Contenido

Las redes de saneamiento se puede construir de dos modos:[8]​.

• - Redes unitarias: las que se proyectan y construyen para recibir en un único conducto, mezclándolas, tanto las aguas residuales (urbanas e industriales) como las pluviales generadas en el área urbana cubierta por la red.

• - Redes separativas o redes separadas: constan de dos canalizaciones totalmente independientes; una, la red de saneamiento, transporta las aguas residuales domésticas, comerciales e industriales hasta una estación depuradora; y la otra, la red de drenaje pluvial, conduce las aguas pluviales hasta el receptor, que puede ser un río, un lago o el mar.

Las redes de saneamiento surgieron en las ciudades europeas durante el siglo en respuesta a los problemas sanitarios y epidemiológicos generados por la deficiente evacuación de las aguas fecales. En aquel momento la mayoría de estas ciudades disponían ya de un sistema de colectores destinados a la evacuación de las aguas de lluvia y residuales, pero sin conexión a estas de las bajantes de los edificios. Las aguas residuales se vertían a la calle y la lluvia las arrastraba a las cloacas, desde donde iban a una cauce.

Desde mediados del siglo empezaron a construirse redes separativas, tras la aparición de los primeros sistemas de depuración, y con base en los siguientes argumentos:.

• - la separación reduce los costes de depuración y simplifica los procesos, puesto que el caudal tratado es menor y, lo que es incluso más importante, más constante;.

• - la separación reduce la carga contaminante vertida al medio receptor por los episodios de rebosamiento de las redes unitarias.

Siendo correctos los argumentos anteriores, existen también una serie de inconvenientes del saneamiento separativo, del cual desde finales de los años 1990 se está incrementando su uso, principalmente en redes de nueva implantación (la separación de redes unitarias existentes pronto se vio como económica y técnicamente inviable).

Para el buen funcionamiento de las redes separadas debe prestarse mucha atención a los aspectos que siguen:.

• - Debe existir un estricto control de vertidos") para evitar que se acometan caudales residuales a la red de pluviales (que irían directamente al medio natural sin depurar) y viceversa. Esto último redundaría en una explotación más compleja y costosa de la red de saneamiento.

• - La separación completa implica redes interiores separativas en los edificios, con duplicación de las bajantes. En este frente los costes de instalación son importantes.

• - Las aguas pluviales urbanas no son aguas limpias, sino que suelen estar sucias, por lo que su vertido directo al cauce puede generar una contaminación apreciable.

• - La red de pluviales de una red separativa puede permanecer, en climas secos, sin agua durante periodos de tiempo extensos, sin la autolimpieza de los conductos en tiempo de lluvia, por lo que puede llegar a ser necesaria la descarga de caudales de agua limpia por la red (arquetas de descarga en las cabeceras del saneamiento), reduciendo las ventajas de ahorro y eficiencia.

En comparación con las redes unitarias, los principales problemas son:.

• - El coste de instalación es muy superior, entre 1,5 y 2 veces la red unitaria equivalente.

• - Los grandes cambios en el caudal dificultan mucho la operación de las plantas de tratamiento. Frecuentemente en los periodos de lluvias intensas las plantas de tratamiento son simplemente "by-pasadas", vertiendo los efluentes directamente sin tratamiento en los cuerpos receptores o construyendo balsas de retención para guardar durante unos días el exceso de aguas llegadas, mientras se van depurando.

Current trends

Since the last decade of the century, there has generally been a concern on the part of governments to reduce the gap between the coverage of water supply networks and sewage networks.

Simultaneously, it is no longer accepted to think about sanitation if the appropriate treatment, based on the categorization of the recipient, of the collected wastewater is not also integrated. (In Europe it is mandatory in towns of more than 5,000 inhabitants).

With almost always budgetary restrictions, except in exceptional cases, the competent authorities give priority to sanitation networks over rainwater collection networks.

In many countries, the characteristics of sanitation networks have been standardized.[9][note 1]​.

Initially, sanitation networks were built with cement pipes, masonry galleries, and fiber cement; and in some cases stoneware pipes were used; currently, the most commonly used materials are polyvinyl, PVC, polyethylene, polypropylene, as well as pipes made of polyester resins reinforced with GRP fiberglass.

Since the 1990s, pipe sizing has become increasingly common, considering not only the minimum velocity of the water in the pipe but also the drag force of the flow. This variant allows working with smaller slopes, which is an advantage in very flat areas.

