuhan mikroalga dan mengurangi kemungkinan terjadinya kontaminasi. Fotobioreaktor yang optimal dibutuhkan untuk mendapatkan pertumbuhan mikroalga yang baik. Simulasi CFD merupakan cara yang butuh biaya sedikit untuk memprediksi pertumbuhan mikroalga pada macam-macam kondisi lingkungan. Fotobioreaktor berbentuk rectangular airlift dengan mikrolaga Synechococcus sp. HS-9 disimulasikan terhadap penggunaan baffle horizontal dengan berbagai konfigurasi. Penelitian ini bertujuan untuk mengetahui konfigurasi yang optimal sehingga mixing dan pertumbuhan mikroalga yang baik dapat tercapai. ANSYS Fluent digunakan untuk menyelesaikan CFD. User-defined functions digunakan untuk mengintegrasikan persamaan pertumbuhan kinetic mikroalga ke model tiga dimensi fotobioreaktor. Hasil simulasi pertumbuhan mikroalga diperoleh terhadap posisi dan waktu di dalam fotobioreaktor selama beberapa hari. Sedimentasi dan self-shading dapat menghambat pertumbuhan mikroalga, oleh karena itu dibutuhkan mixing yang baik. Fotobioreaktor denagn horizontal baffle dapat mengkarakterisasi mixing lebih baik dibandingkan dengan fotobioreaktor tanpa baffle.

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ABSTRACTMicroalgae produce biomass used as one of the renewable energy sources. Microalgae cultivation is done in a closed container called photobioreactor. The utilization of photobioreactor is meant to control some parameters affecting microalgae growth and reduce the possibility of contamination. The optimal photobioreactor is required to obtain the best microalgae growth. CFD simulation is a cost-effective way to predict microalgae growth under various environmental conditions. Rectangular airlift shaped photobioreactor with Synechococcus sp. HS-9 microalgae are simulated for the application of horizontal baffle with a different configuration. This research is proposed to get insights on the optimal configuration so that the mixing and good microalgae growth can be achieved. ANSYS Fluent is used to solve the CFD model. User-defined functions were used to integrate the microalgae kinetic equations into three-dimensional photobioreactor. Microalgae growth simulation results are obtained dependently over space and time within photobioreactor for several days. Biomass sedimentation and self-shading might inhibit microalgae growth, therefore, good mixing is needed. Photobioreactor with horizontal baffle characterize mixing better than photobioreactor without baffle.

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"Pada tahun 2030 Perserikatan Bangsa-Bangsa (PBB) memiliki target untuk semua negara agar mencapai angka kematian bayi hingga paling rendah 12 per 1000 kelahiran hidup, sedangkan Indonesia pada tahun 2015 memiliki angka kematian bayi 14,3 per 1000 kelahiran hidup. Inkubator Grashof adalah peralatan medis untuk menolong bayi prematur di Indonesia yang dapat menekan angka kematian tersebut. Tujuan dari penelitian ini adalah menganalisa aliran udara dan perpindahan kalor yang terjadi antara bayi dengan lingkungan sekitar di dalam inkubator. Kalor metabolisme yang hilang pada bayi, karena aktivitas penguapan melalui jaringan kulit dan sistem pernapasan, diperhitungkan agar hasil yang didapatkan mendekati kondisi aktual. Besar kalor yang dihasilkan dan kerugian panas yang dialami bayi didapatkan dari penelitian sebelumnya (Ginalski et al., 2007)dan temperatur ambien inkubator adalah 25 oC, 28 oC dan 31 oC. Kemudian data yang diperoleh berupa kontur pada bidang-bidang yang menggambarkan aliran udara di dalam inkubator. Perhitungan numerikal dilakukan dengan metode computational fluid dynamics (CFD) menggunakan ANSYS CFX. Hasil yang didapatkan akan dibandingkan dengan hasil eksperimental yang telah ada.

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In 2030 the United Nations (UN) has a target for all countries to reach the lowest neonatal mortality rate of 12 per 1000 live births, while Indonesia had a neonatal mortality rate 14,3 per 1000 live births by 2015. The Grashof Incubator is medical equipment to help preterm infant in Indonesia that can reduce the mortality rate. The main objective of this study is to analyze the air flow and heat transfer that occurs between the baby and the surrounding environment inside the incubator. The metabolic heat loss in infants, due to evaporation activity through the skin and respiratory system, is calculated so that the results obtained are close to the actual conditions. The amount of heat generated and heat loss experienced by infants was obtained from previous studies (Ginalski et al., 2007)and the ambient temperature of the incubator was 25 oC, 28 oC and 31 oC. Then the data obtained in the form of contours in the fields that describe the flow of air in the incubator. Numerical calculations have been performed using the computational fluid dynamics (CFD) using ANSYS CFX. The results obtained were compared with existing experimental results.

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"A hybrid vertical take-off landing (VTOL) UAV combines the concepts of fixed-wing and rotary-wing UAV aircraft in one platform while performing in both conventional and vertical take-off landings. This aircraft has a drawback of significant drag force generated due to fixed-wing. Therefore, a Tilt-Wing often utilized to overcome this obstacle whereby it could be adjusted to the vertical and horizontal directions. To enhance the understanding of generated drag force on both wing model, this study was performed by examine the drag characteristic of the VTOL UAV. The simulations were carried out in the wind speed range by 1.4 m/s, 4.17 m/s, and 6.94 m/s. Simulation results showed that the drag of the UAV Hybrid Tilt-Wing and Fixed-Wing increased at the speed of 1.4 m/s to 6.94 m/s while the highest drag value was 177.51 N on a Fixed-Wing UAV aircraft and 1.97 N on a Tilt-Wing UAV aircraft. The result concluded that Tilt-Wing UAV has less drag which was more efficient than fixed-wing."