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International Meeting on Fluid Dynamics & Fluid Mechanics, will be organized around the theme “”

Fluid Dynamics 2020 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Fluid Dynamics 2020

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Fluid Mechanics is the division of physics that studies fluids (liquids, gases, and plasmas) along with the forces on them. It can be divided into fluid statics which studies about the fluids at rest; fluid kinematics which studies about the fluids in motion and fluid dynamics which studies about the effect of forces on fluid motion. It is likewise a part of continuum mechanics, a subject which models matter without utilizing the facts that it is made out of atoms, that is, it demonstrates matter from a plainly visible perspective instead of from an infinitesimal perspective.

  • Track 1-1Compressible Flow
  • Track 1-2Dimensional Analysis
  • Track 1-3Viscous Flow
  • Track 1-4Laminar and Turblent Flows
  • Track 1-5Continuum Hypothesis
  • Track 1-6Surface Tension

Fluid dynamics is a part of fluid mechanics that defines the flow of fluids - liquids and gases. It has several sub disciplines, including aerodynamics which studies about the air and other gases in motion and hydrodynamics which studies about the liquids in motion. It has a different variety of applications which includes calculating forces and moments on aircraft, determining the mass flow rate of petroleum through pipelines, predicting weather patterns and understanding nebulae in interstellar space.

  • Track 2-1Stream Function
  • Track 2-2Fluid Machinery
  • Track 2-3Motion of Cylinders
  • Track 2-4Aerofoil Theory
  • Track 2-5Bernoulis Theorem and Poiseuilles Law
  • Track 2-6Vortex Motion

Hydraulics is disturbed with the realistic applications of fluids, primarily liquids in motion. It is linked to fluid mechanics, which in large part delivers its theoretical foundation. It deals with such matters as the flow of liquids in pipes, rivers, channels and their confinement by dams and tanks. Some of its considerations apply also to gases, usually in cases where the variations in density are moderately small. Thus, the possibility of hydraulics spreads to such mechanical devices as fans, gas turbines and to pneumatic control systems.

  • Track 3-1Computational hydraulics
  • Track 3-2Hydraulic Transients
  • Track 3-3Hydrostatics
  • Track 3-4Compressor, Actuators & Receiver
  • Track 3-5Process Control pneumatics

CFD is a division of fluid mechanics that uses numerical study and information structures to resolve and evaluate problems that involve fluid flows, are used to perform the calculations essential to pretend the collaboration of liquids and gases with surfaces characterized by limit conditions. Initial investigational authentication of such software is prepared using a wind tunnel with the final authentication coming in full-scale testing, e.g. flight tests.

  • Track 4-1Discretization Method
  • Track 4-2Continuity Equation
  • Track 4-3CFD Technologies & Analysis
  • Track 4-4Computational Grids
  • Track 4-5FDV Equations
  • Track 4-6Numerical Stability

Heat transfer is a modification of thermal engineering that concerns the generation, use, conversion and interchange of thermal energy (heat) among physical systems. It is classified into several mechanisms such as thermal conduction, thermal convection, thermal radiation and transfer of energy by phase changes. Mass transfer is the net measure of mass from one location to another usually meaning stream, phase, fraction or component. It occurs in various procedures such as absorption, evaporation, drying, precipitation, membrane filtration and distillation.

  • Track 5-1Heat Exchanger
  • Track 5-2Laws of thermodynamics
  • Track 5-3Homogeneous chemical reactions
  • Track 5-4Convective Heat & Mass transfer
  • Track 5-5Mass Transfer in biotechnology
  • Track 5-6Astrophysical MHD

Magneto hydrodynamics (MHD), it is also known as magneto-fluid dynamics or hydro magnetics. It is the study of the magnetic properties and performance of electrically conducting fluids. Plasmas, liquid metals, salt water and electrolytes are some of the examples of such magneto fluids.

 

  • Track 6-1Magnetostatic Equilibria
  • Track 6-2Plasma Physical preliminaries
  • Track 6-3MHD Waves & Characteristics
  • Track 6-4Computational nonlinear MHD

It may be considered as the modification of biological engineering or biomedical engineering in which the essential ideologies of fluid dynamics are used to enlighten the mechanisms of biological flows and their interrelationships with functional processes, in health & in diseases/disorder. It intervals from cells to organs, covering diverse features of the functionality of systemic physiology, including cardiovascular, respiratory, reproductive, urinary, musculoskeletal and neurological systems etc.

  • Track 7-1Conservation Laws
  • Track 7-2Cardiovascular fluid dynamics
  • Track 7-3Distributed Control Systems
  • Track 7-4Humanoid robots, service robots
  • Track 7-5Aneurysms

It is a computer model method for studying the physical activities of atoms and molecules. The atoms and molecules are acceptable to cooperate for a fixed period of time, giving a view of the dynamic growth of the system. In the most common type, the paths of atoms and molecules are determined by mathematically solving Newton's equations of motion for a system of interrelating particles, where forces among the particles and their potential energies are frequently considered using interatomic potentials or molecular mechanics force fields.

