Intelligent engineering coatings for in-manufacture and in-service monitoring of critical safety products (CoatIN)
Lead Research Organisation:
University of Manchester
Department Name: Materials
Abstract
Coatings are key to the performance of most manufactured products and they contribute to sustainability by enhancing the efficiency and extending the life of the products that they protect, as well as by enabling the reduced use of scarce bulk materials. Coatings are a vital part of the nation's manufacturing industry, contributing to many sectors, including aerospace, energy, automotive, construction and healthcare. However, until now the UK coatings industry has been lagging behind compared to High Value Manufacturing sectors in terms of design, development, manufacture, and implementation into products, particularly in terms of the degree of digitalisation achieved.
This project will develop intelligent coatings with new functionalities that can self-monitor during manufacture and in-service. The multidisciplinary team will use a suite of modelling tools, sensing technologies and experimental deposition and characterisation facilities at The University of Manchester, the University of Sheffield, Cranfield University, Queen's University Belfast and Swansea University to embed new sensor functionalities within coatings, using a variety of deposition processes.
This EPSRC Exploratory Stream project will be a key step to address the challenges of digitalisation in the UK coatings manufacturing sector. The proposed research will assist UK PLC to develop manufacturing methods which are predictable, digital-enabled and more productive, providing a pathway to world-leading coating manufacturing processes. The research will support the coatings manufacturing industry to achieve best-in-class levels of High Value Manufacturing.
This project will develop intelligent coatings with new functionalities that can self-monitor during manufacture and in-service. The multidisciplinary team will use a suite of modelling tools, sensing technologies and experimental deposition and characterisation facilities at The University of Manchester, the University of Sheffield, Cranfield University, Queen's University Belfast and Swansea University to embed new sensor functionalities within coatings, using a variety of deposition processes.
This EPSRC Exploratory Stream project will be a key step to address the challenges of digitalisation in the UK coatings manufacturing sector. The proposed research will assist UK PLC to develop manufacturing methods which are predictable, digital-enabled and more productive, providing a pathway to world-leading coating manufacturing processes. The research will support the coatings manufacturing industry to achieve best-in-class levels of High Value Manufacturing.
Planned Impact
Recent studies (such as the one by the industry-led Special Interest Group in Surface Engineering and Advanced Coatings) have demonstrated that the UK coatings market is worth about £11 billion annually. Moreover, coatings are vital to over £150bn of products made in the UK each year, and these products drive manufacturing turnovers greater than £380bn in UK companies. Nevertheless, the coatings sector in the UK lags behind other manufacturing process technology sectors, particularly with regard to the level of digitalisation achieved. Such digitalisation capability is needed for coatings to achieve their full potential to add value to products and to contribute optimally to sustainability objectives, given the critical role which coatings can play in conserving energy and materials resources.
This proposal will challenge the traditional mode of coating manufacture by extending the application of coatings beyond a simple protective layer to a functional sensing element, with a capability to monitor and regulate the coating growth process as well as, using the same sensing method, measure the functional performance of the component in-service. This project will establish a new way of thinking that will transform the way coatings are seen in the life-cycle of an engineering component. Establishing coatings as sensing elements that allow not only monitoring and gathering of the deposition process data but also continue to function in-service as an integrated, full life-cycle, cyber-physical devices is a step-change in transformational digital manufacturing and connectivity of safety critical engineering components. This proposal will address the critical need to eliminate waste in coating manufacturing, which accounts for significant productivity losses in UK businesses, and increases costs and lead times of engineering components.
This project will provide the vital first step in the journey towards digital transformation of the UK coatings industry, which will result in improved manufacturing quality, productivity, efficiency and sustainability. Through digitalisation, the coatings industry sector will be able to faster develop novel coatings with improved performance and functionalities directed by end-user needs. Since coatings are critical to the performance of most products, the impact of this project will expand to many sectors in UK industry, ranging from aerospace and automotive to healthcare and food & drink. This project addresses the outcomes of the recent "Made Smarter" review, which estimated that adoption of digitalistion throughout UK industry could add up to £455 billion for UK manufacturing over the next decade, by increasing manufacturing sector growth between 1.5% and 3% per annum. The successful implementation of digitalisation technologies in the UK coatings industry will contribute to making the UK a global leader in industrial digitalisation in the coatings sector.
This proposal will challenge the traditional mode of coating manufacture by extending the application of coatings beyond a simple protective layer to a functional sensing element, with a capability to monitor and regulate the coating growth process as well as, using the same sensing method, measure the functional performance of the component in-service. This project will establish a new way of thinking that will transform the way coatings are seen in the life-cycle of an engineering component. Establishing coatings as sensing elements that allow not only monitoring and gathering of the deposition process data but also continue to function in-service as an integrated, full life-cycle, cyber-physical devices is a step-change in transformational digital manufacturing and connectivity of safety critical engineering components. This proposal will address the critical need to eliminate waste in coating manufacturing, which accounts for significant productivity losses in UK businesses, and increases costs and lead times of engineering components.
