SuDS designs must consider water quality and water quantity in parallel – and use robust design data to avoid problems for asset owners, warns Stuart Crisp, UK manager at Advanced Drainage Systems (ADS).
SuDS design is becoming ever more complex. There’s a growing awareness that we must look after our water quality more carefully, backed up by policy such as the Plan for Water, published last year.
Where there are risks that surface water will carry pollutants, it must be treated, whether using natural or proprietary components, to reduce them to where they are not considered harmful to the environment. Where pollutant loads are low, natural vegetative SuDS may be able to do that job. Where they are higher, some form of manufactured treatment may be needed.
The asset owner needs to be assured that all the components of a SuDS system will perform as designed in relation to water quality as well as water quantity – and that they will continue to do so over the lifetime of the development. That includes ensuring that the data related to the pollutant removal capability of those components is robust. Otherwise, there is a risk that an asset becomes a liability.
Designing for water quality
The CIRIA SuDS Manual C753 suggests a risk-based approach for designing water quality in SuDS management trains – the series of components that make up the drainage system. It provides pollution hazard indices for different types of site, and for three forms of pollution: total suspended solids (TSS), metals and hydrocarbons. It also gives mitigation indices (MIs) for natural SuDS components.
The designer must then select components whose combined MIs meet or exceed the pollution hazard indices for the predicted pollutants, noting that only 50% of the published MI value can be used for components downstream of the first treatment stage.
For manufactured components, British Water’s 2022 how to guide, Applying The CIRIA SuDS Manual (C753) Simple Index Approach To Proprietary Manufactured Stormwater Treatment Devices, provides a method for calculating mitigation indices for TSS, metals and hydrocarbons. This allows manufacturers of treatment devices to publish their MIs to a recognised methodology and designers can select the right combination of elements in a SuDS management train using reliable data, verified by a third party, to meet the pollution hazard indices of a development area.
Adopting a problem
Although it now looks like Schedule 3 of the Flood and Water Management Act 2010 may not be activated until 2025, England will need to meet more demanding requirements for water quality. At this point, the body adopting the SuDS must ensure that they are taking on something that performs as claimed over the whole of its lifetime.
Our advice would be to do due diligence to determine how MIs have been derived, what methodology was applied and to insist that the process and results have been verified by a third party expert.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.
HISTORICALLY, driven by legislation, there’s a tendency to focus on water quantity – how to use SuDS to reduce or delay release of stormwater into sewers and prevent flooding. However, new legislation requires the additional focus on water quality. The SuDS treatment train considers water quality and prevention of pollution from stormwater runoff (alongside flood risk mitigation), with the level of treatment provided based on the anticipated levels and types of pollution.
A SuDS treatment (or management) train should start with prevention such as reducing impermeable surfaces, to reduce run-off and remove sources of pollution. Next comes source control, where rainfall is dealt with close to where it falls by infiltration-based elements such as soakaways, rain gardens and permeable pavements. Site control sees water managed within a local area, for instance directing water to a soakaway or infiltration device and then onto an attenuation pond or tank. Finally, regional control would see a system that could handle run-off from several sites, perhaps resulting in a detention basin or wetland.
The SuDS Manual, C753, published by CIRIA, prescribes a risk-based approach to designing SuDS for water quality. If pollution risks are deemed to be low, then SuDS designers can prioritise water quantity, amenity and biodiversity. If they are medium, then all considerations must be balanced. And if they are high, water quality evaluation must take precedence. It should however be noted that in all cases, including medium and low pollution risk sites, appropriate mitigation should be put in place to reduce the risk of pollution.
There is a range of water quality treatment measures that can be included in a SuDS train. Sometimes it is possible to use a completely natural SuDS train to deal with both water quantity and quality issues. At other times, the best solution combines natural and engineered SuDS elements, or may require proprietary manufactured elements only. This could be due to high levels of pollution loading or the space available.
There are four main types of pollutant that can be found in stormwater run-off: sediments, metals, hydrocarbons and nutrients. Sediments, often referred to in pollution mitigation as total suspended solids (TSS), is particulate matter. It includes tiny particles of soil, such as silt and clay, which have been dislodged by rainwater as it passes over the run-off surfaces.
Metals and metal compounds can be dissolved in run-off or attached to silts and sediments in the water. Copper and zinc are most commonly found in surface water in the UK but there can be cadmium and other toxic metals too. Although plants require very small amounts of copper and zinc to grow, higher concentrations can be damaging to them.
Hydrocarbon pollution comes with run-off from roads, car parks and areas where machines operate and are maintained, due to oil and fuel spills, tyre and brake wear. Changing climate means that rainfall events can be further apart but more intense, which can lead to higher concentrations of pollutants from roads, as they build up for longer before being washed away.
Nutrient pollution, usually nitrogen or phosphorous based, can come from sources such as run-off from agricultural land where fertiliser has been used or combined sewer overflows (CSOs), where sewage and surface water are mixed and discharged into bodies of water. They can lead to algal blooms, which reduces oxygen levels in the water and can negatively impact on aquatic habitats.
