Flow in Branch Pipe: Understanding Reservoir Flow Dynamics

  • Thread starter Thread starter foo9008
  • Start date Start date
  • Tags Tags
    Branch Flow Pipe
Join the discussion
Ask a follow-up here, or get your own question answered by working scientists, mathematicians and engineers — people, not an autocomplete.
Real named experts · corrections over time · the nuance an AI answer skips
8 replies · 4K views
foo9008
Messages
676
Reaction score
4

Homework Statement


in the notes , the author stated that the water from reservoir 1 could flow to reservoir 2 and 3 ... i don't understand how could the water flow from 1 to 2 through junction D ? how could the water flow from low to high ?
OrulDXM.png


Homework Equations

The Attempt at a Solution

 
Physics news on Phys.org
Now my response went into the black hole :cry:

Don't see no D !

And water flows under the driving force we call pressure ! As long as pa > pb it will flow, up or down or sideways from a to b - as long as there is a path!
 
Last edited:
BvU said:
Now my response went into the black hole :cry:

Don't see no D !

And water flows under the driving force we call pressure ! As long as pa > pb it will flow, up or down or sideways - as long as there is a path!
do you mean as long as position reservoir A > B , the pressure is large enough for the water to flow upwards?
 
It's a bit more complicated than that because of the presence of reservoir 3.
It's not the position that 'decides', but the pressure.
From the picture I'd conclude that ##H_J > h_{f2}## is the condition for flow towards the second reservoir. For instance if pipe 3 is very narrow.
 
  • Like
Likes   Reactions: foo9008
BvU said:
It's a bit more complicated than that because of the presence of reservoir 3.
It's not the position that 'decides', but the pressure.
From the picture I'd conclude that ##H_J > h_{f2}## is the condition for flow towards the second reservoir. For instance if pipe 3 is very narrow.
##H_J ? what do you mean by it ?
 
BvU said:
It's a bit more complicated than that because of the presence of reservoir 3.
It's not the position that 'decides', but the pressure.
From the picture I'd conclude that ##H_J > h_{f2}## is the condition for flow towards the second reservoir. For instance if pipe 3 is very narrow.
how to know that if P at A > P at B ?
 
foo9008 said:
how to know that if P at A > P at B ?
That's exactly what they try to teach you with the picture !
##H_J## is the total head at J (what you called D, the branching point). Since that depends on the flows and the flows depend on the head differences, they propose an iterative solution method.
 
  • Like
Likes   Reactions: foo9008
BvU said:
That's exactly what they try to teach you with the picture !
##H_J## is the total head at J (what you called D, the branching point). Since that depends on the flows and the flows depend on the head differences, they propose an iterative solution method.
ok , can i also say it as position of A is the highest , so P/( rho g ) + z has the highest value for A ?
 
BvU said:
That's exactly what they try to teach you with the picture !
##H_J## is the total head at J (what you called D, the branching point). Since that depends on the flows and the flows depend on the head differences, they propose an iterative solution method.
i don't understand how could the water flow from q to 3 and Q2 is 0 ?