Fish can be raised in ponds (aquaculture) receiving effluent or sludge. The fish feed on algae and other organisms that grow in the nutrient-rich water and are eventually harvested for consumption.General term for a liquid that leaves a technology, typically after blackwater or sludge has undergone solids separation or some other type of treatment. Effluent originates at either a collection and storage or a (semi-) centralised treatment technology. Depending on the type of treatment, the effluent may be completely sanitised or may require further treatment before it can be used or disposed of.Mixture of solids and liquids, containing mostly excreta and water, in combination with sand, grit, metals, trash and/or various chemical compounds. A distinction can be made between faecal sludge and wastewater sludge. Faecal sludge comes from on-site sanitation technologies, i.e. it has not been transported through a sewer. It can be raw or partially digested, a slurry or semisolid, and results from the collection and storage/treatment of excreta or blackwater, with or without greywater. Wastewater sludge (also referred to as sewage sludge) originates from sewer-based wastewater collection and (semi-)centralised treatment processes. The sludge composition will determine the type of treatment that is required and the end-use possibilities.Describes technologies for on-site collection, storage, and sometimes (pre-) treatment of the products generated at the user interface. The treatment provided by these technologies is often a function of storage and is usually passive (i.e. requires no energy input), except a few emerging technologies where additives are needed. Thus, products that are ‘treated’ by these technologies often require subsequent treatment before use and/or disposal. In the technology overview graphic, this functional group is subdivided into the two subgroups: “Collection/Storage” and “(Pre-)Treatment”. This allows a further classification for each of the listed technologies with regard to their function: collection and storage, (pre-) treatment only or both.Refers to the methods through which products are returned to the environment, either as useful resources or reduced-risk materials. Some products can also be cycled back into a system (e.g. by using treated greywater for flushing).A functional group is a grouping of technologies that have similar functions. The compendium proposes five different functional groups from which technologies can be chosen to build a sanitation system:
User interface (U), Collection and Storage/Treatment (S), Conveyance (C), (Semi-) Centralised Treatment (T), Use and/or Disposal (U).
A sanitation system is a multi-step process in which sanitation products such as human excreta and wastewater are managed from the point of generation to the point of use or ultimate disposal. It is a context-specific series of technologies and services for the management of these sanitation products, i.e. for their collection, containment, transport, treatment, transformation, use or disposal. A sanitation system comprises functional groups of technologies that can be selected according to context. By selecting technologies from each applicable functional group, considering the incoming and outgoing products, and the suitability of the technologies in a particular context, a logical, modular sanitation system can be designed. A sanitation system also includes the management and operation and maintenance (O & M) required to ensure that the system functions safely and sustainably. The controlled cultivation of aquatic plants and animals.
The utilisation of products derived from a sanitation system.
Any substance that is used for growth. Nitrogen (N), phosphorus (P) and potassium (K) are the main nutrients contained in agricultural fertilisers. N and P are also primarily responsible for the eutrophication of water bodies.
A sanitation system in which excreta and wastewater are collected and stored or treated on the plot where they are generated.
The means of safely collecting and hygienically disposing of excreta and liquid
wastes for the protection of public health and the preservation of the quality of public water bodies and, more generally, of the environment.
Waste matter that is transported through the sewer.
An open channel or closed pipe used to convey sewage. See C.3 and C.4
Used water from any combination of domestic, industrial, commercial or agricultural activities, surface runoff/stormwater, and any sewer inflow/infiltration.
There are three kinds of aquaculture designs for raising fish: (1) fertilisation of Fish Ponds with effluent; (2) fertilization of Fish Ponds with excreta/sludge; and (3) fish grown directly in aerobic ponds T.5 . Fish introduced into aerobic ponds can effectively reduce algae and help control the mosquito population. It is also possible to combine fish and floating plants in a single pond. The fish themselves do not dramatically improve the water quality, but due to their economic value they can offset the costs of operating a treatment facility. Under ideal operating conditions, up to 10,000 kg/ha/month of fish can be harvested in larger-scale aquaculture. If the fish are not acceptable for human consumption, they can be a valuable source of protein for other high-value carnivores (like shrimp) or converted into fish meal for pigs and chickens.
Describes biological processes that occur in the presence of oxygen.The design should be based on the quantity of nutrients to be removed, the type of fish, nutrients required by the fish and the water requirements needed t o ensure healthy living conditions (e.g. low ammonium levels, required water temperature, oxygen levels, etc.). When introducing nutrients as effluent or sludge, it is important not to overload the system. Oxygen levels will show huge diurnal fluctuations due to photosynthesis and respiration. The critical period is early morning before sunrise when aeration may be required to maintain aerobic conditions. The biochemical oxygen demand should not exceed 1 g/m2/day. Only fish tolerant of low dissolved oxygen levels should be chosen such as tilapia, catfish and carp. These species are also tolerant to disease exposure and adverse environmental conditions. The specific choice will depend on local preferences, availability and ambient temperatures.
