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Demo Team Fall 2007 Report

Author: James Leung ml362@cornell.edu, Yuliya Tipograf

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Abstract

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The transparent demonstration plant is a good platform to perform [flocculation] experiments on, due to its manageable size and close approximation of an actual AguaClara water treatment plant. Experiments were done to investigate how more uniform shear in the flocculator - created by obstacles inserted in the vertical sections between bends - improves flocculation. Initial results showed that more uniform shear at the beginning of the flocculator caused effluent turbidity to decrease. Yet when the plant was modified to make it more robust and to make the results more repeatable, those initial results could not be replicated. Certain systematic errors in the initial experiments were eliminated and new errors were introduced. Subsequently, the plant was automated using [Process Controller] to make it more time-efficient, and the desktop turbidity meter was replaced by an inline turbidity meter to eliminate unintended bias in readings. However, the results still showed that the performance of the flocculator did not improve by making shear more uniform. It is probable that the performance of the unmodified plant is already at the theoretical limit, and that improving flocculation at the beginning of the plant cannot decrease the turbidity of the effluent any further.

Keywords: demonstration plant, uniform shear, obstacles, improve flocculation

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Introduction and Objectives

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The demo plant was originally designed as an education and demonstration apparatus. This is the third version that has been build and is the most accurate representation of the actual plants located in Honduras. The previous demo plants were harder to follow and were less efficient.

The current demo plant is gravity-powered. The flow of fluids into the plant is regulated by constant head regulators. These constant head regulators are identical to the regulators used in Honduras. They regulate flow by keeping constant the difference in elevation between the top of the fluid in the regulator and the feed point. While the flow of fluids can be adjusted by changing the height of the feed points, the demo plant is designed to handle 100 mL/min of fluids.

The flocculator is open-top and is made of clear corrugated plastic. Each corrugation forms a channel that has a cross-section 10 mm long by 5 mm wide. Slits are cut in the corrugation to allow flow to weave through the device. The flocculator leads to the sedimentation tank made of the same corrugated plastic material. The corrugations here serve as the lamella. The flow through each lamella is kept uniform by a small orifice at the top of each channel. The orifice creates a significant amount of head loss and negates any difference in head loss between lamellas. The schematic of the demo plant is shown in Figure 1 below.

INSERT FIGURE 1, SCHEMATIC OF DEMO PLANT, HERE

The demo plant is of manageable size and is easy to operate. In addition, it is transparent and allows direct observation of the flocculation and sedimentation processes. These properties make the demo plant very suitable for flocculation experiments that must be carried out under controlled conditions, but in an apparatus that closely models the actual AguaClara water treatment plants.

Currently, most of the shear is provided by the 180° turns at the ends of the baffles. There is much less shear in the vertical sections between baffles. Thus, the difference between the maximum shear and the mean shear of the flocculator is significant. In addition, localized maximum shear at the 180° turns near the end of the flocculator is more than enough to break up flocs, although the mean shear is at a safe level. It is proposed that if the shear level across the vertical sections of the flocculator is more uniform, the flocculator will be more efficiently used and the size of the flocculator can be reduced. In addition, it will effectively reduce maximum shear near the end of the flocculator and reduce floc breakup.
In order to even the shear level, the flow path of water in the vertical section must be disrupted. One can introduce obstacles around which the water must flow. The initial approach was to experiment with disrupting flow at a small scale with the VFHF demonstration plant.

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Procedures

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ClaySuspensionTurbidityandAlumDose">
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Clay Suspension Turbidity and Alum Dose
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For the Suspended Steel Nuts experiment, the concentration of clay in suspension and the alum dose were the same as those used during a public demonstration of the plant. The values were determined by Sara Schwetschenau et al to be optimal for public demonstrations, such that floc formation would be clearly visible.

For the subsequent experiments, the clay concentration was set to produce a suspension with constant known turbidity. The empirical correlation between clay concentration and suspension turbidity (Figure 2) was given by Ian Tse et al.

INSERT FIGURE 2, Correlation between clay concentration and turbidity, HERE

INSERT FORMULA 1 HERE

Values

  • Suspension turbidity (T, NTU)
  • Concentration of kaolin clay (Cclay, mg/L)

The alum dose was set according to the turbidity of the clay suspension (Equation 2). The volumetric flow of alum was then calculated using the dose, the concentration of the alum solution, and the flow of clay suspension into the plant (Equation 3).

