{"paper_id":"4754b980-e772-4d2e-8be3-96ebebbd1ca8","body_text":"Erosion Mapping of Coated Composites: Simulating Conditions for Tidal Turbines Blades | Research Square window.SnipcartSettings = { analytics: { enabled: false } }; (function() { var accessVector = localStorage.getItem('access_vector') || ''; window.dataLayer = window.dataLayer || []; if (accessVector) { window.dataLayer.push({ user: { profile: { profileInfo: { snid: accessVector } } } }); } })(); (function(w,d,s,l,i){w[l]=w[l]||[];w[l].push({'gtm.start':new Date().getTime(),event:'gtm.js'});var f=d.getElementsByTagName(s)[0],j=d.createElement(s),dl=l!='dataLayer'?'&l='+l:'';j.async=true;j.src='https://www.googletagmanager.com/gtm.js?id='+i+dl;f.parentNode.insertBefore(j,f);})(window,document,'script','dataLayer','GTM-K279D39R'); Browse Preprints In Review Journals COVID-19 Preprints AJE Video Bytes Research Tools Research Promotion AJE Professional Editing AJE Rubriq About Preprint Platform In Review Editorial Policies Our Team Advisory Board Help Center Sign In Submit a Preprint Cite Share Download PDF Research Article Erosion Mapping of Coated Composites: Simulating Conditions for Tidal Turbines Blades Emadelddin Hassan, Margaret M Stack This is a preprint; it has not been peer reviewed by a journal. https://doi.org/ 10.21203/rs.3.rs-4888255/v1 This work is licensed under a CC BY 4.0 License Status: Published Journal Publication published 07 Jan, 2025 Read the published version in Journal of Bio- and Tribo-Corrosion → Version 1 posted 8 You are reading this latest preprint version Abstract The tribological mechanisms of potential composite materials that could be used in tidal turbines considered the effects of various erosion parameters on the degradation modes, both with and without particles, in still and seawater conditions. The aim of this study was to investigate the potential of a specialised epoxy erosion-resistant coating for glass fibre-reinforced plastic (GFRP) in resisting the impact of slurry erosion. Slurry erosion is a process by which solid particles suspended in a fluid medium impinge on a surface, causing material loss due to repeated impacts. The coating efficacy was evaluated through a series of tests, including three different speeds and six different impinging angles and the results were used to generate tidal turbine maps. The study provided insights into the durability and of the epoxy and potential use of the coating in tidal turbine blade industries where resistance to erosion is crucial for long-term performance and safety. Figures Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 Introduction Surface coatings have significant potential to reduce wear and erosion (1). In studies of erosion in marine renewable energy systems, such as tidal turbine blades, there have been some recent studies on blade durability in laboratory simulated erosion conditions using a range of experimental protocols (2-7). In these experimental conditions, important parameters such as impact angle, velocity (relating to thrust loading) and particle concentration at the surface interface can be evaluated. Such research are important as tidal energy is increasingly viewed as an important energy resource in the renewable energy spectrum (2,7). However, the high-water densities encountered in blade impact test the current materials and surface engineering approaches. Understanding the mechanics of failure will provide new insights into materials selection in such conditions. Very few studies in recent years have concentrated on erosion resistance in the presence of surface coatings. Such surface engineering approaches are key to extending longevity of the turbine blades. Tailoring the coatings to the environment is the route to preventing failure at interfaces in the material. In this study, a coating was applied to a standard GRP composite and tested in simulated tidal erosion conditions over a spectrum of impact angles and velocities. The results have indicated a very significant difference in erosion mechanism with impact angle. Microscopy and erosion maps were used to identify modes of erosion and mechanisms of degradation. Materials and Methodologies Materials The materials used in this study include FR4-G10 GRP, which serves as the base for the erosion-resistant coating being evaluated. These materials were selected for their unique properties and suitability for the intended purpose of the study. Technical specifications for each of these materials are provided in Table (1), which includes information on their mechanical, thermal, and water absorption properties. To ensure consistent and accurate testing, the materials were prepared by cutting sheets of plate arranged in a specific size of 36mm by 25mm and 3mm thickness. The sheets were cut to fit into the Jet rig specimen holder which is used to direct the slurry at the coated samples. The uniformity and precision of the sample size and arrangement ensure that the results of the tests are reliable and repeatable. The FR4-G10 GRP materials as a base for the coating is based on their durability, strength, and erosion resistance, which are essential properties for withstanding the impact of slurry erosion. Overall, the use of these materials in the study ensures that the results obtained are applicable to real-world scenarios and can provide insights into the efficacy of the epoxy erosion-resistant coating for protecting materials from slurry erosion in various industries. Table 1 Technical Specifications of FR4-G10 GRP Technical Data Units Test Method Values Colour NA NA Light Green Specific Gravity g/cm³ ISO 1183 1.95 Water Absorption mg ISO 62 5.5 Flexural Strength MPa ISO 178 500 Tensile Strength MPa ISO 527 450 (table location before coating composition) Coating Composition Belzona 2141 is a high-performance, erosion-resistance polymeric coating manufactured by Belzona International Ltd, which was selected for testing in this study due to its mechanical properties and high erosion resistance as described in table 2. To apply the Belzona 2141 coating to the FR4-G10 GRP samples, the surface of the samples was first prepared using 80-grit sandpaper, which helps to ensure good adhesion between the coating and the composite material. The Belzona 2911 activator was then mixed with the Belzona 2141 coating to achieve the required polymeric coating. This mixture was carefully prepared according to the manufacturer's instructions to ensure the correct ratio of components and consistency of the coating [1]. Once the samples were prepared and the coating mixture was ready, the coating was applied as a one-coat system by brush [1], [2] to achieve the desired thickness. The coating application process was carried out under the supervision of Belzona representatives to ensure that it was performed correctly and according to the manufacturer's guidelines [1]. After application, the coated samples were left to dry for 24 hours in ambient temperature conditions to allow the coating to cure and reach its full mechanical properties. The coating thickness was measured to ensure that the average thickness of 0.8mm was achieved for all samples. The application process for the Belzona 2141 coating involved careful preparation and application to ensure that the coating was evenly applied and had the required thickness and mechanical properties. The use of this high-performance coating in the study provides valuable insights into its effectiveness in protecting composite materials from slurry erosion in various industrial applications. Table 2 Coating specifications Properties Unit Color Green Hardness ASTM typical value 87 Heat resistance 40 ֯ C Tensile strength ASTM D412 15.2 MPa Tear strength ASTM D624 380 pli Density 1.1 g/cm3 Water absorption nil Impingement Rig Test Set-Up The experimental setup features a custom-designed slurry jet rig as shown in Fig 1, constructed following the guidelines of Hutchings [3]. It consists of a polypropylene conical trapper for efficient sand recirculation, a T-shaped nozzle for slurry generation, and propellers driven by electric motors to ensure uniform mixing and circulation of the slurry. The rig's configuration allows for precise adjustment of parameters such as slurry flow velocity and impingement angle, while operational guidelines dictate a maximum testing duration of 30 minutes to prevent pump overheating. Test Conditions The erosive characteristics were assessed through the examination of mass reduction utilizing an analytical balance with a precision of +/-0.01mg, coupled with a surface analysis conducted using a Scanning Electron Microscope (SEM). Table 3 Test Parameters Parameter Values Impact Angles 15°, 30°, 45°, 60°, 75°, 90° Impact Velocities 6.25 m/s, 8.42 m/s, 10.16 m/s Test Duration 30 minutes per sample Sand Concentration 3% Salinity 3.5% Sand Particle Size 300-600 µm Test Temperature Room temperature Table 4 Nozzles vs Velocities Nozzle Inlet Dia (mm) test Velocity (m/s) 2 6.25 2.5 8.42 3 10.16 The velocities used in the test were regulated by the inlet nozzle diameter, as specified in Table 4. The rig was calibrated to ensure that the desired velocities