This project will provide the vital first step in the journey towards digital transformation of the UK coatings industry, which will result in improved manufacturing quality, productivity, efficiency and sustainability. Through digitalisation, the coatings industry sector will be able to faster develop novel coatings with improved performance and functionalities directed by end-user needs. Since coatings are critical to the performance of most products, the impact of this project will expand to many sectors in UK industry, ranging from aerospace and automotive to healthcare and food & drink. This project addresses the outcomes of the recent "Made Smarter" review, which estimated that adoption of digitalistion throughout UK industry could add up to £455 billion for UK manufacturing over the next decade, by increasing manufacturing sector growth between 1.5% and 3% per annum. The successful implementation of digitalisation technologies in the UK coatings industry will contribute to making the UK a global leader in industrial digitalisation in the coatings sector.
Organisations
- University of Manchester (Lead Research Organisation)
- TRL9 Limited (Project Partner)
- Excelitas Technologies (United Kingdom) (Project Partner)
- Castolin Eutectic (United Kingdom) (Project Partner)
- Micro Materials (United Kingdom) (Project Partner)
- GE Power (Project Partner)
- Manufacturing Technology Centre (United Kingdom) (Project Partner)
- Atomic Weapons Establishment (Project Partner)
- M-Solv (United Kingdom) (Project Partner)
Publications
Goel G
(2021)
A bibliometric study on biomimetic and bioinspired membranes for water filtration
in npj Clean Water
Parris G
(2022)
A critical review of the developments in molecular dynamics simulations to study femtosecond laser ablation
in Materials Today: Proceedings
Venkatachalapathy V
(2023)
A Guiding Framework for Process Parameter Optimisation of Thermal Spraying
in Coatings
Mondal B
(2023)
A resistance-driven H 2 gas sensor: high-entropy alloy nanoparticles decorated 2D MoS 2
in Nanoscale
Sánchez-Arriaga N
(2023)
A Spectroscopic Reflectance-Based Low-Cost Thickness Measurement System for Thin Films: Development and Testing
in Sensors
Hakim Khalili M
(2023)
Additive Manufacturing and Physicomechanical Characteristics of PEGDA Hydrogels: Recent Advances and Perspective for Tissue Engineering
in Polymers
Yin J
(2021)
An analytical model to predict the depth of sub-surface damage for grinding of brittle materials
in CIRP Journal of Manufacturing Science and Technology
Sheoran K
(2023)
An Aniline-Complexed Bismuth Tungstate Nanocomposite Anchored on Carbon Black as an Electrode Material for Supercapacitor Applications
in ChemistrySelect
Rogov A
(2022)
Analysis of electrical response, gas evolution and coating morphology during transition to soft sparking PEO of Al
in Surface and Coatings Technology
Fan P
(2024)
Anisotropic plasticity mechanisms in a newly synthesised high entropy alloy investigated using atomic simulations and nanoindentation experiments
in Journal of Alloys and Compounds
Faisal N
(2022)
Application of Thermal Spray Coatings in Electrolysers for Hydrogen Production: Advances, Challenges, and Opportunities
in ChemNanoMat
Oyekan J
(2020)
Applying a 6 DoF Robotic Arm and Digital Twin to Automate Fan-Blade Reconditioning for Aerospace Maintenance, Repair, and Overhaul.
in Sensors (Basel, Switzerland)
Fan P
(2021)
Atomic-Scale Friction Studies on Single-Crystal Gallium Arsenide Using Atomic Force Microscope and Molecular Dynamics Simulation
in Nanomanufacturing and Metrology
Larrañaga-Altuna M
(2021)
Bactericidal surfaces: An emerging 21st-century ultra-precision manufacturing and materials puzzle
in Applied Physics Reviews
Verma J
(2024)
Cellulose based materials to accelerate the transition towards sustainability
in Industrial Crops and Products
Rana A
(2023)
Cellulose-based materials for air purification: A review
in Industrial Crops and Products
Mir A
(2022)
Challenges and issues in continuum modelling of tribology, wear, cutting and other processes involving high-strain rate plastic deformation of metals
in Journal of the Mechanical Behavior of Biomedical Materials
Khaitan A
(2023)
Characterization of quenched MD simulated porous carbon electrodes for supercapacitors
in Materials Today: Proceedings
Ates B
(2020)
Chemistry, Structures, and Advanced Applications of Nanocomposites from Biorenewable Resources.
in Chemical reviews
Chen WL
(2022)
Clay Swelling: Role of Cations in Stabilizing/Destabilizing Mechanisms.
