Details of Award

NERC Reference : NE/R009090/1

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Early warning decision support system for the management of underwater scour risk for road and railway bridges

Grant Award

Principal Investigator:: Professor D Zonta, University of Strathclyde, Civil and Environmental Engineering
Co-Investigator:: Professor D Val, Heriot-Watt University, Sch of Energy, Geosci, Infrast & Society
Co-Investigator:: Dr J Douglas, University of Strathclyde, Civil and Environmental Engineering
Co-Investigator:: Professor A Tarantino, University of Strathclyde, Civil and Environmental Engineering
Co-Investigator:: Dr NS Ferguson, University of Strathclyde, Civil and Environmental Engineering
Grant held at:: University of Strathclyde, Civil and Environmental Engineering

Science Area:: Freshwater
Overall Classification:: Unknown

Science Classification details

ENRIs:: Environmental Risks and Hazards
Science Topics:: Bridges; Health Monitoring (Civil); Masonry Structures (Civil); Use of Sensors (Civil); Structural Engineering; Smart Sensors; Real-time Monitoring of Sys.; Intelligent Measurement Sys.

Abstract:: PARTNERS- Transport Scotland (TS), Network Rail (NR), SEPA, Arup. CHALLENGE- Flood induced scour is by far the leading cause of bridge failures, resulting in loss of lives, traffic disruption and significant economic losses. TS is responsible for 1,567 bridges, 8% of these currently classified as needing scour protection measures and costing #2m per annum in routine inspections. Similarly, NR Scotland Route includes 1,750 structures susceptible to scour requiring an annual inspection spend of #0.4m. Inspections are expensive and time consuming, and often the information collected is qualitative and subjective. OBJECTIVE- To develop a prototype of a Decision Support System (DSS) for scour risk management for NR's and TS's bridges, which enhances users' safety, while minimizing traffic disruptions and transport agencies' operational cost. The system will estimate, and continuously update, the present and future scour failure risk using (i) real-time information from monitoring of scour depth (ii) rainfall forecast and (iii) river flow characteristics. INNOVATION- Sensor and communication technologies offer the possibility to assess in real time the scour depth at critical bridge locations; yet monitoring an entire infrastructure network is not economically sustainable. A way to overcome this limitation is to install monitoring systems on a limited number of critical locations and use a probabilistic approach to extend this information to the entire asset. In the occurrence of a flood, monitoring observations are used to give the real-time best estimate of bridge failure probability. The sensing technology proposed is a prototype of smart probe with integrated electromagnetic sensors designed to detect changes in the dielectric permittivity of the surrounding bridge foundation, designed and calibrated to detect scour and sediment deposition in various soil types. KEY ACTIVITIES - Collect data from past scour inspection on NR's and TS's inspection records; define formal vulnerability model based on the fragility curve method. - Define flood hazard models based on SEPA rainfall and river flow datasets, and accounting for CCRA climate change prediction. - Model correlation in hazard and vulnerability among different bridges, using Bayesian networks. - Collect data from TS pilot scour monitoring system. - Implement algorithms for updating fragility curves and state variables of the Bayesian network based on real-time information from monitoring system. - Develop a prototype DSS that continuously updates bridge failure risk using real-time information from pilot monitoring system and rainfall forecast. - Produce an exploitation plan. DELIVERABLES- The BRIDGE VULNERABILITY MODEL, the FLOOD HAZARD MODEL and the SCOUR HAZARD MODEL will provide NR and TS with quantitative up-to-date information on the probability of scour failure of each bridge. Before a flood event, this will allow prioritising inspections according to risk and, when necessary, to introduce precautionary bridge closures or traffic management. This framework can be equally used to simulate the impact of potential extreme weather events on travel agencies' network, and to plan in advance appropriate emergency procedures and countermeasures. The TS PILOT SCOUR MONITORING SYSTEM will provide validation to a new technology for direct assessment of underwater scour, which can complement traditional NR's and TS's river-bank visual assessments. The DECISION SUPPORT SYSTEM will provide information for long term prediction of future scour risk to drive strategic maintenance, repair and rehabilitation actions. The same DSS can be used as an early warning system that automatically takes action when the risk estimated exceeds a given threshold. The EXPLOITATION PLAN will set a roadmap to transfer the new technology and knowledge to other infrastructure systems and geographical areas. DURATION- 12 months COST- #94,763.02

Period of Award:: 6 Nov 2017 - 5 Nov 2018
Value:: £96,522

(FY details)

Authorised funds only

NERC Reference:: NE/R009090/1
Grant Stage:: Completed
Scheme:: Innovation
Grant Status:: Closed
Programme:: Innovation - Risk

This grant award has a total value of £96,522

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FDAB - Financial Details (Award breakdown by headings)

DI - Other Costs	Indirect - Indirect Costs	DA - Investigators	DA - Estate Costs	DI - Staff	DI - T&S	DA - Other Directly Allocated
£120	£42,922	£9,536	£13,472	£27,718	£1,936	£820

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