were achieved. This was carried out by first measuring the volume of water in the rig, and then using a timer to record the elapsed time and final volume of water in a separate container. By subtracting the initial volume from the final volume of water that flowed through the container, this determined the volume of water that passed through the rig. The final step involved using the formula below to calculate the velocity of the water flow. where is 'v' is the velocity, 'Q' is the flow rate and 'A' is a cross-sectional area of the flow path. By dividing the flow rate by the flow path's cross-sectional area, the velocity of the water flow was determined. To increase the accuracy of the results, the steps above were repeated three times. This calibration and measurement process allowed to obtain precise data on the velocity of water flow in the Jet rig. Results and Discussion Results The erosion of the coating material was significantly influenced by the impact angle and water flow velocity, according to Fig. 2 it was noted that the coating experienced higher mass loss at impact angles of 60֯ and 90֯, regardless of the velocity. This suggests that these angles are more critical for the durability of the coating and should be considered in the design and operation of turbines. Additionally, the results showed that lower velocities of 6.25 m/s caused less damage to the coating material than the higher velocities of 8.42 m/s and 10.16 m/s. This suggests that a element in the erosion of the coating material is velocity. Moreover, it was noticed that at an impact angle of 45֯, the coating experienced mass loss at velocities of 8.42 m/s and 10.16 m/s. The results of this experiment could have significant implications for the design and operation of tidal turbines. Erosion of the coating material can lead to reduced efficiency and a shorter lifespan of the turbines [4]. Effect of Velocities and Impact Angle on Coating The performance of the tidal turbine relies on the rotor blade, which is a critical component for extracting kinetic energy from the tide stream [5]. The blade is similar in concept to a wind turbine blade, but its design and reliability assessment cannot be based on those of the wind turbine due to differences in seawater density and other factors [2]. However, the efficiency and reliability of the blades are key indicators for a tidal current turbine[6]. The tribological issue, such as leading-edge erosion due to sand particles' impact, cavitation erosion, and the combined effects of seawater and solid particles, can compromise the performance and reliability of the rotor blade [2], [7]. Researchers have investigated the erosion of the rotor blade caused by the impact of erodent under marine simulated conditions, i.e., saltwater plus sand particles, but ignored erosion due to cavitation [2], [8]. [9] also notes that the use of thermoplastic composite blades in a large-scale tidal power turbine is a potential game-changer for the marine energy industry, improving performance and sustainability, while also making the manufacturing process faster and more energy efficient. The impact angle and velocity can significantly affect the erosion of polymeric coatings applied to tidal turbine blades [10], [11]. The erosion losses were evaluated at various impingement angles (15°-90°) and with the change of impact velocity 6.25 m/s, 8.42 m/s and 10.16 m/s, which reflects typical velocities experienced at the leading edge of the blade [11]. The polymeric coating acts as a barrier between the substrate and NaCl solution, slowing the ingress of moisture in composite materials [2]. The impact frequency can affect the ability of a coating to absorb and distribute the energy from an impact [12], which is typically taken into account in current blade coating systems. The results indicate that the impact angle and velocity have a significant effect on the erosion of the samples [13]. At all velocities, the coating experienced higher mass loss at 60֯ and 90֯ impact angles. This can be attributed to the fact that at these angles, the impact energy is concentrated on a smaller area, leading to a higher erosion rate. At 6.25 m/s, the coating experienced a lower mass loss compared to 8.42 m/s and 10.16 m/s, indicating that lower velocity leads to a lower erosion rate. However, at higher velocities of 8.42 m/s and 10.16 m/s, the coating experienced higher mass loss, indicating that higher velocity leads to a higher erosion rate. At 45֯ impact angle, the coating experienced mass loss at velocities 8.42 m/s and 10.16 m/s, indicating that at this angle, higher velocities lead to a higher erosion rate. These results highlight the importance of considering impact angle and velocity when studying erosion and can be useful in designing coatings or materials that are more resistant to erosion [14] Moreover, the coating material's ability to absorb and distribute the energy from an impact can also vary [12]. This further emphasises the importance of selecting the appropriate coating material and application process that can withstand the impact and erosion caused by the water flow. Overall, it is crucial to consider various factors, such as impact angle, velocity, and coating material properties [15], [16], when designing and operating tidal turbines to ensure the longevity and efficiency of the system. SEM Analysis (to be followed by Fig 3) A focused beam of high-energy electrons is used in a scanning electron microscope (SEM) to image the topography and learn about the material composition of conductive specimens. [17]. The SEM consists of an electron gun, a system of magnetic lenses, a scan control, and a detector, which work together to focus the electron beam on the sample and generate high-resolution images of its surface [17]. SEM was used to analyse the surface of an FR4-GRP coated with Belzona 2141. Fig. 3 of the SEM provided evidence of salt deposition on the coating surface, which occurred at an impact angle of 15 and 6.25 m/s velocity. The combination of the SEM image and the observation of an increase in mass in Fig. 30 provide strong evidence that the impact of the erodent caused salt deposition on the surface of the coating. This finding is important because it can have implications for the performance of the coating in tidal turbine operation, as salt deposition can have detrimental effects on the integrity and durability of coatings [10]. Fig. 4 shows the results of an erosion test on a coating surface, specifically at a 75 ֯ angle and a velocity of 8.42 m/s. Fig.4 indicates that this impact caused significant damage to the coating, as evidenced by the presence of voids, cavities, and loose debris scattered around the eroded surface. The specific impact angle of 75 ֯ and a velocity of 8.42 m/s are significant because they provide information about the strength and durability of the coating. The voids and cavities in the fig 4 indicate that the impact caused the coating material to fracture and break apart. This type of damage can weaken the structural integrity of the coating and may compromise its ability to provide protection to the underlying material or surface [18]. The loose debris from sand and broken fibres scattered around the impact site suggests that the force of the impact was strong enough to dislodge and scatter coating material beyond the immediate vicinity. Fig 5 confirms the presence of loose debris and coating erosion due to deformation and cutting action at a higher impact velocity of 10.16 m/s and an impact angle of 90 ֯ . The figure also confirms the ductile cutting in the coating at these test conditions [19]. The presence of loose debris indicates that the impact caused some material to be dislodged or broken apart, similar to what was observed in Fig. 5. The confirmation of loose debris and coating erosion at higher impact conditions suggests that the coating may not be able to withstand high-speed impacts at these conditions. The presence of ductile cutting in the coating further confirms that the coating is a ductile material, as was observed in Fig. 6 at lower impact conditions [20]. The combination of loose debris, coating erosion, and ductile cutting observed in Fig. 32 provides evidence of the extent of damage caused by the impact at these higher impact conditions. The deformation and cutting action caused significant damage to the coating, resulting in the removal of material and the formation of loose debris. The confirmation of ductile cutting at higher impact conditions is significant because it suggests that the coating may undergo significant plastic deformation before fracturing [21]. This information is important for understanding the behaviour of the coating under high-speed impact conditions and for determining the potential applications of the coating in environments with high-speed impacts. Fig. 6 shows that at an impact angle of 75 ֯ and a velocity of 10.16 m/s, the coated surface suffered from pit propagation due to the impact of the erodent. The figure also shows the presence of loose debris and ductile cutting. The observation of pit propagation is significant because it suggests