AguaClara Reach PF 300

Product Description

The AguaClara Reach PF 300 is a compact gravity-fed water treatment system that uses a five-step process to treat and filter water for up to 300 people.

Target Countries

Honduras, India, Nicaragua

Target SDGs

SDG 6: Clean Water and Sanitation

Market Suggested Retail Price

$3,000.00

Target Users (Target Impact Group)

Community

Distributors / Implementing Organizations

This product is implemented and distributed by Cornell University and Agua Clara LLC

Competitive Landscape

Direct competitors include GravityPure UF.

Manufacturing/Building Method

The product is produced within the community using local materials.

Intellectural Property Type

Open Source

User Provision Model

This product is distributed by Cornell University Engineering Department

Distributions to Date Status

Unknown

Design Specifications

The AguaClara PF 300 removes large sediment and grit before introducing coagulant and chlorine through a chemical dosing process. After this, the water begins a flocculation and sedimentation process where the sediment and particulate matter is collected in a flock blanket and disposed of as waste. The residual water passes through angled plates and enters a six-layered Stacked Rapid Sand filter. The effluent water is collected in a distribution tank for use.

Product Schematics

Technical Support

Provided by the manufacturer

Replacement Components

N/A

Lifecycle

Unknown

Manufacturer Specified Performance Parameters

<0.3 NTU effluent turbidity

Vetted Performance Status

0.3 NTU effluent turbidity

Safety

Provided by the manufacturer

Complementary Technical Systems

N/A

Academic Research and References

Chavez, Kenichi, 2013, Introducing AguaClara: The Process of Establishing a Pilot Plant in the State of Chiapas, Cornell Institute of Public Affairs.

Kelley C., Krolick A., Brunner L., Burklund A., Kahn D., Ball W., Weber-Shirk M., 2014, An Affordable Open-Source Turbidimeter, Sensors 14(4), pp. 7142-7155.

Adelman M. et. Al., 2013, Floc Roll-up and its Implications for the Spacing of Inclined Settling Devices, Environmental Engineering Science, 30(6).

Adelman M. et. Al., 2013, A novel fluidic control system for stacked rapid sand filters, Journal of Environmental Engineering.

Swetland, Karen, 2012, From stock to floc: an investigation into the physical/chemical processes controlling aluminum sulfate and polyaluminum chloride behavior in a gravity powered drinking water treatment plant, Cornell University.

Swetland K. et. Al., 2012, Predictive performance model for hydraulic flocculator design with polyaluminum chloride and aluminum sulfate coagulants, Journal of Environmental Engineering.

Compliance with regulations

Effluent turbidity is in compliance with the WHO standard of <5 NTU turbidity

Evaluation methods

Unknown

Other Information

None