h1. The AguaClara Technology
h2. A Brief Overview of the Technology
{float:right|border=2px solid black|width=300px}
[!Ojojona Photos^0015_08_094.jpg|width=300px!|Ojojona Photos]
{float}
The AguaClara technology is an innovative form of flocculation/sedimentation that has been adapted at Cornell University to operate without electrical input. Unlike conventional flocculators, which rely on large motor-driven stirring devices, ours create mixing solely with gravitational forcing through turning channels. The chemical dosing for the plants is all accomplished by using float valve-regulated constant head devices, and the plant flow rates are controlled with engineered orifice positioning.
Sites for AguaClara plants are selected based on the presence of a distribution system, and the apparent commitment of the town to the project. Candidate sites must have coherent juntas, or water boards, and a distribution system in place that will be able to deliver the cleaned water to individuals. AguaClara is responsible for the research and design going into each plant, while construction and plant operations and maintenance is the responsibility of local juntas.
h2. A Detailed Plant Tour
h4. The entrance tank to the rapid mix
{float:left|border=2px solid black|width=300px}
[!Ojojona Photos^0015_08_062.jpgTamara Report Photos^Grit Chamber Figure 6|width=300px!|OjojonaTamara Report Photos]
{float}
Source water flows gravitationally via the pre-existing distribution system to the entrance tank for the AguaClara plants. This entrance tank contains riser pipes with orifices of calculated size and spacing, which restricts the flow rate of water actually being treated to a specified amount. The water leaving the entrance tank is mixed with alum, a coagulant, en route to the flocculator.
\\
{float:right|border=2px solid black|width=300px}
[!Ojojona Photos^0015_08_130.jpg|width=300px!|Ojojona Photos]
{float}
Alum is dosed using a flow control module (FCM) developed by AguaClara. The FCM is a bottle fitted with a plastic float valve on the inlet, and a set length of tubing on the outlet. The float valve ensures a nearly constant head loss through the module, while the exit tubing provides a calculable head loss from friction. Plant operators adjust the alum dosing necessary for plant operation by adjusting the height at which the exit tubing connects with the raw water stream. The operators have a chart that relates influent turbidity to required alum dose, and required alum dose to the required tubing height change. The dose delivered by the FCM is therefore a function of the (constant) head in the bottle, the (constant) length and material of the outflow tubing, and the change in elevation across the tubing length, which is what the operators manipulate to adjust dosing.
\\
//
h4. The rapid mix through the flocculator
{float:right|border=2px solid black|width=300px}
[!Tamara Report Photos^Flocculation Tank Figure 7.jpg|width=300px!|Tamara Report Photos]
{float}
Alum and raw water flow through a short series of pipe elbows acting as a rapid mix. This disperses the alum throughout the raw water stream, ideally coating a significant amount of the suspended particles. This mixed solution then enters the vertical flocculator. The vertical flocculator was also developed at Cornell University, specifically as part of this project. The flocculator is comprised of a series of channels with alternating up and down baffles. The baffles force water to change direction through an amount of space that is calculated to provide target mixing.
This mixing is vital to the water treatment process because it is the engine that drives floc formation. When alum is added to water it decreases the net charge on suspended dirt particles in the flow. When particles collide in an un-coagulated stream (one not treated with alum), they tend to repel one another. Conversely, particles in a coagulated stream are more likely to actually stick together and form larger conglomerates. These larger clumps of particles are referred to as flocs.
At the beginning of flocculation the particles are small. The vertical flocculator has many more tight turns, and therefore creates much more mixing in the early sections of the tank as compared with the later sections. As the stream mixes more and larger flocs form, the number of baffles per unit length of the tank decreases to reduce the strain on the larger flocs. The exact values for mixing parameters at various stages of floc formation is currently a central focus for the AguaClara laboratory research team.
Earlier AguaClara plant designs employed the use of a horizontal flocculator instead of the vertical model now in use. The horizontal model is similar to the vertical one, except that the stream is forced to side-wind from left to right through the channels, instead of up to down. The vertical flocculator has a smaller footprint than its horizontal counterpart, which decreases the overall cost of construction. The vertical model also is less prone to premature sedimentation throughout the tank, which is another main reason why the team has shifted focus to vertical flocculation.
h4. The sedimentation tanks to the customers
The stream leaves the flocculator and travels to the sedimentation tanks via a channel. The tanks each have several bottom-level entrance pipes to distribute water evenly across the floor of each tank, and an effluent launder pipe collects water from the top of each tank. Tanks are fitted with arrays of lamella that are angled 60º from the tank floor. The heavy flocs settle out of the slowly rising water and onto the lamella. The size of the tanks and the positioning of the lamella is engineered to allow the water to rise up through the tank at a slower rate than the flocs fall out onto the lamella.
Sludge, made up of settled-out flocs, collects at the bottom of the sedimentation tanks and may create a diffuse filter for incoming water. Having some degree of sludge build-up is therefore desirable, but excess sludge will begin to rise through the tank if it builds up too much. The AguaClara team has recently begun a new laboratory research project to assess potential design modifications to control the sludge level in a sedimentation tank. Currently plant operators can isolate each sedimentation tank and open a bottom drain to wash the sludge out. Future designs may incorporate some system of sludge hoppers that would remove the sludge only to a specific level in the tank, leaving some to act as a filter. Most of the initial turbidity is currently removed from the water by the time it exits the sedimentation tanks, but the sludge blanket filtering effect may help us achieve even better standards for effluent water.
From the launder at the top of the sedimentation tanks, clear water flows to a plant leveling chamber. This chamber is similar to the plant entrance tank in that riser pipes with engineered orifices are used to regulate the rate at which water flows through the chamber, and therefore the plant as a whole.
Chlorine is added to the clear water as it travels from the plant leveling chamber to the distribution tank. The chlorine is dosed using the same style of flow control module used in alum dosing. Clean, disinfected water then flows from the distribution tank into people's homes.
h2. The Case for Treatment Before Chlorination
Influent water straight from the source contains dirt, organics, and potential pathogens. Although chlorine is used as a broad-spectrum disinfectant worldwide, it is not necessarily an easy solution. Chlorine reacts with organics present in the water, forming carcinogenic compounds. This has the dual effect of not achieving disinfection because the chlorine is "used up" on the dead matter, while also creating a new health hazard. Flocculation is simply the process of sticking all the solids in raw water together, while sedimentation is the process of letting those heavy solids sink out. The resulting water is clear of most solids, which allows us to add chlorine to kill remaining pathogens without producing excessive byproducts.
h2. The Social and Cultural Side
Social sustainability is of key importance to the AguaClara team. The first concern for plant design features is that they be practical for the communities using them. All AguaClara plants are built by locals through construction projects supervised by the Honduran NGO Agua Para el Pueblo (APP). Two Cornell graduates spend each year as employees of APP while assisting with plant operator training and data collection. Groups from Cornell visit the sites of AguaClara plants several times each year, interviewing customers and plant operators to gain an understanding of how to better suit our research and design to the local needs.
| 