Storm drainage networks have several different concepts. They are frequently buried networks, but they are combined with sections made up of open channels.

In the design of the storm drainage networks, in addition to the topography, which also dominates the sanitation network, the rainfall regime in the area plays a very important role.

The current trend is for stormwater networks to be separate from the sanitation networks, instead of unitary, to prevent them from overflowing and to take advantage of their water. [10]​.

La parte principal de dicho sistema está formada por grandes tuberías (es decir, los colectores, drenajes pluviales o "cloacas") que transportan las aguas residuales desde el punto de producción hasta el punto de tratamiento o descarga.

Los tipos de sistemas de saneamiento que generalmente son colectores que funcionan por gravedad incluyen:.

• - Red de saneamiento combinada.

• - Red de saneamiento simplificada.

• - Colector de aguas pluviales.

Las redes de saneamiento que no dependen únicamente de la gravedad incluyen:.

• - Sistema de saneamiento de aguas residuales al vacío[11]​.

• - Sistema de alejamiento y tratamiento de efluente.

Donde no se ha instalado un sistema de saneamiento, las aguas residuales pueden recolectarse de los hogares por tuberías hacia tanques sépticos o fosas negras, donde pueden tratarse o recolectarse en vehículos y llevarse para su tratamiento o eliminación (un proceso conocido como manejo de lodos fecales).

Main network components

The main components of a sanitation network, described in the direction of water circulation, are:

• - the connections, which are the set of elements that allow the water discharged by a building or property to be incorporated into the network. In turn, they are usually composed of:

• a starting manhole, already located inside the private property, and that separates the private sanitation network from the public ones;

• a connection pipe, buried conduit between that starting manhole and the street network; and

• a junction, between the connection pipe and the road network, consisting of a manhole, well or other technical solution.

• - tertiary collectors or sewage conduits, buried conduits in public roads, of small section, that transport the flow of connections and scuppers to a collector;

• - the collectors (or "secondary collectors"), which are the largest section pipes, frequently accessible, that collect water from the tertiary collectors and lead them to the main collectors. They are located buried, on public roads.

• - the main collectors, which are the largest collectors in the population and collect large flows, until they are delivered to their final destination or relieved before being incorporated into an outfall.

• - storm spillways, which are tanks where water from the collectors is retained when it is very high due to the effect of rain, to avoid flooding.

• - interceptor outfalls or simply interceptors, which are pipes that transport the water collected by the collectors to the treatment plant or its discharge into the natural environment, after its flow has already been regulated by the spillway.

Downstream, and outside of what is conventionally considered the sanitation network, the treatment plant and the final discharge of the treated water would be located:

• - through an emissary, taken to a river or stream.

• - discharged into the sea near the coast;

• - discharged into the sea through an underwater outfall, taking them several hundred meters from the coast;

• - reused for irrigation and other appropriate purposes.

Other complementary elements

In all sanitation networks there are also other minor elements:

• - The ditches, gutters and gutters, which collect and concentrate rainwater from the roads and surrounding lands;

• - scuppers, gutters or drains, which are the structures intended to collect rainwater and road washing water;

• - inspection wells, which are vertical chambers that allow access to the collectors to facilitate their maintenance.

And in a certain number of cases other more important structures are necessary:

• - Pumping stations: since the sewage network works by gravity, to function correctly the pipes must have a certain slope "Slope (mathematics)"), calculated to guarantee the water a minimum velocity that does not allow the sedimentation of the solid materials transported. In cities with flat topography, collectors can reach depths greater than 4 - 6 m, which makes their construction difficult and expensive and their maintenance complicated. In these cases it may be convenient to insert pumping stations into the network, which allow the served water to be raised to a level close to the level of the road.

• - Impulse lines: Pressure pipe that begins in a pumping station and ends in another collector or in the treatment station.

• - Retention tanks") or also wells or retention tanks: storage structures that are used in certain cases where it is necessary to laminate the floods produced by large storms, where they are not rare (reservoirs, lamination tanks or wells, or expansion arks")); and where it is necessary to retain a certain initial volume of rainfall to reduce contamination of the receiving environment (reservoirs, tanks or storm wells).

