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Water droplet erosion

Summary

Water droplet erosion (WDE) is "a form of materials wear that is caused by the impact of liquid droplets with sufficiently high speed."[1] The phenomenon was furthermore previously known as liquid impingement erosion (LIE).

Water droplet erosion damage in a steam turbine blade

Distinction from other phenomena edit

The emphasis of discrete water droplets serves to distinguish the WDE problem from liquid jet erosion and cavitation. The impact pressures invoked by discrete water droplet impact have a range considerably higher than the stagnation pressure created by liquid jet.

The difference between WDE and cavitation erosion is the fact that WDE usually comprises a gaseous or vaporous phase containing discrete liquid droplets; while cavitation erosion is observed when a continual liquid phase carries separate gaseous bubbles or cavities inside it.[2]

Recently, Ibrahim & Medraj developed an analytical model to predict the threshold speed of water droplet erosion and verified it experimentally, a challenge having been attempted hitherto without success since the 1950s.[3]

Consequences edit

 
Water droplet erosion damage in wind turbines caused by rain

For an extended period of time, many industries have encountered the problem of erosion due to water droplet impact, and it continues to reappear wherever rotation or movement of a component at high speed in a hydrometer environment is employed. Recently, with the use of larger wind turbine blades, the issue of erosion of the leading edge due to rain droplets has grown more grave. Aerodynamics efficiency of turbine blades is severely diminished due to leading-edge erosion, resulting in a considerable decrease in annual energy production.[4]


References edit

  1. ^ Bhushan, B.; Ko, Pak Lim (2003). "Introduction to Tribology". Applied Mechanics Reviews. 56 (1): B6–B7. Bibcode:2003ApMRv..56B...6B. doi:10.1115/1.1523360.
  2. ^ Wood, Robert J.K. (2017). "Liquid Impingement Erosion[1]". Friction, Lubrication, and Wear Technology. pp. 302–312. doi:10.31399/asm.hb.v18.a0006378. ISBN 978-1-62708-192-4.
  3. ^ Ibrahim and Medraj (2022). "Prediction and experimental evaluation of the threshold velocity in water droplet erosion". Materials & Design. 213. Elsevier: 110312. doi:10.1016/j.matdes.2021.110312.
  4. ^ Elhadi Ibrahim, Mohamed; Medraj, Mamoun (2019). "Water Droplet Erosion of Wind Turbine Blades: Mechanics, Testing, Modeling and Future Perspectives". Materials. 13 (1): 157. Bibcode:2019Mate...13..157E. doi:10.3390/ma13010157. PMC 6982018. PMID 31906204.