Remote, 3D ultrasonic imaging in extreme environments using 2D laser induced phased arrays
Lead Research Organisation:
University of Strathclyde
Department Name: Electronic and Electrical Engineering
Abstract
The application of "phased array ultrasonics" has had a profound impact on science and medicine. It is the technology at the heart of all medical ultrasonic imaging systems and sonars. This proposal brings the equivalent of phased array technology to laser ultrasonics for remote, volumetric, 3D ultrasonic imaging.
In laser ultrasonics the sound is generated through the rapid thermal heating and expansion of the material under test, due to the incident laser radiation. However, there are serious signal-to-noise limitations associated with this technique, which could be addressed using an array configuration just as it happens with conventional, transducer based arrays. Up to now it has been very difficult to perform phased array ultrasonics with lasers because the technology to focus and steer the ultrasonic bulk waves for generation or detection puts severe demands on hardware (multiple lasers for ultrasonic generation or complicated experimental setups) and cost. The proposed work will be based on synthesising the Laser Induced Phased Arrays (LIPAs) in post processing, by first acquiring the Full Matrix and then applying a suitable imaging algorithm (e.g. the Total Focusing Method - TFM). The post processing of the optical based data in LIPAs, keeps the experimental setup simple and cost effective. These remote, couplant-free ultrasonic arrays, made of light, can be applied in extreme environments, for in-line process monitoring or in-service volumetric inspection. The aim of the proposed research is to develop a laser based ultrasonic measurement capability for remote, nondestructive, quantitative evaluation and 3D ultrasonic imaging in extreme environments for safety critical applications, where conventional arrays cannot be applied. 2D LIPAs will be able to image a given defect from a range of angles, obtaining characterisation detail far beyond what is achievable with a 1D array.
The core research objectives within this project are:
* Development of laser induced phased arrays for 3D ultrasonic imaging using FMC and TFM.
* Optimisation of the data collection method to laser ultrasonics to improve speed of process.
* Optimisation of the TFM imaging algorithm to laser ultrasonics for efficient ultrasonic imaging.
* Demonstration of system's industrial application potential for inspection and process monitoring in extreme environments.
The success of this work will benefit the non-destructive testing community, the laser ultrasonics community and will enable engineers and material scientists in need of a technique to address extreme environments and places of restricted access, to test the performance of their structures, either during the manufacturing process (e.g. additive manufacturing) or in-service (e.g. in situ inspection of radioactive waste containers). Examples of potential applications include: process understanding and control for manufacturing in extreme environments such as welding and additive manufacturing, increasing process reliability which is crucial for the future of additive manufacturing; in situ ultrasonic inspection in aero-engines or power generators. Other applications are expected in fields such as chemistry, biology and biomedical imaging where remote ultrasonic imaging is needed in sterilised or corrosive environments.
In laser ultrasonics the sound is generated through the rapid thermal heating and expansion of the material under test, due to the incident laser radiation. However, there are serious signal-to-noise limitations associated with this technique, which could be addressed using an array configuration just as it happens with conventional, transducer based arrays. Up to now it has been very difficult to perform phased array ultrasonics with lasers because the technology to focus and steer the ultrasonic bulk waves for generation or detection puts severe demands on hardware (multiple lasers for ultrasonic generation or complicated experimental setups) and cost. The proposed work will be based on synthesising the Laser Induced Phased Arrays (LIPAs) in post processing, by first acquiring the Full Matrix and then applying a suitable imaging algorithm (e.g. the Total Focusing Method - TFM). The post processing of the optical based data in LIPAs, keeps the experimental setup simple and cost effective. These remote, couplant-free ultrasonic arrays, made of light, can be applied in extreme environments, for in-line process monitoring or in-service volumetric inspection. The aim of the proposed research is to develop a laser based ultrasonic measurement capability for remote, nondestructive, quantitative evaluation and 3D ultrasonic imaging in extreme environments for safety critical applications, where conventional arrays cannot be applied. 2D LIPAs will be able to image a given defect from a range of angles, obtaining characterisation detail far beyond what is achievable with a 1D array.
