Case study:Glenbrook Wetlands: Difference between revisions

From RESTORE
Jump to navigation Jump to search
No edit summary
No edit summary
 
(27 intermediate revisions by 4 users not shown)
Line 1: Line 1:
{{Case study status
{{Case study status
|Approval status=Draft
|Approval status=Approved
}}
}}
{{Location
{{Location
|Location=51.647746622246224, -0.11766529030865058
|Location=51.647746622246, -0.11766529030865
}}
}}
{{Project overview
{{Project overview
|Status=In progress
|Status=In progress
|Project web site url=http://www.thames21.org.uk/salmons-brook/
|Themes=Flood risk management, Habitat and biodiversity, Monitoring, Social benefits, Water quality, Urban
|Themes=Flood risk management, Habitat and biodiversity, Monitoring, Social benefits, Water quality, Urban
|Country=England
|Country=England
Line 14: Line 15:
|Contact organisation=Thames 21
|Contact organisation=Thames 21
|Contact organisation url=www.thames21.org.uk
|Contact organisation url=www.thames21.org.uk
|Partner organisations=London Borough of Enfield, Thames Water, Environment Agency,  
|Partner organisations=London Borough of Enfield, Friends of Boxers Lake, Thames Water, Environment Agency,
|Name of parent multi-site project=Case_study:Rewilding Enfield's Urban Rivers
|Multi-site=No
|Multi-site=No
|Project picture=IMAG0001.jpg
|Project picture=IMAG0001.jpg
|Picture description=Wetland cell 2
|Picture description=Wetland basin 2 - Jan 2016
|Project summary=Thames21 has been working with Enfield Council, The Environment Agency and Thames Water to improve the health of the Salmons Brook and its tributaries.  Enfield has a separate sewage system, meaning that surface water eg. rain running off roads and wastewater are carried in two separate pipes.  As a result, pollutants enter the Salmons Brook in a number of different ways.  Misconnected plumbing contributes nutrients such as phosphates and nitrates and coliform bacteria, road run-off inputs oils and heavy metals such as zinc and copper, and household and industrial waste is dumped into surface water drains.  
|Project summary=Thames21 has been working with Enfield Council, The Environment Agency and Thames Water to improve the health of the Salmons Brook and its tributaries.  Enfield has a separate sewage system, meaning that surface water eg. rain running off roads and wastewater are carried in two separate pipes.  As a result, pollutants enter the Salmons Brook in a number of different ways.  Misconnected plumbing contributes nutrients such as phosphates and nitrates and coliform bacteria, road run-off inputs oils and heavy metals such as zinc and copper, and household and industrial waste is dumped into surface water drains.  
    
    
Line 25: Line 27:


The Glenbrook wetlands were complete in September 2014 after three months of construction.  Local volunteers helped to plant the wetlands in September 2014 and again in March 2015. The system is designed so that in low flow conditions a series of weirs direct all baseflow into the wetlands, whilst in high flow conditions a large proportion of the flow continues downstream and only the first flush is treated.  The headwater of the Glenbrook which feeds this system drains an urban catchment of 42 ha.  In addition, 15 gullies have been redirected from the roads that surround the site into the wetland treatment system through a series of swales.
The Glenbrook wetlands were complete in September 2014 after three months of construction.  Local volunteers helped to plant the wetlands in September 2014 and again in March 2015. The system is designed so that in low flow conditions a series of weirs direct all baseflow into the wetlands, whilst in high flow conditions a large proportion of the flow continues downstream and only the first flush is treated.  The headwater of the Glenbrook which feeds this system drains an urban catchment of 42 ha.  In addition, 15 gullies have been redirected from the roads that surround the site into the wetland treatment system through a series of swales.
   