that the impact caused the coating to undergo significant material removal in the form of pits. The presence of loose debris and ductile cutting further confirms that the impact caused damage to the coating surface [2], [21]. The combination of pit propagation, loose debris, and ductile cutting observed in Fig 6 provides evidence of the extent of damage caused by the impact under these conditions. The deformation and cutting action caused significant damage to the coating, resulting in the formation of pits and the removal of material, which formed loose debris. The observation of ductile cutting in Fig. 6 is consistent with the observation in Fig. 5, which suggests that the coating is a ductile material. This information is important for understanding the behaviour of the coating under high-speed impact conditions and for determining the potential applications of the coating in environments with high-velocity impacts [22]. Erosion Mapping of Surface Coating To visualise damage, erosion maps were created as an alternative method. These maps were constructed using the procedures outlined by [23]. The aim of the study was to produce erosion maps and patterns in coated samples using a developed code written in MATLAB. This map allowed for the analysis and assessment of the coating erosion process, giving valuable insights into material behaviour under different conditions. Utilising the maps can aid in comprehending erosion mechanisms in coating and composite materials, which can assist design engineers in forecasting safety levels during operation and lead to the creation of a more sturdy and long-lasting coating for tidal turbine blades [24]. The erosion map provides a graphical representation of the level of material loss experienced by the coating under different impact velocities and angles [25]. The map in fig. 7 indicates that the coating is most resistant to erosion when tested at impact angles of 15 ֯ , 30 ֯ , 45 ֯ , and 75 ֯ and velocities of 6.25 m/s, 8.42 m/s and 10.16 m/s, suggesting that the coating's design is most effective at deflecting the force of the impacting particles when it is applied at these angles. In contrast, the coating experiences higher levels of erosion when tested at impact angles of 60 ֯ and 90 ֯ and velocities of 6.25 m/s, 8.42 m/s and 10.16 m/s, indicating that the design may not be as effective at deflecting the force of particles at these angles. This suggests that design modifications may be necessary to enhance the coating's performance under these impact conditions[26]. Fig 7 revealed that the coating performed best at a velocity of 6.25 m/s compared to velocities of 8.42 m/s and 10.16 m/s. This data can be used to optimise the design of the tidal turbine blades to reduce the impact of ocean currents and tides, potentially reducing erosion and improving the durability of the coating. Overall, the erosion map provides valuable insights into the behaviour of the coating under different impact conditions [27]. By analysing the map, design engineers can determine the optimal impact angles and velocities for the coating, enabling them to optimise the design of the tidal turbine blades for increased durability and longevity. The map's findings can be used to enhance the efficiency and sustainability of harnessing the power of ocean currents and tides through tidal turbines[28]. Declarations Competing interests There are no competing interests. Ethical Approval Not applicable Funding: The authors would like to acknowledge the support of the Interreg (Northern Ireland—Ireland—Scotland) Special EU Programmes Grant No SPIRE2_INT–VA–049 “Storage Platform for the Integration of Renewable Energy (SPIRE 2)”. Availability of data and materials : Not available Conclusions The study aimed to address the erosion challenges of the coating material used in tidal turbine blades. The study also emphasised the importance of using erosion maps to visualise and analyse the level of material loss under different impact condition. The erosion map produced in the study provides valuable insights into the behaviour of the coating and can be used to optimise the design of tidal turbine blades for increased durability and longevity [7]. The highest erosion was observed at 75 ֯ and 90 ֯ impact angles at all impact velocities. The erosion maps displayed the level of material loss experienced by the coating under different impact conditions, providing valuable insights for the design of tidal turbine blades. References Belzona, “https://www.belzona.com/en/products/2000/2141.aspx.” G. Rasool and M. M. Stack, “Some Views on the Mapping of Erosion of Coated Composites In Tidal Turbine Simulated Conditions,” Tribology Transactions , vol. 62, no. 3, pp. 512–523, 2019, doi: 10.1080/10402004.2019.1581313. J. B. Zu, I. M. Hutchings, and G. T. Burstein, “Design of a slurry erosion test rig,” Wear , vol. 140, no. 2, pp. 331–344, Nov. 1990, doi: 10.1016/0043-1648(90)90093-P. L. X. Cai, Y. Li, S. Sen Wang, Y. He, F. Li, and Z. K. Liu, “Investigation of the erosion damage mechanism and erosion prediction of boronized coatings at elevated temperatures,” Materials , vol. 14, no. 1, pp. 1–18, Jan. 2021, doi: 10.3390/ma14010123. S. Roshanmanesh, F. Hayati, and M. 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Cite Share Download PDF Status: Published Journal Publication published 07 Jan, 2025 Read the published version in Journal of Bio- and Tribo-Corrosion → Version 1 posted Editorial decision: Revision requested 25 Dec, 2024 Reviews received at journal 25 Dec, 2024 Reviewers agreed at journal 19 Dec, 2024 Reviewers agreed at journal 21 Aug, 2024 Reviewers invited by journal 19 Aug, 2024 Editor assigned by journal 14 Aug, 2024 Submission checks completed at journal 14 Aug, 2024 First submitted to journal 09 Aug, 2024 You are reading this latest preprint version Research Square lets you share your work early, gain feedback from the community, and start making changes to your manuscript prior to peer review in a journal. As a division of Research Square Company, we’re committed to making research communication faster, fairer, and more useful. We do this by developing innovative software and high quality services for the global research community. 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Also discoverable on Platform About Our Team In Review Editorial Policies Advisory Board Help Center Resources Author Services Accessibility API Access RSS feed Manage Cookie Preferences © Research Square 2026 | ISSN 2693-5015 (online) Privacy Policy Terms of Service Do Not Sell My Personal Information {\"props\":{\"pageProps\":{\"initialData\":{\"identity\":\"rs-4888255\",\"acceptedTermsAndConditions\":true,\"allowDirectSubmit\":false,\"archivedVersions\":[],\"articleType\":\"Research Article\",\"associatedPublications\":[],\"authors\":[{\"id\":346612828,\"identity\":\"b04ab377-fd14-4cb4-95db-0f20ee0cb5aa\",\"order_by\":0,\"name\":\"Emadelddin Hassan\",\"email\":\"data:image/png;base64,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\",\"orcid\":\"\",\"institution\":\"University of Strathclyde\",\"correspondingAuthor\":true,\"prefix\":\"\",\"firstName\":\"Emadelddin\",\"middleName\":\"\",\"lastName\":\"Hassan\",\"suffix\":\"\"},{\"id\":346612829,\"identity\":\"4f2c7aa6-8c51-4605-b2b6-1be45a3bf6fb\",\"order_by\":1,\"name\":\"Margaret M Stack\",\"email\":\"\",\"orcid\":\"\",\"institution\":\"University of 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Set-Up\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"1.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/17b9911d2c2116f1db186171.png\"},{\"id\":64374541,\"identity\":\"0362376b-7d3a-46c0-9423-455a83984ab0\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 10:03:28\",\"extension\":\"png\",\"order_by\":2,\"title\":\"Figure 2\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":14543,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eMass Difference of Coated samples at 6.25m/s, 8.42m/s and 10.16m/s\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"2.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/ca19c10d696761e5100c8466.png\"},{\"id\":64373361,\"identity\":\"083305ed-1253-439f-a035-01dd90407387\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 09:47:29\",\"extension\":\"png\",\"order_by\":3,\"title\":\"Figure 3\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":318889,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eSEM micrograph and EDX coated sample at 15֯Impact angle and 6.25 m/s velocity\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"3.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/bb942edcd5120795d0efa358.png\"},{\"id\":64373352,\"identity\":\"5f623481-80ed-4e3c-a32c-ed739ecb5d53\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 09:47:28\",\"extension\":\"png\",\"order_by\":4,\"title\":\"Figure 4\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":120731,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eCoated sample at 75 Impact angle and 8.42 m/s velocity\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"4.