Pipelines and tunnels suffer severe wear forces, which can result in premature deterioration of the network. These include root intrusion, shifting of joints, cracks and hole formation leading to a significant volume of leaks with an overall risk to the environment and public health. For example, it is estimated that 500 million m of contaminated water per year can leak into soil and groundwater in Germany.[12] Rehabilitation and replacement of damaged sewage pipes is very expensive. The annual rehabilitation costs for Los Angeles County are approximately 400 million euros,[13]​ and in Germany, these costs are estimated at 100 million euros.[14]​.

Hydrogen sulfide (HS) is indirectly responsible for "biogenic sulfide corrosion" and, consequently, the sewer pipes need rehabilitation work. There are several repair options available to homeowners in a wide range of costs and potential durability. One option is the application of a cementitious material based on calcium aluminate cement, following a cleaning of the corroded structure to remove loose material and contaminants in order to expose a healthy, rough and clean substrate. Depending on the condition and the contamination of concrete, cleaning can vary from simple high-pressure water jet cleaning (200 bar) to actual hydrodemolition (2000 bars).

The sanitation network is considered a basic service, however the coverage of these networks in the cities of developing countries is negligible in relation to the coverage of drinking water networks. This generates significant health problems. For a long time, the concern of municipal or departmental authorities was more concerned with building drinking water networks, leaving the construction of sanitation networks for an indefinite future. Currently, the existence of sanitation networks is a requirement to approve the construction of new developments in most nations.

Grades

• - Collector.

• - Usual definitions in water quality.

• - Submersible pump.

• - Tanker truck.

• - Cloaca.

• - Cloaca Maxima, the "Main Sewer" of Rome.

• - Water purification or treatment.

• - Unblocker.

• - Drainage.

• - Rainwater collection system.

• - Drainage system.

• - Wastewater treatment.

• - Pipe.

• - Septic tank.

• - Wikimedia Commons hosts a multimedia gallery on Sanitation Network.

• - Wikimedia Commons hosts a multimedia category on Paris Sewers.

• - Wikimedia Commons hosts a multimedia category on Cloaca Maxima of Rome.

• - Interview with Engineer Rafael Lenin Castro Zaldarriaga on the evolution of water conduction in Cuba Conversations about water, Chapter V.

• - Antonia Nájar Ruiz, «An eschato-logical affair», Revista de Libros, 162, June 2010.

Contenido

Las redes de saneamiento se puede construir de dos modos:[8]​.

• - Redes unitarias: las que se proyectan y construyen para recibir en un único conducto, mezclándolas, tanto las aguas residuales (urbanas e industriales) como las pluviales generadas en el área urbana cubierta por la red.

• - Redes separativas o redes separadas: constan de dos canalizaciones totalmente independientes; una, la red de saneamiento, transporta las aguas residuales domésticas, comerciales e industriales hasta una estación depuradora; y la otra, la red de drenaje pluvial, conduce las aguas pluviales hasta el receptor, que puede ser un río, un lago o el mar.

Las redes de saneamiento surgieron en las ciudades europeas durante el siglo en respuesta a los problemas sanitarios y epidemiológicos generados por la deficiente evacuación de las aguas fecales. En aquel momento la mayoría de estas ciudades disponían ya de un sistema de colectores destinados a la evacuación de las aguas de lluvia y residuales, pero sin conexión a estas de las bajantes de los edificios. Las aguas residuales se vertían a la calle y la lluvia las arrastraba a las cloacas, desde donde iban a una cauce.

Desde mediados del siglo empezaron a construirse redes separativas, tras la aparición de los primeros sistemas de depuración, y con base en los siguientes argumentos:.

• - la separación reduce los costes de depuración y simplifica los procesos, puesto que el caudal tratado es menor y, lo que es incluso más importante, más constante;.

• - la separación reduce la carga contaminante vertida al medio receptor por los episodios de rebosamiento de las redes unitarias.

Siendo correctos los argumentos anteriores, existen también una serie de inconvenientes del saneamiento separativo, del cual desde finales de los años 1990 se está incrementando su uso, principalmente en redes de nueva implantación (la separación de redes unitarias existentes pronto se vio como económica y técnicamente inviable).

Para el buen funcionamiento de las redes separadas debe prestarse mucha atención a los aspectos que siguen:.

• - Debe existir un estricto control de vertidos") para evitar que se acometan caudales residuales a la red de pluviales (que irían directamente al medio natural sin depurar) y viceversa. Esto último redundaría en una explotación más compleja y costosa de la red de saneamiento.

