Supply Chain - Sewerage - Contractors

The Rivers Lugg and Wye have been identified as having high levels of phosphorus, which is causing eutrophication of these watercourses. Norton Wastewater Treatment Works (WwTW) discharges treated final effluent to the Norton Brook, a tributary of the River Lugg. Presteigne WwTW discharges treated final effluent directly into the River Lugg downstream of the Norton Brook confluence and Weobley WwTW discharges to Newbridge Brook, a tributary of the River Arrow and then River Lugg before joining the River Wye in Hereford. Norton WwTW Norton WwTW is a biofilter works located in Powys serving a population of 320. All wastewater flows arrive to the works by gravity and are treated on site before being discharged. The site previously had a descriptive consent and an unconsented storm discharge. The project driver was to reduce phosphorus to achieve a Total P of 0.65mg/l, with a regulatory completion date of 31 December 2021. Due to the proximity of Norton WwTW to Presteigne WwTW (approximately 3km), an identified option was to pump the Norton flows to the Presteigne catchment. An assessment of the hydraulic and biological capacity of Presteigne WwTW and the Presteigne sewerage network determined there was sufficient capacity to accept the pump-away solution whilst maintaining compliance with all permits. Therefore, the agreed solution was to replace Norton WwTW with a terminal pumping station, pump sewage into the existing sewer network draining to Presteigne WwTW. Consequently, the Norton WwTW would be decommissioned. [caption id="" align="alignnone" width="1200"] Norton SPS progressive cavity pumps - Courtesy of Morgan Sindall Infrastructure[/caption] Norton WwTW: Supply chain - key participants Designer: Arup Main contractor (WwTW & rising main): Morgan Sindall Electrical supply & installation: Protocol Control Systems (PCS) Ltd Inlet screens: Haigh Engineering Mechanical design/installation & steelwork: Industrial Pipework Services (IPS) Ltd Main pumps: Netzsch Pumps Washwater booster: Dutypoint Ltd MCC supply/install: Bridges Electrical Engineers Ltd Transfer to Presteigne Progressive cavity (PC) pumps were selected as the pumping method due to the complex nature of the 2km long rising main. The rising main has a number of peaks and troughs with washouts, air valves and sections operating under gravity. Furthermore, the inverted siphon section of the main may be susceptible to soft blockages which PC pumps were determined to be better suited to than submersible centrifugal pumps. Submersible pumps would be more susceptible to pressure fluctuations caused by potential air gulping in the downhill section of the main. The PC pumps are positioned on an above-ground slab along with valves and pipework to enable good operator and maintenance access. Split stator casing pumps were specified to provide ease of rotor replacement. To protect the PC pumps against ragging and wear, an inlet screen and grit chamber were set up upstream of them. The inlet screen is an Ace Screener® from Haigh Engineering Ltd, equipped with an integrated compactor and liquid separator unit. It is located beside the screen to facilitate the discharge of waste material into a skip. [caption id="" align="alignnone" width="1200"] Norton SPS: MCC kiosk and Haigh Engineering inlet screen - Courtesy of Morgan Sindall Infrastructure[/caption] Rising main Due to the length of the rising main, and the low flows coming into the pumping station on a regular basis, the output from the SPS would have been likely to suffer from septicity. This would cause particular odour problems as the discharge makes its way through the Presteigne network towards Presteigne WwTW. It was decided that potable water dosing be included within the design to reduce the risk of septicity. This has the added benefit of assisting in moving solids along the long rising main, which reduced the risk of soft blockages in the inverted siphon section of the main. During the construction of the rising main, a spider plough was utilised for sections within fields. This allowed for simultaneous excavation, pipe-laying, and covering to take place, resulting in minimal visual impact on the landscape. Additionally, this approach resulted in reduced staff involvement during this stage of construction, which was another advantage. A final air valve was required on the rising main before discharge, which is in close proximity to local housing and a children’s park. To prevent any odour-related complaints that might arise from the air valve, a carbon filter has been installed to scrub odours from the air released from the air valve. The chosen filter is a passive filter that can be easily installed within the air valve chamber. [caption id="" align="alignnone" width="1200"] Spider plough operation to construct the Norton WwTW pump away rising main - Courtesy of Morgan Sindall Infrastructure[/caption] Presteigne WwTW Presteigne WwTW is a biofilter works serving a population of 1,906 with a driver to reduce Total P to 1mg/l. The proposed solution is to provide chemical dosing at Presteigne to treat all the Presteigne network flows along with the additional pumped flows from Norton WwTW. The chosen system was ferric dosing with primary dosing upstream of the existing primary settlement tank (PST). A ferric delivery area design included a bunded tanker area in case of ferric spillages. This area had drainage with an interlock system, which meant the drainage penstock would close during ferric filling to prevent uncontrolled spillage to the environment. Innovative new dosing pipelines were utilised of flexible reinforced PVC type ‘hose-within-hose’ to provide double containment and an integral leakage detection system and alarm. This meant long continuous hose lengths can be run without breaks. An anti-ragging static mixer and pipework were located above ground to reduce health and safety risks, costs and environmental impacts associated with excavation works. To cope with the increased sludge production due to primary ferric dosing, a new sludge pumping station using PC pumps was designed. This is located alongside the existing PST de-sludge chamber. This was an above-ground element of mechanical plant, with access provided for operation and maintenance. Split casing pumps were specified to provide ease of rotor replacement. The progressive cavity pumps (duty/standby) couple directly into the sludge hopper chamber of the PST. [caption id="" align="alignnone" width="1200"] Presteigne WwTW: Ferric point of application (PoA) unit - Courtesy of Morgan Sindall Infrastructure[/caption] Alkalinity dosing was required as a result of the new ferric dosing. The identified solution for this was a small bag dosing plant with on-site mixing to create a liquid dose. A new point of application facility located on the side of the existing PST which discharges to the biological filter. It was determined that this point had enough hydraulic mixing for an effective alkalinity dose. The new works is achieving its ammonia consent with the current loading, but it had been identified that ammonia compliance could be a risk during AMP9. Nitrifying sand filters have been proposed as a technology to treat the ammoniacal nitrogen as a tertiary treatment solution. This has an added benefit of tertiary solids removal to give confidence in the total phosphorus consent. However, given the excellent performance of the works against consent and nitrifying capacity of the existing biofilters, the nitrifying sand filters will be phased into the works when required. Works included a new sampling arrangement with sampling kiosk, complete with an upstream diversion and reception chamber for when the nitrifying sand filter is constructed. Presteigne WwTW: Supply chain - key participants Designer: Arup Main contractor: Morgan Sindall Electrical supply & installation: Protocol Control Systems (PCS) Ltd Ferric dosing: Colloide Engineering Mechanical design/installation & steelwork: Industrial Pipework Services (IPS) Ltd Alkalinity dosing - BiCarb: Rospen Industries Primary settlement tank auto-desludge: SEEPEX UK Ltd Motor control centre supply & installation: GPS Group [caption id="" align="alignnone" width="1200"] Presteigne WwTW: Ferric dosing system and safety shower - Courtesy of Morgan Sindall Infrastructure[/caption] Innovations A number of innovations have been developed throughout the detailed design stage of Presteigne, including removing a number of pumping operations, thereby simplifying the process, and reducing costs and environmental impacts. The design also allowed for the removal of motorised mixing points for chemical dosing in favour of using the works hydraulics for mixing. Furthermore, a conventional solution would have called for an additional PST and humus settlement tank (HST) to provide redundancy to the works. By investigating the process performance, it was determined that the existing single PST and HST were sufficient across the operating range of the works. Therefore, the design proposed temporary bypass connection points upstream of both the PST and HST, with identified lay-down areas for temporary settlement units to be brought on site if required. This meant that the construction works could be completed within the existing site land boundary and saving capital and operational cost and carbon emissions. Weobley WwTW Weobley WwTW is a biofilter works located in Herefordshire serving a population of 1,153. All flows arrive to the works by gravity and are treated on site before being discharged. The works has P removal driver to achieve a Total P of 1.5mg/l. As at Presteigne WwTW, the proposed solution was to provide chemical dosing to reduce phosphorus. A ferric dosing system with primary dosing upstream of the existing PST complete with a ferric delivery area was provided. Given the added ferric dosing, it was expected there would be more sludge production. The existing sludge holding tanks had low abilities for controlling decant. The solution included for a new discharge tree with access arrangement to the existing sludge holding tanks for better operation. The existing works had no inlet screening, with only a macerator on site upstream of primary settlement. A Huber Technology RO9 screen with integrated screenings handling was installed in the existing inlet channel and provided new mechanical flooring with removable sections to provide flexibility for operating and maintenance of the screen. [caption id="" align="alignnone" width="1200"] Weobley WwTW: (left) Huber Technology inlet screen and (right) flow to full treatment pump station - Courtesy of Morgan Sindall Infrastructure[/caption] This provided significant cost and embodied carbon savings compared to a completely new screening installation. Downstream of the screen, an inlet flume was provided for flow measurement and control of the downstream lift pumping station. The flume was constructed off-site, allowing for greater dimensional accuracy than an on-site constructed flume, as well as reduced downtime for the site. A new lift pumping station for all incoming flows for treatment was required to provide a separate lift to the balancing tanks then the unscreened storm flows. The existing inlet pumping station was re-purposed as the storm pumping station, meaning the more efficient pumping station was operating for more of the time compared to the older storm pumping station, which only operated intermittently - hence saving on energy usage and operational carbon. An existing multi-use returns pumping station was used to pump humus returns and storm returns to the head of the works. This asset consisted of outdated and poorly operating pumps and valve work. A solution was developed to replace mechanical equipment within the existing dry-well, saving the need for a new complete pumping station. Weobley WwTW: Supply chain - key participants Designer: Arup Main contractor: Morgan Sindall Electrical supply & installation: Protocol Control Systems (PCS) Ltd Mechanical design & installation: Whitland Engineering MCC supply & installation: Lloyd Morris Electrical Ltd Pumps & package pump station: Xylem Water Solutions Potable water booster supply: Dutypoint Ltd Ferric dosing supply: Colloide Engineering Inlet screen supply: Huber Technology Safety shower supply: Hughes Safety Showers [caption id="" align="alignnone" width="1200"] Weobley WwTW: Ferric point of application units - Courtesy of Morgan Sindall Infrastructure[/caption] BIM BIM capabilities were utilised at all three sites to design the schemes, and the wider engineering team used site-wide 3D models to great effect to review the works and propose any improvements. Furthermore, this provided an engaging and relatable interface to present the schemes solution to stakeholders, as well as using engineering drawings. Project completion Welsh Water’s have invested £5.9m at the Norton and Presteigne WwTWs and £2.7m at Weobley WwTW. These phosphorous removal schemes are the first tranche to be completed of a programme of upgrades to existing wastewater treatment works that will improve water quality in the Wye and Lugg river basin catchments. Learnings from these schemes have been used by Arup and Morgan Sindall and shared with the Welsh Water Capital Delivery Alliance partners to improve scheme delivery of other rural wastewater treatment works. Through early engagement with chemical dosing suppliers, potable water designs and DfMA MCC suppliers, design enabling efficiencies in design and construction costs to be realised have been standardised. Norton & Presteigne WwTWs were commissioned in March 2022 and Weobley WwTW was commissioned in March 2023.