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/7391d69cd6f54075635c6ce4.png\"},{\"id\":64373356,\"identity\":\"3d777ce8-ab28-42f4-904c-95baf9c1d622\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 09:47:28\",\"extension\":\"png\",\"order_by\":5,\"title\":\"Figure 5\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":141950,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eCoated sample at 90 Impact angle and 10.16m/s velocity\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"5.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/ba77848a31029cf83bc138fd.png\"},{\"id\":64373358,\"identity\":\"826ae72b-d30d-40d3-9d55-567f6de51caa\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 09:47:28\",\"extension\":\"png\",\"order_by\":6,\"title\":\"Figure 6\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":130246,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eCoated sample at 75 Impact angle and 10.16m/s velocity.\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"6.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/3cde7988c5f16cf0d1fe848a.png\"},{\"id\":64373931,\"identity\":\"bff3cf86-d481-463a-a5e9-ebe4721bb96d\",\"added_by\":\"auto\",\"created_at\":\"2024-09-12 09:55:28\",\"extension\":\"png\",\"order_by\":7,\"title\":\"Figure 7\",\"display\":\"\",\"copyAsset\":false,\"role\":\"figure\",\"size\":131173,\"visible\":true,\"origin\":\"\",\"legend\":\"\\u003cp\\u003eErosion map of surface coating\\u003c/p\\u003e\",\"description\":\"\",\"filename\":\"7.png\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/a011d78dc2cd7fd37cef65bd.png\"},{\"id\":73693854,\"identity\":\"abe5ef76-94f6-471d-8082-a62aa49328f3\",\"added_by\":\"auto\",\"created_at\":\"2025-01-13 16:08:33\",\"extension\":\"pdf\",\"order_by\":0,\"title\":\"\",\"display\":\"\",\"copyAsset\":false,\"role\":\"manuscript-pdf\",\"size\":1486002,\"visible\":true,\"origin\":\"\",\"legend\":\"\",\"description\":\"\",\"filename\":\"manuscript.pdf\",\"url\":\"https://assets-eu.researchsquare.com/files/rs-4888255/v1/6288a909-84e1-4a24-8d42-493cd6f238f9.pdf\"}],\"financialInterests\":\"No competing interests reported.\",\"formattedTitle\":\"Erosion Mapping of Coated Composites: Simulating Conditions for Tidal Turbines Blades\",\"fulltext\":[{\"header\":\"Introduction\",\"content\":\"\\u003cp\\u003eSurface coatings have significant potential to reduce wear and erosion (1). \\u0026nbsp;In studies of erosion in marine renewable energy systems, such as tidal turbine blades, there have been some recent studies on blade durability in laboratory simulated erosion conditions using a range of experimental protocols (2-7). In these experimental conditions, important parameters such as impact angle, velocity (relating to thrust loading) and particle concentration at the surface interface can be evaluated.\\u003c/p\\u003e\\n\\u003cp\\u003eSuch research are important as tidal energy is increasingly viewed as an important energy resource in the renewable energy spectrum (2,7). However, the high-water densities encountered in blade impact test the current materials and surface engineering approaches. \\u0026nbsp;Understanding the mechanics of failure will provide new insights into materials selection in such conditions.\\u003c/p\\u003e\\n\\u003cp\\u003eVery few studies in recent years have concentrated on erosion resistance in the presence of surface coatings. \\u0026nbsp; Such surface engineering approaches are key to extending longevity of the turbine blades. \\u0026nbsp;Tailoring the coatings to the environment is the route to preventing failure at interfaces in the material.\\u003c/p\\u003e\\n\\u003cp\\u003eIn this study, a coating was applied to a standard GRP composite and tested in simulated tidal erosion conditions over a spectrum of impact angles and velocities. \\u0026nbsp;The results have indicated a very significant difference in erosion mechanism with impact angle. \\u0026nbsp;Microscopy and erosion maps were used to identify modes of erosion and mechanisms of degradation.\\u003c/p\\u003e\"},{\"header\":\"Materials and Methodologies\",\"content\":\"\\u003cp\\u003e\\u003cstrong\\u003eMaterials\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe materials used in this study include FR4-G10 GRP, which serves as the base for the erosion-resistant coating being evaluated. These materials were selected for their unique properties and suitability for the intended purpose of the study. Technical specifications for each of these materials are provided in Table (1), which includes information on their mechanical, thermal, and water absorption properties.\\u003c/p\\u003e\\n\\u003cp\\u003eTo ensure consistent and accurate testing, the materials were prepared by cutting sheets of plate arranged in a specific size of 36mm by 25mm and 3mm thickness. The sheets were cut to fit into the Jet rig specimen holder which is used to direct the slurry at the coated samples. The uniformity and precision of the sample size and arrangement ensure that the results of the tests are reliable and repeatable.\\u003c/p\\u003e\\n\\u003cp\\u003eThe FR4-G10 GRP materials as a base for the coating is based on their durability, strength, and erosion resistance, which are essential properties for withstanding the impact of slurry erosion.\\u003c/p\\u003e\\n\\u003cp\\u003eOverall, the use of these materials in the study ensures that the results obtained are applicable to real-world scenarios and can provide insights into the efficacy of the epoxy erosion-resistant coating for protecting materials from slurry erosion in various industries.\\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003eTable\\u0026nbsp;1\\u0026nbsp;Technical Specifications of FR4-G10 GRP\\u003c/p\\u003e\\n\\u003ctable border=\\\"1\\\" cellspacing=\\\"0\\\" cellpadding=\\\"0\\\" align=\\\"left\\\" width=\\\"100%\\\"\\u003e\\n \\u003ctbody\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eTechnical Data\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eUnits\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eTest Method\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eValues\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eColour\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eNA\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eNA\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eLight Green\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eSpecific Gravity\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eg/cm\\u0026sup3;\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eISO 1183\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e1.95\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eWater Absorption\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003emg\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eISO 62\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e5.5\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eFlexural Strength\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eMPa\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eISO 178\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e500\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eTensile Strength\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eMPa\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eISO 527\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"25%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e450\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003c/tbody\\u003e\\n\\u003c/table\\u003e\\n\\u003cp\\u003e(table location before coating composition)\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eCoating\\u003c/strong\\u003e\\u003cstrong\\u003e\\u0026nbsp;Composition\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eBelzona 2141 is a high-performance, erosion-resistance polymeric coating manufactured by Belzona International Ltd, which was selected for testing in this study due to its mechanical properties and high erosion resistance as described in table 2.\\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003eTo apply the Belzona 2141 coating to the FR4-G10 GRP samples, the surface of the samples was first prepared using 80-grit sandpaper, which helps to ensure good adhesion between the coating and the composite material. The Belzona 2911 activator was then mixed with the Belzona 2141 coating to achieve the required polymeric coating. This mixture was carefully prepared according to the manufacturer\\u0026apos;s instructions to ensure the correct ratio of components and consistency of the coating [1].\\u003c/p\\u003e\\n\\u003cp\\u003eOnce the samples were prepared and the coating mixture was ready, the coating was applied as a one-coat system by brush [1], [2]\\u0026nbsp;to achieve the desired thickness. The coating application process was carried out under the supervision of Belzona representatives to ensure that it was performed correctly and according to the manufacturer\\u0026apos;s guidelines [1].\\u003c/p\\u003e\\n\\u003cp\\u003eAfter application, the coated samples were left to dry for 24 hours in ambient temperature conditions to allow the coating to cure and reach its full mechanical properties. The coating thickness was measured to ensure that the average thickness of 0.8mm was achieved for all samples.