Transfer function of flow measurement system HELP

AI Thread Summary
The discussion focuses on deriving the transfer function for a volumetric flow measurement system, with participants sharing relevant equations and their interpretations. Key equations include the relationship between flow, pressure difference, and force on the transducer. The user expresses difficulty in breaking down the problem further and seeks guidance on manipulating equations to derive the transfer function. There is confusion regarding the origin of a specific term in the equations, particularly A^2/a^2, and how smaller diameter pipes affect pressure readings. Overall, the conversation emphasizes the complexities of fluid dynamics in relation to flow measurement systems.
cabellos2
Messages
13
Reaction score
0
Transfer function of flow measurement system HELP!

1.

I have attached the question, which is to derive the transfer function of a volumetric flow measurement system...

2.

I know of the following relevant equations:

F = Ma = MD^2.x

Flow f = area x velocity

and f through a restriction f = C(p2-p1)

Also Force F = pressure x Area

3.

When considering the Mass alone I have

Sum of forces F = F - kx - BDx = MD^2.x

therefore x/F = 1 / K + BD + MD^2

and finally, x/F = (1/k) / 1 + (B/k)D + (M/k)D^2




However I am struggling to break the problem down further. Which parts of the system do I also need to consider and how do I go about manipulation of the equations to derive the transfer function...??

Your help is very much appreciated.
 

Attachments

Physics news on Phys.org


You have an equation relating pressure difference to volumetric flow. The pressure on each side of the transducer would have a contribution to force on the transducer plate.
 


I am still struggling with this one I am afraid. I can't figure out where the 2Mf/k . A^2/a^2 term originates from...

Some guidance would be very much appreciated...
 


Ok this is where I have solved to thus far:

I have the equation x/F = 1 / (k + BD + MD^2)

but F = Pressure x Area

so Pressure difference on transducer mass P2 - P3 x Area = Force (F)

therefore,

x / A (P2-P3) = 1 / (k + BD + MD^2)

and then,

x / (P2 - P3) = A / (k + BD + MD^2)

then finally divide rhs of equation by k to give,

x / (P2 - P3) = A/k / ((1 + B/k(D) + M/k(D^2))

My next equation of (P2 - P3)C = f

so substituting this in gives,

x/flow = A/CK / ((1 + B/k(D) + M/k(D^2))

BUT where does the A^2 / a^2 term come in...??

Any pointers?

Thanks
 


I would guess this.
You may consider the smaller diameter pipes to be obstructions. Whenever the plate would be in motion \left( \frac{dx}{dt} \neq 0 \right) then fluid would be flowing through these pipes. Thus p1 would not be equal to p2 and p3 would not be equal to p4.

Even though fluid would not pass through the plate, you may consider the path through both smaller pipes as one flow.
 

Similar threads

Process Control (transfer function) problem
Replies
1
Views
2K
From differential equations to transfer functions
Replies
5
Views
2K
Engineering What is wrong in this 2nd order transfer function?
Replies
2
Views
2K
Engineering Is it possible for a low pass filter to have such a transfer function?
Replies
16
Views
2K
Oven controller block diagram, transfer function and temperature calcs
Replies
24
Views
5K
Engineering Average heat transfer coefficient (forced convection)
Replies
6
Views
3K
Does the transfer function exist for an unforced system?
Replies
12
Views
3K
Converting linear state space into a transfer function
Replies
1
Views
2K
Engineering Determine the transfer function of the block diagram
Replies
4
Views
1K
Using Newton's Method to Solve and Using Fsolve in Matlab
Replies
2
Views
2K

Hot Threads

Recent Insights

Back
Top