Located south of the village of Chilton Foliat and north-west of the town of Hungerford there is an existing sewage treatment works (STW) that serves a population of approximately 400 people. The works discharge into the River Kennet, one of England’s most important chalk streams which is home to an extensive range of rare plants and animals that are unique to the area, and as such it is designated as a Site of Special Scientific Interest (SSSI). The project objective is to divert flows from Chilton Foliat STW by extending the existing rising main from Mill House Sewage Pumping Station (SPS) in Chilton Foliat to the adjacent catchment of Hungerford and onwards to Hungerford STW, allowing for the future decommissioning of Chilton Foliat STW. Basis of design The project is part of a flow compliance scheme for Thames Water working in collaboration with the local action group, Action for the River Kennet (ARK), and the Environment Agency (EA) to improve the quality of flows discharged to the River Kennet. Mott MacDonald Bentley (MMB) developed the design to divert and extend the existing rising main pipe towards the Hungerford catchment to the south-east of Chilton Foliat. The rising main would be extended by an additional 1400m and discharge into a new 150mm diameter gravity sewer system, before connecting into the existing Hungerford sewer system approximately 310m further to the south-east. Due to the undulating topography, the rising main section contained a mix of both rising and falling gradients along its length. As a result of this alignment, hydraulic and surge assessments highlighted the need for additional air release valves and also a variation in pipe sizes between 125mm OD and 160mm OD to maintain the required flow velocities whilst preventing air locking in the pipe. [caption id="" align="alignnone" width="1200"] Aerial view of setup - Courtesy of A. Thomas Plant Hire Ltd (ATP)[/caption] Assessment of the existing pump arrangement at Mill House SPS confirmed that they would be suitable to transfer flows along the new rising main pipe alignment which had a reduced head to that of the previous arrangement. However, the existing pumps were determined to be nearing the end of their asset life and their replacement was also included. The gravity sewer section was designed to maintain self-cleansing for the expected pass forward flow of up 8 l/s with the fall gradient varying between 1 in 90 and 1 in 60. Rising main installation method selection With consideration towards health, safety, and the environment, as well as constraints within the  programme, a fast and effective pipe installation method was deemed to be crucial. Following detailed geotechnical site investigation works, various methods were explored. In consultation with A. Thomas Plant Hire Ltd (ATP), and drawing on MMB’s experience of using pipe ploughing from projects with other clients, the project team confirmed that the ground conditions were well suited to using pipe plough pipe installation equipment; with projected pipe laying rates in excess of 500m per day. Due to the SSSI status of the river and the surrounding area, and the Kennet and Lambourn Floodplain Special Area of Conservation (SAC) being home to the endangered Desmoulin’s whorl snail, MMB had to produce a Habitats Regulations Assessment (HRA) to mitigate any potential impacts of the pipe installation; a process made more onerous by a recent case law. As the largest environmental risk to the protected areas would be the contamination of groundwater or its escape overland, the use of the pipe plough would help reduce, and even eliminate, the potential for contaminated surface and groundwater from reaching the adjacent watercourses. [caption id="" align="alignnone" width="1200"] (top left) winch/anchor unit, (bottom left) bedding conveyor and (right) test pit on installed pipe - Courtesy of MMB[/caption] Pipe plough benefits The quality and safe nature of the installation, as well as the programme and carbon efficiencies made pipe ploughing a strong solution for the installation of the rising main. There are many benefits to using pipe ploughing techniques other than just improved installation time, lessened disruption and reduced visual impact. Using polyethylene (PE100) pipe jointed using electrofusion in an above-ground, controlled environment, removes the need for any persons to work within the confined space. Furthermore, the pipe plough is a pipe install method that is highly configurable and a standardised process that allows for the simultaneous installation of pipework, pipe bedding and marker tape, preventing the need for open excavations. Challenges As pipe ploughing is an emerging technology and new to Thames Water, there were some initial concerns how the design requirements would be met. However, MMB were able to offer reassurance through engagement with ATP, who provided video footage and technical data to prove that the pipeline installation would be done in accordance with the standards for sewage pipelines, sewage rising mains and civil engineering specification. Another challenge was the requirement to confirm that adequate amounts of pipe bedding would surround the pipe. This was demonstrated by the visual inspection of a 50m trial run. Where a trial hole was dug over the newly installed pipe. Happy with the information and demonstration, the project moved forward with the project. [caption id="" align="alignnone" width="1200"] The pipe plough - Courtesy of MMB[/caption] Chilton Foliat STW Flow Compliance: Supply chain - key participants Client: Thames Water Principal designer & contractor: Mott MacDonald Bentley Pipe plough pipe installation (rising main) subcontractor: A. Thomas Plant Hire Ltd (ATP) Manhole & gravity sewer installation subcontractor: Hercules Site Services Pumps: Xylem Water Solutions Progress Design Start Date: 16 May 2022 Construction Start Date: 16 January 2023 By the end of March 2023 the following works were completed: Topsoil stripped along the approximate 1800m long working easement. Above-ground electrofusion welding of PE100 pipework including a number of lengths for random destructive testing of joints. Installation of 1400m of PE100 rising main over 2 days. Reinstatement of the subsoil ready for chamber installation. Installation of 310m of clay gravity sewer by traditional open cut methods. Construction of all air valve, washout and gravity chambers. In the near future the final connection will be completed along with the final surface reinstatements. The next project in the area will be the decommissioning of Chilton Foliat STW. [caption id="" align="alignnone" width="1200"] (left) Pipe plough in progress and (right) reducer installed - Courtesy of A. Thomas Plant Hire Ltd (ATP)[/caption] Future uses of the pipe plough Due to the guidance system and the fully adjustable plough, it is also possible to lay at a set gradient, meaning the pipe plough can be used to lay gravity sewer pipeline as well. However, consideration of standards and specifications will need to be considered. ATP have also advised that given suitable design and pipe material selection together with suitable ground conditions, a ploughed pipe could be installed without pipe bedding, potentially allowing for a reduction in carbon and plant required on site; something MMB are keen to pursue. Thames Water have also been suitably impressed with the technology’s potential to reduce programme, lessen carbon, and eliminate environmental risks, and are looking to promote its use on other framework projects through their internal innovation share mechanism. A preliminary review of their asset standards  will be undertaken to see if updates could be made to encourage alternative methods of installation.

The Exmouth Offshore Project is a key element of the wider Exmouth programme of works to deliver no more than 10 significant (>50m3) spills per annum from the aggregation of Maer Road Sewage Pumping Station (SPS) Combined Sewer Overflow (CSO) and Phear Park SPS CSO. The output from the programme will reduce spill frequencies for better environmental conditions as a long-term solution with a positive impact on the bathing waters. The works were undertaken in Sandy Bay Devon Cliff Holiday Park in Exmouth and was delivered around Sandy Bay’s winter maintenance window, compressing 15,000 working hours within just 13 weeks. Overrunning the programme would have directly impacted Sandy Bay’s tourist season, with significant revenue loss (approximately £2m/day). The works were located only 4 meters from a Blue Flag beach. Introduction & background

The Exmouth Offshore Project required the installation of an 804m long, 900mm diameter, gravity long sea outfall, to achieve an increased flow rate of 991 litres per second.

The works took place in Sandy Bay Devon Cliff Holiday Park (Exmouth), one of the UK’s largest caravan sites, with over 2200 units and 10,000 visitors per week in the summer season and were only permitted during the Sandy Bay winter maintenance period.

South West Water contracted Galliford Try as principal designer and contractor for the project.

[caption id="attachment_17044" align="alignnone" width="1200"] (left) Pipe string along coastal path and (right) Pushing pipe lower car park and compound - Courtesy of South West Water[/caption] Construction

To meet this challenging programme, specialist horizontal directional drilling (HDD) contractor Peter McCormack & Sons mobilised one of the largest and most powerful drilling rigs ever used in the UK, to complete the largest forward reaming (48”) operation in the country.

The works required 18 months of planning and the programme challenge included expediting the specialist reamers, 1.2m in diameter manufactured in America and imported to precise programme requirements. The methodology and accurate planning minimised programme risk by minimising the use of marine spread.

This relied on forward reaming (pushing the pipe from land), which is an unconventional method for the length and diameter of pipe of this scale, but reduced the reliance on marine support in winter sea conditions reducing weather risk.

Early marine trenching support was mobilised to clear boulders at the exit point at seabed over two days. Survey marine vessel continued throughout the project to confirm HDD exit point.

818m of HDPE pipe was welded on land, stretching in a single length at strategically high ground to slide the pipe. This allowed to fully pressure test the pipe to give complete confidence in the weld quality. The project team considered both the safety of the public accessing the coastal footpath adjacent to the works and maintenance operations within the holiday park with accurate interface management. In addition to this, the project team worked closely with landowners to agree a route for the welded pipeline to be positioned, in readiness for the pipe push with regular communications with landowners.

[caption id="attachment_17047" align="alignnone" width="1200"] (top left) 500t drill rig compound and entry point and (bottom) pipe pushing operation at sunrise - Courtesy of South West Water[/caption]

The works naturally attracted attention, and allowed the team the opportunity to explain the work that were undertaking and the long-term benefits South West Water outfall would provide to wider Exmouth storm overflow project.

The project compressed 15,000 working hours within 13 weeks which equates to 10 months of normal working hours. This could only be achieved by running a continuous 24x7 drilling operation. Despite the intensive nature of this challenge, the team completed the HDD works ahead of programme, on budget with zero harm to the team, zero pollution incident, and minimal impact to the public. This pipe is a wider part of Exmouth stream of works including storm overflows to achieve long term goal.

Exmouth Outfall: Supply chain - key participants Client: South West Water Principal contractor: Galliford Try Design: Pell Frischmann Design of outfall route & drilling specialist/sub-contractor: Peter McCormack & Sons Ltd Topographic, GPR & boreholes: AGS Ground Solutions Unexploded ordnance survey report: 1st Line Defence 900MM PE pipe supplier: Egeplast international GmbH (Germany) HDD 500t kit & drilling tools: American Augers (USA) Pipe pusher: VanLeewen Trenchless Technology (Netherlands) Welding plant supplier: Ritmo remedy 1000FA (Italy) Concrete: Aggregate Industries Welding plant operator: Pipe Force Martin Woodcock Fiberglass systems: Pipex px Crane hire: Spence Crane Hire Ltd Plant hire: Plantforce Rentals Ltd Plant: Sunbelt Rentals Ltd Aggregate: Steve Wills Haulage [caption id="attachment_17043" align="alignnone" width="1200"] 500 T drilling rig - Courtesy of Galliford Try[/caption] Teamwork and Inclusion

Working collaboratively towards a common agenda, multiple partners were involved including the pipe supplier, drillers, pipe pushers, pipe welders, crane operators, mud pump operators, water tank suppliers, fuel suppliers etc.

