MATHCAD Design of Filter and Clear Well
PDF version of our MATHCAD File.
Mathcad Code Explanation:
Target Input:
This is where the user inputs:
* The plant flow rate (Q)
* Number of granular Filters (N)
* Backwash Time between 5-10 min (Tbw)
* Percent the Sand Bed expands (Texpansion)
Condition Input:
This is where the parameters of the construction materials are entered:
* Diameter of particles, depth of bed, porosity, specific gravity, and d60 of sand and gravel.
* Water Treatment Filtration Rate
* Diameter of backwash orifice, clear well, and piping (which should be moved to fluid functions)
* Roughness and length of piping
* Density, and dynamic and kinematic viscosity of water
Calculations:
First we determine the size of the filter and head loss in normal filtration through the sand and gravel bed.
Then we use two approaches to find the area of the clear well . The first is based upon conventional knowledge that the back wash velocity needs to be 10 times the filter velocity. From there we know that the space between the top of the filter bed and the bottom of the clear well is linked directly to the amount of head loss between those two points (head loss from the pipe, elbows, expansion and contraction, expansion of the bed). To do this, we used information from Schulz and Okun (1992).
The second approach is to use the empirical formula, called the Weber Equation. The velocity for filtration is based on the sand's d60 (this equation is meant only for sand) and the specific weight of both water and sand.
Then the velocity for backwash is based on the filtration velocity, the sand's porosity and the ratio of height of the expanded and unexpanded filter bed.
Unable to find DVI conversion log file.
Once the back wash velocity is determined, solving the clear well and filter dimensions are the same process.
Design Output for Agalteca Plant, Q=6.3 L/s:
|
Conservative |
Empirical |
|---|---|---|
Filter Square Side |
1.5m |
1.5m |
Filter Height |
3.95m |
2.56m |
Clear Well Diameter |
6m |
6m |
Clear Well Height |
1.37m |
1.23m |
Mathcad Conclusions:
1) Our design based on simple hydraulics will work. However, it is a very large filter and will not be sustainable economically. The material cost for construction will be too high.
2) The design based on the empirical Weber equation (instead of the conservative approach) is much smaller and less expensive. We need to fine tune the material parameters we were using and make certain the equations were valid for our application. Also, the full validity of the empirical Weber equation is not certain.
3) If the empirical equations are valid, then we can change parts of the design, by changing the sand parameters. For example, lower BW velocity by lowering the d60 (diameter that 60% of the particles if less than or equal to) and specific weight of the media.