INSERT FORMULA 2 HERE

Values

  • Alum dose (D, mg/ L)
  • Suspension turbidity (T, NTU)

INSERT FORMULA 3 HERE

Values

  • Alum dose (D, mg/ L)
  • Flow rate of alum (Qalum, mL/min)
  • Flow rate of clay suspension (Qclay, mL/min)
  • Concentration of alum solution (Calum, mg/L)

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Shear and Degree of Mixing

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Flocculation is facilitated by velocity gradients, or shear. Shear causes suspended particles to collide. Chemical coagulants, such as aluminum sulfate (alum) and poly-aluminum chloride (PAC), neutralize the negative surface charge of the particles and encourage them to adhere to one another after collisions. The two work in tandem to form flocs. Thus, higher shear causes more collisions and results in larger flocs. The number of collisions is also proportional to the amount of time that the suspended particles spend in the region of shear. Thus, longer time results in larger flocs.
It is necessary to have a quantity that measures the amount of shear that the suspended particles have been subjected to, since that determines the size of the flocs. This quantity is the product of shear (G, s-1), and the amount of time spent in the region of shear (¿, s). The resulting dimensionless number (G¿) is a measure of mixing.

However, shear is also capable of breaking up flocs. Larger flocs, with greater cross-sectional areas, span larger velocity gradients and are subjected to higher forces. Thus, they are more susceptible to breakup than smaller flocs in the same shear. Therefore, the maximum shear that a floc can tolerate decreases with size. It is paramount to create high to promote flocculation without exceeding the limit that the flocs can tolerate.

The relationships between the relevant quantities for a vertical flow, baffled hydraulic flocculator are given below.

INSERT FORMULA 4 HERE

Values

  • Average shear ( , s-1)
  • Gravitational acceleration (g, 9.81 m/s2)
  • Head loss (hl, m)
  • Flow rate (Q, m3/s)
  • Kinematic viscosity of water (¿, 10-6 m2/s)
  • Height of flow channel (h, m)
  • Width of flow channel (w, m)
  • Baffle spacing (b, m)

INSERT FORMULA 5 HERE

Values

  • Maximum shear created (Gmax, s-1)
  • Minor loss coefficient (K)

INSERT FORMULA 6 HERE

Values

  • Maximum shear allowed (Gmax,design, s-1)
  • Diameter of floc (dfloc, m)
  • Shear strength of floc (¿floc, 0.8 Pa)
  • Coefficient of drag of floc (CD)
  • Density of water (¿w, 1000 kg/m3)

INSERT FORMULA 7 HERE

Values

  • Residence time of baffle (\theta baffle, s)
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(this closes the Methods cloak)

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Results">
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Results
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Enter your Results here.

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Conclusions

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Enter your Conclusions here.

Unknown macro: {toggle-cloak} ExampleTable">
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ExampleTable

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Wiring standard used for combining power supplies and analog data acquisition in a Category 5 Ethernet cable.

T-568B standard

T-568A standard

voltage

white/orange

white/green

S-

orange

green

S+

white/green

white/orange

ground

blue

blue

-5 V

white/blue

white/blue

+5 V

green

orange

+10V

white/brown

white/brown

-15 V

brown

brown

+15 V

Here is an example table. I refer to the table by creating an internal link (an anchor) that will take the viewer to the top of the table. For example here I am talking about the analog wiring standard that we use in the AguaClara laboratory. Note that I position the floating table above the paragraph where it is first referenced so that it appears along the side of that paragraph. I haven't figured out an automatic way to set the width of the table. Currently I am doing it by trial and error. If someone figures out a better way, please edit this!

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Figures and captions

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[!Process Controller^stampbox.jpg|width=200px!|Process Controller^stampbox.jpg]

Basic Stamp® microprocessor control box with ports for 6 on/off devices and 6 variable speed peristaltic pumps.

I recommend
An output control box designed and fabricated around the Basic Stamp® Microprocessors (Parallax 16 port BS2sx and 40 port BS2p BASIC Stamp® modules) is used for on/off control of up to six devices and for variable control of up to six peristaltic pumps.

The float macro keeps the graphic and the caption together and floats the figure on the page with text wrapping around it automatically. Because the top of the figure will align with the text that the float is above, I recommend insert the figure wrapped in the float macro immediately above the paragraph where the first reference to the figure occurs. This will place the figure along side the paragraph with the reference. Use anchors to refer to the figure just like you would use "Figure 11" refernces in a conventional manuscript. There is no way to implement auto numbering of the Figures so for now don't even bother to use numbers in the Figure. Instead, in the body of the report where you first reference the output control box add an anchor link that connects to the Figure. Use heading 5 for table and figure captions. This makes it possible to generate a list of tables and figures. Note that there is no numbered Figure reference in the caption. Also note that the image is a hyperlink to the full size original image. If the image is from a different source file the hyperlink should be to the original source file such as a MathCAD or Excel sheet.

In this example I set the size of the float and the size of the image to 200px. The viewer can see the full image by clicking on it.

You can also use the chart macro to create a chart dynamically within the wiki.

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chart: Error while converting wiki markup to storage format.
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Bogus models showing the relationship between velocity and time.
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