Difference between revisions of "Floating Plant Pond"
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'''A floating plant pond is a modified maturation pond with floating (macrophyte) plants. Plants such as water hyacinths or duckweed float on the surface while the roots hang down into the water to uptake nutrients and filter the water that flows by.''' | '''A floating plant pond is a modified maturation pond with floating (macrophyte) plants. Plants such as water hyacinths or duckweed float on the surface while the roots hang down into the water to uptake nutrients and filter the water that flows by.''' | ||
Revision as of 13:35, 5 March 2009
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A floating plant pond is a modified maturation pond with floating (macrophyte) plants. Plants such as water hyacinths or duckweed float on the surface while the roots hang down into the water to uptake nutrients and filter the water that flows by.
Water hyacinths are perennial, freshwater, aquatic macrophytes that grow especially fast in wastewater. The plants can grow large: between 0.5 to 1.2m from top to bottom. The long roots provide a fixed medium for bacteria which in turn degrade the organics in the water passing by.
Duckweed is a fast growing, high protein plant that can be used fresh or dried as a food for fish or poultry. It is also tolerant of a variety of conditions and can remove significant quantities of nutrients from wastewater. To provide extra oxygen to a floating plant technology, the water can be mechanically aerated but at the cost of increased power and machinery. Aerated ponds can withstand higher loads and can be built with smaller footprints. Non-aerated ponds should not be too deep otherwise there will be insufficient contact between the bacteria-harbouring roots and the wastewater.
Advantages | Disadvantages/limitations |
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- Water hyacinth grows rapidly and is attractive. - High reduction of BOD and solids; low reduction of pathogens. - Low to moderate capital cost; operating cost can be offset by revenue. - Potential for local job creation and income generation. - Can be built and maintained with locally available materials. |
- Can become an invasive species if released into natural environments. - Requires large land (pond) area. |
Adequacy
The technology can achieve high removal rates of both BOD and suspended solids, although pathogen removal is not substantial. Harvested hyacinths can be used as a source of fibre for rope, textiles, baskets, etc. Depending on the income generated, the technology can be cost neutral. Duckweed can be used as the sole food source to some herbivorous fish.
This technology is only appropriate for warm or tropical climates with no freezing temperatures, and preferably with high rainfall and minimal evaporation. Different, locally appropriate plants can be selected depending on availability and the wastewater type. Trained staff is required for the constant operation and maintenance of the pond.
Health Aspects/Acceptance
Water hyacinth has attractive, lavender flowers. A well designed and maintained system can add value and interest to otherwise barren land. Adequate signage and fencing should be used to prevent people and animals from coming in contact with the water.
Maintenance
Floating plants require constant harvesting. The harvested biomass can be used for small artisanal businesses, or it can be composted. Mosquito problems can develop when the plants are not harvested regularly. Depending on the amount of solids entering, the pond must be desludged periodically.
References
- Elizabeth Tilley et.al (2008). Compendium of Sanitation Systems and Technologies (low res version). Department of Water and Sanitation in Development Countries (Sandec) at the Swiss Federal Institute of Aquatic Science and Technology (Eawag). (Provides a full overview of sanitation systems.)
- Abbasi, SA. (1987). Aquatic plant based water treatment systems in Asia. pp 175–198, In: Aquatic Plants for Water Treatment and Resource Recovery, K.R. Reddy and W.H. Smith (eds.), Magnolia Publishing Inc., Orlando, Florida.
- Bagnall, LO., Schertz, CE. and Dubbe, DR. (1987). Harvesting and handling of biomass. pp. 599–619, In: Aquatic Plants for Water Treatment and Resource Recovery, K.R. Reddy and W.H. Smith (eds.), Magnolia Publishing Inc., Orlando, Florida.
- Crites, R. and Tchobanoglous, G. (1998). Small and Decentralized Wastewater Management Systems. WCB and McGraw-Hill, New York, USA, pp 609–627. (Comprehensive summary chapter including solved problems)
- Gerba, CP., et al. (1995). Water-Quality Study of Graywater Treatment Systems. Water Resources Bulletin 31(1): 109–116.
- Iqbal, S. (1999). Duckweed Aquaculture-Potentials, Possibilities and Limitations for Combined Wastewater Treatment and Animal Feed Production in Developing Countries. Sandec, Dübendorf, Switzerland.
- McDonald, RD. and Wolverton, BC. (1980). Comparative study of wastewater lagoon with and without water hyacinth. Economic Botany: 34 (2): 101–110.
- Polprasert, C., et al. (2001). Wastewater Treatment II, Matural Systems for Wastewater Management. IHE, Delft. (Comprehensive Design Manual: see Chapter 4 – Water Hyacinth Ponds.)
- Rose, GD. (1999). Community-Based Technologies for Domestic Wastewater Treatment and Reuse: options for urban agriculture. IDRC, Ottawa. Available: http://idrinfo.idrc.ca
- Skillicorn, W., Journey, K. and Spira, P. (1993). Duckweed aquaculture: A new aquatic farming system for developing countries. World Bank, Washington, DC. Available: http://www.p2pays.org/ref/09/08875.htm (Comprehensive manual)
- US Environmental Protection Agency (1988). Design Manual: Constructed Wetlands and Aquatic Plant Systems for Municipal Wastewater Treatment. USEPA, Cincinnati, Ohio. Available: http://www.epa.gov/owow/wetlands/pdf/design.pdf