The core research objectives within this project are:
* Development of laser induced phased arrays for 3D ultrasonic imaging using FMC and TFM.
* Optimisation of the data collection method to laser ultrasonics to improve speed of process.
* Optimisation of the TFM imaging algorithm to laser ultrasonics for efficient ultrasonic imaging.
* Demonstration of system's industrial application potential for inspection and process monitoring in extreme environments.
The success of this work will benefit the non-destructive testing community, the laser ultrasonics community and will enable engineers and material scientists in need of a technique to address extreme environments and places of restricted access, to test the performance of their structures, either during the manufacturing process (e.g. additive manufacturing) or in-service (e.g. in situ inspection of radioactive waste containers). Examples of potential applications include: process understanding and control for manufacturing in extreme environments such as welding and additive manufacturing, increasing process reliability which is crucial for the future of additive manufacturing; in situ ultrasonic inspection in aero-engines or power generators. Other applications are expected in fields such as chemistry, biology and biomedical imaging where remote ultrasonic imaging is needed in sterilised or corrosive environments.
Planned Impact
The aim of the proposed research is a laser based ultrasonic measurement capability for remote, non destructive, quantitative evaluation and 3D ultrasonic imaging. These remote, couplant-free ultrasonic arrays, made of light, will be applied in extreme environments, for in-line process monitoring or in-service volumetric inspection of safety critical applications, where conventional arrays cannot be applied.
Such capability is expected to enhance UK's competitiveness in manufacturing, sensing and non-destructive testing (NDT). Advanced materials push the performance limits to extreme environments and can only be used safely if appropriate sensing technologies have been developed. This is why it is expected that the impact from the proposed research will be transformative: it will enable engineers and materials scientists to test the performance of their structures, either during the manufacturing process (e.g. additive manufacturing) or in-service (e.g. in situ inspection of radioactive waste containers), something that is not possible with the existing technology. Just as importantly, reduced usage of resources and safer management of nuclear waste benefit society as a whole and are part of this project's social impact.
The primary beneficiaries of this research are the NDT community, the laser ultrasonics community, engineers and material scientists in need of a technique to address extreme environments and places of restricted access.
The proposed work is anticipated to benefit a broad range of end-users including the additive manufacturing, power generation, aerospace and oil & gas sectors. This is both from enabling general NDT of components as well as process monitoring. A wider impact is expected in fields such as chemistry, biology and biomedical imaging where remote ultrasonic imaging is needed in sterilised or corrosive environments which a remote technique that is able to offer 3D ultrasonic imaging, in extreme environments will be able to address, unlike the currently existing technology.
There will be a Research fellow and a University funded PhD student directly involved in this research. By the end of their respective projects they will have been exposed to a variety of NDT ultrasound techniques, they will be aware of the challenges in the field and will have a multi-disciplinary approach to remote ultrasonic imaging. They will be working in close collaboration with the industry and academic world and it is anticipated that, as they progress with their respective careers they will further influence the field.
Such capability is expected to enhance UK's competitiveness in manufacturing, sensing and non-destructive testing (NDT). Advanced materials push the performance limits to extreme environments and can only be used safely if appropriate sensing technologies have been developed. This is why it is expected that the impact from the proposed research will be transformative: it will enable engineers and materials scientists to test the performance of their structures, either during the manufacturing process (e.g. additive manufacturing) or in-service (e.g. in situ inspection of radioactive waste containers), something that is not possible with the existing technology. Just as importantly, reduced usage of resources and safer management of nuclear waste benefit society as a whole and are part of this project's social impact.
The primary beneficiaries of this research are the NDT community, the laser ultrasonics community, engineers and material scientists in need of a technique to address extreme environments and places of restricted access.
