Just some simple fluid mechanics questions

In summary, the principle states that the total pressure of a fluid is equal to the sum of the static pressure and the dynamic pressure. If you increase velocity, the pressure will also increase. However, if you keep the static and head pressure constant, and increase the velocity, the total pressure is higher.
  • #1
kv2
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bernoulli's principle says..
total pressure = static pressure + dynamic pressure + pressure from height, right?

but how come I hear that an increase in velocity is a decrease in pressure? if you increase velocity as the 'v' part in dynamic pressure won't the entire pressure increase as well? because it just adds to the rest. Same thing with height pressure. if height is higher, won't the total pressure be more because you mutiply height to gravity and density, then you add to other pressures.

I read as an example on a site... that when you turn on the shower in the bath tub the curtains get pulled inward beacuse of a decrease in pressure ( . )

Well if it starts raining outside then, does this mean atmospheric pressure is no longer 14.7psi, but less?

this is confusing. please clarify, thanks.
 
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  • #2
The total pressure must be the same,that's why you're using that formula due to Daniel Bernoulli.That's why static pressure must drop,once the dynamical one incresed.

Daniel.
 
  • #3
The increase in velocity = decrease in pressure statement is in reference to a given flow stream, not different ones. In other words, given a flow stream where velocity is X, if that flow stream were to be reduced in area, then velocity would increase. And if velocity increases in that flow stream, then the static pressure decreases.

You are correct that given the equation, if the static and head pressure stays constant, and one simply increases the velocity, then the total pressure is higher. But note that if this is the case, when you increase velocity, the flow rate must also increase. So you're comparing two flow streams, one has more flow than the other.

Regarding the shower curtain, someone's messing with your mind. I believe that has to do with warming the air inside the shower, the warm air is more bouyant, and cold air wants to get in at the bottom, which pushes the shower curtain in. That's a thermal effect, not a mechanical one.
 
  • #4
shower curtains

Q_Goest said:
Regarding the shower curtain, someone's messing with your mind. I believe that has to do with warming the air inside the shower, the warm air is more bouyant, and cold air wants to get in at the bottom, which pushes the shower curtain in. That's a thermal effect, not a mechanical one.
I don't believe it's a thermal effect: try it with cold water. Up until a few years ago, I would have said that the reason for the shower curtain sucking inward was the Coanda effect and viscosity--the same effect that causes a piece of paper to rise when you blow over it. (This "blowing across the paper" demo is usually meant to demonstrate Bernoulli; but it doesn't.) But a few years ago someone at the University of Massachusetts actually did a mathematical model of the problem and found that the main thing going on was that a vortex is created in the shower: the resulting low pressure pulls the curtain inward. (I don't know the details of his model.)
 
  • #5
Just to make it clear about the Bernoulli principle:
This derives a relation VALID ON A STREAMLINE.
Since we also need STATIONARY CONDITIONS in order to use (the usual) Bernoulli, it follows that Bernoulli equally well can be said to relate the energy for the SAME fluid particle at two distinct points on its trajectory (since the particle trajectory will coincide with the streamline in the stationary case).

Now, if the particle has a greater speed at some point of its trajectory, it has necessarily experienced a tangential acceleration.
But, (ignoring change in gravitational potential for simplicity), if a fluid particle is to accelerate along its trajectory, then the pressure at the point where it has lowest velocity must be greater than the pressure value at the point where it accelerates to...
 
  • #6
ohh... so the statement "increase in velocity results in decrease in pressure" refers to the static pressure of the fluid, not the total? is static pressure just commonly referred to as just "pressure" or something? or am i still mistaken?

so increase in velocity will increase the dynamic pressure of a fluid but in turn, the static pressure MUST decrease? what if it doesn't?

thanks guys. :approve:
 

1. What is fluid mechanics?

Fluid mechanics is the branch of physics that deals with the study of fluids (liquids and gases) and how they behave under various conditions such as at rest, in motion, and when interacting with solid surfaces.

2. What are the different types of fluids?

There are two main types of fluids: liquids and gases. Liquids have a definite volume but no definite shape, while gases have neither a definite volume nor shape. Some examples of liquids include water, oil, and blood, while examples of gases include air, oxygen, and carbon dioxide.

3. What is the difference between laminar and turbulent flow?

Laminar flow occurs when a fluid moves in smooth, parallel layers, with little to no mixing between layers. Turbulent flow, on the other hand, is characterized by chaotic, irregular motion and mixing of fluid particles. The transition from laminar to turbulent flow is determined by the Reynolds number, which takes into account the fluid velocity, density, and viscosity.

4. How is Bernoulli's principle related to fluid mechanics?

Bernoulli's principle states that in a steady flow, the total energy of a fluid remains constant. This means that if the velocity of a fluid increases, its pressure decreases, and vice versa. This principle is important in understanding the lift force on an airplane wing and the flow of fluids through pipes and pumps.

5. What are some real-world applications of fluid mechanics?

Fluid mechanics has many practical applications, including the design of aircraft, cars, and ships; the optimization of hydraulic and pneumatic systems; the study of weather patterns; and the development of medical devices such as ventilators and blood flow meters. It is also used in chemical engineering to design and optimize processes involving fluids.

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