Works include:
*Overdeepened and incised channel bed raised
*Tree works and creation of 6 linked wetland basins, swales taking road run off into basins
|Monitoring surveys and results=Nitrogen and phosphate are essential for river life but in excess they cause eutrophication. This results in reduced levels of oxygen in the water and may cause toxic algal blooms. Nitrate may be present as ammonia, nitrite or nitrate (measured together as Total Nitrogen), but nitrate is the most stable form. Our water quality monitoring has shown that the SUDS basins are effective at removal of Total nitrogen, nitrates and phosphates. Water quality improves between sampling location 1 (the inflow to the SUDS) and location 2 (outflow from the SUDS), particularly in total nitrogen (dropping from 10mg/l to 6mg/l) and nitrate (dropping from 13mg/l to 7mg/l), bringing water quality within acceptable guideline levels (as defined in EA General Quality Assessment, Water Framework Directive 2014).  
|Monitoring surveys and results=Nitrogen and phosphate are essential for river life but in excess they cause eutrophication. This results in reduced levels of oxygen in the water and may cause toxic algal blooms. Nitrate may be present as ammonia, nitrite or nitrate (measured together as Total Nitrogen), but nitrate is the most stable form. Our water quality monitoring has shown that the SUDS basins are effective at removal of Total nitrogen, nitrates and phosphates. Water quality improves between sampling location 1 (the inflow to the SUDS) and location 2 (outflow from the SUDS), particularly in total nitrogen (dropping from 10mg/l to 6mg/l) and nitrate (dropping from 13mg/l to 7mg/l), bringing water quality within acceptable guideline levels (as defined in EA General Quality Assessment, Water Framework Directive 2014).  


Line 32: Line 36:


Invertebrate surveys have also been carried out as part of this project.  A masters student from Kings College London (KCL) undertook research into invertebrate populations at each of the project sites.  Linking the invertebrate survey results to water quality data, the student predicted the impact/ potential impact of each of the SuDS/wetland schemes on population sizes and diversity over time.  There was no existing data on invertebrates for the catchment before research was carried out.  As predicted the invertebrate survey confirmed findings of poor water quality, with pollution sensitive taxa very badly represented.  The study concluded that the SuDS have the potential to improve water quality and ecological outcomes downstream, but far greater efforts in reducing pollutants from vehicle use and misconnections will be required to resolve the problems of urban diffuse pollution.
Invertebrate surveys have also been carried out as part of this project.  A masters student from Kings College London (KCL) undertook research into invertebrate populations at each of the project sites.  Linking the invertebrate survey results to water quality data, the student predicted the impact/ potential impact of each of the SuDS/wetland schemes on population sizes and diversity over time.  There was no existing data on invertebrates for the catchment before research was carried out.  As predicted the invertebrate survey confirmed findings of poor water quality, with pollution sensitive taxa very badly represented.  The study concluded that the SuDS have the potential to improve water quality and ecological outcomes downstream, but far greater efforts in reducing pollutants from vehicle use and misconnections will be required to resolve the problems of urban diffuse pollution.
|Lessons learn=At this site in particular we came across some levels of reticence from the local community to the project, mainly due to the significant changes to the landscape and lack of familiarity around SuDS, as well as a lack of understanding of why they were desperately needed.  We overcame this by being very  transparent and available, and in taking care of the site and the stream and making obvious improvements to its health and potential as a wildlife habitat.  Regular communications in many forms were key.  This became the site at which volunteer days were best attended by local residents.  In future projects it would be ideal to spend a time in the build-up to the project engaging the community about water quality issues, rather than to do this simultaneously with planning the SuDS.  
|Lessons learn=At this site in particular we came across some levels of reticence from the local community to the project, mainly due to the significant changes to the landscape and lack of familiarity around SuDS, as well as a lack of understanding of why they were desperately needed.  We overcame this by being very  transparent and available, and in taking care of the site and the stream and making obvious improvements to its health and potential as a wildlife habitat.  Regular communications in many forms were key.  This became the site at which volunteer days were best attended by local residents.  In future projects it would be ideal to spend a time in the build-up to the project engaging the community about water quality issues, rather than to do this simultaneously with planning the SuDS.  