The proposed work is anticipated to benefit a broad range of end-users including the additive manufacturing, power generation, aerospace and oil & gas sectors. This is both from enabling general NDT of components as well as process monitoring. A wider impact is expected in fields such as chemistry, biology and biomedical imaging where remote ultrasonic imaging is needed in sterilised or corrosive environments which a remote technique that is able to offer 3D ultrasonic imaging, in extreme environments will be able to address, unlike the currently existing technology.
There will be a Research fellow and a University funded PhD student directly involved in this research. By the end of their respective projects they will have been exposed to a variety of NDT ultrasound techniques, they will be aware of the challenges in the field and will have a multi-disciplinary approach to remote ultrasonic imaging. They will be working in close collaboration with the industry and academic world and it is anticipated that, as they progress with their respective careers they will further influence the field.
Publications
Lukacs P
(2024)
Online evolution of a phased array for ultrasonic imaging by a novel adaptive data acquisition method.
in Scientific reports
Lukacs P.
(2021)
REMOTE, VOLUMETRIC ULTRASONIC IMAGING OF DEFECTS USING TWO-DIMENSIONAL LASER INDUCED PHASED ARRAYS
in Proceedings of 2021 48th Annual Review of Progress in Quantitative Nondestructive Evaluation, QNDE 2021
Lukacs P.
(2021)
ADAPTIVE DATA ACQUISITION FOR FAST ULTRASONIC IMAGING USING LASER INDUCED PHASED ARRAYS
in Proceedings of 2021 48th Annual Review of Progress in Quantitative Nondestructive Evaluation, QNDE 2021
| Description | Key Finding 1: Volumetric (3D) ultrasonic images of the interior of Aluminium components have been obtained using a remote, couplant free technique. The developed technique is based on lasers for ultrasonic generation and detection. The data acquisition method Full Matrix Capture (FMC) was followed and 2-dimentional (2D) Laser Induced Phased Arrays (LIPAs) were synthesised in post processing using the imaging algorithm of the Total Focusing Method. 2D LIPAs of 11x11 elements were synthesised and 3D, volumetric images of flat bottom blind holes were successfully imaged to a maximum depth of 15mm from the surface of an aluminium component. This finding meets the 1st Objective of the EP/T012862/1 project. Key Finding 2: A novel data acquisition method, the Selective Matrix Capture (SMC), has been introduced. The SMC can adapt the array geometry during data acquisition (on-the-fly), to the demands of the inspected structure, such as the defects encountered. This adaptive data acquisition method is enabled by the use of Laser Induced Phased Arrays (LIPAs) which provide remote, couplant -free and flexible ultrasonic imaging method that has the capabilities to change array parameters, including the number of array elements, pitch, frequency and element distribution. In contrast this is not possible using conventional, transducer-based phased arrays, which are constrained by their fixed characteristics.. The SMC acquires data more efficiently (faster data acquisition and reduced data volume) without a priori knowledge of the location of the defects, while still achieving the superior imaging quality provided by the previously used Full Matrix Capture (FMC) data acquisition method. In order to demonstrate the benefits of SMC, LIPAs were synthesised to image ultrasonically a 1mm diam. side drilled hole in an aluminium sample. The side drilled hole was located 15mm below the scanned surface. The results from the new SMC method and the existing FMC method were compared. The SMC showed an improvement of 10 times in data acquisition time compared to the FMC, 16 times reduction of data volume and achieved comparable imaging quality with an improvement of signal-to-noise-ratio of 2dB compared the FMC. This finding meets the 2nd Objective of the EP/T012862/1 project. |
