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Drones in Wind Power Industry Global Market Outlook 2018-2027

Drones in Wind Power Industry Global Market Outlook 2018÷2027 - Single User

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Unique market report provides an incisive and reliable overview of drones (UAVs) in wind power industry for the period 2018 ÷ 2027...

Update: 1Q 2019
Format: 1 file(s) (PDF report) in English language and 1 file(s) with contacts of key industry vendors ready to import in your CRM software
Author: Drone Market WatchTM
Pages: 165
Report production №:
DMWIN38920181289
Subscription: In the report price is included subscription for 1 year period with 4 quarterly updates
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24 hours by e-mail with 100% Money Back Guarantee

  • This unique independent, 160+ page report of Drone Market Watch™ analyzes global market for drones (UAVs) application in the wind power industry regarding market dynamics, technology characteristics, industry structure, innovations and key industry vendors. Through extensive research and discussions with experts in the industry, Drone Market Watch™ has identified a series of market trends that will impact this market over the coming decade.
    Wind power industry is developing rapidly in the past decade and at the end of 2018 almost 382,310 wind turbines are operational at global level. This means more than 1,146,930 wind turbine blades are subject to physical wear out and need regular inspections throughout their lifespan. Drones (UAVs) provide regular inspection works of wind turbines and wind blades quicker, safer and cost efficient than traditional methods.
    Drones in Wind Power Industry Global Market Outlook 2018 ÷ 2027 is essential reading for you or anyone in with an interest in the rising application and role of drones (UAVs) in the wind power industry, explaining how this market will develop over the next ten years. Purchasing this report will aid your company’s ability to recognize important market opportunities and understand the possibilities for investment in this area. For your convenience we offer opportunity for orders with customized report content. Reasons to buy this market report are, but no limited to:
    • The potential of drones (UAVs) application in wind power industry by regions
    • Over 95 charts, maps, figures and tables
    • Contact details of over 50 key industry vendors ready то import in your CRM software
    • Historical market data provided from 1997 to 2018 and forecasts until 2027
    • Development scenario of the global drones (UAVs) market in wind power industry until 2027
    • Drone (UAV) unit cost and services cost in wind power industry 2018
    • Regulatory flight policies at global, regional and country level (44 countries) related to the use of drones (UAVs) in wind power industry
    • Expected revenue forecast from drone (UAV) sales and related services over the next 10 years (2018 – 2027)
    • SWOT Analysis
    • Market dynamics comprising main market drivers, restraints and challenges
    • Drone (UAV) vendors active in wind turbine inspection market (hardware manufacturers)
    • Drone (UAV) inspection services and solutions providers (hardware, optics, sensors, software)
    • Key technologies and innovations as main drivers of drones (UAVs) in wind power industry
    • Investment potential and opportunities

    At next pages you will see the full table of content of this report. To order this report just click on the button "ADD TO CART". Table of contents is referential and may vary upon report updates. If you have any other questions or data requests please do not hesitate to call us on ++44 203 60 80 138 or write an e-mail to orders@dronemarketwatch.com