Capturing TSS pollution should generally be the focus of water treatment strategies in SuDS design since this removes both the solid particles and any pollution clinging to them. This can be done using a natural SuDS feature, such as planting for bioretention or a swale. Manufactured components such as filtration devices, silt traps or vortex separators can also be used upstream to remove solids before water is discharged into ponds, for instance.
Removal of sediment and solids is also important from a water quantity perspective. Build-ups reduce the capacity of a water storage element, whether natural or manufactured. How and when to remove sediment should be considered at the design stage and should be part of a planned maintenance regime.
Without a means of reducing suspended solids upstream of an attenuation device, sediment build-up within the device can reduce its efficiency over time. Some recently introduced underground arch-shaped SuDS attenuation devices have their own built-in systems for intercepting solids which are fast and simple to maintain.
Mitigation indices
The SuDS Manual sets out a simple method for dealing with water pollution risks, requiring the determination of pollution hazard indices for the area under consideration and then matching a SuDS device with matching mitigation indices.
In Table 26.2, the manual provides pollution hazard indices for a range of applications and for three types of pollution: TSS, metals and hydrocarbons. So, for example, for a busy public car park such as a supermarket or hospital, the index for TSS is 0.7, for metals is 0.6 and for hydrocarbons 0.7.
The next step is to identify a form of SuDS treatment that can provide the necessary mitigation indices, either as a single treatment stage or using a combination of components. The Manual has a table for that too, Table 26.3. However, this table only provides mitigation indices for natural SuDS components. The mitigation indices for the natural SuDS components were compiled by a team of experts, drawing information from a selection of published papers.
Mitigation indices for proprietary manufactured treatment systems must be provided by the manufacturer using recognised test methods and 3rd party verified data.
British Water has published a Code of Practice for the Assessment of Manufactured Treatment Devices Without a means of reducing suspended solids upstream of an attenuation device, sediment build-up within the device can reduce its efficiency over time. Some recently introduced underground arch- shaped SuDS attenuation devices have their own built-in systems for intercepting solids which are fast and simple to maintain
Designed to Treat Surface Run-off. It uses rainfall time-series data for the UK to determine an appropriate treatment flow rates based on first-flush principles and uses a combination of two established test protocols – the German Deutsches Institut für Bautechnik (DIBt) and the New Jersey Corporation for Advanced Technology (NJCAT) from the US to create the British Water test methods.
In 2022 British Water published a ‘how to’ guide, Applying The CIRIA SuDS Manual (C753) Simple Index Approach To Proprietary/Manufactured Stormwater Treatment Devices, which provides a calculation methodology to derive mitigation indices for TSS, metals and hydrocarbons based on the British Water Code of Practice, or the DIBt or the NJCAT, test results. This enables manufacturers of proprietary treatment products to have their mitigation indices published so that they can be considered as part of a SuDS management train.
British Water publishes a List of Assessed Surface Water Treatment Devices, details of which can be found on their website.
For more information on Advanced Drainage Systems’ SuDS attenuation components, including a handy Design Tool, Mitigation Indices Data Sheet, Structural Design Technical Note and Installation App or to book a CPD, go to www.adspipe.co.uk
Following on from their article on SuDS and water quality in our June 2023 issue, Jo Bradley and Stuart Crisp take a practical look at how to design SuDS management trains to protect water quality – as well as preventing flooding, creating amenity and enhancing biodiversity.
In our previous article we looked at the issue of water quality in SuDS design. Historically, SuDS designers have often focussed on flood prevention and amenity, but a well-designed system must consider measures to remove pollutants too. With an increasing focus on water quality from legislators and the public, this element of SuDS design is more important than ever.
Clearly, the way that surface water is treated before it enters a water body or returns to the ground will vary depending on how high the risk of pollution is. This article looks at what that means in practice through some illustrative examples of what SuDS management trains may look like for low, medium and high-risk development types.
A SuDS management train is a combination of interconnected SuDS components, used in series around a development site to capture, store and convey surface water and – where needed – to treat it to remove particulate, dissolved and dispersed pollutants. Designers must choose from a variety of SuDS components, both natural and manufactured, to control water quantity and quality, to create amenity value and to increase biodiversity.
The biodiversity piece of the SuDS puzzle is gaining more weight as new regulations come into force for larger developments. In simple terms, the biodiversity net gain regulations mean that planning permission will only be granted to new developments that enhance the natural environment rather than detract from it.
Deploying natural SuDS elements such as filter strips, swales or ponds can be a good way to increase biodiversity. In this respect the new biodiversity requirements appear to dovetail well with the planned enactment of Schedule 3 of the Flood and Water Management Act 2010, now expected in 2025, which will mandate SuDS for new developments in England.
However, there is a caveat. The mantra that ‘natural is best’ is leading to some misguided decisions.
SuDS designs that don’t take pollutant loading into account are resulting in the destruction of vegetation and in the creation of new habitats which are potentially poisoning the wildlife they have attracted. For instance, a study by Glasgow University indicated that pollutants in some SuDS ponds are inhibiting amphibian breeding and development, when compared to natural ponds in the same area.