A mutually inclusive team worked. Collaborative teamwork environment with no risk-taking policy with a culture of everyone working on site and delivery people have same respect with different roles and responsibilities.

Cultural Behaviour Safety videos were shared on regular basis to remind site team safety, culture, and respect aspect. Site team was well trained and fully skilled to follow safety rules religiously. No one was either bigger or lower than anyone which was demonstrated by actions through a mutually inclusive respectful culture. Shift change and intermittent toolbox talks were carried out. Several graduates and other interested people were taken to site for their learning. One of the UK’s Water Plcs were visited the site for their learning.

[caption id="attachment_17046" align="alignnone" width="1200"] (left) Drill pipe and pilot drill bit and (right) outfall pipe, roller and guide - Courtesy of Galliford Try[/caption] Health & Safety considerations

Accurate and realistic RAMS were produced. Uninterrupted CCTV monitoring was placed. Each shift had a team of 25 highly skilled and well-trained site team with zero risk taking policy. Specific H&S steps:

Strict one-way system with separate entry and exit points for plant and construction vehicles. Separate entry and exist of South West Water Operators to make existing pumping station in safe operation. Detailed interface management plan of each operational activity including regular on site maintenance of drilling rigs. An hourly check of whole plant, Noise barriers and vibration control equipment for public safety and wellbeing with fully secured fence - large visible metal sign boards and multiple laminated signs in and around the Sandy Bay for public awareness. On duty several field marshals to navigate foot path users. Same drilling team was kept. Compressed programme 15,000 working hours within 13 weeks. Injury free 15,000 working hours into 13 weeks. No near miss. No pollution incident.

Noise barriers and vibration control equipment was installed for the safety and benefits of local community and footpath users. This was checked daily by the site team and the environmental manager to ensure there were zero environmental and H&S incidents.

Protecting the Blue Flag beach

To protect the Blue Flag beach, the entire working area was surrounded by flood barrier to prevent drilling fluids from escaping the site to avoid any risk of pollution of sea. All drilling fluids were recycled by using a recycling centrifuge system. This sustainable innovation allowed the drilling arisings to be fully dewatered, allowing transportation of the inert material without the risk of silt on the road network, causing unnecessary nuisance to the travelling public. This initiative minimised water use and mitigated 364 lorry movements through Exmouth, saving 92T eCO2.

[caption id="attachment_17042" align="alignnone" width="1200"] 900mm diameter pipe welder - Courtesy of Galliford Try[/caption] Conclusion

Despite the intensive nature of this challenge, by running a continuous horizontal directional drilling operation over a 24/7 operating pattern, the works were completed on budget and ahead of the programme. There were no time delays, no environmental impacts to the blue flag beach (just 4m from the site), and any impacts to the Holiday Park were minimal.

South West Water have showcased this project through the media and LinkedIn focusing on the engineering challenges the team faced and promoting both construction and the wider environmental benefits of this scheme.

The team have produced a presentation given by Galliford Try’s team to over 250 employees nationally to share the best practice and learnings from this project across their entire business.

South West Water are extremely pleased with progress of these works to meet their commitments with the Environment Agency.  Relationships with the Holiday Park management are extremely good, and the owners are grateful for the efforts the team and SWW have made to complete these works with minimal disruption to their business.

September 2022 saw the successful completion of a new kilometre outfall pipeline in Arklow, Ireland. The lack of wastewater treatment facilities in Arklow resulted in untreated wastewater being discharged directly to the Avoca River. The design and construction of a new wastewater treatment plant and long sea outfall was required to improve the water quality of the Avoca River and bring benefits in terms of health, environmental integrity and facilitate economic and social development for Arklow town and its surrounds, which has been constrained by the lack of adequate wastewater treatment capacity. This paper focuses solely on the marine design/construction elements of the project as construction of the new treatment works and other associated structures are still ongoing. Background Arklow is a town in County Wicklow on the southeast coast of Ireland. There were no wastewater treatment facilities in Arklow town and as a result, untreated wastewater was being discharged directly into the Avoca River. This was not compliant with obligations under the European Union Urban Wastewater Treatment Directive. Uisce Éireann, therefore proposed a development to provide an effective wastewater collection network, treatment capacity and treated effluent outfall that would improve water quality in the Avoca River. Ward & Burke was appointed as the main contractor for delivering the Arklow Wastewater Treatment Plant (WwTP) project, with the design and construction of the associated long sea outfall sub-contracted to Van Oord Ireland Ltd. Royal HaskoningDHV was appointed by Van Oord as designer for the long sea outfall (LSO). The overall project required the design, construct and implementation of the following: A new, state of the art, wastewater treatment plant that has been designed to provide an ultimate treatment capacity for a population equivalent of up to 36,000 at the Old Wallboard Factory, North Quay, Ferrybank. Sewer pipelines (along the North and South Quays) to bring the untreated wastewater to the WwTP. A marine outfall pipeline to safely discharge the treated wastewater to the Irish Sea. Upgrade of the existing rock armour revetment adjoining the site. [caption id="" align="alignnone" width="1200"] Outfall pipe arrival from Norway by sea to the dock in Arklow for preparation and assembly - Courtesy of Van Oord Ireland[/caption] The proposed outfall pipeline was required to discharge the treated effluent from the wastewater treatment plant to receiving waters. Both marine and river outfall options were initially considered for the proposed development. However, hydrodynamic and water quality modelling demonstrated that the wastewater discharge standards required for a river outfall would be much more onerous than that of a marine outfall. For that reason, the river outfall was not considered further. Solution The detailed design of the new outfall system for the Arklow Wastewater Treatment Plant Project considered and finalised the new outfall pipe route, hydraulic design, preferred material and construction methodology, pipe weighting, backfill and diffuser arrangement. The outfall system comprised of a 630mm outer diameter pipeline (630mm OD SDR 17 PE100 pipe) and started at a connection point onshore, behind the revetment and extended offshore for approximately CH927m to the discharge location. The outfall discharge arrangement/diffuser configuration was located in approximately 13m of water depth from the Extreme Water Level (EWL) and consists of six risers (355mm O.D. SDR 17 PE100 pipe), four diffuser ports (160mm O.D. SDR 17 PE100 pipe) each with 24 return duckbill valves that horizontally discharge the treated effluent at a height of approximately 1m above the seabed level. The detailed design trench detail was developed to provide a minimum cover depth to the outfall pipeline of 1.5m following installation. This cover depth allowed for both seasonal and long-term fluctuations on the seabed levels and protection from potential damage due to dragging anchors. The trench was backfilled with selected as dug material, typically medium dense sands and gravels, that were side-cast during the trench excavation. Where the outfall crossed beneath the existing and proposed coastal revetment, the pipe wall structural thickness was checked and verified to prevent any high point loads from the revetment rock armour. [caption id="" align="alignnone" width="1200"] Outfall pipe floated along the quay wall in Arklow prior to preparation and assembly works - Courtesy of Pipelife Norge AS[/caption] The marine outfall was also designed to be stable in the ‘worst case’ design loads for current and wave loading conditions provided. It was therefore necessary to weight the pipeline with concrete collars and subsequently concrete kennels after installation (float and flood method), to provide a specific gravity of not less than 1.35 that could be achieved without any reliance on backfill material. This installation weight was provided with 1015kg (290kg/m) (in air) fixed weight concrete collars at 3.5m centres and to satisfy the permanent on bottom stability, 2292kg (654.86kg/m) (in air) concrete kennels were provided at 3.5m centres in between the fixed weight concrete collars. The collars and kennels were provided by Tracey Concrete. Constraints Arklow is a town with a population of 14,000 people and a small port which generates medium to high traffic within the port. This constituted working and delivery restrictions during the preparations of the offshore section of the outfall pipeline. In addition, the turbulent weather did not allow for preparing the outfall pipeline offshore, outside of the port vicinity. Additionally, a survey undertaken by Uisce Éireann showed an existing subsea cable in close proximity to the designed LSO route. The cable supplied power to a substation located South of the site location from the offshore Arklow Bank Wind Farm. The survey undertaken by Uisce Éireann confirmed the location of the power cable and showed that the cable route was outside the redline boundary for the works. However, the owner/operator of the subsea power cable was consulted to ensure that the new LSO route and location was compliant with the applicable exclusion zones/constraints for the subsea power cable. [caption id="" align="alignnone" width="1200"] Welding of risers for diffuser section of outfall pipe - Courtesy of Van Oord Ireland[/caption] Site investigation Site information was provided by Uisce Éireann from a ground investigation undertaken in 2017 at the proposed site location, as well as information from the Geological Survey Ireland (GSI) website borehole archive that included relevant land-based and overwater boreholes. The ground investigation indicated that the ground conditions generally comprised of a variable sequence of medium dense to coarse soils and gravel. The offshore investigation data indicated that there is a significant variation in the ground conditions between the boreholes which were spaced at approximately 150m intervals e.g., buried valleys, rock outcrops etc. Large boulders of metamorphic rock were also encountered in the boreholes. Whilst the depth of the boulders generally exceeded 3m below bed level, the presence of boulders at shallower depths could not be discounted and posed a risk for the construction of the outfall. The requirement for further site investigations were identified and these included magnetometry, sub-bottom profiling and unexploded ordinance (UXO) surveys to determine the mitigation measures required to be undertaken prior to the proposed works and construction of the pipeline. Arklow LSO : Supply chain - key participants Arklow WwT Project delivery contractor: Ward & Burke Long sea outfall design/build: Van Oord Ireland Ltd Van Oord designer: Royal HaskoningDHV HDPE pipe: Pipelife Norge AS Concrete collars & kennels: Tracey Concrete Tideflex S35 valves: MeasurIT Technologies [caption id="" align="alignnone" width="1200"] Excavation of trench at the onshore connection point using the backhoe dredger ‘Razende Bol’ - Courtesy of Van Oord Ireland[/caption] Marine works A total length of 927m of polyethylene pipe (630mm OD SDR 17 PE100) was manufactured by Pipelife Norge AS, in three lengths of 309m which were then towed from Norway by sea to the dock in Arklow, Ireland for preparation and assembly. Along the quay wall, concrete collars, each weighing 1 tonne were installed around the pipe strings at 3.5m centre to centre distances. The collars were lifted from land with special lifting equipment and the two halves of the collar were connected from the water using small workboats. Flanges were fitted with the assistance of a marine tug boat and the on board crane. During these operations the HDPE pipe was lifted out of the water. The lifting operations of the pipeline where analysed in detail to predict stresses in the material and the bending radius of the pipe. Using this analysis the lifting operations could be adjusted to prevent buckling or damaging the HDPE pipe. For the installation of six riser feet on the pipe, a spreader beam was used to lift the pipe 1m out of the water. The usage of the spreader beam followed from the analysis done for the lifting. Excavation of the trench was carried out using land-based excavators on the revetment and Van Oord’s backhoe dredger ‘Razende Bol’ for the marine trench. A minimum cover of 1.5m above the crown of the pipe was required for the outfall pipeline through its entire route. The excavated trench material was cast adjacent to the trench for re-use as backfill material upon completion of installation. [caption id="" align="alignnone" width="1200"] (left) Outfall pipe during sinking operation and (right) outfall pipe aligned prior to sinking operation - Courtesy of Van Oord Ireland[/caption] Installation After pipe preparations were completed and the trench was excavated, the pipe installation commenced. The three separate pipe sections were connected with flange connections next to the quay wall in Arklow in order to create one long pipe length of 927m. Bend restrictors to prevent over-bending at the flange-flange interface were also installed. The finished pipeline was manoeuvred out of the port using two tugs and multiple small work boats. The pipe was anchored overnight just outside the Arklow port. Before the sinking operation, the pipes were aligned and brought into the onshore connections point where pumps were set-up to flood and sink the pipe. The pipes were pulled into the shore using a pre-installed pull wire and an onshore drum winch. The polyethylene pipelines were installed using the ‘float and flood’ method starting from the fixed onshore end. During the sinking operation, the offshore end of the pipes were connected to a multicat which was moored alongside the backhoe dredger ‘Razende Bol’ for proper positioning. The controlled pumping of seawater into the onshore pipe end, initiated the sinking process which caused the pipe to form an S-curve of approximately 20m long between the seabed and seawater surface. Two tug boats (shoal busters) were used in order to position the pipe correctly at the location of sinking. As a contingency measure and to ensure the installation process was well controlled, a foam pig was pre-installed in order to create a seal between the pipe section filled with air and the section filled with water, in case the pipe had to be re-floated due to inclement weather. Once the pipe sections were completely installed in the trench, the profile was checked by a multibeam survey to verify the final pipe position. Post pipe installation, the foam pig was removed from the pipe. A Type II pressure test of 2.25 bar was performed in accordance with the procedure set out in IGN 4-01-03, to 1.5 x the maximum internal working pressure. [caption id="" align="alignnone" width="1200"] Outfall pipe concrete collars being fitted in water with special lifting equipment - Courtesy of Van Oord Ireland[/caption] Once the outfall pipeline had been sunk to the sea bottom and pressure tested, concrete kennels, each weighing 1 tonne were placed in between the concrete collars at 3.5m centre to centre spacings to provide additional permanent weighting. Additionally, six diffusers were installed from the backhoe dredger platform by divers. Each diffuser comprised of a flanged PE pipe, fittings and a riser with a four-port crosshead, each with a flange allowing for Tideflex S35 valves to be fitted directly. Included as part of the diffuser installation, was a removable access flange at the top of the riser to enable access inside the riser. After completing the diffuser and kennel installation, the pipe was backfilled over its full length to provide 1.5m cover. Rock armour protection was further provided extending approximately 7m around the diffuser section from its centre to protect the area around the diffuser from scour. Also provided was a steel protection frame for the diffuser, fitted with sacrificial anodes to allow a 50yr design life for protection from dropped objects, anchors, trawlers and fishing nets. Finally, on the offshore end a marker buoy and on the onshore end a Saint Andrews Cross were installed to mark the pipeline location. Due to the turbulent weather at the site location, including hold points in the working method, so that each installation step could be paused at planned intervals, allowed Van Oord to work around the weather. Additionally, working with local contractors who helped to adjust and adapt work methods and techniques within the limited amount of space, allowed the team to prepare and install the outfall system using specialised equipment and marine vessels, with minimal disruption to the environment and public. In particular, a bespoke rigging system was designed and fabricated using a local yard to assist with the efficient installation of the collars whilst working from the water. [caption id="" align="alignnone" width="1200"] Outfall pipe during sinking operation - Courtesy of Van Oord Ireland[/caption] Conclusions The successful completion of this project will allow treated effluent to be safely discharged from the new Arklow WwTP once operational and bring benefits in terms of health, environmental integrity and facilitate economic and social development for Arklow town and its surrounds, which had been constrained by the lack of adequate wastewater treatment capacity.