\\u003c/p\\u003e\\n\\u003cp\\u003eThe application process for the Belzona 2141 coating involved careful preparation and application to ensure that the coating was evenly applied and had the required thickness and mechanical properties. The use of this high-performance coating in the study provides valuable insights into its effectiveness in protecting composite materials from slurry erosion in various industrial applications.\\u003c/p\\u003e\\n\\u003cp\\u003eTable 2 Coating specifications\\u003c/p\\u003e\\n\\u003ctable border=\\\"1\\\" cellspacing=\\\"0\\\" cellpadding=\\\"0\\\" width=\\\"97%\\\"\\u003e\\n \\u003ctbody\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eProperties\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eUnit\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eColor\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eGreen\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eHardness\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eASTM typical value 87\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eHeat resistance\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e40\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e C\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eTensile strength\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eASTM D412 15.2 MPa\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eTear strength\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eASTM D624 380 pli\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eDensity\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e1.1 g/cm3\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eWater absorption\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003enil\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003c/tbody\\u003e\\n\\u003c/table\\u003e\\n\\u003cp\\u003e\\u0026nbsp;\\u003cstrong\\u003eImpingement Rig Test Set-Up\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe experimental setup features a custom-designed slurry jet rig as shown in Fig 1, constructed following the guidelines of Hutchings [3]. It consists of a polypropylene conical trapper for efficient sand recirculation, a T-shaped nozzle for slurry generation, and propellers driven by electric motors to ensure uniform mixing and circulation of the slurry. The rig\\u0026apos;s configuration allows for precise adjustment of parameters such as slurry flow velocity and impingement angle, while operational guidelines dictate a maximum testing duration of 30 minutes to prevent pump overheating.\\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eTest Conditions\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe erosive characteristics were assessed through the examination of mass reduction utilizing an analytical balance with a precision of +/-0.01mg, coupled with a surface analysis conducted using a Scanning Electron Microscope (SEM). \\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003eTable 3 Test Parameters\\u003c/p\\u003e\\n\\u003ctable border=\\\"1\\\" cellspacing=\\\"0\\\" cellpadding=\\\"0\\\" width=\\\"565\\\"\\u003e\\n \\u003ctbody\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eParameter\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eValues\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eImpact Angles\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e15\\u0026deg;, 30\\u0026deg;, 45\\u0026deg;, 60\\u0026deg;, 75\\u0026deg;, 90\\u0026deg;\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eImpact Velocities\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e6.25 m/s, 8.42 m/s, 10.16 m/s\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eTest Duration\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e30 minutes per sample\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eSand Concentration\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e3%\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eSalinity\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e3.5%\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eSand Particle Size\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e300-600 \\u0026micro;m\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eTest Temperature\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003eRoom temperature\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003c/tbody\\u003e\\n\\u003c/table\\u003e\\n\\u003cp\\u003eTable 4 Nozzles vs Velocities\\u003c/p\\u003e\\n\\u003ctable border=\\\"1\\\" cellspacing=\\\"0\\\" cellpadding=\\\"0\\\" width=\\\"100%\\\"\\u003e\\n \\u003ctbody\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"49.494949494949495%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003eNozzle Inlet Dia (mm)\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50.505050505050505%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e\\u003cstrong\\u003etest Velocity (m/s)\\u003c/strong\\u003e\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"49.494949494949495%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e2\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50.505050505050505%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e6.25\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"49.494949494949495%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e2.5\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50.505050505050505%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e8.42\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003ctr\\u003e\\n \\u003ctd width=\\\"49.494949494949495%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e3\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003ctd width=\\\"50.505050505050505%\\\" valign=\\\"top\\\"\\u003e\\n \\u003cp\\u003e10.16\\u003c/p\\u003e\\n \\u003c/td\\u003e\\n \\u003c/tr\\u003e\\n \\u003c/tbody\\u003e\\n\\u003c/table\\u003e\\n\\u003cp\\u003eThe velocities used in the test were regulated by the inlet nozzle diameter, as specified in Table 4. The rig was calibrated to ensure that the desired velocities were achieved. This was carried out by first measuring the volume of water in the rig, and then using a timer to record the elapsed time and final volume of water in a separate container. By subtracting the initial volume from the final volume of water that flowed through the container, this determined the volume of water that passed through the rig.\\u003c/p\\u003e\\n\\u003cp\\u003e\\u0026nbsp;The final step involved using the formula below to calculate the velocity of the water flow.\\u003c/p\\u003e\\n\\u003cp\\u003e\\u0026nbsp;\\u003cimg src=\\\"data:image/png;base64,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\\\"\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003ewhere is \\u003cstrong\\u003e\\u0026apos;v\\u0026apos;\\u003c/strong\\u003e is the velocity, \\u003cstrong\\u003e\\u0026apos;Q\\u0026apos;\\u003c/strong\\u003e is the flow rate and \\u003cstrong\\u003e\\u0026apos;A\\u0026apos;\\u003c/strong\\u003e is a cross-sectional area of the flow path.\\u003c/p\\u003e\\n\\u003cp\\u003eBy dividing the flow rate by the flow path\\u0026apos;s cross-sectional area, the velocity of the water flow was determined. To increase the accuracy of the results, the steps above were repeated three times. This calibration and measurement process allowed to obtain precise data on the velocity of water flow in the Jet rig.\\u003c/p\\u003e\"},{\"header\":\"Results and Discussion\",\"content\":\"\\u003cp\\u003e\\u003cstrong\\u003eResults\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe erosion of the coating material was significantly influenced by the impact angle and water flow velocity, according to Fig. 2 it was noted that the coating experienced higher mass loss at impact angles of 60֯ and 90֯, regardless of the velocity. This suggests that these angles are more critical for the durability of the coating and should be considered in the design and operation of turbines.\\u003c/p\\u003e\\n\\u003cp\\u003eAdditionally, the results showed that lower velocities of 6.25 m/s caused less damage to the coating material than the higher velocities of 8.42 m/s and 10.16 m/s. This suggests that a element in the erosion of the coating material is velocity. Moreover, it was noticed that at an impact angle of 45֯, the coating experienced mass loss at velocities of 8.42 m/s and 10.16 m/s.\\u003c/p\\u003e\\n\\u003cp\\u003eThe results of this experiment could have significant implications for the design and operation of tidal turbines. Erosion of the coating material can lead to reduced efficiency and a shorter lifespan of the turbines [4].