What’s the risk?
For sites where there is a low risk of pollutants being present in surface water runoff, such as small or medium-sized housing developments, a focus on natural SuDS works well. However, where there is a higher risk of the presence pollutants such as sediments, metals, hydrocarbons and nutrients, a more balanced approach to designing SuDS management trains is needed, with an understanding of the expected concentrations of such pollutants and how to deal with them.
The CIRIA SuDS Manual C753 provides a method for dealing with water pollution risks by determining pollution hazard indices for a particular site and then matching SuDS components in the treatment train which have combined pollution mitigation indices equal to or exceeding the pollution hazard indices. The manualprovides pollution hazard indices for a variety of land uses and for three types of pollution: total suspended solids (TSS), metals and hydrocarbons. It also provides mitigation indices for natural SuDS components.
For manufactured components, British Water’s 2022 How To Guide, Applying The CIRIA SuDS Manual (C753) Simple Index Approach To Proprietary/Manufactured Stormwater Treatment Devices, provides a method for calculating mitigation indices for TSS, metals and hydrocarbons.
Note that maintenance considerations are a key part of the design process. All SuDS components, including pretreatment and storage elements, whether natural or manufactured, must be properly maintained so that the system operates as designed. Failure to do so could mean that pollutants are washed on into water bodies and ground water.
More background on these issues can be found in our previous article in the June 2023 issue of Drain Trader.
Low risk Case Study 1: Medium sized residential development
Pollution hazard level | Low |
Total suspended solids (TSS) | 0.5 |
Metals | 0.4 |
Hydrocarbons | 0.4 |
Table 1: Pollution hazard indices for medium-sized housing development (source: CIRIA C753 Table 26.2)
Type of SuDS component* | TSS | Metals | Hydrocarbons |
Swale | 0.5 | 0.6 | 0.6 |
Permeable pavement | 0.7 | 0.6 | 0.7 |
Detention basin | 0.5 | 0.5 | 0.6 |
Bioretention system | 0.8 | 0.8 | 0.8 |
Table 2: Mitigation indices for SuDS components selected (source: CIRIA C753 Table 26.3)
*Remember that after the first SuDS component in the treatment train, only half of the mitigation indices for other downstream components can be used in the calculation.
Consider a new housing development of around 50 homes. According to the CIRIA SuDS Manual, there are likely to be low levels of pollutants in any surface water runoff which means that they can be dealt with using natural SUDS.
Surface water from roads around the development could be collected in swales – shallow drainage channels which run parallel to the roads. These could convey water into a detention basin which would fill up during a heavy rainfall event and then dry out over time, so that pollutants left on the surface are degraded. Run-off from roofs and footpaths would be directed into bioretention zones or rain gardens with engineered media and planting to store and attenuate water.
Residential parking areas may have permeable paving to allow the rainwater to return to the ground where it falls. Permeable concrete block paving is often cited as a permeable paving media, but alternatives include appropriately graded bituminous and concrete pavements, grass reinforcement and bound or unbound gravels.
In areas where planning requirements call for phosphorus neutrality, the treatment train should start by maximising the opportunity for infiltration of stormwater to the ground, since the soil will capture phosphorous in the runoff. A bioretention zone or rain garden would be a good way to achieve this.
Water that cannot be infiltrated may need to pass through a suitable sediment capture component such as a vortex grit separator or oil/water separator (road gullies and catch pits are not recommended) which removes most of the sediment before transferring flow to growing plants that can remove more of the phosphorous. More guidance can be found in CIRIA publication C808 Using SuDS to reduce phosphorous in surface water runoff.
Low risk Case Study 2: School
Pollution hazard level | Low |
Total suspended solids (TSS) | 0.5 |
Metals | 0.4 |
Hydrocarbons | 0.4 |
Table 3: Pollution hazard indices for school (source: CIRIA C753 Table 26.2)
Type of SuDS component* | TSS | Metals | Hydrocarbons |
Swale | 0.5 | 0.6 | 0.6 |
Permeable pavement | 0.7 | 0.6 | 0.7 |
Detention basin | 0.5 | 0.5 | 0.6 |
Bioretention system | 0.8 | 0.8 | 0.8 |
Table 4: Mitigation indices for SuDS components selected (source: CIRIA C753 Table 26.3)
*Remember that after the first SuDS component in the treatment train, only half of the mitigation indices for other downstream components can be used in the calculation.
When designing SuDS for schools, there should be a strong focus on amenity. There is a fantastic opportunity to tell the story of the water cycle to the children who attend the school through the choice of components selected for the SuDS management train.
Water from the roof of the building can be carried in leaping gutters from the edge of the building into a bioremediation zone, which is an area of vegetation with layers of gravel and sand below them, designed to channel and filter surface water. Or the water could run down rain chains into planters, which the children would be able to plant up each year.