Describes biological processes that occur in the presence of oxygen.The materials required are those necessary to build a pond T.5 . The ponds can be lined or left unlined if the soil has a high clay content. An initial fish population must be brought, and sometimes additional fish feed, depending on the conditions.
The degradation of organic matter with the goal of reducing readily biodegradable compounds to lessen environmental impacts (e.g., oxygen depletion, nutrient leaching).A Fish Pond is only appropriate where there is enough land (or a pre-existing pond), a source of fresh water and a suitable climate. The water used to dilute the waste should not be too warm, and the ammonium level should be kept low or negligible due its toxicity to fish. Fish Ponds can be considered from the stabilization phase, when the construction or use of bigger sanitation infrastructure is possible. This technology is appropriate for warm or tropical climates with high levels of sunlight (ponds should not be shaded by trees or buildings) with no freezing temperatures, and preferably with high rainfall and minimal evaporation.
The phase change from liquid to gas that takes place below the boiling temperature and normally occurs on the surface ofThe fish should be stocked in the pond and harvested when they reach an appropriate age/size. Partial harvesting can maintain a suitable biomass while maintaining the availability of fish for consumption over time. Knowledge of fish health and care is important for the staff to understand what conditions are needed and which measures to take if the fish population faces a problem (disease, death in numbers). The pond should be drained periodically so that; (1) it can be desludged and; (2) it can be left to dry in the sun for 1 to 2 weeks to destroy any pathogens living on the bottom or sides of the pond. Workers should wear appropriate personal protective equipment.
Refers to plants or animals grown using the water and/or nutrients flowing through a sanitation system. The term biomass may include fish, insects, vegetables, fruit, forage or other beneficial crops that can be utilised for food, feed, fibre and fuel production.Mixture of solids and liquids, containing mostly excreta and water, in combination with sand, grit, metals, trash and/or various chemical compounds. A distinction can be made between faecal sludge and wastewater sludge. Faecal sludge comes from on-site sanitation technologies, i.e. it has not been transported through a sewer. It can be raw or partially digested, a slurry or semisolid, and results from the collection and storage/treatment of excreta or blackwater, with or without greywater. Wastewater sludge (also referred to as sewage sludge) originates from sewer-based wastewater collection and (semi-)centralised treatment processes. The sludge composition will determine the type of treatment that is required and the end-use possibilities.Describes technologies for on-site collection, storage, and sometimes (pre-) treatment of the products generated at the user interface. The treatment provided by these technologies is often a function of storage and is usually passive (i.e. requires no energy input), except a few emerging technologies where additives are needed. Thus, products that are ‘treated’ by these technologies often require subsequent treatment before use and/or disposal. In the technology overview graphic, this functional group is subdivided into the two subgroups: “Collection/Storage” and “(Pre-)Treatment”. This allows a further classification for each of the listed technologies with regard to their function: collection and storage, (pre-) treatment only or both.Refers to the methods through which products are returned to the environment, either as useful resources or reduced-risk materials. Some products can also be cycled back into a system (e.g. by using treated greywater for flushing).A functional group is a grouping of technologies that have similar functions. The compendium proposes five different functional groups from which technologies can be chosen to build a sanitation system:Various health hazards are associated with waste-fed aquaculture, especially hazards associated with excreta-related pathogens. The World Health Organization Guidelines for the Safe Use of Wastewater, Excreta and Greywater should be consulted for detailed information and specific guidance. The timing of the application of wastewater and excreta is an important risk management tool. It is recommended to stop the application of wastewater and excreta two or three weeks before harvest or alternatively to transfer the fish for depuration in ponds which are not fed with wastewater or sludge. Before consumption fish should be stored in clean water for at least three days. Fish should always be cooked before consumption. If a fish is healthy, cleaned after harvest and cooked well, it is considered safe for consumption.
