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The impact arises from the study of extreme ocean waves and their interaction with marine structures. It is relevant to the offshore, shipping, coastal and marine renewables industries and has been both economic and regulatory, involving:
(a) The establishment of revised guidelines for the design of new structures / vessels.
(b) Enhancing best practice, both from an economic and a safety perspective.
(c) Reducing the uncertainty in critical design issues, thereby improving overall reliability.
(d) Enabling "end-of-life" extensions for existing structures.
(e) Facilitating the effective decommissioning of redundant structures.
(f) Contributing to the development of new industrial R&D equipment, thereby assisting specialist UK manufacturers to secure international orders.
Research led by Professors Cawley and Lowe (employed at Imperial College over the whole 1993-2013 period) resulted in guided wave inspection being established as a new non-destructive evaluation (NDE) method. It is used worldwide to screen long lengths of pipework for corrosion, particularly in the petrochemical industry. A spin-out company has been established that employs seven PhD graduates in NDE from Imperial and the technology is also licensed to another company. Turnover on equipment sales 2008-2013 exceeds £50M and the service companies using the equipment generate about £75M pa in revenue worldwide and employ about 300 FTE staff to carry out the inspection. The oil companies benefit from greatly reduced cost of inspection, especially in areas such as insulated, offshore and buried pipes where access is difficult and expensive for conventional inspection methods. Furthermore, the reliability of inspection is significantly improved, leading to major improvements in safety.
Research in the Department of Civil and Structural Engineering at the University of Sheffield on dynamic performance and vibration serviceability has contributed to internationally applied guidance on building serviceability for floors, buildings, stadia and other structures and has led to the spin-out Full Scale Dynamics Ltd (FSDL). Based on our research FSDL provides applied research and consultancy services, and has delivered projects approaching £1m since 2008. FSDL has demonstrated significant reach through its work with blue chip clients nationally and internationally. Our research has impacted on leading national sport infrastructure (such as Premiership Football stadia and notably the Olympic 2012 Velodrome) and public companies to deliver economic benefits by providing evidence based compliance, demonstrating that stadia, hospitals, manufacturing plants and other public structures comply with safety and vibration serviceability standards. Interventions based on our research and implemented via FSDL have, on numerous occasions, avoided potentially serious economic and safety consequences due to the poor vibration performance of structures.
Guidelines and standards underpinned by Strathclyde research have improved the design, assessment and the safety of marine structures subjected to wave impact in large steep waves. The guidelines and standards are widely used in the design of floating structures, particularly Floating Production, Storage and Offloading vessels (FPSOs) and offshore wind turbines. Since January 2008 the work has impacted the design, strength assessment and failure analysis of fixed offshore oil and gas platforms, renewable energy devices and ships. The guidelines and standards are used by designers to mitigate against damage caused by breaking wave impact, thereby improving the safety of mariners and offshore workers, reducing lost production due to downtime, and cutting the risk of environmental impact due to oil pollution. The research has also been used by Strathclyde researchers in industry-focussed studies, in legal work related to the loss of the oil tanker Prestige (2009-2013), in the assessment of the Schiehallion FPSO for BP (2010), and design of a Scottish harbour wave screen (2009) that allows ferries to access and stay in the harbour in more severe weather.
Edinburgh Designs Ltd., (EDL) was spun-out to exploit ERPE research from the original Wave Power Group. With six staff and an annual turnover approaching £2M EDL has supplied the equipment and control systems for wave tanks in 19 countries including the world's largest computer-controlled wave test facility, the US Navy Manoeuvring and Station Keeping Tank. They are currently completing the world's first circular tank, combining waves with currents in any relative direction, which is operated by the 6 person company, "FloWave" EDL, still run by the founding staff, it is the world-leading supplier of wave-making technology for scientific and recreational facilities.
A novel application of parametric resonance (PR) is described, which has improved the effectiveness of a vibrating screen used for size-sorting of crushed rock. These improvements have had an economic impact on the Ukrainian company that makes the screens: the mathematics developed in Aberystwyth permits a stable, high amplitude PR-regime to be found, reducing the damage to the screen mesh and increasing its longevity. This new technology is allowing the company to reduce costs and equipment downtime and is enabling them to gain a market advantage by being able to sort wetter materials than previously.
Large-amplitude horizontally propagating internal solitary waves commonly occur in the interior of the ocean. This case study presents evidence to demonstrate the impact of research conducted by Professor Grimshaw at Loughborough University on the development and utilisation of Korteweg- de Vries (KdV) models of these waves, which has formed the paradigm for the theoretical modelling and practical prediction of these waves.
These waves are highly significant for sediment transport, continental shelf biology and interior ocean mixing, while their associated currents cause strong forces on marine platforms, underwater pipelines and submersibles, and the strong distortion of the density field has a severe impact on acoustic signalling.
The theory developed at Loughborough University has had substantial impact on the strategies developed by marine and naval engineers and scientists in dealing with these issues.
Impact: Economic and societal The Millimetre Wave and Electron Paramagnetic Resonance (EPR) group has developed internation-ally award-winning instrumentation, and associated components that have been produced commercially by Thomas Keating Ltd. They have also led a pio-neering public understanding programme (PUP).
Significance: Thomas Keating have developed a range of new product lines serving > 20 international customers including [text removed for publication] of recent orders. The PUP has reached ~82 000 at-tendees.
Reach: Systems have been sold internationally and PUP has developed into specific exhibitions at a range of science centres.
Attribution: The work has been led by PHYESTA Researcher Dr Graham Smith
In Europe, there are over a million kilometres of oil pipelines, nearly a million kilometres of railway tracks, 600 offshore platforms and 300 suspension cable bridges. However, these assets are aging as they have been in use for many years and operate under harsh conditions. Brunel research team has advanced ultrasonic non-destructive testing (NDT) which has the ability to inspect buried pipes in their original place without removing the pipes or damaging their surrounding environment. In addition, the research was pursued to improve the NDT of rail tracks, storage tanks, flexible risers in offshore platforms and aircraft wires. The research has been commercially exploited and incorporated into Teletest Focus System Mark III by Plant Integrity Limited. The significant improvement has led Plant Integrity to terminate the sale of Teletest Mark III and introduce a new version, Teletest Focus System Mark IV, to the market in late 2010. Since then, Plant Integrity has doubled its turnover from sales of Teletest Focus System Mark IV from £1 million to £2 million in less than a year.
Radiation sources and amplifiers, in the spectral region from microwave to terahertz, are extensively used in UK industry and public sectors such as security, defence, health and the environment. Companies, including e2v Technologies plc. (e2v) and TMD Technologies Ltd. (TMD), have developed and sold new radiation products based on post-1996 research undertaken at the University of Strathclyde. Their devices accessed new frequency ranges with considerable increases in power and bandwidth. The designs were transferred to industry, where devices have been constructed, jobs created, policy changed and considerable investments made. These sources have had extensive beneficial impact through applications in defence, surveillance, materials processing, health sciences and environmental monitoring.