St Augustines Road is a busy thoroughfare in Chesterfield linking the town to Matlock and the south-eastern edge of the Peak District. Lying within the Yorkshire Water (YW) waste catchment area, the road is steep in its nature with gradients often exceeding 7%. Due to the local hydraulic catchment and topography, during heavy rainfall events flooding occurred at the road’s intersection with Derby Road (A6). The flooding lifted manhole covers from their frames which caused significant damage to the highway. It also caused internal and external damage to the surrounding properties. To combat this, mitigation was carried out by Yorkshire Water and Chesterfield Borough Council (CBC), including the implementation of mitigation measures such as non-return air bricks and flood gates, however, this had limited success. CBC also commissioned the construction of a detention basin to the rear of the flooding properties; but again with limited success. Hydraulic study As a result of the mitigation’s limited success, a hydraulic study was commissioned by Yorkshire Water. This confirmed the root cause of the flooding was hydraulic overloading of both the foul and surface water sewers. A notional solution was developed by Yorkshire Water which included the upsizing of these sewers, with some form of temporary storage for the foul system to retain flows in a rainfall event. Later iterations of the hydraulic model revealed that improvements to the surface water network would in fact also reduce the frequency of flooding on the foul water network due to interactions between the two systems during storm conditions. In light of this information, in May 2021 Yorkshire Water secured funding to implement a series of significant improvements on St Augustines Road. Preferred solution The preferred solution included the construction of a new outfall into the River Rother and the transfer of all flows from the surface water sewer in Derby Road. This would provide a much greater flooding resilience in the existing system. The existing 225mm surface water sewer was to be upsized to Ø750mm along its 320m length. It would then be diverted via a tunnel underneath Derby Road into the wetland area immediately adjacent into the River Rother. Here, a new outfall would be constructed to discharge the surface water sewer into the river network. [caption id="" align="alignnone" width="1200"] (left) The preferred option and (right) flooding on St Augustines Road - Courtesy of Galliford Try[/caption] Constraints and engineering challenges The preferred solution progressed to detailed design with several technical challenges to be overcome. Several of these challenges were exacerbated by the need to construct the outfall into the River Rother outside of the salmonoid spawning season. An Environment Agency (EA) bespoke Flood Risk Assessment Permit, (FRAP) was required to construct the outfall and all in-channel activities were required to be undertaken before 1 October 2021 in order to mitigate the impact on any spawning salmon. A significant flow rate of up to 0.89m3/s would be discharged into the river during storm events and river scour was a concern. In order to combat the scour on the riverbed and riverbanks, there was a requirement to reduce the velocity of the flow before it interacted with the River Rother, causing excessive turbulence. To achieve this, box culverts were selected due their unique cross section and significant channel width. This slowed velocities down to near 1m/s, which is widely regarded to have negligible effects on turbulence and thus reducing scour. The headwall was also designed to allow flows to enter the River Rother at a 45° angle, as per EA Standard Rules SR2015 guidelines, further reducing the risk of scour on the opposite riverbank and riverbed. Outfall design This design however did not come without complications, such as the need to carry out the structural design, build and installation of a bespoke outfall within a few months. BSP Consulting was commissioned to carry out the structural design of the outfall which was to be precast, reducing the need for in situ concrete handling adjacent to the sensitive receptor. Off-site build (OSB) also reduced the construction programme and allowed the headwall to be manufactured concurrently within the determination period of the FRAP. [caption id="" align="alignnone" width="1200"] Outfall under construction - Courtesy of Galliford Try[/caption] Poor ground and underfoot conditions adjacent to the River Rother proved too risky and problematic for traditional mobile crane lifts, so all lifts of the precast sections were to be undertaken with a tracked excavator. This further constrained the design and restricted the maximum mass of each section to 13 tonnes. Consequently, in its final iteration the precast headwall was designed in two sections and was combined with an in situ toe and infill slab/wall which completed the structural design. Design During the design stages, extensive ground investigation was carried out. This identified water bearing sand and gravel strata adjacent to the river which transitioned to mudstones and clays towards St Augustines Road. It was this change in strata which posed a significant challenge for the no-dig section of the work beneath Derby Road. This section of work was critical as it linked the outfall to the upsizing work on St Augustines Road. Discussions were held with Active Tunnelling Ltd who proposed the use of the guided auger bore technique to install the sewer in this transitional strata. Although initially designed as a 750mm diameter sewer, this was reduced to 600mm which was the maximum diameter which could be accommodated by the tunnelling contractors. Hydraulic modelling was undertaken by RES Environmental to confirm the viability of this proposal and in order to compensate for this localised throttling, the pipeline had to be upsized locally to 900mm immediately upstream of the tunnel. The alignment of the tunnel was severely limited due to proximity of existing buildings on Derby Road. BSP Consulting was again called into action as pre-condition surveys and settlement calculations were commissioned in order to understand the impact of the tunnelling works on these at-risk properties. [caption id="" align="alignnone" width="1200"] (left) Installation of drive pit on St Augustines Road, (middle) guided auger bore rig, and (right) the transition between 600mm and culverts - Courtesy of Galliford Try[/caption] Settlement calculations were undertaken using the “Guide to best practice for the installation of pipe jacks and microtunnels technique” and a predicted settlement of <3mm was deemed to be acceptable. The pre-condition surveys highlighted only minor cosmetic issues and were used as reference to the state of repair of the properties prior to construction work commencing. The majority of the civil design was undertaken in house. This element included a design coordination role combining and processing the information received from the consultants and stakeholders. An example of the numerous stakeholders which were consulted is that of the Coal Authority. Initial searches indicated the presence of historical coal workings. More detail was sought and records indicated the presence of an adit within 20m of the proposed pipeline. A coal permit was sought from the Coal Authority and the design progressed whilst this was processed. St Augustines Road (Chesterfield) Flood Alleviation: Supply chain: key participants Principal contractor & civils design: Galliford Try Temporary works & headwall design: BSP Consulting Hydraulic modelling: RES Environmental Ltd Ecological consultants: Middlemarch Environmental Traffic management: Amberon Traffic Management GRP & utility mapping: Cloud Conversion Ground investigation: Grange Geo Consulting Ltd Pipelaying & outfall construction: Arthur Civil Engineering Trenchless installation: Active Tunnelling Ltd Cofferdam design & supply: National Trench Safety UK ‘EndSafe’ safety barrier: Groundforce Shorco Cofferdam installation: Ivor King Piling Dewatering: Alba De-Watering Services Ltd Precast concrete: Bonna Sabla CCTV, CIPP & cleansing: CPS Drainage Solutions Handrailing & grille design: Galliford Try (Fabrications) Silt curtain: Murlac Land and Marine Environmental Solutions Pumping: Selwood Ltd Ridgistorm pipes: Polypipe Civils Pipe & flap valve supplier: Keyline Civils Specialists Landscaping & site clearance: Landscape Maintenance Services Ltd Reinstatement of traffic signals & street furniture: Swarco Aggregates & muck away: JC Balls & Sons Brickwork: Derwent Joinery & Construction Gates & fencing: SFC (Midlands) Limited Surfacing: BDS (Yorkshire) Ltd [caption id="" align="alignnone" width="1200"] Service detection - Courtesy of Galliford Try[/caption] Installation The Environment Agency granted the FRAP on 13 August 2021, and the detailed design was finalised and submitted to Yorkshire Water’s technical approval committee on 16 August 2021. Work began on site a few days later, leaving just six weeks to construct the headwall and cease all in-channel activities as per the conditions of the FRAP. Work commenced immediately on the enabling works, with particular attention paid to the temporary works. Haul road To provide drainage to the waterlogged land adjacent to the River Rother, a land drainage scheme was commissioned, designed and installed by Lincolnshire Drainage. This provided a more suitable foundation on which to install the haul road and working laydown areas. The haul road was designed by BSP Consulting and was of substantial construction given the underlying strata, at 700mm thickness with geotextile layers to improve longevity. Ground dewatering After the installation of the haul road, wellpoint dewatering was installed around the outfall area and along the proposed culvert alignment. The dewatering was installed by Alba De-Watering Services Ltd at 1.5m centres. However, due to the underlying mudstone, each well had to be pre-augered and was then installed using the more traditional spout method to ensure that a reasonable well depth was achieved to adequately dewater the working area. A silt curtain was supplied and installed by Murlac Land and Marine Environmental Solutions prior to the channel works to minimise silt and sediment damage downstream from the works. It proved to be very effective during the cofferdam installation. [caption id="" align="alignnone" width="1200"] Cofferdam and silt curtain - Courtesy of Galliford Try[/caption] Cofferdam A cofferdam was required to retain the River Rother and this was designed and supplied by National Trench Safety UK and installed by the primary subcontractor Arthur Civil Engineering. The cofferdam was unique in design in that it utilised Larsson piles in a trapezium shape (plan) to minimise over-dig yet still accommodate the headwall and first culvert. The cofferdam was installed by Ivor King Piling using a 35t excavator with a Movax side grip pile driver attachment. The cofferdam was effective but 4” end suction pumps supplied by Selwood Ltd were still required to maintain the cofferdam and keep water levels low. Headwall installation Once the cofferdam was watertight, the headwall toe was cast in situ, after which the precast headwall arrived in two sections as planned. It was lifted into position by Arthur Civil Engineering using a 50t tracked excavator. An administrative issue led to the need to negotiate a 2-week FRAP extension with the EA and the headwall was completed and the cofferdam removed by 14 October in accordance with the conditions of the revised FRAP. Pipeline works Construction works on the remainder of the project continued in March 2022. A temporary one-way system was implemented to provide a safe working area to install the remainder of the pipeline with open cut works commencing on 14 March. The open cut works progressed steadily with over 100 services safely crossed. The later spring and summer months provided excellent conditions for online sewer relay with drought-like conditions, culminating in hosepipe bans for the majority of the UK. [caption id="" align="alignnone" width="1200"] Open cut pipelaying - Courtesy of Galliford Try[/caption] Prior to the tunnelling works commencing, concern was raised over the proximity of the tunnel as it crossed under a 225mm foul water sewer in Derby Road. With a clearance of just 300mm, the existing foul sewer was inspected by CPS Drainage Solutions using CCTV and a precautionary 5m cured-in-place patch liner was installed to strengthen the sewer prior to the guided auger bore operation. No-dig works commenced in early June and progressed well without incident and were completed towards the end of the summer. No settlement was detected during the installation and no visual deformations were reported from the nearby structures. Open cut works continued late into the summer with flooding benefits delivered by 5 October. Significant rainfall events have since occurred and the feedback from residents previously affected by the flooding has been positive. Off-site build Off-site build was utilised heavily without which it would not have possible to abide by the conditions set in the FRAP and achieve the tight programme when constructing the outfall into the River Rother. The headwall and culvert manhole cover slabs were precast by Galliford Try off site and the hand railing and grille were fabricated by Galliford Try (Fabrications). The flap-valve was fabricated off-site by Keyline Civils Specialists. [caption id="" align="alignnone" width="1200"] 900mm Ridgistorm pipe from Polypipe Civils ready for installation - Courtesy of Galliford Try[/caption] Public engagement & community impact Throughout the project customer engagement was a priority for Galliford Try and Yorkshire Water. Although COVID-19 curtailed some of the engagement meetings which were planned at the start of the project, regular communication with residents of St Augustines Road and surrounding area took place. A significant quantity of the communication was made to the local residents Facebook group, which provided timely and accurate updates on progress. Traditional letters were also posted as back up and for those who didn’t have access to Yorkshire Water’s online updates. Towards the end of the project volunteers from Galliford Try and Yorkshire Water spent a day helping out at the local food bank on St Augustines Road and made a donation of £500 to assist with their ongoing charitable cause. Project success The project is considered huge a success for Galliford Try and is the largest single project completed on the Infrastructure Framework for Yorkshire Water within the AMP7 period.