Line 38: Line 41:
    
    
We experienced some design issues which resulted from a lack of quality data pre-project, for example on flows.  It would have been prohibitively expensive for us to get the data needed on this project budget, but it meant that some SuDS elements such as weirs required some costly remediation work.
We experienced some design issues which resulted from a lack of quality data pre-project, for example on flows.  It would have been prohibitively expensive for us to get the data needed on this project budget, but it meant that some SuDS elements such as weirs required some costly remediation work.
}}
{{Image gallery}}
{{Case study image
|File name=Basin 1 creation.JPG
|Caption=Creating basin 1
}}
{{Case study image
|File name=Site of basin 6.JPG
|Caption=Site of basin 6
}}
{{Case study image
|File name=Basin 6 with water.JPG
|Caption=Basin 6 with water
}}
{{Case study image
|File name=Planting in basin 6.JPG
|Caption=Planting in basin 6 - April 2015
}}
{{Case study image
|File name=Drain marking pic.jpg
|Caption=Drain markers installed around site
}}
{{Case study image
|File name=Misconnections pollution.JPG
|Caption=Pollution from misconnections
}}
{{Case study image
|File name=Basin 2 July 2015.JPG
|Caption=Basin 2 July 2015
}}


{{Case study image
|File name=Planting basin 3.JPG
|Caption=Planting wetland basin 3
}}
}}
{{Image gallery}}
{{Image gallery end}}
{{Image gallery end}}
{{Toggle button}}
{{Toggle button}}
{{Toggle content start}}
{{Toggle content start}}
{{Case study subcatchment}}
{{Case study subcatchment
{{Site}}
|Subcatchment=Salmons Brook
{{Project background}}
}}
{{Motivations}}
{{Site
{{Measures}}
|Name=Glenbrook
|WFD water body code=GB106038027960
|WFD (national) typology=Type 18: small loess-loam dominated lowland river
|WFD water body name=Salmons Brook
|Heavily modified water body=Yes
|Protected species present=No
|Invasive species present=Yes
|Dominant substrate=London Clay
|River corridor land use=Urban
}}
{{Project background
|Reach length directly affected=220
|Project started=2012/09/01
|Funding sources=Defra, Environment Agency, London Borough of Enfield, Thames Water,
}}
{{Motivations
|Specific mitigation=Poor water quality (urban run off and misconnections), Urbanisation,
|Hydromorphological quality elements=Good status in 2011
|Biological quality elements=In 2011 - Phytobenthos, macrophytes, invertebrates poor and fish moderate
|Physico-chemical quality elements=In 2011 - Ammonia moderate, dissolved oxygen and phosphate poor, annex 8 chem. high
|Other motivation=Improving a public space, flood protection, terrestrial biodiversity improvements
}}
{{Measures
|Bank and bed modifications measure=Bed raising,
|Floodplain / River corridor=Tree management, Creation of swales and wetland basin,
|Planform / Channel pattern=n/a
|Other technical measure=n/a
|Management interventions=Opening of tree canopy to encourage varied ground flora
|Social measures=Community consultation, Community involvement, Community Education, Interpretation boards, Improved public access,
|Wider stakeholder / citizen engagement=n/a
}}
{{Hydromorphological quality elements header}}
{{Hydromorphological quality elements header}}
{{End table}}
{{End table}}

Latest revision as of 08:35, 6 June 2017

0.00
(0 votes)


To discuss or comment on this case study, please use the discussion page.


Location: 51° 38' 51.89" N, 0° 7' 3.60" W
Loading map...
Left click to look around in the map, and use the wheel of your mouse to zoom in and out.


Project overview

Edit project overview
Status In progress
Project web site http://http://www.thames21.org.uk/salmons-brook/
Themes Flood risk management, Habitat and biodiversity, Monitoring, Social benefits, Water quality, Urban
Country England
Main contact forename Aimee
Main contact surname Felus
Main contact user ID User:AimeeThames21
Contact organisation Thames 21
Contact organisation web site http://www.thames21.org.uk
Partner organisations London Borough of Enfield, Friends of Boxers Lake, Thames Water, Environment Agency
Parent multi-site project

Case_study:Rewilding Enfield's Urban Rivers

This is a parent project
encompassing the following
projects
No
Wetland basin 2 - Jan 2016

Project summary

Edit project overview to modify the project summary.


Thames21 has been working with Enfield Council, The Environment Agency and Thames Water to improve the health of the Salmons Brook and its tributaries. Enfield has a separate sewage system, meaning that surface water eg. rain running off roads and wastewater are carried in two separate pipes. As a result, pollutants enter the Salmons Brook in a number of different ways. Misconnected plumbing contributes nutrients such as phosphates and nitrates and coliform bacteria, road run-off inputs oils and heavy metals such as zinc and copper, and household and industrial waste is dumped into surface water drains.