• - La separación completa implica redes interiores separativas en los edificios, con duplicación de las bajantes. En este frente los costes de instalación son importantes.

• - Las aguas pluviales urbanas no son aguas limpias, sino que suelen estar sucias, por lo que su vertido directo al cauce puede generar una contaminación apreciable.

• - La red de pluviales de una red separativa puede permanecer, en climas secos, sin agua durante periodos de tiempo extensos, sin la autolimpieza de los conductos en tiempo de lluvia, por lo que puede llegar a ser necesaria la descarga de caudales de agua limpia por la red (arquetas de descarga en las cabeceras del saneamiento), reduciendo las ventajas de ahorro y eficiencia.

En comparación con las redes unitarias, los principales problemas son:.

• - El coste de instalación es muy superior, entre 1,5 y 2 veces la red unitaria equivalente.

• - Los grandes cambios en el caudal dificultan mucho la operación de las plantas de tratamiento. Frecuentemente en los periodos de lluvias intensas las plantas de tratamiento son simplemente "by-pasadas", vertiendo los efluentes directamente sin tratamiento en los cuerpos receptores o construyendo balsas de retención para guardar durante unos días el exceso de aguas llegadas, mientras se van depurando.

Current trends

Since the last decade of the century, there has generally been a concern on the part of governments to reduce the gap between the coverage of water supply networks and sewage networks.

Simultaneously, it is no longer accepted to think about sanitation if the appropriate treatment, based on the categorization of the recipient, of the collected wastewater is not also integrated. (In Europe it is mandatory in towns of more than 5,000 inhabitants).

With almost always budgetary restrictions, except in exceptional cases, the competent authorities give priority to sanitation networks over rainwater collection networks.

In many countries, the characteristics of sanitation networks have been standardized.[9][note 1]​.

Initially, sanitation networks were built with cement pipes, masonry galleries, and fiber cement; and in some cases stoneware pipes were used; currently, the most commonly used materials are polyvinyl, PVC, polyethylene, polypropylene, as well as pipes made of polyester resins reinforced with GRP fiberglass.

Since the 1990s, pipe sizing has become increasingly common, considering not only the minimum velocity of the water in the pipe but also the drag force of the flow. This variant allows working with smaller slopes, which is an advantage in very flat areas.

Storm drainage networks have several different concepts. They are frequently buried networks, but they are combined with sections made up of open channels.

In the design of the storm drainage networks, in addition to the topography, which also dominates the sanitation network, the rainfall regime in the area plays a very important role.

The current trend is for stormwater networks to be separate from the sanitation networks, instead of unitary, to prevent them from overflowing and to take advantage of their water. [10]​.

La parte principal de dicho sistema está formada por grandes tuberías (es decir, los colectores, drenajes pluviales o "cloacas") que transportan las aguas residuales desde el punto de producción hasta el punto de tratamiento o descarga.

Los tipos de sistemas de saneamiento que generalmente son colectores que funcionan por gravedad incluyen:.

• - Red de saneamiento combinada.

• - Red de saneamiento simplificada.

• - Colector de aguas pluviales.

Las redes de saneamiento que no dependen únicamente de la gravedad incluyen:.

• - Sistema de saneamiento de aguas residuales al vacío[11]​.

• - Sistema de alejamiento y tratamiento de efluente.

Donde no se ha instalado un sistema de saneamiento, las aguas residuales pueden recolectarse de los hogares por tuberías hacia tanques sépticos o fosas negras, donde pueden tratarse o recolectarse en vehículos y llevarse para su tratamiento o eliminación (un proceso conocido como manejo de lodos fecales).

Main network components

The main components of a sanitation network, described in the direction of water circulation, are:

• - the connections, which are the set of elements that allow the water discharged by a building or property to be incorporated into the network. In turn, they are usually composed of:

• a starting manhole, already located inside the private property, and that separates the private sanitation network from the public ones;

• a connection pipe, buried conduit between that starting manhole and the street network; and

• a junction, between the connection pipe and the road network, consisting of a manhole, well or other technical solution.

• - tertiary collectors or sewage conduits, buried conduits in public roads, of small section, that transport the flow of connections and scuppers to a collector;

• - the collectors (or "secondary collectors"), which are the largest section pipes, frequently accessible, that collect water from the tertiary collectors and lead them to the main collectors. They are located buried, on public roads.