\\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eEffect of Velocities and Impact Angle on Coating\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe performance of the tidal turbine relies on the rotor blade, which is a critical component for extracting kinetic energy from the tide stream [5]. The blade is similar in concept to a wind turbine blade, but its design and reliability assessment cannot be based on those of the wind turbine due to differences in seawater density and other factors [2]. However, the efficiency and reliability of the blades are key indicators for a tidal current turbine[6]. The tribological issue, such as leading-edge erosion due to sand particles\\u0026apos; impact, cavitation erosion, and the combined effects of seawater and solid particles, can compromise the performance and reliability of the rotor blade [2], [7]. Researchers have investigated the erosion of the rotor blade caused by the impact of erodent under marine simulated conditions, i.e., saltwater plus sand particles, but ignored erosion due to cavitation [2], [8]. [9] also notes that the use of thermoplastic composite blades in a large-scale tidal power turbine is a potential game-changer for the marine energy industry, improving performance and sustainability, while also making the manufacturing process faster and more energy efficient.\\u003c/p\\u003e\\n\\u003cp\\u003eThe impact angle and velocity can significantly affect the erosion of polymeric coatings applied to tidal turbine blades [10], [11]. The erosion losses were evaluated at various impingement angles (15\\u0026deg;-90\\u0026deg;) and with the change of impact velocity 6.25 m/s, 8.42 m/s and 10.16 m/s, which reflects typical velocities experienced at the leading edge of the blade [11]. The polymeric coating acts as a barrier between the substrate and NaCl solution, slowing the ingress of moisture in composite materials [2]. The impact frequency can affect the ability of a coating to absorb and distribute the energy from an impact [12], which is typically taken into account in current blade coating systems.\\u003c/p\\u003e\\n\\u003cp\\u003eThe results indicate that the impact angle and velocity have a significant effect on the erosion of the samples [13]. At all velocities, the coating experienced higher mass loss at 60֯ and 90֯ impact angles. This can be attributed to the fact that at these angles, the impact energy is concentrated on a smaller area, leading to a higher erosion rate. At 6.25 m/s, the coating experienced a lower mass loss compared to 8.42 m/s and 10.16 m/s, indicating that lower velocity leads to a lower erosion rate. However, at higher velocities of 8.42 m/s and 10.16 m/s, the coating experienced higher mass loss, indicating that higher velocity leads to a higher erosion rate. At 45֯ impact angle, the coating experienced mass loss at velocities 8.42 m/s and 10.16 m/s, indicating that at this angle, higher velocities lead to a higher erosion rate. These results highlight the importance of considering impact angle and velocity when studying erosion and can be useful in designing coatings or materials that are more resistant to erosion [14]\\u003c/p\\u003e\\n\\u003cp\\u003eMoreover, the coating material\\u0026apos;s ability to absorb and distribute the energy from an impact can also vary [12]. This further emphasises the importance of selecting the appropriate coating material and application process that can withstand the impact and erosion caused by the water flow. Overall, it is crucial to consider various factors, such as impact angle, velocity, and coating material properties [15], [16], when designing and operating tidal turbines to ensure the longevity and efficiency of the system.\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eSEM Analysis (to be followed by Fig 3)\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eA focused beam of high-energy electrons is used in a scanning electron microscope (SEM) to image the topography and learn about the material composition of conductive specimens. [17]. The SEM consists of an electron gun, a system of magnetic lenses, a scan control, and a detector, which work together to focus the electron beam on the sample and generate high-resolution images of its surface [17].\\u003c/p\\u003e\\n\\u003cp\\u003eSEM was used to analyse the surface of an FR4-GRP coated with Belzona 2141. Fig. 3 of the SEM provided evidence of salt deposition on the coating surface, which occurred at an impact angle of 15 and 6.25 m/s velocity.\\u003c/p\\u003e\\n\\u003cp\\u003eThe combination of the SEM image and the observation of an increase in mass in Fig. 30 provide strong evidence that the impact of the erodent caused salt deposition on the surface of the coating. This finding is important because it can have implications for the performance of the coating in tidal turbine operation, as salt deposition can have detrimental effects on the integrity and durability of coatings [10].\\u003c/p\\u003e\\n\\u003cp\\u003eFig. 4 shows the results of an erosion test on a coating surface, specifically at a 75\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e angle and a velocity of 8.42 m/s. Fig.4 indicates that this impact caused significant damage to the coating, as evidenced by the presence of voids, cavities, and loose debris scattered around the eroded surface.\\u003c/p\\u003e\\n\\u003cp\\u003eThe specific impact angle of 75\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and a velocity of 8.42 m/s are significant because they provide information about the strength and durability of the coating. The voids and cavities in the fig 4 indicate that the impact caused the coating material to fracture and break apart. This type of damage can weaken the structural integrity of the coating and may compromise its ability to provide protection to the underlying material or surface [18]. The loose debris from sand and broken fibres scattered around the impact site suggests that the force of the impact was strong enough to dislodge and scatter coating material beyond the immediate vicinity.\\u003c/p\\u003e\\n\\u003cp\\u003eFig 5 confirms the presence of loose debris and coating erosion due to deformation and cutting action at a higher impact velocity of 10.16 m/s and an impact angle of 90\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e. The figure also confirms the ductile cutting in the coating at these test conditions [19].\\u003c/p\\u003e\\n\\u003cp\\u003eThe presence of loose debris indicates that the impact caused some material to be dislodged or broken apart, similar to what was observed in Fig. 5. The confirmation of loose debris and coating erosion at higher impact conditions suggests that the coating may not be able to withstand high-speed impacts at these conditions. The presence of ductile cutting in the coating further confirms that the coating is a ductile material, as was observed in Fig. 6 at lower impact conditions [20].\\u003c/p\\u003e\\n\\u003cp\\u003eThe combination of loose debris, coating erosion, and ductile cutting observed in Fig. 32 provides evidence of the extent of damage caused by the impact at these higher impact conditions. The deformation and cutting action caused significant damage to the coating, resulting in the removal of material and the formation of loose debris.\\u003c/p\\u003e\\n\\u003cp\\u003eThe confirmation of ductile cutting at higher impact conditions is significant because it suggests that the coating may undergo significant plastic deformation before fracturing [21].\\u0026nbsp;\\u003c/p\\u003e\\n\\u003cp\\u003eThis information is important for understanding the behaviour of the coating under high-speed impact conditions and for determining the potential applications of the coating in environments with high-speed impacts.\\u003c/p\\u003e\\n\\u003cp\\u003eFig. 6 shows that at an impact angle of 75\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and a velocity of 10.16 m/s, the coated surface suffered from pit propagation due to the impact of the erodent. The figure also shows the presence of loose debris and ductile cutting.\\u003c/p\\u003e\\n\\u003cp\\u003eThe observation of pit propagation is significant because it suggests that the impact caused the coating to undergo significant material removal in the form of pits. The presence of loose debris and ductile cutting further confirms that the impact caused damage to the coating surface [2], [21].\\u003c/p\\u003e\\n\\u003cp\\u003eThe combination of pit propagation, loose debris, and ductile cutting observed in Fig 6 provides evidence of the extent of damage caused by the impact under these conditions. The deformation and cutting action caused significant damage to the coating, resulting in the formation of pits and the removal of material, which formed loose debris.\\u003c/p\\u003e\\n\\u003cp\\u003eThe observation of ductile cutting in Fig. 6 is consistent with the observation in Fig. 5, which suggests that the coating is a ductile material. This information is important for understanding the behaviour of the coating under high-speed impact conditions and for determining the potential applications of the coating in environments with high-velocity impacts [22].\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eErosion Mapping of Surface Coating\\u0026nbsp;\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eTo visualise damage, erosion maps were created as an alternative method. These maps were constructed using the procedures outlined by [23].