As for the housing development, school parking could utilise a permeable pavement. Water from the access road could run off into swales or filter strips. If the water can be managed at the surface, so that the children can see it moving around the site, this can help them to see how precious rainfall is.
For some schools, it may be possible to include a pond or permanent wetland, subject to a risk assessment which should take into account factors such as the ages and abilities of children at the school, whether they can access the water body when unsupervised and the depth of the water. Where they can safely be included, ponds or wetlands in the management train creates habitats for wildlife and provides new learning opportunities.
Medium risk Case Study 3: Retail car park
Pollution hazard level | Medium |
Total suspended solids (TSS) | 0.7 |
Metals | 0.6 |
Hydrocarbons | 0.7 |
Table 5: Pollution hazard indices for retail car park (source: CIRIA C753 Table 26.2)
Type of SuDS component* | TSS | Metals | Hydrocarbons |
Vortex separator | 0.8 | 0.5 | 0.7 |
Detention basin | 0.5 | 0.5 | 0.6 |
Table 6: Mitigation indices for SuDS components selected (source: CIRIA C753 Table 26.3)
For a site where there will be a larger car park, such as a retail development, SuDS management trains must be designed to cope with anthropogenic pollutants in the surface water: tyre wear particles, brake dust and hydrocarbons. Permeable paving may not be appropriate as an infiltration system as the risk of pollutants getting into the groundwater could be too high.
In this imagined development, there is sufficient space around the parking bays for a detention basin which will hold surface water in the case of heavy rainfall events. However, before the water goes to the basin, it must be pre-retreated to remove as much of the sediment as possible, and with it the pollutants that are attached to the sediment particles. A vortex separator, upstream of the basin, could perform this role.
From a biodiversity perspective, note that just because it is possible to create a new habitat doesn’t mean it is the right thing to do. Creating a small green space in a very dense urban area with no connectivity to other green spaces could be detrimental, rather than beneficial, to any wildlife that finds its way there.
Medium risk Case Study 4: Car park, constrained space
Pollution hazard level | Medium |
Total suspended solids (TSS) | 0.7 |
Metals | 0.6 |
Hydrocarbons | 0.7 |
Table 7: Pollution hazard indices for retail car park (source: CIRIA C753 Table 26.2)
Type of SuDS component | TSS | Metals | Hydrocarbons |
StormTech with Isolator Row | 0.8 | 0.6 | 0.7 |
Table 8: Mitigation indices for SuDS components selected (source: British Water Web Site – List of Assessed Surface Water Treatment Devices)
For car parks and other areas with a similar pollution risk, where the space for vegetative SuDS is limited, underground attenuation and treatment could make sense. The constraint on space could be due the limited land availability, which can be the case with smaller brownfield plots, or because losing too many parking spaces would make a development unviable.
In this situation, below-ground attenuation and treatment devices could work well. While components such as geocellular crates need additional devices upstream of them to remove sediment and other pollutants, there are now systems that have an in-built and easy-to-clean treatment system. In this example, we deploy the StormTech system which includes an Isolator Row to filter out sediment. This can be cleaned out at intervals using standard sewer jetting equipment, accessed via a manhole.
High risk Case Study 5: Motorway,
Pollution hazard level | High |
Total suspended solids (TSS) | 0.8 |
Metals | 0.8 |
Hydrocarbons | 0.9 |
Table 9: Pollution hazard indices for motorway (source: CIRIA C753 Table 26.2)
Type of SuDS component* | TSS | Metals | Hydrocarbons |
Oil/water separator | 0.8 | 0.6 | 0.9 |
Pond | 0.7 | 0.7 | 0.5 |
Table 10: Mitigation indices for SuDS components selected (sources: SPEL Class 1 Separator product literature; CIRIA C753 Table 26.3)
*Remember that after the first SuDS component in the treatment train, only half of the mitigation indices for other downstream components can be used in the calculation.
Although runoff from many motorways and major trunk roads currently goes straight into water courses without being treated, this should not be an option for new motorways. There is a high risk that there will be heavy amounts of pollutants in the water and that these will do harm to wildlife and plants.
For any application with high pollutant loading and a known presence of harmful runoff that can cause damage to the environment, the water should be treated before entering any vegetative components of a SuDS management train. In this example, we would deploy a properly sized oil/water separator which can take out over 80% of the TSS before it goes into the pond/basin and will capture oil spillages from accidents on the carriageway.
Having been treated to remove the sediment, the water could flow into a pond. Choosing a pond rather than a basin means that more of the residual sediment will settle out because the body of water in the pond slows down the flow more effectively and the sediment rests in one place for longer. However, pollutants clinging to the sediment will remain at the bottom of the pond and may need to be removed periodically.
It is important to get the balance right between pre-treatment in a manufactured device, where the sediment can be easily removed, and treatment in the pond where removal of the sediment is more difficult and expensive. Savings made in capital costs by selecting a smaller separator will soon be overshadowed by the long-term costs of removing sludge from the pond.
.
