Multi-Robot Coverage Path Planning for the Inspection of Offshore Wind Farms: A Review

Author:

Foster Ashley J. I.1ORCID,Gianni Mario2ORCID,Aly Amir1ORCID,Samani Hooman3ORCID,Sharma Sanjay1ORCID

Affiliation:

1. School of Engineering, Computing and Mathematics, Faculty of Science and Engineering, University of Plymouth, Plymouth PL4 8AA, UK

2. School of Electrical Engineering, Electronics and Computer Science, University of Liverpool, Liverpool L69 3BX, UK

3. Creative Computing Institute, University of the Arts London, London SE5 8UF, UK

Abstract

Offshore wind turbine (OWT) inspection research is receiving increasing interest as the sector grows worldwide. Wind farms are far from emergency services and experience extreme weather and winds. This hazardous environment lends itself to unmanned approaches, reducing human exposure to risk. Increasing automation in inspections can reduce human effort and financial costs. Despite the benefits, research on automating inspection is sparse. This work proposes that OWT inspection can be described as a multi-robot coverage path planning problem. Reviews of multi-robot coverage exist, but to the best of our knowledge, none captures the domain-specific aspects of an OWT inspection. In this paper, we present a review on the current state of the art of multi-robot coverage to identify gaps in research relating to coverage for OWT inspection. To perform a qualitative study, the PICo (population, intervention, and context) framework was used. The retrieved works are analysed according to three aspects of coverage approaches: environmental modelling, decision making, and coordination. Based on the reviewed studies and the conducted analysis, candidate approaches are proposed for the structural coverage of an OWT. Future research should involve the adaptation of voxel-based ray-tracing pose generation to UAVs and exploration, applying semantic labels to tasks to facilitate heterogeneous coverage and semantic online task decomposition to identify the coverage target during the run time.

Funder

EPSRC DTP (ORE) at the University of Plymouth

Publisher

MDPI AG

Subject

Artificial Intelligence,Computer Science Applications,Aerospace Engineering,Information Systems,Control and Systems Engineering

Reference83 articles.

1. UKRI (2023, November 13). Harnessing Offshore Wind. Available online: https://www.ukri.org/news-and-events/responding-to-climate-change/topical-stories/harnessing-offshore-wind/.

2. (2023, November 13). GWEC Global Offshore Wind Report 2022. Available online: https://gwec.net/wp-content/uploads/2022/06/GWEC-Global-Offshore-Wind-Report-2022.pdf.

3. Onshore versus offshore wind power trends and recent study practices in modeling of wind turbines’ life-cycle impact assessments;Desalegn;Clean. Eng. Technol.,2023

4. ORE Catapult (2023, November 13). Offshore Wind Operations & Maintenance: A £9bn per Year Opportunity by 2030 for the UK to Seize. Available online: https://ore.catapult.org.uk/?orecatapultreports=offshore-wind-operations-maintenance-9bn-year-opportunity-2030-uk-seize.

5. Fenstermaker (2023, November 13). Wind Turbine Drone Inspections. Available online: https://blog.fenstermaker.com/wind-turbine-drone-inspections/.

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