The Stroud Sewerage Strategy is a major investment by Severn Trent which is required to overhaul of the existing sewer network by installing almost 3.5km of enlarged sewer pipe, separating surface water from the sewage network, creating additional storage with smart controls to hold stormwater back during large storm events before returning it to the treatment works when the rainfall has subsided, and making improvements to Stanley Downton Sewage Treatment Works. This paper follows on from the case study published in Water Projects 2022, which focussed on the design and optioneering elements of the programme of works. Scope of works The Stroud Sewerage Strategy is made up of five key elements: Trunk sewer improvements. Combined sewer overflow & storage. Surface water separation. Infiltration reduction. Stanley Downton WwTW. Construction started in March 2022 and details of the progress to date (July 2023) is covered in this case study. New trunk sewer In order to reduce the risk of sewer flooding and convey flows from the existing Wallbridge CSO, design and build contractor Galliford Try was required to design and build a second trunk sewer system, transferring flows 3.65km to the new CSO site on the outskirts of Stroud. The new sewer network will operate entirely under gravity, with no siphons and falls at a minimum gradient of 1:500. [caption id="" align="alignnone" width="1200"] (left) The launch of TBM Marvellous Mining Molly and (right) shaft with pipe jacks installed about to be benched - Courtesy of Galliford Try[/caption] Due to varying local topography and numerous obstacles along the route the team opted for a combination of open cut and pipe jack tunnelling techniques for the trunk sewer - details below. Pipe diameter : Length Details 750mm = 900m Open cut works: 2-5m deep, includes 1 x River Frome crossing 1500mm = 769m Open cut works: 3-6m deep, includes 1 x River Frome crossing 900mm = 35m TBM Marvellous Mining Molly: 1 x tunnel drive crossing under A419 1200mm = 550m TBM Lilian: 4 x tunnel drives under Dudbrige Road (dual carriageway), car parks and private land 1200mm = 650m TBM Suzanne: 6 x tunnel drives under Stroudwater Navigation Canal & major gas mains 1500mm = 591m TBM Florence: 3 x tunnel drives under A419, Stroudwater Navigation Canal & Painswick Stream BSP Consulting Ltd carried out the structural design of all 12 tunnelling shafts (varying from 3.66m, 5m and 6m in diameter), with the ring segments and cover slabs supplied by Macrete (Ireland) Ltd. BSP also undertook the design calculations and documentation required for the five tunnelled highway crossings consents (CD622) and the buried service damage assessment reports for eight key service crossings along the route (the pipeline analysis was undertaken using Oasys software). Active Tunnelling Ltd developed a bespoke tunnel boring machine setup for the 900mm micro-tunnel which involved installing an initial 600mm laser guided auger followed by a forward reaming TBM head into the auger screw. This setup avoided the need to install a 1200mm pipe which would have caused additional risk to an existing underpass in close proximity. [caption id="" align="alignnone" width="1200"] TBM Marvellous Mining Molly in position to start mining - Courtesy of Galliford Try[/caption] Stroud Sewerage Strategy: Supply chain - key participants Client: Severn Trent Design & build contractor: Galliford Try Hydraulic model: Richard Allitt Associates Principal ecologists: RammSanderson Ecology Ltd River & spillway reinstatement: Salix River and Wetland Services Silt mitigation: Frog Environmental Water vole licensing: Wildwood Ecology Land & planning Agents: Dalcour Maclaren Topographical Surveys: Geomap Ltd Ground investigation: Grange Geo Consulting Hydraulic model: Innovyze (Infoworks ICM) Physical model: Framatome BHR Group Shafts & pipejacking: Active Tunnelling Tunnel design: BSP Consulting Traffic management: Amberon Ltd Remediation & asbestos management: Churngold Construction Water main diversions: Heartland Pipelines Sewer lining: Colus Ltd Temporary PortaDams: OnSite Central Steel fabrication & penstocks: GT Fabrications Valves: AVK UK Ltd Open cut pipework: LCS Groundworks Ltd Open cut pipes: Marshalls CPM Electrical installation & MCC: Cema Ltd DI pipework: Electrosteel Castings (UK) Ltd Shaft rings & cover slabs: Macrete (Ireland) Ltd Jacking pipes: FP McCann Ltd Washwater pumps: KGN Pillinger Lifting equipment: T Allen Engineering Services Submersible pumps: Xylem Water Solutions CSO screens: Longwood Engineering Co Ltd Prefabricated chambers & backdrops: Polypipe Civils & Green Urbanisation Access covers: Steelway Brickhouse Manhole covers: Saint Gobain PAM UK Fencing & tree clearance: Landscape Maintenance Services Interception chamber Galliford Try was required to design a new interception chamber to convey all the flows of the existing Nailsworth Sewer into the new network. Working on a live network and dealing with large flow rates naturally led the team to design a prefabricated chamber to minimise the installation time. Designers from Galliford Try and Polypipe Civils & Green Urbanisation developed a solution that incorporated a permanent backdrop, temporary flume pipe and four connections (750mm, 750mm, 1200mm and 1500mm in diameter). It was built off-site in three sections and assembled on site in one day. [caption id="" align="alignnone" width="1200"] (left) Installation of prefabricated chamber within live sewer line and (right) inside the prefabricated chamber - Courtesy of Galliford Try[/caption] River Frome crossings Due to the need to retain a constant gradient, both sewer crossings under the River Frome were very shallow with very little cover to the erodible bed level. Without creating syphons, open cutting through the river was the only feasible solution. A temporary bypass channel was constructed and lined using Salix River and Wetland Services coca matting and Frog Environmental rock rolls to prevent mobilising sediment during the works. Temporary PortaDams from OnSite Central Ltd were installed to isolate a section of river. RammSanderson Ecology Ltd provided ecological support, including moving 1554 fish between dams (129 brown trout, 493 brook lamprey, 715 bullheads, 209 sticklebacks, five eels and three roach). This element of work required a huge amount of planning and permits from Galliford Try’s Environmental Team, the Environment Agency and Natural England. [caption id="" align="alignnone" width="1200"] Construction of bypass channel and (inset) installation of the temporay PortaDam from OnSite Central Ltd  - Courtesy of Galliford Try[/caption] New CSO shaft Construction of the new 25m diameter, 28m deep combined sewer overlflow shaft started in summer 2023. A detailed update will be published on WaterProjectsOnline.com later in the year. Surface water separation The 3.88 hectares of impermeable surface area being separated from the existing catchment is situated in Stroud town centre and involved designing a new 555m long, 300mm diameter, intricate surface water sewer network within the constraints of a densely built-up area to intercept flows which otherwise would have ended up in the combined network and added to the spill events in the downstream catchment. Galliford Try undertook GPR surveys and numerous trial holes to create a map of existing buried assets and plan a route for the new sewer network. To reduce service diversions to a minimum, a number of bespoke manholes were designed, and the Galliford Try team proposed relining the existing foul sewer rather than replacing it which considerably reduced disruption and construction timescales on site. Flows from the newly separated network are transferred to Stroudwater Canal via a 232m long connection across a supermarket and council car park and under an existing retaining wall. Due to the interface with the general public and potential upheaval of working in car parks, Galliford Try chose to install the 600mm diameter pipes by using a laser guided auger. In conjunction with specialist Active Tunnelling Ltd, drive and reception pits were carefully positioned within car parking bays and the route designed to minimise disruption as far as practicable. On completion of the works, all affected stakeholders were positive and complimentary over the tidiness of the work sites. [caption id="" align="alignnone" width="1200"] (left) Excavation of shaft and (right) preparations for open cut rising main installation - Courtesy of Galliford Try[/caption] Infiltration reduction To free up capacity for foul flows in the existing network, Galliford Try eliminated 3 l/s of infiltration with specialist Colus Ltd by installing 475m of liners and injecting two-part polyurethane sealant at key locations. The constant groundwater flow was caused through a combination of old cracked sewers, old brick manholes with blown mortar and badly made connections onto the existing network. Conclusion At the time of writing (July 2023), the last remaining parts of the project include modifications to the storm return pipework at Stanely Downton WwTW, and the demolition of the existing Wallbridge CSO site. These works will be undertaken upon completion and commissioning of the new assets. The whole team from engineers, design, procurement, commercial and project management working on this difficult project have pulled together to overcome numerous unforeseen physical, environmental, financial and stakeholder challenges in Stroud. The author wishes to credit everyone involved; sub-contractors, supply chain and the client for achieving what has been delivered to date.