High risk Case Study 6: waste management site
Pollution hazard level | High |
Total suspended solids (TSS) | 0.8 |
Metals | 0.8 |
Hydrocarbons | 0.9 |
Table 11: Pollution hazard indices for waste management site (source: CIRIA C753 Table 26.2)
Type of SuDS component* | TSS | Metals | Hydrocarbons |
Oil water separator | 0.8 | 0.6 | 0.9 |
Stormwater filter | 0.8 | 0.6 | 0.7 |
Retention basin | 0.5 | 0.5 | 0.6 |
Automatic closure device at outlet from drainage network |
Table 12: Mitigation indices for SuDS components selected (sources: SPEL Class 1 Separator product literature,; CIRIA C753 Table 26.3)
*Remember that after the first SuDS component in the treatment train, only half of the mitigation indices for other downstream components can be used in the calculation.
The first step in designing a SuDS management train for a waste management site would be to determine what pollutants would be present on the site and their expected concentrations. These could include metals, hydrocarbons, chemicals and organic compounds.
Once the pollutants have been identified, suitable filters, treatment media or other manufactured devices can be specified. Surface water from any waste processing facility should be treated before it enters any vegetative SuDS features.
For our imagined site, which is processing mixed household waste at a recycling centre, there are risks of leaks and spillages from the oil tank, battery recycling, green waste, discarded paints and household pesticides and more. An oil/water separator will capture oil spillages but spillages of other substances, and pollution from dissolved metals must be captured using additional devices. This could be a special type of stormwater filter, using treatment media to capture the dissolved pollutants.
The SuDS management train should conclude with a vegetative device such as a retention basin where natural processes and micro-organisms can break down any residual pollutants, and the last suspended particles in the runoff can settle on the bottom of the basin. These devices will need to be monitored and maintained, and regular inspections will ensure that any problems are identified and rectified quickly.
Since waste treatment sites can have a high risk of fire, another important water quality issue for waste treatment sites is how the water used to fight a fire would be captured and treated. There needs to be a closure device at the outlet of the site to prevent contaminated water from leaving the area.
Informed decisions
The design of SuDS management trains is a multi-faceted exercise. Beyond controlling the quantity of water leaving a development, designs must preserve water quality and optimise opportunities to add amenity value and boost biodiversity.
Where the risk of pollutants in surface water runoff is low, the SuDS management train may consist only of natural components. For sites with a medium risk of pollutants, surface water should be treated before it reaches detention features such as ponds, basins or proprietary below-ground systems. Pre-treatment using natural or manufactured components may be possible, depending on circumstances. Surface water from high-risk sites with high pollutant loading should be treated by a suitable manufactured device before it is discharged into vegetative SuDS components.
Differences in the mitigation indices and the sizing of SuDS components to meet the treatment flow rate and the hydraulic (maximum) flow rate also need to be taken into account. Designers also need to have an understanding of the risk of the captured pollutants being flushed out during exceedance events and the pros and cons of the alternative options available.
Design choices should also take maintenance requirements and costs over the lifetime of a development into account, not least because of the need to create asset management strategies and agree commuted sums where SuDS are to be adopted. No system will perform as designed from a water quality or quantity perspective if its components are not properly inspected and maintained. This applies to both vegetative and manufactured elements.
Financial viability is an unavoidable issue. Current regulations regarding SuDS and commercial viability vary in Scotland and Wales. England has yet to decide; a consultation on the implantation of Schedule 3 is expected this year. For restricted brownfield sites, such as the one considered above, it could make sense to allow some room for manoeuvre, depending on the social, economic and environmental impacts of the planned development.
If we are to put together all the pieces of a SuDS jigsaw to the best effect, there must be early conversations between a broader range of stakeholders. Professionals across the supply chain will need to upskill and share knowledge. Some manufacturers of proprietary SuDS systems provide CPD seminars to help SuDS practitioners prepare for the recent changes and those round the corner.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.
Stuart Crisp, UK manager of Advanced Drainage Systems (ADS), looks at looming legislation which will mandate Sustainable Drainage Systems and explains why their adoption will require new skills for specifiers and developers.
In January 2023, the Government announced plans to finally implement Schedule 3 of the Flood and Water Management Act 2010, which will make the adoption of Sustainable Drainage Systems (SuDS) mandatory in England, as it has been in Wales since 2019. In Scotland, Schedule 3 has not been implemented, but SuDS is generally a requirement within planning legislation.
“Schedule 3 is a game changer for the drainage industry”
Subject to consultation, the implementation of Schedule 3, which includes SuDS approval and adoption, is expected in late 2024. That means there is less than a year for specifiers and developers to get up to speed with the range and implications of possible solutions, both above and below ground.
While developers currently have the right to connect drainage systems into sewers, that is unlikely to be the case anymore without prior justification and consent. Instead, they will have to show that they have included SuDS in their schemes and demonstrate how that SuDS system can be maintained over the lifetime of a development.
Designers and specifiers will have to think about more than just hydraulic design, and consider whole-life maintenance and treatment to deal with water quality issues and specific pollutants. There will probably be a transition period as Schedule 3 comes in, but it makes sense to upskill now in order to future-proof the design and specification of systems that are being planned now.
