Radius
The variable that had the strongest effect on fluid flow would depend on the specific context and conditions of the flow system being analyzed. Variables such as pressure gradient, viscosity, and geometry of the system can all significantly influence fluid flow. More information would be needed to determine which variable had the strongest effect in a particular scenario.
Increasing the flow radius generally leads to an increase in flow rate, as there is more cross-sectional area for fluid to flow through. Conversely, decreasing the flow radius usually results in a decrease in flow rate due to the reduction in available space for fluid passage.
I have no opinion until I see the complete experimental set-up.
An irregular fluid flow refers to a fluid motion that is not consistent or smooth, characterized by fluctuations and turbulence in the flow pattern. It can be caused by factors such as obstacles in the fluid's path, changes in the flow velocity, or variations in fluid properties. Irregular fluid flow can affect the efficiency and performance of systems where fluids are involved, such as pipelines or aircraft wings.
That's more or less what fluid means: something that can flow.
Fluid flow can be controlled by adjusting parameters such as pressure, flow rate, and pipe size. Valves can also be used to regulate or stop the flow of fluid through a system. Additionally, controlling the temperature and viscosity of the fluid can influence its flow behavior.
I have no opinion until I see the complete experimental set-up.
no, it a flow variable
The flow rate of liquid from a dropper typically increases with higher liquid density. This is due to the increased weight of the liquid causing it to flow more quickly through the dropper. Conversely, lower density liquids flow more slowly from a dropper.
An irregular fluid flow refers to a fluid motion that is not consistent or smooth, characterized by fluctuations and turbulence in the flow pattern. It can be caused by factors such as obstacles in the fluid's path, changes in the flow velocity, or variations in fluid properties. Irregular fluid flow can affect the efficiency and performance of systems where fluids are involved, such as pipelines or aircraft wings.
It is a flow.
Flow
yes it is because of the instent cash flow of the variable flow of expenses.
Viscosity is the fluid property that measures its resistance to flow. It determines how easily a fluid can deform and flow. Fluids with high viscosity, like honey, flow more slowly than fluids with low viscosity, like water.
That's more or less what fluid means: something that can flow.
Flow meter categories based on fluid Some flow meters can be easily eliminated because they simply will not work with the application. For instance, electromagnetic flow meters will not work with hydrocarbons and require a conductive liquid to function. Many flow meters cannot measure gases or slurries. Listed below are some of the main flow meter categories paired with the fluid type the meters can handle. Gas – Coriolis Mass, Thermal Mass, Ultrasonic, Variable Area, Variable Differential Pressure, Positive Displacement, Turbine Liquid – Coriolis Mass, Thermal Mass, Ultrasonic, Variable Differential Pressure, Positive Displacement, Turbine, Electromagnetic Slurry – Coriolis Mass, some subsets of Variable Differential Pressure, Electromagnetic, Ultrasonic Vapour – Vortex, Ultrasonic, Diaphragm, Floating Element
A Rotameter is a device that measures the flow rate of liquid or gas in a closed tube. It is occasionally misspelled as "rotometer." It belongs to a class of meters called variable area meters, which measure flow rate by allowing the cross-sectional area the fluid travels through to vary, causing some measurable effect.
flow