The Ards North Long Sea Outfall, constructed at Ballyferris on the east coast of the Ards Peninsula, has an asset design life of 60 years and can convey flows of up to 4200 m3/day of treated effluent from the Ards North WwTW to the pre-determined deep water discharge point in the Irish Sea. Legislative compliance was demonstrated by computational and hydrodynamic effluent dispersion modelling and the termination point for the outfall was at a pre-agreed location 500m offshore. The treated effluent is dispersed and diluted through a multiple port diffuser in 4m depth of seawater. Ards North WwTW The Ards North WwTW catchment is seasonal with significant summer peaks in flow generated by holiday parks. In addition, the initial contract documents required a long sea outfall to be designed for storm tank overflows. This resulted in a significant range of design flows and challenges to achieve an asset standard compliant hydraulic design. Flows ranged from: Minimum flow rate (Winter DWF): 13 l/s FFT Ards North WwTW: 48.22 l/s Maximum flow rate (Formula A at WwTW): 74 l/s Given the range of flows, the exemplar design included a pressurised outfall fed from a header tank and final effluent pumping station. [caption id="" align="alignnone" width="1200"] Tow and sink operation - Courtesy of NI Water[/caption] Exemplar design Farrans Construction along with RPS Consulting Engineers were appointed to develop the exemplar design for construction. The completed design evolved during the design period with initial designs providing capacity for the full range of flows. On award, RPS completed a pipeline route assessment using Civil 3D ground models to review the option of providing a gravity solution capable of delivering the full range of design flows through the outfall to the diffuser against 1:100-year storm conditions with an appropriate allowance for sea level rise to 2030. RPS Water Environment & Marine completed an assessment of the tidal range and sea level rise to develop a maximum tidal discharge level. Admiralty Tide Tables for the secondary ports of Donaghadee and Portavogie were used, and linear interpolation of the Highest Astronomical Tide (HAT) and Mean Low Water Spring  (MLWS) levels provided tidal levels. Sea level rise due to climate change was assessed using derived data through UKCIP18, providing a tidal range of +3.64 to -1.91m AOD Belfast which was adopted for the design process. Hydraulic analysis Ground modelling and initial hydraulic analysis confirmed that any gravity solution would require significant depths of excavation on the land-based section, and it was concluded that a pressurised system using a header tank was the preferred solution reducing the depth of dig, associated costs, health and safety risks during construction, and whole life operation and maintenance of the asset. Potential pipeline routes were identified and appraised to establish the best option considering lands access, road opening, future maintenance to fittings and furniture, ground conditions and depth of dig. The preferred option was a route across agricultural land, local roads before passing through a caravan holiday park to the high-water mark where the land and marine-based sections of the outfall would join. [caption id="" align="alignnone" width="1200"] Aligning pipeline over pre-dredged trench - Courtesy of NI Water[/caption] A range of pipeline diameters and materials were considered to achieve optimum velocities, a balance between pipe diameter and TWL in the proposed header tank. PE pipes were selected for the outfall with varying SR ratings used to offer material cost savings using only higher rated pipes for the marine sections to take account of installation (towing and sinking) stresses on the system. Specialist hydraulic modelling was then completed by Hydraulic Analysis Limited (HAL) to provide confidence in the performance of the system against all combinations of design flows and tidal levels. The analysis confirmed the pipe diameter selection, siting of air and scour valves and provided specific specifications for pipeline gradients, bends and air valves installation to ensure stable free surface flow conditions were achieved within the mains gravity driven sections. Renegotiated WOC During the detailed design stage, a renegotiation of the Water Order Consent (WOC) allowed for discharge of storm flows from the Ards North WwTW direct to an adjacent watercourse. This significantly reduced the maximum design flow for the long sea outfall and on reassessment allowed the removal of the effluent pumping station and header tank offering significant operational savings for NI Water. [caption id="" align="alignnone" width="1200"] Barge mobilisation from Bangor Marina - Courtesy of Farrans[/caption] The final solution was therefore to discharge treated effluent directly from the sample chamber to a gravity outfall which acts in part as a pressurised system. This amendment to the design approach was verified by HAL and removal of the pumping station and header tank was agreed by all prior to finalising the construction details including: Design of pipeline bedding and surround for both land and marine-based works. Land-based pipelines were designed as traditional open-cut installations with bedding and surround specified to meet the requirements of BS EN 1295-1:2019 Structural Design of Buried Pipelines. Air, scour and hatchbox chamber details for the land-based section. Given the variation in summer and winter dry weather flows, the inclusion of hatch boxes was provided for maintenance and to aid cleaning of the outfall. Marine section bedding and surround. The marine section was considered as two sections namely: Inter-tidal zone where the pipeline was bedded in suitable granular bedding and surround and installed with collars and kennels for flotation resistance and stability. The pipeline was protected with 2 layers of rock armour. Offshore zone where the pipeline was installed in a deeper pre-dredged trench with an imported granular bed and surround and restrained against flotation using kennels at 3m centres. This section of the pipeline was backfilled with as-dug excavated rock. The outfall was completed with a collar and kennel arrangement and a 4-port crosshead diffuser, fabricated from 400mm OD PE pipework and fitted with four 150mm diameter Tideflex non-return valves. The diffuser arrangement is protected by a galvanised steel frame with sacrificial anodes. Design for construction complied with the requirements of the NI Water Asset Standards and Specifications, CESWI, Relevant CIRIA Guidance and other Industry accepted standards. [caption id="" align="alignnone" width="1200"] The outfall was installed off the coast at Ballyferris adjacent to a caravan park - Courtesy of NI Water[/caption] Undertakings Farrans Construction was appointed as principal designer and contractor for the works, including an early contractor involvement stage consisting of scope and design development, stakeholder engagements, statutory approvals and ground investigations. Farrans appointed Marine Specialists Ltd, a specialist subcontractor, to assist in completing these works. Ards North LSO: Supply chain - key participants Client: NI Water Principal designer/contractor: Farrans Construction Project management/technical support: Tetra Tech Exemplar design: RPS Consulting Engineers Hydraulic modelling: Hydraulic Analysis Ltd Specialist marine subcontractor: Marine Specialists Ltd PE pipe & fittings: Associated Pipeline Products Precast concrete collars: Ardmore Precast [caption id="" align="alignnone" width="1200"] (left) Onshore pipeline assembly - Courtesy of Farrans, and (right) installation of concrete kennels - Courtesy of NI Water[/caption] Installation The primary method of installation was by open-cut trench and rock breaking technique with contingency arrangements in place for encountering ‘unbreakable’ materials, consisting of a drill, blast, dig methodology. The works were completed in the following phases: Phase 1: Works comprised shore-based operations to prove the trench to depth along the intertidal zone, consisting of rock breaking, excavation and temporary backfilling of the trench. This phase was designed to mitigate the risk of delay due to adverse weather conditions and capitalised on large spring tides by utilising land-based equipment during the winter months. It would also minimise the disruption to the public by reducing the duration of pipeline installation and final connection on the beach. Phase 2: This involved the marine-based operations, rock breaking and excavation of the trench proven to depth with the use of a barge-based 60t 360° track excavator with a 14m reach, Topcon 3D GPS system, 4t breaker and ripper tooth. The excavator operated from a pontoon barge 26.8m x 12.2m with a deck capacity of 360t. Phase 3:  This phase included a combination of both shore and marine-based operations. The trenching extended seaward in accordance with the limiting conditions for weather, visibility, sea state, wind and gusts. The position, alignment and depth of the trench were confirmed by the 3D GPS systems and regular bathymetric surveys. The pipeline The pipe lengths (supplied by Associated Pipeline Products) were butt fusion welded, prefabricated to a string length of 500m, fitted with concrete collars (ballast weights) and tested. At the ends of the pipe string, a pupped stub was welded complete with stainless steel backing rings. A blank flange was bolted to the stub/backing ring to allow for the entrapment of air within the pipeline allowing the pipeline to float when placed in the water. Shore-based excavation work was completed at low tide to re-excavate the trench along the intertidal zone previously proven in phase 1 of the works in preparation for pipe tow-and-sink operation. Once the trench was proven to depth and prepared for pipeline installation, the pipe string was gradually moved toward the water using land-based excavators. [caption id="" align="alignnone" width="1200"] Re-excavating the proven trench - Courtesy of Farrans[/caption] At high tide, the pipe was floated, towed and positioned above the pre-dredged trench. Connection was made to the pre-installed land section of the outfall and the pipe was filled with water allowing a gradual sinking and pipe placement along the trench. Backfilling operations commenced once the pipe was surveyed and verified. Professionally qualified divers installed the prefabricated diffuser head. Live underwater video surveys were conducted to monitor the installation of all equipment. The execution of these activities adhered to stringent health and safety protocols, strict environmental considerations, and project timelines, ensuring the successful completion of the project on time and within budget. Community liaison Safety was at the heart of the project and protecting the public while works were ongoing on the beach, in close proximity to a holiday park was paramount. NI Water and Farrans undertook a range of initiatives to ensure that local holidaymakers, residents and the wider public were aware of the planned installation, including leaflet drops, beach signage, posters and importantly a children’s safety art competition. [caption id="" align="alignnone" width="1200"] NI Water and Farrans held a joint safety initiative for children in caravan parks - Courtesy of NI Water[/caption] Successful delivery The installation of the long sea outfall pipe was a complex and challenging element of the wider £18m Ards North Wastewater Improvement Project and required extensive planning, communications and collaboration with a wide range of stakeholders. With a wealth of expertise and experience on board and as a result of meticulous planning, strong teamwork and robust health and safety measures, the new long sea outfall was successfully installed in summer 2022, well in advance of commissioning of the new WwTW in spring 2023. This critical piece of infrastructure, along with the new Ards North WwTW and both new and upgraded pumping stations in the catchment, will support long-term economic growth in local development and tourism and will benefit all those living, working, visiting or investing in this scenic part of the Ards Peninsula.