Currently, SuDS can be adopted by water companies as long as systems comply with the Design and Construction Guidance (DCG), which sets out how SuDS should be delivered. However, it is not compulsory to jump through the adoption hoops. The end result of this is that some assets do meet prescribed and consistent standards of quality and performance, may not be properly maintained and, consequently, there are problems down the line.
The DCG was updated last year to include arch-shaped belowground attenuation structures. One such system offers a flexible and cost-effective alternative to other below-ground attenuation structures such as crates or large-diameter pipes, with the benifit of built-in stormwater quality management, reducing the extent of additional treatment required elsewhere in the SuDS system.
It is expected that Schedule 3 will change the assessment and adoption of SuDS to become SuDS approving bodies (SABs), which will be within unitary councils or county councils. And new statutory guidance will be introduced, taking over from DCG to cover design, construction and operation over an asset’s lifetime.
The statutory requirements in England may be more onerous than both the DCG and the current non-statutory standards in terms of what will be acceptable for planning approval and adoption after construction. SuDS adoption becoming mandatory, with few exceptions, will raise the bar.
Happily, poor quality products and poorly executed designs are likely to be challenged and disappear from the market. For anyone looking to start the upskilling process now, training and CPDs are already available from some manufacturers and should include information on legislation, best practice and comparable systems.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.
In April 2023, Defra published its so-called ‘Plan for Water’ (fully titled Our integrated plan for delivering clean and plentiful water).
The aim of the plan is to create a more holistic approach to water management, ensuring that there is enough water to supply the UK’s population, and that the water in rivers, lakes and other water bodies is free from pollution. It promises action on all sources of pollution: wastewater treatment, agriculture, plastics, urban stormwater, road run-off and chemicals.
Among the raft of proposed legislation are changes to planning policy which aim to ensure that new developments are designed to reduce the likelihood of both flooding and water shortages. Water companies, which will have to produce Drainage and Wastewater Management Plans, could be involved in planning decisions.
The Plan for Water references the Government’s intention to finally implement Schedule 3 of the Flood and Water Management Act 2010, which covers SuDS approval and adoption, in England – subject to consultation. This could make the inclusion of SuDS standard practice in the design, construction and adoption of nearly all new developments from 2024.
Should Schedule 3 of the Flood and Water Management Act come into legislation, maintenance and longevity issues will be brought to the fore. In Wales, where Schedule 3 has already been adopted, developers are expected to create a maintenance plan and the adopting authority will be required to carry out the maintenance for the lifetime of a scheme.
SuDS Approval Bodies (SABs) within county and unitary authorities will be responsible for securing the means to maintain the SuDS they adopt, and it could be that the regulatory framework in England is similar to that used in Wales. As currently understood, the developer will provide a commuted sum as funding to the SAB at the point of handover.
Run-off from roads
The Plan also talks about the strategic road network and how more is needed to prevent pollution from highway run-off discharging into water courses. There are various approaches to treat polluted run-off from roads before it is infiltrated into the ground, enters a water body or stormwater sewer, with the possibility of using SuDS as part of the water treatment train.
Run-off from roads can contain high amounts of suspended solids which sit on the bed of a watercourse, bringing with them other pollutants which are released over time. Pollutants include polycyclic aromatic hydrocarbons (PAH), metals and microplastics from brakes and tyres. The result is a build-up of toxic pollution in riverbeds, water, fish and other aquatic life.
Only 4,000 out of 26,000 outfalls and soakaways from the Strategic Road Network, run by National Highways in England, have measures in place to treat pollution. The Plan for Water mentions this and says that it is “considering actions to take to reduce the impacts of the Strategic Road Network on water quality as part of developing the next Road Investment Strategy.”
The Government will also consider ‘targeted action’ for roads owned by local authorities whose road run-off is contributing to pollution.
Nutrient pollution
The Plan for Water reports £2.5bn of planned and made investment in wastewater treatment works between 2020 and 2025, which it says will halve phosphorous pollution. And it promises legislation to force water companies to make upgrades to nutrient removal near protected habitats. The Government’s Environment Act 2021 set a legally binding target to reduce phosphorus in treated wastewater by 80% by 2038 compared to a 2020 baseline, with an interim target of 50% by 2028.
Recent studies carried out by Stormwater Shepherds indicate that phosphorus pollution is not a major problem from stormwater runoff from most urban catchment surfaces. However, well designed SuDS help alleviate nutrient pollution where it is a problem. CIRIA guide C808, Using SuDS to reduce phosphorous in surface water run-off, published in 2022, provides guidance on how to do this. Similarly, the recently published CIRIA C815, which relates to SuDS for nitrogen reduction, may be regarded as a companion document to C808.
More SuDS, better quality
With water quality concerns moving up the agenda for members of the public, as well as national and local governments, the need for well designed, constructed and maintained SuDS will only increase. Depending on parameters including application, land area available, levels of pollution and flow rates, natural SuDS, engineered SuDS or a combination of the two can be the most appropriate solution.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.