| Exploitation Route | The research described in this proposal will impact and benefit directly the UK and international lasers ultrasonics community and physical acoustics community: Remote, 3D, volumetric ultrasonic imaging using 2D laser phased arrays has never been attempted before. In addition, focusing and steering of ultrasonic waves generated/detected by lasers is done in post processing, in a simple experimental setup and fast enough for industrial applications is an ambitious attempt never realised before in such an extent as envisioned in this project. The effects will be transformative for the laser ultrasonics field and comparable to the impact that the ultrasonic phased arrays using conventional transducers have had for the ultrasonics field, increasing our imaging capabilities, quality and speed. The applications are by no means limited to process monitoring and extreme environments but can be readily applied to the majority of laser ultrasonics research areas including integrated and continuous structural health monitoring, non-destructive testing in places with restricted access, non-contact acoustic microscopy and medical imaging. This work will also develop instrumentation for in-line process monitoring and in-service inspection. These data will help understanding and controlling the additive manufacturing process, avoiding the development of defects and manipulating the final structure's properties. Such information, in the form of remote ultrasonic 3D imaging, can enable material scientists, as well as those performing NDT with a quantitative tool for making and evaluating structures that are otherwise impossible to test. These data will help understanding and controlling the additive manufacturing process, avoiding the development of defects and manipulating the final structure's properties. Such information, in the form of remote ultrasonic 3D imaging, can enable material scientists, as well as those performing NDT with a quantitative tool for making and evaluating structures that are otherwise impossible to test. A wider impact and benefit of the relevant academic community is expected in fields such as chemistry, biology and biomedical imaging where remote ultrasonic imaging is needed in sterilised or corrosive environments. |
| Sectors | Aerospace Defence and Marine Energy Healthcare Manufacturing including Industrial Biotechology Transport |
| URL | https://doi.org/10.1115/QNDE2021-74694 |
| Description | The findings from this award have been used to attract further funding from the industry. Up until today (March 2024) there has been further funding from the industry of the total of £155,100 (Sellafield, BAE Systems, Hitachi) with £77,300 of these funds going towards further research in the PI's team at the University of Strathclyde. This project's findings have also been used to raise follow on funding from UKRI in the form of: 1) a new, collaborative research project (EPSRC responsive mode), b) a Royce Institute Industrial Collaboration Partnership grant together with a new industrial partner (WAAM3D ltd). The results of this project have been used to initiate a new academic collaboration between Nottingham, Bristol and Strathclyde Universities. One paper with research findings has already been published (in Materials&Design) and another is under review (in Scientific Reports). The datasets from this research project have been shared with colleagues from Bristol University to support their research and are also available to the public as datasets. The researcher who was employed in this research has used its findings to support a successful grant with the UKAN+ and in collaboration with Sellafield. The PhD student who has been linked with this project has used the findings to support a successful application for the EPSRC funded doctoral prize which has allowed him to make first steps towards research independence. The PI has presented the results in several occasions where she has been invited to talk (EPRI workshop, UKAEA workshop) as means to engage with the industry and academia. |
| First Year Of Impact | 2023 |
| Sector | Energy,Manufacturing, including Industrial Biotechology |
| Impact Types | Economic |
| Description | Adaptive Laser Induced Phased Arrays (ALIPA) |
| Amount | £1,072,240 (GBP) |
| Funding ID | EP/V051814/1 |
| Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 11/2021 |
| End | 07/2024 |
| Description | EPSRC Doctoral Prize |
| Amount | £36,000 (GBP) |
| Funding ID | EP/T517938/1 |
| Organisation | University of Strathclyde |
| Sector | Academic/University |
| Country | United Kingdom |
| Start | 02/2023 |
| End | 01/2024 |
| Description | EPSRC Future Manufacturing Research Hubs - Research Feasibility Study Grant |
| Amount | £49,999 (GBP) |
| Funding ID | EP/P006930/1 |
| Organisation | University of Huddersfield |
| Sector | Academic/University |
| Country | United Kingdom |
| Start | 01/2022 |
| End | 07/2022 |
| Description | Royce Industrial Collaboration Programme |
| Amount | £123,308 (GBP) |
| Funding ID | ICP315 |
| Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 11/2023 |
| End | 03/2024 |
| Description | UKAN+ Funding Call 3 - Knowledge Transfer |
| Amount | £29,878 (GBP) |
| Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 03/2024 |
| End | 08/2024 |
| Title | Data for "Online evolution of a phased array by means of an adaptive data acquisition method" |
| Description | Supporting dataset for the publication: "Online evolution of a phased array by means of an adaptive data acquisition method". The file contains all the signals used to produce the images in the paper, using information mentioned in the paper, e.g. pitch and filter centre frequency. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2023 |
| Provided To Others? | Yes |
| Impact | No impacts to report yet. |
| URL | https://pureportal.strath.ac.uk/en/datasets/0950371c-0dc5-4eea-a7c9-007c135290a5 |
| Title | Data for: "Near-surface defect imaging in additively manufactured components by SAW suppression in laser induced phased array acquired data" |
| Description | Dataset for the publication: 'Near-surface defect imaging in additively manufactured components by SAW suppression in laser induced phased array acquired data'. The file contains all the signals and the signal and image processing parameters used to produce the images in the paper. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2023 |
| Provided To Others? | Yes |
| Impact | The database is used by the group in Strathclyde and the collaborating group in Bristol through the "Adaptive Laser Induced Phased Arrays" project. |
| URL | https://pureportal.strath.ac.uk/en/datasets/0cfd48c9-733d-4636-8f0a-b28bf48a34bd |
| Title | Remote Ultrasonic Imaging of a Wire Arc Additive Manufactured Ti-6Al-4V Component using Laser Induced Phased Array |
| Description | Supporting dataset for the publication: "Remote Ultrasonic Imaging of a Wire Arc Additive Manufactured Ti-6Al-4V Component using Laser Induced Phased Array".The file contains all the signals used to produce the images in the paper, using information mentioned in the paper, e.g. pitch and filter centre frequency. |
| Type Of Material | Database/Collection of data |
| Year Produced | 2021 |
| Provided To Others? | Yes |
| Impact | Data are used by the group in Strathclyde and the Bristol group who are collaborating in the "Adaptive Laser Induced Phased Arrays" project |
| URL | https://cord.cranfield.ac.uk/articles/dataset/Remote_Ultrasonic_Imaging_of_a_Wire_Arc_Additive_Manuf... |
| Description | Independent advisor for USES of novel Ultrasonic and Seismic Embedded Sensors for the non-destructive evaluation and structural health monitoring of critical infrastructure and human-built objects (HORIZON.1.2 - Marie Sklodowska-Curie Actions (MSCA) ) |
| Organisation | European Union |
| Country | European Union (EU) |
| Sector | Public |
| PI Contribution | I am a member of the Independent advisory board for USES of novel Ultrasonic and Seismic Embedded Sensors for the non-destructive evaluation and structural health monitoring of critical infrastructure and human-built objects (HORIZON.1.2 - Marie Sklodowska-Curie Actions (MSCA) ), which is a European Union programme for doctoral education and postdoctoral training. |
| Collaborator Contribution | All travel expenses are paid for meetings. Opportunity for networking with the international ultrasonics community. |
| Impact | This collaboration is multi-disciplinary bringing together physicists, mathematicians, engineers and geo-scientists. |
| Start Year | 2023 |
| Description | PhD co-supervision with UKAEA |
| Organisation | UK Atomic Energy Authority |
| Country | United Kingdom |
| Sector | Public |
| PI Contribution | Expertise and experimental results. |
| Collaborator Contribution | Time with experienced staff, specialised and characterised samples. |
| Impact | One accepted conference paper at the IEEE Symposium on Fusion Engineering (SOFE) 2023, to be presented in July 2023 One accepted conference paper at NDE in Nuclear 2023, to be presented in June 2023 |
| Start Year | 2023 |
| Description | WAAM3D partnership through the Royce Industrial Collaboration Programme |
| Organisation | WAAM3D Limited |
| Country | United Kingdom |
| Sector | Private |
| PI Contribution | The PI's team in Strathclyde have contributed expertise, facilities and equipment towards this collaboration. |