With great support from local people we’ve created Sustainable Drainage Systems (SuDS), or ’rainscapes’ to intercept the pollution. As well as filtering pollutants out of water, the SuDS also help reduce local flood risk by slowing the flow, create wildlife habitats and provide new amenities for local people.

The Glenbrook is a tributary of the Salmons Brook. It flows through underground pipes for much of its length. Hidden away it is damaged, and when it first emerges above ground it is already very badly polluted. Six linked wetlands have been created here to filter pollutants from the stream. The flow is directed through each wetland, being successively cleaned as it is slowed through the basins. Plants use nutrients such as phosphate and nitrate to grow, removing them from the water and stopping them polluting the stream. Bacteria in the soil and root systems break down oils and heavy metals. Once established the planted wetlands not only clean the water, they also add a new dimension to the habitat mosaic for wildlife, and give interest and colour for those passing by.

The Glenbrook wetlands were complete in September 2014 after three months of construction. Local volunteers helped to plant the wetlands in September 2014 and again in March 2015. The system is designed so that in low flow conditions a series of weirs direct all baseflow into the wetlands, whilst in high flow conditions a large proportion of the flow continues downstream and only the first flush is treated. The headwater of the Glenbrook which feeds this system drains an urban catchment of 42 ha. In addition, 15 gullies have been redirected from the roads that surround the site into the wetland treatment system through a series of swales.

Works include:

  • Overdeepened and incised channel bed raised
  • Tree works and creation of 6 linked wetland basins, swales taking road run off into basins

Monitoring surveys and results

Edit project overview to modify the Monitoring survey and results.


Nitrogen and phosphate are essential for river life but in excess they cause eutrophication. This results in reduced levels of oxygen in the water and may cause toxic algal blooms. Nitrate may be present as ammonia, nitrite or nitrate (measured together as Total Nitrogen), but nitrate is the most stable form. Our water quality monitoring has shown that the SUDS basins are effective at removal of Total nitrogen, nitrates and phosphates. Water quality improves between sampling location 1 (the inflow to the SUDS) and location 2 (outflow from the SUDS), particularly in total nitrogen (dropping from 10mg/l to 6mg/l) and nitrate (dropping from 13mg/l to 7mg/l), bringing water quality within acceptable guideline levels (as defined in EA General Quality Assessment, Water Framework Directive 2014).

Coliform bacteria derive from faecal waste and are an indicator of pathogens in the aquatic environment. They enter waterways from misconnected toilets, sewage treatment plant overflow, domestic pets and agricultural run off. The SUDS basins are extremely effective at removal of coliform bacteria. Water quality improves between sampling location 1 (the inflow to the SUDS) and location 2 (outflow from the SUDS), with coliform counts dropping from approximately 1400 total coliform colonies to approximately 400 total coliform colonies, bringing water quality within acceptable guideline levels (under EC Bathing Water Directive).

Invertebrate surveys have also been carried out as part of this project. A masters student from Kings College London (KCL) undertook research into invertebrate populations at each of the project sites. Linking the invertebrate survey results to water quality data, the student predicted the impact/ potential impact of each of the SuDS/wetland schemes on population sizes and diversity over time. There was no existing data on invertebrates for the catchment before research was carried out. As predicted the invertebrate survey confirmed findings of poor water quality, with pollution sensitive taxa very badly represented. The study concluded that the SuDS have the potential to improve water quality and ecological outcomes downstream, but far greater efforts in reducing pollutants from vehicle use and misconnections will be required to resolve the problems of urban diffuse pollution.

Lessons learnt

Edit project overview to modify the lessons learnt.


At this site in particular we came across some levels of reticence from the local community to the project, mainly due to the significant changes to the landscape and lack of familiarity around SuDS, as well as a lack of understanding of why they were desperately needed. We overcame this by being very transparent and available, and in taking care of the site and the stream and making obvious improvements to its health and potential as a wildlife habitat. Regular communications in many forms were key. This became the site at which volunteer days were best attended by local residents. In future projects it would be ideal to spend a time in the build-up to the project engaging the community about water quality issues, rather than to do this simultaneously with planning the SuDS.