\\u003c/p\\u003e\\n\\u003cp\\u003eThe aim of the study was to produce erosion maps and patterns in coated samples using a developed code written in MATLAB. This map allowed for the analysis and assessment of the coating erosion process, giving valuable insights into material behaviour under different conditions. Utilising the maps can aid in comprehending erosion mechanisms in coating and composite materials, which can assist design engineers in forecasting safety levels during operation and lead to the creation of a more sturdy and long-lasting coating for tidal turbine blades [24].\\u003c/p\\u003e\\n\\u003cp\\u003eThe erosion map provides a graphical representation of the level of material loss experienced by the coating under different impact velocities and angles [25]. The map in fig. 7 indicates that the coating is most resistant to erosion when tested at impact angles of 15\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e, 30\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e, 45\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e, and 75\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and velocities of 6.25 m/s, 8.42 m/s and 10.16 m/s, suggesting that the coating\\u0026apos;s design is most effective at deflecting the force of the impacting particles when it is applied at these angles.\\u003c/p\\u003e\\n\\u003cp\\u003eIn contrast, the coating experiences higher levels of erosion when tested at impact angles of 60\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and 90\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and velocities of 6.25 m/s, 8.42 m/s and 10.16 m/s, indicating that the design may not be as effective at deflecting the force of particles at these angles. This suggests that design modifications may be necessary to enhance the coating\\u0026apos;s performance under these impact conditions[26].\\u003c/p\\u003e\\n\\u003cp\\u003eFig 7 revealed that the coating performed best at a velocity of 6.25 m/s compared to velocities of 8.42 m/s and 10.16 m/s. This data can be used to optimise the design of the tidal turbine blades to reduce the impact of ocean currents and tides, potentially reducing erosion and improving the durability of the coating.\\u003c/p\\u003e\\n\\u003cp\\u003eOverall, the erosion map provides valuable insights into the behaviour of the coating under different impact conditions [27]. By analysing the map, design engineers can determine the optimal impact angles and velocities for the coating, enabling them to optimise the design of the tidal turbine blades for increased durability and longevity. The map\\u0026apos;s findings can be used to enhance the efficiency and sustainability of harnessing the power of ocean currents and tides through tidal turbines[28].\\u003c/p\\u003e\"},{\"header\":\"Declarations\",\"content\":\"\\u003cp\\u003eCompeting interests There are no competing interests.\\u003c/p\\u003e\\n\\u003cp\\u003eEthical Approval Not applicable\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eFunding:\\u003c/strong\\u003e\\u003c/p\\u003e\\n\\u003cp\\u003eThe authors would like to acknowledge the support of the Interreg (Northern Ireland—Ireland—Scotland) Special EU Programmes Grant No SPIRE2_INT–VA–049 “Storage Platform for the Integration of Renewable Energy (SPIRE 2)”.\\u003c/p\\u003e\\n\\u003cp\\u003e\\u003cstrong\\u003eAvailability of data and materials\\u003c/strong\\u003e: Not available\\u003c/p\\u003e\"},{\"header\":\"Conclusions\",\"content\":\"\\u003cul\\u003e\\n \\u003cli\\u003eThe study aimed to address the erosion challenges of the coating material used in tidal turbine blades. The study also emphasised the importance of using erosion maps to visualise and analyse the level of material loss under different impact condition.\\u0026nbsp;\\u003c/li\\u003e\\n \\u003cli\\u003eThe erosion map produced in the study provides valuable insights into the behaviour of the coating and can be used to optimise the design of tidal turbine blades for increased durability and longevity\\u0026nbsp;[7].\\u003c/li\\u003e\\n \\u003cli\\u003eThe highest erosion was observed at 75\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e and 90\\u003cspan dir=\\\"RTL\\\"\\u003e֯\\u003c/span\\u003e impact angles at all impact velocities. The erosion maps displayed the level of material loss experienced by the coating under different impact conditions, providing valuable insights for the design of tidal turbine blades.\\u003c/li\\u003e\\n\\u003c/ul\\u003e\"},{\"header\":\"References\",\"content\":\"\\u003col\\u003e\\n\\u003cli\\u003eBelzona, \\u0026ldquo;https://www.belzona.com/en/products/2000/2141.aspx.\\u0026rdquo;\\u003c/li\\u003e\\n\\u003cli\\u003eG. Rasool and M. M. Stack, \\u0026ldquo;Some Views on the Mapping of Erosion of Coated Composites In Tidal Turbine Simulated Conditions,\\u0026rdquo; \\u003cem\\u003eTribology Transactions\\u003c/em\\u003e, vol. 62, no. 3, pp. 512\\u0026ndash;523, 2019, doi: 10.1080/10402004.2019.1581313.\\u003c/li\\u003e\\n\\u003cli\\u003eJ. B. Zu, I. M. Hutchings, and G. T. Burstein, \\u0026ldquo;Design of a slurry erosion test rig,\\u0026rdquo; \\u003cem\\u003eWear\\u003c/em\\u003e, vol. 140, no. 2, pp. 331\\u0026ndash;344, Nov. 1990, doi: 10.1016/0043-1648(90)90093-P.\\u003c/li\\u003e\\n\\u003cli\\u003eL. X. Cai, Y. Li, S. Sen Wang, Y. He, F. Li, and Z. K. Liu, \\u0026ldquo;Investigation of the erosion damage mechanism and erosion prediction of boronized coatings at elevated temperatures,\\u0026rdquo; \\u003cem\\u003eMaterials\\u003c/em\\u003e, vol. 14, no. 1, pp. 1\\u0026ndash;18, Jan. 2021, doi: 10.3390/ma14010123.\\u003c/li\\u003e\\n\\u003cli\\u003eS. Roshanmanesh, F. Hayati, and M. Papaelias, \\u0026ldquo;Tidal turbines,\\u0026rdquo; \\u003cem\\u003eNon-Destructive Testing and Condition Monitoring Techniques for Renewable Energy Industrial Assets\\u003c/em\\u003e, pp. 143\\u0026ndash;158, Jan. 2020, doi: 10.1016/B978-0-08-101094-5.00010-1.\\u003c/li\\u003e\\n\\u003cli\\u003eA. Muratoglu and M. I. Yuce, \\u0026ldquo;Performance Analysis of Hydrokinetic Turbine Blade Sections,\\u0026rdquo; 2015.\\u003c/li\\u003e\\n\\u003cli\\u003eC. Johnstone, M. Stack, S. Sharifi, C. Johnstone, and M. M. Stack, \\u0026ldquo;Tribological challenges of scaling up tidal turbine blades.\\u0026rdquo; [Online]. Available: https://www.researchgate.net/publication/299369786\\u003c/li\\u003e\\n\\u003cli\\u003eJ. F. Manwell, J. G. McGowan, and A. L. Rogers, \\u0026ldquo;Wind Energy Explained: Theory, Design and Application,\\u0026rdquo; 2010.\\u003c/li\\u003e\\n\\u003cli\\u003eNational Renewable Energy Laboratory (lead) and Verdant Power, \\u0026ldquo;Tidal Power Turbine Demonstrates Thermoplastic Blades,\\u0026rdquo; https://www.energy.gov/eere/water/articles/tidal-power-turbine-demonstrates-thermoplastic-blades.\\u003c/li\\u003e\\n\\u003cli\\u003eG. Rasool, C. Johnstone, and M. M. Stack, \\u0026ldquo;Tribology of Tidal Turbine Blades: Impact angle effects on erosion of polymeric coatings in sea water conditions.\\u0026rdquo;\\u003c/li\\u003e\\n\\u003cli\\u003eR. A. R. Ahamed, C. M. Johnstone, and M. M. Stack, \\u0026ldquo;Impact Angle Effects on Erosion Maps of GFRP: Applications to Tidal Turbines,\\u0026rdquo; \\u003cem\\u003eJ Bio Tribocorros\\u003c/em\\u003e, vol. 2, no. 2, Jun. 2016, doi: 10.1007/s40735-016-0044-1.\\u003c/li\\u003e\\n\\u003cli\\u003eA. Dashtkar \\u003cem\\u003eet al.\\u003c/em\\u003e, \\u0026ldquo;Rain erosion-resistant coatings for wind turbine blades: A review,\\u0026rdquo; \\u003cem\\u003ePolymers and Polymer Composites\\u003c/em\\u003e, vol. 27, no. 8, pp. 443\\u0026ndash;475, May 2019, doi: 10.1177/0967391119848232.\\u003c/li\\u003e\\n\\u003cli\\u003eS. Wang, G. Liu, J. Mao, Q. He, and Z. Feng, \\u0026ldquo;Effects of Coating Thickness, Test Temperature, and Coating Hardness on the Erosion Resistance of Steam Turbine Blades,\\u0026rdquo; \\u003cem\\u003eJ Eng Gas Turbine Power\\u003c/em\\u003e, vol. 132, no. 2, Nov. 2009, doi: 10.1115/1.3155796.\\u003c/li\\u003e\\n\\u003cli\\u003eS. Hassani, J. E. Klemberg-Sapieha, M. Bielawski, W. Beres, L. Martinu, and M. Balazinski, \\u0026ldquo;Design of hard coating architecture for the optimization of erosion resistance,\\u0026rdquo; \\u003cem\\u003eWear\\u003c/em\\u003e, vol. 265, no. 5\\u0026ndash;6, pp. 879\\u0026ndash;887, Aug. 2008, doi: 10.1016/J.WEAR.2008.01.021.\\u003c/li\\u003e\\n\\u003cli\\u003eM. M. Stack, B. D. Jana, and S. M. Abdelrahman, \\u0026ldquo;Models and mechanisms of erosion\\u0026ndash;corrosion in metals,\\u0026rdquo; \\u003cem\\u003eTribocorrosion of Passive Metals and Coatings\\u003c/em\\u003e, pp. 153\\u0026ndash;187e, Jan. 2011, doi: 10.1533/9780857093738.1.153.\\u003c/li\\u003e\\n\\u003cli\\u003eJ. S. Chouhan \\u003cem\\u003eet al.\\u003c/em\\u003e, \\u0026ldquo;Preliminary investigation of slurry erosion behaviour of tantalum,\\u0026rdquo; \\u003cem\\u003eWear\\u003c/em\\u003e, vol. 516\\u0026ndash;517, p. 204605, Mar. 2023, doi: 10.1016/J.WEAR.2022.204605.\\u003c/li\\u003e\\n\\u003cli\\u003eR. Schmitt, \\u0026ldquo;Scanning Electron Microscope,\\u0026rdquo; in \\u003cem\\u003eCIRP Encyclopedia of Production Engineering\\u003c/em\\u003e, G. Laperri\\u0026egrave;re Luc and Reinhart, Ed., Berlin, Heidelberg: Springer Berlin Heidelberg, 2014, pp. 1085\\u0026ndash;1089. doi: 10.1007/978-3-642-20617-7_6595.