There’s a choice of underground SuDS attenuation systems for new developments, each with their pros and cons. In the first article in a series of two, Stuart Crisp, UK manager of Advanced Drainage Systems, looks at large diameter pipes and crates together with the codes and standards that should be referenced in a product specification.
Large diameter pipes can be used for attenuation as a pipe laid in a single run or more commonly as a manifolded system, with pipes running in parallel lines. The most commonly used materials are concrete and plastic, although there are thin steel pipes and a hybrid product combining plastic and steel on the market.
Large diameter pipes can be a cost-effective choice of attenuation system, as long as there is sufficient available area to accommodate the volume of water that has to be stored. Where the attenuation space is beneath a public road, pipes that meet the required structural performance and highways authority requirements, can sometimes be used.
The choice of material will depend on considerations including capital cost, whole life cost taking into account maintenance and how many times a system may need replacing or upgrading and logistics requirements such as construction plant lifting capacity required and space for installation.
Pipes should be designed to BS 9295 to ensure their structural performance. Note that when pipes are laid in parallel, as is often the case for below-ground SuDS attenuation applications, a different approach to structural design is usually required compared with pipes laid as a single run.
For concrete pipes, BS EN 1916 and BS 5911-1 provide the details for product specifications. For plastic pipes, BS EN 13476 provides the details for product specifications.
Table of Standards relevant to large diameter pipes | |
BS 9295:2020 | Guide to the structural design of buried pipes |
Table of Standards Relevant to Concrete large diameter pipes | |
BS EN 1916: 2002 | Concrete pipes and fittings, unreinforced, steel fibre and reinforced |
BS5911-1 | Concrete pipes and ancillary concrete products (recently updated to align with Eurocodes) |
Table of Standards relevant to plastic pipes | |
EN 13476 | Plastics piping systems for non-pressure underground drainage and sewerage – Structured-wall piping systems of unplasticised polyvinyl chloride (PVC-U), polypropylene (PP) and polyethylene (PE) |
Crates or geocellular units can be a desirable choice of attenuation system where there is limited plan area since they provide a large void space for a limited footprint. There are a variety of geocellular unit types on the market which can be used at varying depths from shallow sub-base replacement systems for car parks to deeper attenuation tanks for higher volumes of storage.
Geocellular units are typically manufactured from polypropylene (PP) or PVC by injection molding, extrusion of joining thermoformed sheets. Assessment of the performance of thermoplastics (including plastic pipes and arches) needs to take into account the influence of creep over time; creep is the tendency to deform permanently over time under a constant stress.
Structural assessments of crates must consider short-term loading such as traffic and long-term loading, such as the weight of material above the tank and lateral earth loads. Use BS EN 17150, 17151 and 17152-1, along with material tests, to determine characteristic long-term and short-term strengths and specifications.
A geotextile or geomembrane is also part of the geocellular attenuation system and therefore must be properly specified, selected and installed. Catchpits, separators and other pre-treatment measures are vital to prevent the build-up of silt and sediment within the geocellular structure. CIRIA C737 explains how the long-term volume capacity of a crate should take into account the impact of silt and sediment. The need for effective sediment management as part of a crate-based below-ground SuDS attenuation system is also emphasized in CIRIA C753 The SuDS Manual.
Table of Standards relevant to crates | |
CIRIA C737 | Structural and geotechnical design of modular geocellular drainage systems |
BS EN17152-1 | Plastics piping systems for non-pressure underground conveyance and storage of non-potable water – Boxes used for infiltration, attenuation and storage systems Part 1: Specifications for storm water boxes made of PP and PVC-U |
Stuart Crisp is UK Manager for Advanced Drainage Systems (ADS). ADS is America’s largest manufacturer of thermoplastic corrugated drainage pipes and a specialist in water management systems. StormTech has a long and successful track record with over 50,000 below ground SuDS attenuation system installations using in excess of 3m units.
Originally published in Water magazine October 2023
Designers need a better understanding of the maintenance requirements of different SuDS components to ensure that the systems they design will perform as intended. Stuart Crisp, UK manager at Advanced Drainage Systems (ADS), reports.
The issue of SuDS maintenance has always been a thorny one. Research suggests that the question of who will be responsible for the maintenance, and the cost of it, has been a prime factor in their slow uptake in the United Kingdom.
With the Government’s intention to implement Schedule 3 of the Flood and Water Management Act 2010 (FWMA) in England, making the installation and adoption of SuDS mandatory, concerns over maintenance issues again come to the fore. Developers, designers and installers need to understand the maintenance implications for alternative solutions considered for a project (in addition to, for example, hydraulic performance, structural integrity and water quality) and then offered to the adopting body responsible for the long-term operation of the SuDS asset. For underground attenuation devices, these vary significantly.
The more onerous the maintenance requirements, the higher the risk of them not being properly executed. The impacts of poor maintenance regimes and difficult-to-clean systems can be significant, increasing the risk of blockages – leading to loss of capacity and flooding – and pollutants washing out into water bodies.