The WINEP Durham Transfers Project was designed to improve the quality of the Blackdene Burn, a watercourse located in the north Durham area. During AMP7, sewage treatment works (STW) sites within Northumbrian Water Group (NWG) ownership were identified for improvements in phosphorus concentrations within final effluent discharge to the environment. The scope of this project is to address the improvements at both Plawsworth STW and Pity Me STW, which currently discharge to the Blackdene Burn. Background

Esh-Stantec was appointed by NWG to progress the proposed solution; a phased approach whereby, during AMP7, final effluent from both STWs will be transferred to a discharge point on the River Wear via transfer pumping stations. The transfer of flows will be facilitated via new rising mains and gravity sewerage which will connect immediately upstream of the existing outfall from Brasside STW. In line with the phased approach, planned upgrades to Brasside STW in AMP8 will increase its treatment capacity and allow for the eventual abandonment of Plawsworth and Pity Me STWs along with chemical dosing to meet planned phosphorus limits discharging to the River Wear.

The designed solution allows for projected growth across the Plawsworth and Pity Me catchments (including the completion of the significant Sniperley development) with an AMP8 solution transferring all raw flows from Plawsworth and Pity Me to the upgraded Brasside STW for treatment, with final effluent from Brasside STW ultimately discharging to the River Wear.

The objective of this appointment is to provide the assets required to enable to the transfer of flows from Pity Me and Plawsworth STWs in the AMP7 and AMP8 scenarios. It is anticipated that the project will be completed in December 2024.

[caption id="attachment_18551" align="alignnone" width="1200"] Piling operations by Francis & Lewis International Ltd, for the construction of the pipe bridge substructure - Courtesy of Esh-Stantec[/caption] WINEP Durham Transfer: Supply chain - key participants Client: Northumbrian Water Principal designer & contractor: Esh-Stantec Esh Group Stantec UK Structural consultant: James Christopher Consulting Ltd M&E, including supply & installation of generators, MCCs & pumps to wet wells: Retroflo Ltd Directional drilling of 3km of rising main & installation of all AV chambers: Ken Rodney Construction Ltd Auger boring under the East Coast Mainline, coordinating with Network Rail, & supply/installation of track monitoring: Terra Solutions Ltd Design, manufacture, & installation of pipe bridge: Francis & Lewis International Ltd Design & sinking of segmental shafts: Active Tunnelling Ltd Temporary works/shoring: MGF Ltd New transfer stations

The first stage of the scheme involves the transfer of fully treated, final effluent to the River Wear, meaning that Plawsworth and Pity Me STWs remain fully operational throughout the construction of all assets which will become live prior to the upgrade of Brasside STW.

Plawsworth Transfer Station: The new transfer assets at Plawsworth STW were carefully designed and sequenced around the limited working room in the site and the requirement to maintain treatment operations during construction. The Plawsworth Transfer Pumping Station comprises:

A 4m diameter, 6m deep wet well shaft (sunk as a caisson). MCC and associated kiosk. Generator and associated kiosk. Above-ground valve arrangement. Flow meter chamber and all associated interconnecting pipework and ducting.

In AMP7, final effluent flows are intercepted and directed into the new wet well before being pumped to the River Wear. Due to the transfer of final effluent, a reduced emergency storage volume has been provided within the new wet well.

In AMP8, following upgrades to Brasside STW, raw flows will be intercepted upstream of the inlet works and diverted to the new SPS for transfer to Brasside via a new 250mm rising main. As part of the conversion from a treatment works to a terminal pumping station, the existing humus tank will be re-purposed to provide additional emergency storage in line with EA guidelines for the transfer of raw sewage flows and minimise emergency overflow spills to the environment.

In addition to emergency storage, a permanent standby generator has been incorporated into the design which will automatically cut in if there is a loss of power to the site.

The pumping station was designed as a three pump station (duty/assist/standby) to transfer ultimate AMP8 flows up to 32 l/s, however, in the AMP7 scenario,  the pumping station will operate as a duty/standby/standby station, with the individual pumps sized to transfer 24 l/s of final effluent to maintain a minimum velocity in the rising main.

Pity Me Transfer Station: The main works at Pity Me STW comprises the following:

A 6m diameter, 9m deep wet well shaft (sunk as a caisson) with built-in emergency storage volume sized for ultimate raw flows. MCC and associated kiosk. Generator and associated kiosk. Valve chamber. Flow meter chamber and all associated interconnecting pipework and ducting.

Similar to Plawsworth, the pumping station was designed as a three pump station to transfer 34 l/s in AMP7, with a duty/standby/standby arrangement, and up to 61 l/s in AMP8, after conversion to a duty/assist/standby arrangement. In both the final effluent and raw flow scenarios, pumped flows will exit the works via a new 280mm rising main.

[caption id="attachment_18550" align="alignnone" width="1200"] Active Tunnelling constructing the new wet well shaft at Pity Me STWCourtesy of Esh-Stantec[/caption] Transfer rising mains

Approximately 2.1km of 250mm PE rising main and associated air valve/washout chambers has been installed from Plawsworth STW. The rising main pipework was installed predominantly via a trenchless technique, namely horizontal directional drilling (HDD), primarily due to lack of available access from the adjacent A167 highway to facilitate traditional open cut construction, as well as unfavourable ground conditions.

A new 280mm  rising main was installed over an 850m length from Pity Me STW. Due to a tight working corridor situated between a garden centre and the Blackdene Burn, as well as the requirement to cross beneath the A167, a highly trafficked highway, the rising mains was also installed via HDD. This use of a trenchless installation technique minimised disruption to local business and removed the requirement for traffic management on a busy commuter route.

eDNA samples taken from ponds adjacent to Pity Me in the feasibility stage confirmed the presents of great crested newts. In lieu of protracted traditional population surveys and subsequent licenced activities to mitigation including fencing and capture to clear the working area, a District Level License (DLL) was secured from Natural England and works were completed under an approved method statement with supervision from a consultant ecologist.

The 280mm and 250mm rising mains from Pity Me and Plawsworth connect to a common chamber located at the high point of the new network, where they will discharge flows to a new DN400 gravity sewer.

[caption id="attachment_18547" align="alignnone" width="1200"] Construction of new valve chamber and associated pipework at Pity Me STW - Courtesy of Esh-Stantec[/caption] New gravity sewerage

2.4km of new DN400 gravity sewerage, with associated manhole chambers, was constructed to receive the pumped flows from both Pity Me and Plawsworth STWs. Careful consideration was given to the design of the new sewerage to ensure capacity (including future growth) and self-cleansing requirements are met in all flow scenarios, including when Pity Me and Plawsworth transfer pumps operate either in isolation or in parallel.

The construction of the new gravity sewer poses some complex crossings and challenging ground conditions. The crossing of Chester Low Road, another busy road for both commuters and customers of a popular local retail park, The Arnison Centre, was originally planned for open cut excavation. However, subsequent on-site observations with regard to topography, a number of high-risk services including high voltage electric cables and a uPVC water main, and running sands within nearby open cut trenches led to the conclusion that it would not be possible to safely support the excavation during construction. Therefore, the road crossing was completed via guided auger bore. Not only did this mitigate the disruption and health and safety risks associated with damaging services, but it also minimised disruption to local businesses and residents as the road remained operational throughout the process.

East Coast Main Line crossing

Further downstream, the new gravity line is also set to cross beneath Network Rail’s East Coast Main Line. The proposal is to install a 610mm sacrificial steel sleeve via a guided auger bore beneath the embankment, once complete the 400mm NB gravity pipe will be sleeved and the anulus grouted. Extensive liaison is ongoing with Network Rail in the lead up to the under track crossing (UTX) to gain the necessary approvals and fully understand the constraints which must be met during construction. These constraints include but are not limited to 24/7 working for the duration of the tunnelling works, installation of track monitoring and an approved contractor on standby in case there is a requirement for emergency track repair.

[caption id="attachment_18549" align="alignnone" width="1200"] Aerial view of working area at Brasside STW - Courtesy of Esh-Stantec[/caption] Brasside pipe bridge

Approximately 800m upstream of the Brasside STW outfall connection, the sewer crosses a watercourse located within a steep ravine and dense woodland at the existing Brasside Sewage Pumping Station (SPS).

At the optioneering stage of the project, it was proposed that this crossing would take place via an inverted siphon arrangement. However, subsequent hydraulic modelling deemed that, due to topography constraints, it would not be feasible to achieve sufficient capacity while maintaining self-cleansing velocities in both the AMP7 and AMP8 flow scenarios without connecting to the existing outfall further downstream. This would have required construction works within ancient woodland, imposing the requirement for Environmental Impact Assessment (EIA) and potentially preventing the obtention of a Lawful Development Certificate.

Therefore, to mitigate the risk of repeat maintenance issues and potential asset failure, a pipe bridge was progressed as the preferred option having discounted a further interstage pumping station at the low point due to a lack of space within the existing Brasside SPS site and the associated operational carbon and expenditure.

The route of the pipe bridge was designed to mitigate environmental impact, by including bends within the bridge structure and above ground pipework to take advantage of existing operational land and avoid clearance of significant trees within a conservation area. The interface between the bridge structure and the above ground ductile iron pipework has been carefully modelled and iteratively designed to assess the impact of bridge movement and deflection on the pipe joints and select joints which provide appropriate tolerances for these movements.