in ACS omega
Kumar Mishra R
(2021)
Computational prediction of electrical and thermal properties of graphene and BaTiO3 reinforced epoxy nanocomposites
in Biomaterials and Polymers Horizon
Hawi S
(2022)
Critical Review of Nanopillar-Based Mechanobactericidal Systems
in ACS Applied Nano Materials
Sood A
(2023)
Curcumin-loaded alginate hydrogels for cancer therapy and wound healing applications: A review
in International Journal of Biological Macromolecules
Bishnoi P
(2024)
Direct Ethanol Fuel Cell for Clean Electric Energy: Unravelling the Role of Electrode Materials for a Sustainable Future
in Advanced Energy and Sustainability Research
Title | Nature inspired materials: Emerging trends and future prospects |
Description | Nature inspired materials images |
Type Of Art | Film/Video/Animation |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Nature_inspired_materials_Emerging_trends_and_future_pr... |
Title | Nature inspired materials: Emerging trends and future prospects |
Description | Nature inspired materials images |
Type Of Art | Film/Video/Animation |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Nature_inspired_materials_Emerging_trends_and_future_pr... |
Title | Nature inspired materials: Emerging trends and future prospects |
Description | Nature inspired materials images |
Type Of Art | Film/Video/Animation |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Nature_inspired_materials_Emerging_trends_and_future_pr... |
Description | 1. Thermal spray monitoring systems developed. - LSBU 2. Digital Twins developed for plasma electrolytic processes. - The University of Manchester |
Exploitation Route | Ongoing work |
Sectors | Digital/Communication/Information Technologies (including Software) Energy Manufacturing including Industrial Biotechology Retail |
Description | These are early days however, we do anticipate important transfer of systems developed to industry. |
First Year Of Impact | 2023 |
Sector | Digital/Communication/Information Technologies (including Software),Manufacturing, including Industrial Biotechology |
Impact Types | Economic |
Title | Dataset: A Spectroscopic Reflectance-Based Low-Cost Thickness Measurement System for Thin Films: Development and Testing |
Description | This data repository contains the following information related to the Article: "A Spectroscopic Reflectance-Based Low-Cost Thickness Measurement System for Thin Films: Development and Testing" File 1: RMSE and MSE calculation for SENSOR1 File 2: RMSE and MSE calculation for SENSOR2 File 3: RMSE and MSE calculation for SENSOR2 using HAL/DEUT light source File 4: Interference Interval Method Calculation and Reflectance Curve Modelling |
Type Of Material | Database/Collection of data |
Year Produced | 2023 |
Provided To Others? | Yes |
URL | https://figshare.shef.ac.uk/articles/dataset/_strong_Dataset_A_Spectroscopic_Reflectance-Based_Low-C... |
Title | Data supporting the publication 'Clay swelling: role of cations in stabilizing/destabilizing mechanisms' |
Description | In the compressed dataset, there are two subdirectories, one in the name of 'Example' and another 'PostprocessData'. The Example directory contains input files, output data and postprocessed data for case Na12 starting at a d-space of onelayer value, where files starts with in.* are input files for lammps software, files ending with .dat or .lmptrj are output files from lammps, and files ending with .mat are matlab processed data. The 'postporcessedata' contains matlab processed results for all simulations in this study, contains simulation for NaMMT, KMMT, CaMMT and NaBD starting at onelayer, twolayer and threelayer d-space values. |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Data_supporting_the_publication_Clay_swelling_role_of_... |
Title | Data supporting: 'Mechanical Behavior of 3D Printed Poly(ethylene glycol) Diacrylate Hydrogels in Hydrated Conditions Investigated Using Atomic Force Microscopy' |
Description | 1. File AFM-Lines: Raw files for all force-distance curves along with excel file summarizing all the indentions on a single line taken at different height on the surface of the hydrogel. 2. File AFM-Maps: Raw files for all force-distance curves along with excel file summarizing all the indentation maps taken at the middle section on the surface of the hydrogel. |
Type Of Material | Database/Collection of data |
Year Produced | 2023 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Data_supporting_Mechanical_Behavior_of_3D_Printed_Poly... |
Title | Data supporting: 'Nanoindentation Response of 3D Printed PEGDA Hydrogels in a Hydrated Environment' |
Description | Raw and processed data sets from nanoidentation response of 3D printed hydrogels. 1. Raw data of nanoindentation response. 2. Representative load-displacement curves for each type of hydrogel. 3. Representative data for creep for different types of hydrogels. 4. Representative data for NMR spectras of different types of hydrogels. 5. Representative data for glass transition of different types of hydrogels. |
Type Of Material | Database/Collection of data |
Year Produced | 2023 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Nanoindentation_Response_of_3D_Printed_PEGDA_Hydrogels... |
Title | Thermal response of multi-layer UV crosslinked PEGDA hydrogels |
Description | All data sets are raw data from thermoresponse behaviour of hydrogels. 1. Swelling test for multi-150 um hydrogels with 1.8 mg/ml of photoabsorber.2. Swelling test for mono-5 mm hydrogels with 0 mg/ml of photoabsorber.3. Swelling test for multi-20 um hydrogels with 9 mg/ml of photoabsorber.4. Swelling test for mono-3 mm and mono-1.5 mm hydrogels with 0 mg/ml of photoabsorber.5. Cyclic test for multi-150 um hydrogels.6. Dried weight and solid residue weight of all hydrogels samples7. EWC, NWF, NVF-summary for all hydrogel samples8. DSC-TG-Thermogram-All sample types |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Thermal_response_of_multi-layer_UV_crosslinked_PEGDA_h... |