Guidance
The SuDS Manual, CIRIA C753, recognizes that underground attenuation crates are ‘difficult to clean’ and that their capacity will reduce over time. Section 21.5.3 of the manual recommends that the size of crates should be increased by 10% to allow for accumulation of sediment. This applies even when a maintenance programme is deployed, since it isn’t always possible to remove all sediment during cleaning. Commercial developments, high density residential development, car parks and highways face the highest potential loss of storage, according to the guidance.
For both crates and large diameter pipes, some form of silt separation and removal system upstream is normally required to slow down the rate of sediment build-up and to remove some of the pollutants that cling to those particles. These upstream components must also be inspected and cleaned at intervals prescribed in a SuDS maintenance plan.
In designing its StormTech underground attenuation device, ADS sought to remove the need for costly upstream pre-treatment. An inbuilt ‘Isolator Row’ – essentially a modified version of the standard StormTech elliptical arches – collects the sediment before the water moves into the main body of the system.
Independent tests have demonstrated that the Isolator Row removes over 80% of total suspended solids (TSS), together with the metals, hydrocarbons, phosphorus, nitrogen, and other surface water pollutants that cling to them. The Isolator Row is easily accessed via a closely located manhole, and can be cleaned out with standard sewer-cleaning equipment.
Natural SuDS need maintenance too
Natural SuDS, as well as engineered ones, also need regular and planned maintenance. These range from frequent interventions such as litter picking and inspection of inlets and outlets to more occasional and seasonal activities such as vegetation management and removal of silt build-up.
Again, failure to maintain natural attenuation components such as ponds can have negative impacts. A 2018 study of SuDS in East Kilbride by the University of Glasgow, published in The Glasgow Naturalist, found that pollutants in some SuDS ponds were hindering amphibian breeding and development and that more frequent monitoring and management would be wise.
Whether natural or engineered SuDS, or a combination, maintenance regimes and their associated cost, should not be a barrier to their implementation. However, it is important that maintenance issues are understood, planned and communicated at the earliest stages of a project.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.
Designers need a better understanding of the maintenance requirements of different SuDS components to ensure that the systems they design will perform as intended, Advanced Drainage Systems UK manager Stuart Crisp, reports.
The issue of SuDS maintenance has always been a thorny one. Research suggests that the question of responsibility for the maintenance, and the cost of it, has been a prime factor in their slow uptake in the UK.
With the government’s intention to implement Schedule 3 of the Flood and Water Management Act 2010 in England, making the installation and adoption of SuDS mandatory, concerns about
maintenance issues have again come to the fore. Developers, designers and installers need to understand the maintenance implications for alternative solutions considered for a project and then offered to the adopting body responsible for the long-term operation of the SuDS asset. These are in addition to, for example, hydraulic performance, structural integrity and water quality. For underground attenuation devices, these vary significantly.
The impacts of poor maintenance regimes and difficult to clean systems can be significant, increasing the risk of blockages – leading to loss of capacity and flooding – and pollutants washing out into water bodies.
The SuDS Manual, Ciria C753, recognises that underground attenuation crates are “difficult to clean” and that their capacity will reduce over time. Section 21.5.3 of the manual recommends that the size of crates should be increased by 10% to allow for accumulation of sediment. This applies even when a maintenance programme is deployed, since it is not always possible to remove all sediment during cleaning. Commercial developments, high density residential development, car parks and highways face the highest potential loss of storage, according to the guidance.
For crates and large diameter pipes, some form of silt separation and removal system upstream is normally required to slow down the rate of sediment build up and to remove some of the pollutants that cling to those particles. These upstream components must also be inspected and cleaned at intervals prescribed in a SuDS maintenance plan.
In designing its StormTech underground attenuation device, ADS sought to remove the need for costly upstream pre-treatment. An inbuilt “Isolator Row” – essentially modified StormTech elliptical arches –
collects the sediment before the water moves into the main body of the system.
Independent tests have demonstrated that the Isolator Row removes more than 80% of total suspended solids, together with the metals, hydrocarbons, phosphorus, nitrogen and other surface water pollutants that cling to them. The Isolator Row is easily accessed via a closely located manhole, and can be cleaned out with standard sewer cleaning equipment.
Natural SuDS, as well as engineered ones, also need regular and planned maintenance. These range from frequent interventions such as litter picking and inspection of inlets and outlets to more occasional and seasonal activities such as vegetation management and removal of silt build up.
Again, failure to maintain natural attenuation components such as ponds can have negative impacts.
A 2018 study of SuDS in East Kilbridge by the University of Glasgow published in The Glasgow Naturalist, found that pollutants in some SuDS ponds were hindering amphibian breeding and development and that more frequent monitoring and management would be wise.
Whether natural or engineered SuDS, or a combination, maintenance regimes and their associated costs, should not be a barrier to their implementation. However, it is important that maintenance issues are understood, planned and communicated at the earliest stages of a project.
For more information on Advanced Drainage Systems, visit www.adspipe.co.uk.