[caption id="attachment_18552" align="alignnone" width="1200"] Construction of pipe bridge structure by Francis & Lewis International Ltd - Courtesy of Esh-Stantec[/caption] Conclusion

The design of the WINEP Durham Transfers Scheme serves to meet regulatory deadlines by achieving a sustainable multi-stage solution which meets the needs of the current and future catchment population.

At the time of writing (July 2024), construction is progressing well, and all rising main pipework and transfer station substructures have been installed. The gravity sewer is predominantly complete with the two key crossings remaining, pending final Network Rail approval to complete the rail crossing and final structural design of the pipe bridge to install the above-ground pipework adjacent to Brasside SPS.

The current construction programme shows that flows will be turned in December 2024, transferring final effluent to the River Wear in the interim and, in AMP8, transferring raw flows to Brasside STW for treatment. This will achieve the removal of treated effluent from the Blackdene Burn, in turn significantly improving water quality while meeting WINEP obligations. Furthermore, the completion of the scheme in AMP8 will serve to rationalise the NWG sewage network in the area and improve the resilience of the network by serving catchment growth and improving treatment capacity.

The Severn Estuary is renowned for its tidal range of 12-14 meters, the second largest in the world, and as such poses significant challenges for civil and marine works. In late 2024, a critical infrastructure upgrade project was completed near Nash, Newport, replacing a long sea outfall pipeline originally constructed in 1960 to extend its operational life. The project involved installing a 1.4km 560mmØ high-density polyethylene (HDPE) outfall pipe to replace the deteriorated concrete-coated steel pipe. Situated within one of the UK’s most ecologically sensitive regions and a Site of Special Scientific Interest (SSSI) in the Severn Estuary, the project not only secured infrastructure integrity but also adhered to stringent environmental protection measures. Project challenges and environmental safeguards

Kaymac Marine & Civil Engineering Ltd was appointed as the principal designer and contractor for the £8.4m outfall replacement project.

The Severn Estuary is designated as a Site of Special Scientific Interest (SSSI), which protects its tidal flats, salt marshes, and diverse wildlife, which required the project team to introduce and adhere to comprehensive environmental safeguards.

[caption id="attachment_19920" align="alignnone" width="1200"] The in-land RC chamber connecting the new and existing pipe (during construction) - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption]

Sediment control measures such as careful selection of plant and equipment, implemented in collaboration with National Resources Wales (NRW), minimised water quality impacts during the excavation and pipe-laying activities.

Kaymac Marine & Civil Engineering Ltd drew upon its deep industry expertise and practical experience to drive the design direction and successfully secure all necessary permits and permissions for the project. Working closely with the local council and NRW, Kaymac led the process of obtaining the required Marine License, Environmental Permits, and Planning Permissions, ensuring full compliance with all regulatory requirements.

Through comprehensive site investigations and advanced geophysical and bathymetric surveys, Kaymac Marine & Civil Engineering Ltd identified critical site-specific characteristics that directly influenced the project’s design. This informed approach allowed the team to craft tailored solutions that addressed regulatory concerns while optimising project outcomes.

Kaymac’s practical experience played a crucial role in addressing the expectations of the environmental regulators. By proactively collaborating with NRW and other stakeholders, the team was able to satisfy stringent environmental requirements, demonstrating how the proposed designs minimised ecological impacts while maintaining structural and operational integrity.

[caption id="attachment_19919" align="alignnone" width="1200"] New valves within the inland chamber - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption]

This expertise and experience, coupled with a solutions-focused mindset, not only streamlined the approval process but also ensured that the final design adhered to both regulatory standards and the project’s overarching goals.

To maintain quality standards and to ensure the works could be undertaken within the licencing timeframes, Kaymac Marine & Civil Engineering Ltd engaged suppliers early on, securing essential equipment and materials; whilst conducting regular necessary quality visits and inspections to ensure technical and Quality compliance.

Severn Estuary LSO Replacement: Supply chain - key participants Principal Designer & Contractor: Kaymac Marine & Civil Engineering Ltd Designer: Pebble Engineering Ltd Specialist design: Morek Engineering Ltd Specialist design: H2NA Ltd HDPE pipe: Pipelife Norge AS Precast concrete collars: Poundfield Precast Precast concrete mattresses: Subsea Protection Systems Duckbill check valves: Measurit Technologies Valves: Scott Parnell Landside temporary works & shoring MGF Ltd Huennebeck Construction materials Scott Parnell Neal Soils Wright Readymix Stone Supplies IPP Floating plant Jenkins Marine Kraken Marine Services P&D Environmental Construction plant hire Land & Water Plant Hire Flannery Plant Weldex RW Christopher Crane Hire Ltd United Rentals Atlas Winch & Hoist Services Ltd A1 Surveys MTK Breakers LGS Gap Hire Services HV Fusion Severn Environmental Services ABP Newport & Barry [caption id="attachment_19913" align="alignnone" width="1200"] Trench excavation prior to the first section of pipe installation - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption] Detailed design & planning

A comprehensive understanding of the physical forces that dominate the ocean environment, their origins, and the likelihood and intensity of these forces over the lifespan of an outfall is critical to its effective design, regardless of the construction materials used.

These forces can compromise the outfall’s integrity either directly or indirectly, such as through seabed erosion or by destabilising its foundation. Additionally, sediment transport can obstruct diffuser orifices, potentially leading to system failure. These factors were considered and mitigated during the planning and design phases to ensure the long-term functionality for this particular environment.

Kaymac Marine & Civil Engineering Ltd appointed Pebble Engineering Ltd as designers and worked collaboratively to develop the construction methods and subsequently the detailed design of the outfall.

Both the construction method and the detailed design needed to align and complement each other, with regard to compliance of the aforementioned environmental and planning regulations, the seabed conditions present on site and the anticipated physical conditions (such as sea, wind, wave, tidal and current) of the works location.

Delivery & preparation of HDPE pipe

The new high-density polyethylene (HDPE) long sea outfall pipe, measuring 1.4km in length and 560mm in diameter, was manufactured by Pipelife Norge AS in Norway and was towed 1,134 nautical miles to Newport in 11 sections under a single trip.

Upon arrival at ABP Newport Docks, each pipe section was stringently inspected, tested and then later prepared for installation.

The preparation works involved the installation of over 260 bespoke precast concrete ballast collars that were designed to ensure stability of the pipeline against the hydrodynamic forces of the watercourse and the natural buoyancy of the HDPE material, once it had been sunk to its installed position within the trench.

[caption id="attachment_19915" align="alignnone" width="1200"] Pipe being prepared for connection - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption] Innovative installation techniques in a tidal environment

The use of specialised low pressure bearing amphibious excavators handled intertidal trenching at low tide, while a GPS-equipped dredging vessel undertook the offshore trenching requirements. The installation spanned an approximate 28-day period, working shift patterns under challenging tidal conditions, with trenches reaching depths of approximately 1.5–2 meters.

A key milestone involved towing the first 250 meter section of the pipe from ABP Newport, navigating the currents and flows of the Severn Estuary, to the installation site, approximately three nautical miles away. This segment, equipped with 50 concrete collars, was positioned over the trench as the tide receded, sunk under the guidance of Kaymac’s divers to ensure accuracy, before being backfilled with the previously excavated spoil.

Finally, the precast articulated concrete mattresses from Subsea Protection Systems Ltd were installed by utilising a crane barge to provide additional scour protection and stability to the outfall. Such mattresses have been used successfully for decades to protect oil and gas pipelines and since the early 1990s, they have been increasingly used to protect ocean outfalls.

Throughout the project, Kaymac employed a flotation and submersion technique whereby each 250 meter long section was towed into position and the seaward end of the previously installed pipe length was recovered to the working platform, before connecting to the new length and then sinking within the new pre-excavated trench.

[caption id="attachment_19916" align="alignnone" width="1200"] First section of the pipe within the trench during low tide ahead of backfilling - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption]

Ensuring an accurate and safe sinking procedure in the Severn Estuary required considerable planning efforts from the delivery team, taking into consideration tidal movements and slack water periods. Each sinking activity was planned meticulously to ensure that a constant submersion rate could be implemented, assisted by a number of key specialist vessels being present to position and secure the pipe section in place whilst the slack water period approached.

Slack water periods in this location are relatively short and as such, the rate of pipe submersion needed to be planned and controlled by adjusting both the water inflow and air release rates. To avoid a bending radius that could become smaller than its allowable minimum and further, to prevent the pipe wall buckling, the rates needed to be carefully monitored and controlled, all whilst considering the load imposed by the ballast weights, the varying tidal water depth and the pulling forces applied to the outfall by the marine plant.

The pipe installation continued in four separate sections, totalling 1.47km, with a diffuser head separately installed through diving operations at the seaward end. A backhoe dredger was used to place the previously excavated material on to the pipe.

Following the backfilling, approximately 210 of the precast articulated concrete mattresses in total, each weighing 8.3t in air, were laid over the installed lengths of pipe from the crane barge. The backfilling and mattress installation were monitored and supervised by Kaymac’s dive teams, ensuring the accuracy and efficiency of both activities throughout the scheme.

Civil operations, plant isolations and final connection

To prevent disruption to the client during their day-to-day operations, the marine activities to install the replacement outfall were carried out alongside the existing operational outfall. Simultaneously, inland operations were undertaken by Kaymac’s skilled civils teams, who installed a temporary sheet piled cofferdam to excavate and expose the existing valve and land-based outfall arrangement.

Two short operational isolations were required; the first to replace the existing land based valve and connecting pipes, and the second to connect the new replacement outfall to the existing infrastructure. Again, these isolations were planned precisely around suitable tidal windows, to maximise working efficiency and to minimise interruption to the plant operations.

During the first isolation, the existing land-based single non-return valve was replaced with new valves and a T-piece arrangement system that would permit future inspection and maintenance requirements.

Once the land based replacement and connection works were complete, the replacement valve arrangement was housed within a newly constructed reinforced concrete chamber, built alongside the normal operations of the plant. The chamber was designed to permit safe future access around the valve arrangement and to retain a section of the existing flood defence embankment.

The second isolation took place while the land-based civil works were underway to construct the new chamber. Working at low tidal periods, a bespoke HDPE pipe section was fabricated that considered both the vertical and horizontal changes in direction to align with the newly installed outfall. This section was installed to connect the newly installed outfall to the existing pipeline ahead of removing the isolation.

[caption id="attachment_19918" align="alignnone" width="1200"] Old pipe being removed during low tide - Courtesy of Kaymac Marine & Civil Engineering Ltd[/caption] Conclusion

The long sea outfall replacement project stands as a model of responsible marine engineering within sensitive ecosystems.

By balancing complex engineering requirements with rigorous environmental protection, Kaymac Marine & Civil Engineering Ltd are proud to have played a key role in improving Newport’s existing infrastructure; blending innovative marine engineering techniques with stringent environmental safeguards to protect and enhance the unique ecology of the Severn Estuary.