russ_watters said:Welcome to PF!
Do you have an idea about what might happen?
For sizing valves we use Q=Cv x pressure drop. Cv is a dimensionless number indicating the orifice size. Q=flow. This simple calculation can grow to be very complex when variables like piping, temperature, viscosity, critical pressure drops and many others are included. But the base is fairly accurate for cold water at low pressure drops (200 or so). What it tells you is that if the inlet pressure and Delta-P remain constant, the flow will vary with orifice size.Aj83 said:For a fixed pressure differential will the flow rate remain constant or will it increase as the restriction decreases. So imagine certain volumetric flow rate through partially opened valve, will the flow rate increase or will it remain constant as the valves is opened further? Assume density is constant and no pressure losses. Thanks
russ_watters said:Minus losses, the velocity should stay about the same, but yes, flow rate will increase because the orifice gets larger.
Aj83 said:Right, Let me put it in another way. If you put your finger in front of a pipe outlet, let's say while watering your garden, so that you are blocking the outlet partially. When you do that, will there be a reduction in flow rate or will the velocity increase to keep the flow rate same?
I am trying to get my head around continuity equation (mass flow rate)in = (mass flow rate)out or considering density remains constant (Volume flow rate)in = (Volume flow rate)out.
Also q=vA (q=volume flow rate, v=velocity, A=cross sectional area)
So my understanding is that keeping the pressure differential same,if you change the cross sectional area, the velocity will adjust accordingly to keep the flow rate same and vice versa. Which is what we see in a nozzle, when the area decreases the velocity increases. So why does flow rate increases when you open the valve further (increasing the exit cross section), shouldn't velocity decrease as the area increases while flow rate remaining constant?
P.S To keep things simple, let's say we don't take the pressure losses into account due to viscosity or any changes in temperature.
Aj83 said:For a fixed pressure differential will the flow rate remain constant or will it increase as the restriction decreases. So imagine certain volumetric flow rate through partially opened valve, will the flow rate increase or will it remain constant as the valves is opened further? Assume density is constant and no pressure losses. Thanks
Isn't that the situation of a water tap? Increase the opening and the volume flow rate increases.Aj83 said:I think the velocity will decrease and flow rate will remain same due to continuity?
harrylin said:Isn't that the situation of a water tap? Increase the opening and the volume flow rate increases.
The continuity equation merely tells you that the in-flow equals the out-flow at a certain valve opening.
Aj83 said:So say tap is open to some specific flow rate, if you put a nozzle (a converging shape) at its end why does the velocity increase? or why does velocity increase if you put your finger such that its blocking the exit partially?
jbriggs444 said:There are (at least) three effects that may apply.
1. Water hammer.
When you squeeze down the nozzle or put your thumb over the end of the hose the water in the hose has momentum -- it cannot slow down instantly. So there is a momentary pressure increase across the orifice.
This will explain a momentary increase in exit velocity.
2. Bernoulli.
For a fixed pressure drop there is a fixed increase in kinetic energy per unit volume. Drop the orifice size while maintaining a fixed pressure drop and nozzle velocity does not increase at all.
By itself, this will predict that squeezing down the nozzle will not result in a long-term increase nozzle velocity. But it will predict a reduction in flow rate.
3. Where's the bottleneck.
If there is no constriction at the end of the hose then there is no pressure drop at the end of the hose. If the water company is supplying water at (for instance) 60 psi and the water pressure on egress from the hose is 0 psi then there has to be a pressure drop somewhere.
Bernoulli can explain some of this pressure drop. The unrestricted flow velocity out the end of the hose with the faucet wide open can be respectable. But in my gardening experience, it's nowhere near as high as the stream velocity you get with a nozzle.
Reduce the orifice size and you reduce the flow rate (as above). This, in turn reduces the pressure drop at all the other bottlenecks in the system. You have less pressure drop within the length of the hose, less pressure drop at the faucet, less pressure drops in the pipes in your house and less pressure drop at every elbow, tee and water meter.
Now you have closer to 60 psi at the nozzle and closer to 60 psi worth of velocity at the nozzle.
This predicts the long term increase in nozzle velocity that is seen.
jbriggs444 said:You should not with one breath say "let's ignore pressure losses" and with the next breath ask "why do we see what we see in the real world". I maintain that real-world pressure losses added up from the water company to the end of the hose are non-negligible.
The evidence for this is what I've already given: The arc of water from the end of a hose running wide open and pointed at an upward angle does not reach very high. The arc of water from the end of a hose with a nozzle reaches higher.
Ideally -- ignoring pressure losses due to viscosity the height of a stream pointed upward at a steep angle should be roughly equal to the height of the local water tower, with or without a nozzle.
You asked for a situation where you can keep the pressure drop the same "by changing the restriction". If we take you at your literal word, there is a common device that does exactly that. It is called a pressure regulator. When output pressure is low, it opens a valve wider. When output pressure is high it closes the valve tighter.
Aj83 said:So say tap is open to some specific flow rate, if you put a nozzle (a converging shape) at its end why does the velocity increase? or why does velocity increase if you put your finger such that its blocking the exit partially?
Flow rate refers to the volume of fluid that passes through a particular point in a given amount of time. It is typically measured in units of volume per unit of time, such as liters per minute or cubic meters per second.
Valves are used to control the flow rate of a fluid by either increasing or decreasing the opening through which the fluid can pass. By adjusting the valve, the flow rate can be changed to meet the desired rate for a specific application.
Yes, valves can be used to increase flow rate. By fully opening the valve, the flow rate will increase to its maximum capacity. However, this may also depend on other factors such as the pressure and viscosity of the fluid.
No, flow rate is not always constant in a system with valves. The flow rate can be adjusted by changing the position of the valve, so it can vary depending on the valve's setting.
The appropriate valve size for a desired flow rate can be determined by considering the fluid properties, system pressure, and required flow rate. By using equations and flow rate charts, the valve size can be calculated to ensure the desired flow rate is achieved.