• - the main collectors, which are the largest collectors in the population and collect large flows, until they are delivered to their final destination or relieved before being incorporated into an outfall.

• - storm spillways, which are tanks where water from the collectors is retained when it is very high due to the effect of rain, to avoid flooding.

• - interceptor outfalls or simply interceptors, which are pipes that transport the water collected by the collectors to the treatment plant or its discharge into the natural environment, after its flow has already been regulated by the spillway.

Downstream, and outside of what is conventionally considered the sanitation network, the treatment plant and the final discharge of the treated water would be located:

• - through an emissary, taken to a river or stream.

• - discharged into the sea near the coast;

• - discharged into the sea through an underwater outfall, taking them several hundred meters from the coast;

• - reused for irrigation and other appropriate purposes.

Other complementary elements

In all sanitation networks there are also other minor elements:

• - The ditches, gutters and gutters, which collect and concentrate rainwater from the roads and surrounding lands;

• - scuppers, gutters or drains, which are the structures intended to collect rainwater and road washing water;

• - inspection wells, which are vertical chambers that allow access to the collectors to facilitate their maintenance.

And in a certain number of cases other more important structures are necessary:

• - Pumping stations: since the sewage network works by gravity, to function correctly the pipes must have a certain slope "Slope (mathematics)"), calculated to guarantee the water a minimum velocity that does not allow the sedimentation of the solid materials transported. In cities with flat topography, collectors can reach depths greater than 4 - 6 m, which makes their construction difficult and expensive and their maintenance complicated. In these cases it may be convenient to insert pumping stations into the network, which allow the served water to be raised to a level close to the level of the road.

• - Impulse lines: Pressure pipe that begins in a pumping station and ends in another collector or in the treatment station.

• - Retention tanks") or also wells or retention tanks: storage structures that are used in certain cases where it is necessary to laminate the floods produced by large storms, where they are not rare (reservoirs, lamination tanks or wells, or expansion arks")); and where it is necessary to retain a certain initial volume of rainfall to reduce contamination of the receiving environment (reservoirs, tanks or storm wells).

Pipelines and tunnels suffer severe wear forces, which can result in premature deterioration of the network. These include root intrusion, shifting of joints, cracks and hole formation leading to a significant volume of leaks with an overall risk to the environment and public health. For example, it is estimated that 500 million m of contaminated water per year can leak into soil and groundwater in Germany.[12] Rehabilitation and replacement of damaged sewage pipes is very expensive. The annual rehabilitation costs for Los Angeles County are approximately 400 million euros,[13]​ and in Germany, these costs are estimated at 100 million euros.[14]​.

Hydrogen sulfide (HS) is indirectly responsible for "biogenic sulfide corrosion" and, consequently, the sewer pipes need rehabilitation work. There are several repair options available to homeowners in a wide range of costs and potential durability. One option is the application of a cementitious material based on calcium aluminate cement, following a cleaning of the corroded structure to remove loose material and contaminants in order to expose a healthy, rough and clean substrate. Depending on the condition and the contamination of concrete, cleaning can vary from simple high-pressure water jet cleaning (200 bar) to actual hydrodemolition (2000 bars).

The sanitation network is considered a basic service, however the coverage of these networks in the cities of developing countries is negligible in relation to the coverage of drinking water networks. This generates significant health problems. For a long time, the concern of municipal or departmental authorities was more concerned with building drinking water networks, leaving the construction of sanitation networks for an indefinite future. Currently, the existence of sanitation networks is a requirement to approve the construction of new developments in most nations.

Grades

• - Collector.

• - Usual definitions in water quality.

• - Submersible pump.

• - Tanker truck.

• - Cloaca.

• - Cloaca Maxima, the "Main Sewer" of Rome.

• - Water purification or treatment.

• - Unblocker.

• - Drainage.

• - Rainwater collection system.

• - Drainage system.

• - Wastewater treatment.

• - Pipe.

• - Septic tank.

• - Wikimedia Commons hosts a multimedia gallery on Sanitation Network.

• - Wikimedia Commons hosts a multimedia category on Paris Sewers.

• - Wikimedia Commons hosts a multimedia category on Cloaca Maxima of Rome.

• - Interview with Engineer Rafael Lenin Castro Zaldarriaga on the evolution of water conduction in Cuba Conversations about water, Chapter V.

• - Antonia Nájar Ruiz, «An eschato-logical affair», Revista de Libros, 162, June 2010.