Yes, that is when Bernoulli applies.tonyjk said:thank you.. so the pressure of the fluid is doing work(internal energy let's say) on the fluid right?
rcgldr said:Where Bernoulli doesn't apply is in the case where external work is done on a flow. For example, in the immediate vicinity of a propeller, there's a pressure jump with little or ideally, no change in speed. This the area where work is performed by the propeller, which violates Bernoulli. However Bernoulli does apply to the flow fore and aft of the propeller, assuming no other external forces are involved.
boneh3ad said:Bernoulli's equation also does not apply to unsteady flows, compressible flows or flows with dissipative phenomena such as viscosity. Those are part of the assumptions used in the derivation of the equation.
Yes, these are often called "unsteady bernoulli" for unsteady flow, "compressible bernoulli" for compressible flow, or "extended bernoulli" for viscous flow. Or there is even a version of the same form that doesn't need to be applied along streamlines if your flow is irrotational.arildno said:For steady, non-dissipative flows with a steady state relation between pressure and density, say in form of a power-law, Bernoulli-like equations may readily be derived for such compresible cases.
they even have their uses.
Bernoulli's Equation is a fundamental principle in fluid mechanics that describes the relationship between fluid velocity, pressure, and potential energy. It states that as the velocity of a fluid increases, the pressure decreases, and vice versa.
Bernoulli's Equation can be used to explain the phenomenon of pressure increase in a fluid, such as when the fluid is flowing through a narrowing pipe. As the fluid's velocity increases due to the decrease in cross-sectional area, the pressure decreases according to the equation.
The units of measurement for Bernoulli's Equation are typically given in terms of pressure (e.g. pascals, bars, pounds per square inch) and velocity (e.g. meters per second, feet per second). However, the equation can also be used with other units of measurement as long as they are consistent.
Bernoulli's Equation is valid for incompressible fluids, meaning that the fluid's density remains constant even as the velocity and pressure change. It may also be used for compressible fluids under certain conditions, but the equation will need to be modified to account for changes in density.
Bernoulli's Equation has many practical applications, such as in the design of airfoils for airplanes and the calculation of flow rates in pipes. It is also used in weather forecasting to understand the flow of air around high and low pressure systems. In addition, it is important in understanding the circulation of blood in the human body and the function of ventilation systems in buildings.