\\u003c/li\\u003e\\n\\u003cli\\u003eT. A. Ring, P. Feeney, D. Boldridge, J. Kasthurirangan, S. Li, and J. A. Dirksen, \\u0026ldquo;Brittle and Ductile Fracture Mechanics Analysis of Surface Damage Caused During CMP.\\u0026rdquo;\\u003c/li\\u003e\\n\\u003cli\\u003eG. Prashar, H. Vasudev, and L. Thakur, \\u0026ldquo;Performance of different coating materials against slurry erosion failure in hydrodynamic turbines: A review,\\u0026rdquo; \\u003cem\\u003eEng Fail Anal\\u003c/em\\u003e, vol. 115, p. 104622, Sep. 2020, doi: 10.1016/J.ENGFAILANAL.2020.104622.\\u003c/li\\u003e\\n\\u003cli\\u003eM. Naveed, H. Schlag, F. K\\u0026ouml;nig, and S. Wei\\u0026szlig;, \\u0026ldquo;Influence of the Erodent Shape on the Erosion Behavior of Ductile and Brittle Materials,\\u0026rdquo; \\u003cem\\u003eTribol Lett\\u003c/em\\u003e, vol. 65, no. 1, p. 18, 2016, doi: 10.1007/s11249-016-0800-x.\\u003c/li\\u003e\\n\\u003cli\\u003eG. R. Desale, B. K. Gandhi, and S. C. Jain, \\u0026ldquo;Effect of erodent properties on erosion wear of ductile type materials,\\u0026rdquo; \\u003cem\\u003eWear\\u003c/em\\u003e, vol. 261, no. 7\\u0026ndash;8, pp. 914\\u0026ndash;921, Oct. 2006, doi: 10.1016/J.WEAR.2006.01.035.\\u003c/li\\u003e\\n\\u003cli\\u003eS. H. Musavi, B. Davoodi, and M. Nankali, \\u0026ldquo;Assessment of Tool Wear and Surface Integrity in Ductile Cutting Using a Developed Tool,\\u0026rdquo; \\u003cem\\u003eArab J Sci Eng\\u003c/em\\u003e, vol. 46, no. 8, pp. 7773\\u0026ndash;7787, 2021, doi: 10.1007/s13369-021-05560-4.\\u003c/li\\u003e\\n\\u003cli\\u003eE. Hassan \\u003cem\\u003eet al.\\u003c/em\\u003e, \\u0026ldquo;Erosion Mapping of Through-Thickness Toughened Powder Epoxy Gradient Glass-Fiber-Reinforced Polymer (GFRP) Plates for Tidal Turbine Blades,\\u0026rdquo; \\u003cem\\u003eLubricants\\u003c/em\\u003e, vol. 9, no. 3, p. 22, Feb. 2021, doi: 10.3390/lubricants9030022.\\u003c/li\\u003e\\n\\u003cli\\u003eJ. Sloan and M. Stack, \\u0026ldquo;On the Construction of Raindrop Erosion Maps for Steel,\\u0026rdquo; 2020.\\u003c/li\\u003e\\n\\u003cli\\u003eM. M. Stack, N. Corlett, and S. Zhou, \\u0026ldquo;Construction of erosion-corrosion maps for erosion in aqueous slurries,\\u0026rdquo; \\u003cem\\u003eMaterials Science and Technology\\u003c/em\\u003e, vol. 12, pp. 662\\u0026ndash;672, 1996.\\u003c/li\\u003e\\n\\u003cli\\u003eM. Patel, D. Patel, S. Sekar, P. B. Tailor, and P. V. Ramana, \\u0026ldquo;Study of Solid Particle Erosion Behaviour of SS 304 at Room Temperature,\\u0026rdquo; \\u003cem\\u003eProcedia Technology\\u003c/em\\u003e, vol. 23, pp. 288\\u0026ndash;295, 2016, doi: 10.1016/j.protcy.2016.03.029.\\u003c/li\\u003e\\n\\u003cli\\u003eG. Rasool, A. C. Middleton, and M. M. Stack, \\u0026ldquo;Mapping Raindrop Erosion of GFRP Composite Wind Turbine Blade Materials: Perspectives on Degradation Effects in Offshore and Acid Rain Environmental Conditions,\\u0026rdquo; \\u003cem\\u003eJ Tribol\\u003c/em\\u003e, vol. 142, no. 6, Feb. 2020, doi: 10.1115/1.4046014.\\u003c/li\\u003e\\n\\u003cli\\u003eG. Rasool, S. Sharifi, C. Johnstone, and M. M. Stack, \\u0026ldquo;Mapping Synergy of Erosion Mechanisms of Tidal Turbine Composite Materials in Sea Water Conditions,\\u0026rdquo; \\u003cem\\u003eJ Bio Tribocorros\\u003c/em\\u003e, vol. 2, no. 2, Jun. 2016, doi: 10.1007/s40735-016-0040-5.\\u003c/li\\u003e\\n\\u003c/ol\\u003e\"}],\"fulltextSource\":\"\",\"fullText\":\"\",\"funders\":[],\"hasAdminPriorityOnWorkflow\":false,\"hasManuscriptDocX\":true,\"hasOptedInToPreprint\":true,\"hasPassedJournalQc\":\"\",\"hasAnyPriority\":false,\"hideJournal\":false,\"highlight\":\"\",\"institution\":\"\",\"isAcceptedByJournal\":true,\"isAuthorSuppliedPdf\":false,\"isDeskRejected\":\"\",\"isHiddenFromSearch\":false,\"isInQc\":false,\"isInWorkflow\":false,\"isPdf\":false,\"isPdfUpToDate\":true,\"isWithdrawnOrRetracted\":false,\"journal\":{\"display\":true,\"email\":\"info@researchsquare.com\",\"identity\":\"journal-of-bio--and-tribo-corrosion\",\"isNatureJournal\":false,\"hasQc\":true,\"allowDirectSubmit\":false,\"externalIdentity\":\"jbtc\",\"sideBox\":\"Learn more about [Journal of Bio- and Tribo-Corrosion](http://link.springer.com/journal/40735)\",\"snPcode\":\"40735\",\"submissionUrl\":\"https://submission.nature.com/new-submission/40735/3\",\"title\":\"Journal of Bio- and Tribo-Corrosion\",\"twitterHandle\":\"\",\"acdcEnabled\":true,\"dfaEnabled\":true,\"editorialSystem\":\"em\",\"reportingPortfolio\":\"Springer Hybrid\",\"inReviewEnabled\":true,\"inReviewRevisionsEnabled\":false},\"keywords\":\"\",\"lastPublishedDoi\":\"10.21203/rs.3.rs-4888255/v1\",\"lastPublishedDoiUrl\":\"https://doi.org/10.21203/rs.3.rs-4888255/v1\",\"license\":{\"name\":\"CC BY 4.0\",\"url\":\"https://creativecommons.org/licenses/by/4.0/\"},\"manuscriptAbstract\":\"\\u003cp\\u003eThe tribological mechanisms of potential composite materials that could be used in tidal turbines considered the effects of various erosion parameters on the degradation modes, both with and without particles, in still and seawater conditions. The aim of this study was to investigate the potential of a specialised epoxy erosion-resistant coating for glass fibre-reinforced plastic (GFRP) in resisting the impact of slurry erosion. Slurry erosion is a process by which solid particles suspended in a fluid medium impinge on a surface, causing material loss due to repeated impacts. The coating efficacy was evaluated through a series of tests, including three different speeds and six different impinging angles and the results were used to generate tidal turbine maps. The study provided insights into the durability and of the epoxy and potential use of the coating in tidal turbine blade industries where resistance to erosion is crucial for long-term performance and safety.\\u003c/p\\u003e\",\"manuscriptTitle\":\"Erosion Mapping of Coated Composites: Simulating Conditions for Tidal Turbines Blades\",\"msid\":\"\",\"msnumber\":\"\",\"nonDraftVersions\":[{\"code\":1,\"date\":\"2024-09-12 09:47:23\",\"doi\":\"10.21203/rs.3.rs-4888255/v1\",\"editorialEvents\":[{\"type\":\"communityComments\",\"content\":0},{\"type\":\"decision\",\"content\":\"Revision requested\",\"date\":\"2024-12-25T08:47:10+00:00\",\"index\":\"\",\"fulltext\":\"\"},{\"type\":\"editorInvitedReview\",\"content\":\"\",\"date\":\"2024-12-25T08:33:47+00:00\",\"index\":\"hide\",\"fulltext\":\"\"},{\"type\":\"reviewerAgreed\",\"content\":\"80708282478615187099225865975291096895\",\"date\":\"2024-12-20T00:44:59+00:00\",\"index\":\"hide\",\"fulltext\":\"\"},{\"type\":\"reviewerAgreed\",\"content\":\"135229233661603345280232394752202381137\",\"date\":\"2024-08-21T04:57:48+00:00\",\"index\":\"hide\",\"fulltext\":\"\"},{\"type\":\"reviewersInvited\",\"content\":\"\",\"date\":\"2024-08-19T04:54:50+00:00\",\"index\":\"\",\"fulltext\":\"\"},{\"type\":\"editorAssigned\",\"content\":\"\",\"date\":\"2024-08-14T23:10:32+00:00\",\"index\":\"\",\"fulltext\":\"\"},{\"type\":\"checksComplete\",\"content\":\"\",\"date\":\"2024-08-14T23:09:24+00:00\",\"index\":\"\",\"fulltext\":\"\"},{\"type\":\"submitted\",\"content\":\"Journal of Bio- and Tribo-Corrosion\",\"date\":\"2024-08-09T16:05:54+00:00\",\"index\":\"\",\"fulltext\":\"\"}],\"status\":\"published\",\"journal\":{\"display\":true,\"email\":\"info@researchsquare.com\",\"identity\":\"journal-of-bio--and-tribo-corrosion\",\"isNatureJournal\":false,\"hasQc\":true,\"allowDirectSubmit\":false,\"externalIdentity\":\"jbtc\",\"sideBox\":\"Learn more about [Journal of Bio- and Tribo-Corrosion](http://link.springer.com/journal/40735)\",\"snPcode\":\"40735\",\"submissionUrl\":\"https://submission.nature.com/new-submission/40735/3\",\"title\":\"Journal of Bio- and Tribo-Corrosion\",\"twitterHandle\":\"\",\"acdcEnabled\":true,\"dfaEnabled\":true,\"editorialSystem\":\"em\",\"reportingPortfolio\":\"Springer Hybrid\",\"inReviewEnabled\":true,\"inReviewRevisionsEnabled\":false}}],\"origin\":\"\",\"ownerIdentity\":\"e843c034-cddd-4aec-bdc3-92398f69e670\",\"owner\":[],\"postedDate\":\"September 12th, 2024\",\"published\":true,\"recentEditorialEvents\":[],\"rejectedJournal\":[],\"revision\":\"\",\"amendment\":\"\",\"status\":\"published-in-journal\",\"subjectAreas\":[],\"tags\":[],\"updatedAt\":\"2025-01-13T16:00:18+00:00\",\"versionOfRecord\":{\"articleIdentity\":\"rs-4888255\",\"link\":\"https://doi.org/10.1007/s40735-025-00941-w\",\"journal\":{\"identity\":\"journal-of-bio--and-tribo-corrosion\",\"isVorOnly\":false,\"title\":\"Journal of Bio- and Tribo-Corrosion\"},\"publishedOn\":\"2025-01-07 15:57:12\",\"publishedOnDateReadable\":\"January 7th, 2025\"},\"versionCreatedAt\":\"2024-09-12 09:47:23\",\"video\":\"\",\"vorDoi\":\"10.1007/s40735-025-00941-w\",\"vorDoiUrl\":\"https://doi.org/10.1007/s40735-025-00941-w\",\"workflowStages\":[]},\"version\":\"v1\",\"identity\":\"rs-4888255\",\"journalConfig\":\"researchsquare\"},\"__N_SSP\":true},\"page\":\"/article/[identity]/[[...version]]\",\"query\":{\"redirect\":\"/article/rs-4888255\",\"identity\":\"rs-4888255\",\"version\":[\"v1\"]},\"buildId\":\"qtupq5eGEP_6zYnWcrvyt\",\"isFallback\":false,\"isExperimentalCompile\":false,\"dynamicIds\":[84888],\"gssp\":true,\"scriptLoader\":[]}","source_license":"CC-BY-4.0","license_restricted":false}