Water quality issues were far more significant than we had anticipated on commencement of the project, particularly in relation to domestic misconnections. Serious pollutant levels damaged the beginning of our SuDS system as Glenbrook. We also found that although we proved our systems had a beneficial impact on water quality, just downstream of each project were outfalls which would bring in yet more pollutants. Therefore SuDS alone could not demonstrate catchment level water improvements needed under WFD. Small scale SuDS have a place in a suite of wider measures that need to be tackled with more drive, especially pollutant impacts from misconnections and vehicle use.

We experienced some design issues which resulted from a lack of quality data pre-project, for example on flows. It would have been prohibitively expensive for us to get the data needed on this project budget, but it meant that some SuDS elements such as weirs required some costly remediation work.


Image gallery


Creating basin 1
Site of basin 6
Basin 6 with water
Planting in basin 6 - April 2015
Drain markers installed around site
Pollution from misconnections
Basin 2 July 2015
Planting wetland basin 3
ShowHideAdditionalImage.png


Catchment and subcatchment

Catchment

River basin district Thames
River basin London

Subcatchment

River name Salmons Brook
Area category 10 - 100 km²
Area (km2)
Maximum altitude category 100 - 200 m
Maximum altitude (m) 136136 m <br />0.136 km <br />13,600 cm <br />
Dominant geology Calcareous
Ecoregion Great Britain
Dominant land cover Suburban
Waterbody ID GB106038027960



Other case studies in this subcatchment: Alma Road Rain Gardens, Bury Lodge Wetlands, Enfield Town Park Wetlands, Grovelands Park Wetlands, Houndsden Road Rain Gardens, Laymer Road Silt Trap and Recreational Ground, Rewilding Enfield's Urban Rivers, Salmons Brook Flood Alleviation Scheme, Montagu Recreation Ground site, Salmons Brook River Restoration at Laymer Road, Salmons Brook at Grange Park


Site

Name Glenbrook
WFD water body codes GB106038027960
WFD (national) typology Type 18: small loess-loam dominated lowland river
WFD water body name Salmons Brook
Pre-project morphology
Reference morphology
Desired post project morphology
Heavily modified water body Yes
National/international site designation
Local/regional site designations
Protected species present No
Invasive species present Yes
Species of interest
Dominant hydrology
Dominant substrate London Clay
River corridor land use Urban
Average bankfull channel width category
Average bankfull channel width (m)
Average bankfull channel depth category
Average bankfull channel depth (m)
Mean discharge category
Mean annual discharge (m3/s)
Average channel gradient category
Average channel gradient
Average unit stream power (W/m2)


Project background

Reach length directly affected (m) 220220 m <br />0.22 km <br />22,000 cm <br />
Project started 2012/09/01
Works started
Works completed
Project completed
Total cost category
Total cost (k€)
Benefit to cost ratio
Funding sources Defra, Environment Agency, London Borough of Enfield, Thames Water

Cost for project phases

Phase cost category cost exact (k€) Lead organisation Contact forename Contact surname
Investigation and design
Stakeholder engagement and communication
Works and works supervision
Post-project management and maintenance
Monitoring



Reasons for river restoration

Mitigation of a pressure Poor water quality (urban run off and misconnections), Urbanisation
Hydromorphology Good status in 2011
Biology In 2011 - Phytobenthos, macrophytes, invertebrates poor and fish moderate
Physico-chemical In 2011 - Ammonia moderate, dissolved oxygen and phosphate poor, annex 8 chem. high
Other reasons for the project Improving a public space, flood protection, terrestrial biodiversity improvements


Measures

Structural measures
Bank/bed modifications Bed raising
Floodplain / River corridor Tree management, Creation of swales and wetland basin
Planform / Channel pattern n/a
Other n/a
Non-structural measures
Management interventions Opening of tree canopy to encourage varied ground flora
Social measures (incl. engagement) Community consultation, Community involvement, Community Education, Interpretation boards, Improved public access
Other n/a


Monitoring

Hydromorphological quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Biological quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Physico-chemical quality elements

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative

Any other monitoring, e.g. social, economic

Element When monitored Type of monitoring Control site used Result
Before measures After measures Qualitative Quantitative


Monitoring documents



Additional documents and videos


Additional links and references

Link Description

Supplementary Information

Edit Supplementary Information