Consists of urine and faeces that are not mixed with any flushwater. Excreta is relatively small in volume, but concentrated in both nutrients and pathogens. Depending on the characteristics of the faeces and the urine content, it can have a soft or runny consistency.Refers to (semi-solid) excrement that is not mixed with urine or water. Depending on diet, each person produces approximately 50–150 L per year of faecal matter of which about 80 % is water and the remaining solid fraction is mostly composed of organic material. Of the total essential plant nutrients excreted by the human body, faeces contain around 39 % of the phosphorus (P), 26 % of the potassium (K) and 12 % of the nitrogen (N). Faeces also contain the vast majority of the pathogens excreted by the body, as well as energy and carbon rich, fibrous material.Mixture of solids and liquids, containing mostly excreta and water, in combination with sand, grit, metals, trash and/or various chemical compounds. A distinction can be made between faecal sludge and wastewater sludge. Faecal sludge comes from on-site sanitation technologies, i.e. it has not been transported through a sewer. It can be raw or partially digested, a slurry or semisolid, and results from the collection and storage/treatment of excreta or blackwater, with or without greywater. Wastewater sludge (also referred to as sewage sludge) originates from sewer-based wastewater collection and (semi-)centralised treatment processes. The sludge composition will determine the type of treatment that is required and the end-use possibilities.The liquid produced by the body to rid itself of nitrogen in the form of urea and other waste products. In this context, the urine product refers to pure urine that is not mixed with faeces or water. Depending on diet, human urine collected from one person during one year (approx. 300 to 550 L) contains 2 to 4 kg of nitrogen. The urine of healthy individuals is sterile when it leaves the body but is often immediately contaminated by coming into contact with faeces.Describes technologies for on-site collection, storage, and sometimes (pre-) treatment of the products generated at the user interface. The treatment provided by these technologies is often a function of storage and is usually passive (i.e. requires no energy input), except a few emerging technologies where additives are needed. Thus, products that are ‘treated’ by these technologies often require subsequent treatment before use and/or disposal. In the technology overview graphic, this functional group is subdivided into the two subgroups: “Collection/Storage” and “(Pre-)Treatment”. This allows a further classification for each of the listed technologies with regard to their function: collection and storage, (pre-) treatment only or both.Refers to the methods through which products are returned to the environment, either as useful resources or reduced-risk materials. Some products can also be cycled back into a system (e.g. by using treated greywater for flushing).A functional group is a grouping of technologies that have similar functions. The compendium proposes five different functional groups from which technologies can be chosen to build a sanitation system:Raising fish is an income-generating activity, which can help finance the operation and maintenance of existing ponds. Capital costs are low if this activity is done in existing ponds and medium if the ponds first need to be built. The main operational costs are for pond and fish management and the required human resources. Funds must be allocated for sludge removal every few years.
Mixture of solids and liquids, containing mostly excreta and water, in combination with sand, grit, metals, trash and/or various chemical compounds. A distinction can be made between faecal sludge and wastewater sludge. Faecal sludge comes from on-site sanitation technologies, i.e. it has not been transported through a sewer. It can be raw or partially digested, a slurry or semisolid, and results from the collection and storage/treatment of excreta or blackwater, with or without greywater. Wastewater sludge (also referred to as sewage sludge) originates from sewer-based wastewater collection and (semi-)centralised treatment processes. The sludge composition will determine the type of treatment that is required and the end-use possibilities.Describes technologies for on-site collection, storage, and sometimes (pre-) treatment of the products generated at the user interface. The treatment provided by these technologies is often a function of storage and is usually passive (i.e. requires no energy input), except a few emerging technologies where additives are needed. Thus, products that are ‘treated’ by these technologies often require subsequent treatment before use and/or disposal. In the technology overview graphic, this functional group is subdivided into the two subgroups: “Collection/Storage” and “(Pre-)Treatment”. This allows a further classification for each of the listed technologies with regard to their function: collection and storage, (pre-) treatment only or both.Refers to the methods through which products are returned to the environment, either as useful resources or reduced-risk materials. Some products can also be cycled back into a system (e.g. by using treated greywater for flushing).A functional group is a grouping of technologies that have similar functions. The compendium proposes five different functional groups from which technologies can be chosen to build a sanitation system:This technology may be of interest in contexts where there are little or no sources of dietary protein. The quality and condition of the fish will influence local acceptance. There may be concerns about contamination of the fish; in some cultures, fish grown in this way may be completely unacceptable. It is however a common practice in many countries and the fish usually find a ready market as they cost less to grow than fish grown on expensive feeds. The introduction of Fish Ponds may require additional information or hygiene promotion activities.
Input Products
Output Products
Emergency Phase
Stabilisation | + |
Recovery | + + |
Challenging Ground Conditions
Semi-Suitable |
Application Level / Scale
Neighbourhood | + |
City | + + |
Water-based and Dry Technologies
Water-Based & Dry |
Management Level
Shared | + |
Public | + + |
Technical Complexity
Medium |
Space Required
High |
General information on aquaculture
Mara, D. D. (2003): Domestic Wastewater Treatment in Developing Countries. Earthscan, London, UK
Guidelines for the safe reuse of wastewater and excreta in aquaculture
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