  • Track 8-1Molecular Simulation
  • Track 8-2Quantum Methods
  • Track 8-3NMR Structures
  • Track 8-4Electrostatic Energy
  • Track 8-5Statistical Mechanical Foundations
  • Track 8-6Monte Carlo Technique
  • Track 8-7Heat Exchangers

Aerospace is the social strength in science, engineering and business to hang in the atmosphere of Earth (aeronautics) and surrounding space (astronautics). These organizations research, design, manufacture, operate or maintain aircraft or spacecraft. It’s movement is very miscellaneous, with a gathering of commercial, industrial and military applications.

  • Track 9-1Aerospace Components
  • Track 9-2MEMS Angular rate Sensors
  • Track 9-3Aerodynamic Heating
  • Track 9-4Advanced Nanomaterials
  • Track 9-5Natural/Synthetic Hybrid Components

Turbine is a device that transforms the energy in a stream of fluid into mechanical energy. The conversion is usually accomplished by transient the fluid through an arrangement of stationary passages or vanes that substitute with passages containing of finlike blades devoted to a rotor. Turbine also converts rotational energy from a fluid that is picked up by a rotor system into usable work or energy.

  • Track 10-1Pelton Wheel
  • Track 10-2Francis & Kaplan Turbine
  • Track 10-3Steam, Water & Radient turbines
  • Track 10-4Gas turbine
  • Track 10-5Turboshaft

Microfluidics is the study of precise control and manipulation of fluids that are geometrically constrained to a small, normally sub millimetre, range. It has application in various fields like engineering, physics, chemistry, biochemistry, nanotechnology and biotechnology, from real applications to the plan of systems in which little volumes of fluids are used to attain multiplexing, automation etc. It has appeared in the beginning of the 1980s and is used in the expansion of inkjet print heads, DNA chips, lab-on-a-chip technology, micro-propulsion and micro-thermal technologies.

 

  • Track 11-1Thermal Flow Sensors
  • Track 11-2Electrowetting Theory
  • Track 11-3Cellular biophysics
  • Track 11-4Acoustic droplet ejection (ADE)
  • Track 11-5Electroosmotic Flows
  • Track 11-6Microfluidic Devices

In continuum mechanics, the Newtonian fluid is a fluid in which the viscid pressures arising from its flow, at each point, are linearly comparative to the local strain rate—the rate of change of its distortion over time. A non-Newtonian fluid is a fluid that does not track Newton's law of viscosity. Generally, the viscidness (the gradual deformation by shear or tensile stresses) of non-Newtonian fluids is reliant on shear rate or shear rate history. Approximately non-Newtonian fluids with shear-independent viscosity, display regular stress-differences or other non-Newtonian performance.

  • Track 12-1Plasmas in Magnetic fields
  • Track 12-2Nucleation
  • Track 12-3Bubble Dynamics
  • Track 12-4Hydrodynamic Cavitation
  • Track 12-5Flow Phenomena
  • Track 12-6Material Functions

It is the quantification of majority fluid movement. Flow can be measured in a diversity of ways. Positive-displacement flow meters gather a static volume of fluid and then tally the number of times the volume is occupied to measure flow. Other flow measurement systems rely on forces formed by the flowing stream as it overwhelms a known constriction, to calculate the flow indirectly.

  • Track 13-1Pressure Measurement
  • Track 13-2Velocity Measurement
  • Track 13-3Vorticity stream function
  • Track 13-4Signal to Noise Ratio Effects
  • Track 13-5Signal Processors
  • Track 13-6Flow Conditioning Devices
  • Track 13-7Conductivity of Insulator & Superlattices

It is denoted as k, λ, or κ & it is the property of a material to conduct heat. It is evaluated mainly in terms of Fourier's Law for heat conduction. Heat transfer arises at a lower rate in resources of low thermal conductivity than in resources of high thermal conductivity. Consistently, materials of high thermal conductivity are broadly used in heat sink applications and materials of low thermal conductivity are mainly used as thermal insulation. The temperature of a material depends upon the thermal conductivity. Thermal resistivity is the reciprocal of thermal conductivity.

  • Track 14-1Insulation & Modelling
  • Track 14-2Conductivity Materials
  • Track 14-3Semiconductors & Thermoelectric Materials
  • Track 14-4Emerging Materials
  • Track 14-5Thermal Properties & Applications

Aeroacoustics is a division of acoustics that studies noise generation by means of either turbulent fluid motion or aerodynamic forces relating with surfaces. Noise generation can also be connected with intermittently varying flows. A prominent example of this phenomenon is the Aeolian tones formed by wind blowing over fixed objects.

  • Track 15-1Computational Aero acoustics
  • Track 15-2Linear Acoustics
  • Track 15-3Aeroelasticity of Turbomachines
  • Track 15-4Fluid Acoustics
  • Track 15-5Aero-acoustic analogies

It is an interdisciplinary journal dedicated to the publication of simple and accurate studies approximately relating to normal fluid systems mainly as agents for the passage and distribution of environmental contamination.

 

 

  • Track 16-1Continnum Mechanics
  • Track 16-2Surface Waves
  • Track 16-3Hydrstatic Pressure
  • Track 16-4Numerical Methods
  • Track 16-5Mass, Energy & Momentum Conservation