MechasFluid
PIPE NETWORK ANALYSIS
Saturday, 23 May 2015 | 21:26 | 0 comment(s)
Pipe network analysis
In fluid dynamics, pipe
network analysis is the analysis of the fluid
flow through a hydraulics network,
containing several or many interconnected branches. The aim is to determine the flow rates and pressure drops in
the individual sections of the network. This is a common problem in hydraulic
design.
In order to direct water to
many individuals in a municipal water supply, many times the water is routed
through a water
supply network. A major part of this network may consist of
interconnected pipes. This network creates a special class of problems in
hydraulic design typically referred to as pipe network analysis. The modern
solution for this is to use specialized software in order to automatically
solve the problems. However, the problems can also be addressed with simpler
methods like a spreadsheet equipped with a solver, or a modern graphing
calculator.
Network
analysis
Once the friction factors
are solved for, then we can start considering the network problem. We can solve
the network by satisfying two conditions.
- At any junction, the flow into a junction equals the flow out of the junction
- Between any two junctions, the head loss is independent of the path taken.
The classical approach for
solving these networks is to use the Hardy
Cross method. In this formulation, first you go through
and create guess values for the flows in the network. That is, if Q7 enters a
junction and Q6 and Q4 leave the same junction, then the initial guess must
satisfy Q7 = Q6 + Q4. After the initial guess is made, then, a loop is
considered so that we can evaluate our second condition. Given a starting node,
we work our way around the loop in a clockwise fashion, as illustrated by Loop
1. We add up the head losses according to the Darcy–Weisbach equation for each
pipe if Q is in the same direction as our loop like Q1, and subtract the head
loss if the flow is in the reverse direction, like Q4. In order to satisfy the
second condition, we should end up with 0 about the loop if the network is
completely solved. If the actual sum of our head loss is not equal to 0, then
we will adjust all the flows in the loop by an amount given by the following
formula, where a positive adjustment is in the clockwise direction.
where
- · n is 1.85 for Hazen-Williams and
- · n is 2 for Darcy–Weisbach.
The clockwise specifier (c)
means only the flows that are moving clockwise in our loop, while the
counter-clockwise specifier (cc) is only the flows that are moving
counter-clockwise.
This adjustment won't solve
the problem, since with most networks we will have several loops. It is ok to
do this adjustment, however, because our flow changes won't alter condition 1,
and therefore, our other loops will still satisfy condition 1. However, we
should use the results from the first loop if we progress to any other loops.
The more modern method is
simply to create a set of conditions from your junctions and head-loss
criteria. Then, use a Root-finding
algorithm to find Q values that satisfy all
the equations. The literal friction loss equations will use a term called Q2,
but we want to preserve any changes in direction. Create a separate equation
for each loop where the head losses are added up, but instead of squaring Q,
use |Q|·Q instead (with |Q| the absolute value of Q)
for the formulation so that any sign changes will reflect appropriately in the
resulting head-loss calculation.
CONCLUSION
Piping systems are documented in piping and instrumentation diagrams (P&IDs). If necessary, pipes can be cleaned by the tube cleaning process. Within industry, piping is a system of pipes used to convey fluids (liquids and gases) from one location to another. The engineering discipline of piping design studies the efficient transport of fluid.
"Piping" sometimes refers to Piping Design, the detailed specification of the physical piping layout within a process plant or commercial building. In earlier days, this was sometimes called Drafting, Technical drawing, Engineering Drawing, and Design but is today commonly performed by Designers who have learned to use automated Computer Aided Drawing / Computer Aided Design (CAD) software.
Plumbing is a piping system with which most people are familiar, as it constitutes the form of fluid transportation that is used to provide potable water and fuels to their homes and businesses. Plumbing pipes also remove waste in the form of sewage, and allow venting of sewage gases to the outdoors. Fire sprinkler systems also use piping, and may transport nonpotable or potable water, or other fire-suppression fluids.
Piping also has many other industrial applications, which are crucial for moving raw and semi-processed fluids for refining into more useful products. Some of the more exotic materials of construction are Inconel, titanium, chrome-moly and various other steel alloys.
REFERENCES
-Çengel, A. Yusof. Cimbala, M. John (2014). Fluid Mechanics. Singapore: Mc Graw Hill Education
-Douglas J. F. 2005. Fluid Mechanics. Pearson 5th Edition.
-Sturm T. W. 2001. Open Channel Hydraulics; McGraw-Hill. UK.
-Jain S. C. 2001. Open Channel Flow. John Wiley & Sons.
-Chin D.A. 2000. Water Resources Engineering. Prentice Hall.
-Subramanya K., 1997. Flow in Open Channels. Tata McGraw-Hill, New Delhi.
-Fluid Mechanics Module, Penerbit UTHM, Noor Aliza Ahmad, Roslinda Seswoya & Zarina Md Al
-(2009, Nov). Fluid Mechanics. Retrieved from http://en.wikipedia.org/wiki/Fluid_mechanics
-(2015,May). Pipe network analysis. Retrieved from http://en.wikipedia.org/wiki/Pipe_network_analysis
-(2011, June). Branching pipe. Retrieved from http://www.unimasr.net/
-(2010, August). Pipe in series and parallel. Retrieved from http://nptel.ac.in/courses/112104118/lecture-36/36-1_flow_through_branched_pipe.htm
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