| Collaborator Contribution | WAAM3D have contributed the following to the PI's research team: 1. Active participation as an industrial partner, providing guidance on requirements/applications, communicating the project team's industrial/commercial robustness needs, and attending meetings (value £2k) 2. Provision of a one-year license, free of charge, for the WAAMPlanner software and WAAMCtrl software, used for path planning, online monitoring, and control of the WAAM process. We will also allocate software engineer time to modify the software for supporting the integration of NDT functions, if necessary (£8k) 3. Allocation of AM engineer time and technical support for WAAM deposition at Strathclyde, and the provision of WAAM samples from WAAM3D for testing (£3k) 4. Design study of laser safety requirement for commercial system (£2k) |
| Impact | 1. The designs and build a of robotic laser ultrasound systems for in process wire-based DED inspection of parts 2. A robotic laser ultrasound inspection system that can be integrated to a wire-based DED cell The collaboration is multi-disciplinary bringing together robotic experts, laser ultrasonic inspection leaders and an internationally innovative wire-based DED equipment manufacturer. |
| Start Year | 2024 |
| Description | EPRI: Workshop on Technologies for Advanced NDE at High Temperatures |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Industry/Business |
| Results and Impact | The workshop on high-temperature NDE was organised by the Electric Power Research Institute (EPRI, US) with the aim to present cutting edge technologies that can perform non destructive evaluation in extreme high temperatures (>300-800oC) for various applications with a focus at nuclear energy. There were 18 presentations in total and I was invited to be one of these 18 presentations. I presented our latest progress on remote, volumetric Laser Induced Phased Arrays. There were more than 100 participants from around the world, representing the industrial sectors of end users of NDE as well as equipment manufacturers. |
| Year(s) Of Engagement Activity | 2021 |
| Description | Laser ultrasonics for non-contact, in-process NDE during manufacturing in extreme environments |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Industry/Business |
| Results and Impact | Laser ultrasonics for non-contact, in-process NDE during manufacturing in extreme environments |
| Year(s) Of Engagement Activity | 2022 |
| Description | Showcase during the the Annual British Conference on Non-Destructive Testing |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Industry/Business |
| Results and Impact | Showcase and remote live demonstration of the laser ultrasonics system at the Showcase Day of the Annual British Conference on Non-Destructive Testing celebrating the 60th anniversary of conferences of the British Institute of NDT. 100 parrticipants from relevant industries, business and practitioners visited the demonstration and discussed the capabilities and limitations of the technique. |
| Year(s) Of Engagement Activity | 2023 |
| URL | https://www.bindt.org/events-and-awards/ndt-2023/showcase-day/ |
| Description | Technology Transfer Event at the UK Research Centre for Non Destructive Evaluation |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Industry/Business |
| Results and Impact | On line, remote demonstration of the remote ultrasonic volumetric imaging system using Laser Induced Phased Arrays. Around 100 participants from around the world from industrial sectors covering Aerospace, Oil and Gas, Energy, Manufacturing etc as well as organisations such as the British Institute of Non Destructive Testing. Other audience included PGR students and academics from 5 UK Universities. There has been followed up interest for industrial collaborations. |
| Year(s) Of Engagement Activity | 2021,2022,2023,2024 |
| URL | https://rcnde.ac.uk/jan_meetings_online/ |
| Description | UKAEA: Pipe Maintenance in Fusion - Online Workshop |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Industry/Business |
| Results and Impact | About 50-70 international organisations that are involved in national and international programs for commercialisation of nuclear fusion attended the online workshop related to non-destructive testing of pipes in nuclear fusion power plants. Participants came from all major countries that are actively developing nuclear fusion (e.g. UK, Germany, Japan, France (ITER) etc). Our current developments on pipe inspection were presented and discussed regarding the potential for implementation. These talks have led to current discussion for a research project with the UKAEA. |
| Year(s) Of Engagement Activity | 2023 |