Flow measurement

Flow measurement is the quantification of bulk fluid movement. Flow can be measured using devices called flowmeters in various ways. The common types of flowmeters with industrial applications are listed below: Obstruction type (differential pressure or variable area) Inferential (turbine type) Electromagnetic Positive-displacement flowmeters, which accumulate a fixed volume of fluid and then count the number of times the volume is filled to measure flow. Fluid dynamic (vortex shedding) Anemometer Ultrasonic flow meter Mass flow meter (Coriolis force). Flow measurement methods other than positive-displacement flowmeters rely on forces produced by the flowing stream as it overcomes a known constriction, to indirectly calculate flow. Flow may be measured by measuring the velocity of fluid over a known area. For very large flows, tracer methods may be used to deduce the flow rate from the change in concentration of a dye or radioisotope. Both gas and liquid flow can be measured in physical quantities of kind volumetric or mass flow rates, with units such as liters per second or kilograms per second, respectively. These measurements are related by the material's density. The density of a liquid is almost independent of conditions. This is not the case for gases, the densities of which depend greatly upon pressure, temperature and to a lesser extent, composition. When gases or liquids are transferred for their energy content, as in the sale of natural gas, the flow rate may also be expressed in terms of energy flow, such as gigajoule per hour or BTU per day. The energy flow rate is the volumetric flow rate multiplied by the energy content per unit volume or mass flow rate multiplied by the energy content per unit mass. Energy flow rate is usually derived from mass or volumetric flow rate by the use of a flow computer. In engineering contexts, the volumetric flow rate is usually given the symbol , and the mass flow rate, the symbol . For a fluid having density , mass and volumetric flow rates may be related by .

Ionic wind amplifier for energy-efficient air propulsion: Prototype design, development, and evaluation

Painting Taylor vortices with cellulose nanocrystals: Suspension flow supercritical spectral dynamics

Numerical Analysis of Apparatus-Induced Dispersion for Density-Dependent Solute Transport in Porous Media

Numerical Analysis of Apparatus-Induced Dispersion for Density-Dependent Solute Transport in Porous Media

Ionic wind amplifier for energy-efficient air propulsion: Prototype design, development, and evaluation

Painting Taylor vortices with cellulose nanocrystals: Suspension flow supercritical spectral dynamics