  • FOREWORD 11
    1. METHODOLOGY 12
    1.1. Research Methodology 12
    1.2. Limitations 13
    2. EXECUTIVE SUMMARY 14
    2.1. Introduction 14
    2.2. Market Overview 14
    2.3. Market Forecast Summary 15
    3. MARKET DRIVERS 17
    3.1. Wind Turbines Inspection 17
    3.1.1. Wind Turbine Blade Inspection for Leading Edge Erosion 17
    3.1.2. Inspection of Wind Turbine Blade Lighting Receptor 18
    3.1.3. Wind Turbine Blade Wrinkling, Dry Fiber and De-bonding (Delamination) 20
    3.1.4. Tower and Nacelle Inspection 21
    3.1.5. Offshore Wind Turbine Inspection Challenges 22
    3.1.6. Inspection in Construction Phase of Wind Farms 22
    3.2. Environmental Impact Assessment of Wind Farms 23
    3.3. Feasibility Analyses, On-Site Wind Farm Evaluations and Technical Due Diligence 24
    3.4. Surveillance and Security of Wind Farms 24
    3.5. Global Wind Power Market Development. Current State and Development Perspectives to 2027 25
    3.6. DRONE (UAV) GLOBAL FLIGHT REGULATORY FRAMEWORK OVERVIEW 33
    3.6.1. ICAO REGULATIONS 33
    3.6.2. NORTH AMERICA 37
    3.6.2.1. USA 38
    3.6.2.2. Canada 41
    3.6.3. EUROPE 42
    3.6.3.1. EASA - European Level Regulations 43
    3.6.3.2. Austria 47
    3.6.3.3. Belgium 48
    3.6.3.4. Bulgaria 48
    3.6.3.5. Czech Republic 49
    3.6.3.6. Denmark 49
    3.6.3.7. France 50
    3.6.3.8. Germany 51
    3.6.3.9. Greece 52
    3.6.3.10. Hungary 53
    3.6.3.11. Ireland 53
    3.6.3.12. Italy 54
    3.6.3.13. Netherlands 54
    3.6.3.14. Poland 55
    3.6.3.15. Portugal 55
    3.6.3.16. Romania 56
    3.6.3.17. Russia 56
    3.6.3.18. Serbia 57
    3.6.3.19. Slovakia 57
    3.6.3.20. Spain 58
    3.6.3.21. Sweden 58
    3.6.3.22. Switzerland 59
    3.6.3.23. Turkey 61
    3.6.3.24. Ukraine 62
    3.6.3.25. United Kingdom 62
    3.6.4. ASIA - PACIFIC 64
    3.6.4.1. Australia 65
    3.6.4.2. China 66
    3.6.4.3. Hong Kong 67
    3.6.4.4. India 68
    3.6.4.5. Japan 69
    3.6.4.6. South Korea 71
    3.6.4.7. Thailand 71
    3.6.4.8. Taiwan 72
    3.6.5. LATIN AMERICA 72
    3.6.5.1. Brazil 73
    3.6.5.2. Chile 74
    3.6.5.3. Mexico 75
    3.6.6. MIDDLE EAST 75
    3.6.6.1. Egypt 76
    3.6.6.2. Israel 76
    3.6.6.3. Saudi Arabia 77
    3.6.6.4. United Arab Emirates (UAE) 78
    3.6.7. AFRICA 80
    3.6.7.1. Morocco 80
    3.6.7.2. South Africa 81
    4. MARKET ANALYSIS, TRENDS AND FORECASTS 84
    4.1. Drone (UAV) Unit Cost in Wind Power Industry 84
    4.1.1. Drone (UAV) Unit Cost for Wind Turbine Inspection 84
    4.1.2. Drone (UAV) Unit Cost for Environmental Impact Assessments of Wind Farms 85
    4.1.3. Drone (UAV) Unit Cost for Feasibility analyses, On-site Wind farm Evaluations and Technical Due Diligence 85
    4.1.4. Drone (UAV) Unit Cost for Surveillance and Security of Wind Farms 86
    4.2. Drone (UAV) Services Cost in Wind Power Industry 86
    4.2.1. Drone (UAV) Services Cost for Wind Turbine Inspections 86
    4.2.2. Drone (UAV) Services Cost for Environmental Impact Assessments of Wind Farms 87
    4.2.3. Drone (UAV) Services Cost for Feasibility analyses, On-site Wind farm Evaluations and Technical Due Diligence 87
    4.2.4. Drone (UAV) Services Cost for Surveillance and Security of Wind Farms 88
    4.3. Global Annual Wind Turbine Units Inspected by Drones (UAVs) 88
    4.4. Global Revenue of Drones (UAVs) in Wind Power Sector 91
    4.4.1. Global Cumulative Revenue by Segment and Region 92
    4.4.1.1. Wind Turbine Inspection 92
    4.4.1.2. Environmental Impact Assessment of Wind Farms 93
    4.4.1.3. Feasibility Analyses, On-Site Wind Farm Evaluation and Technical Due Diligence 94
    4.4.1.4. Surveillance and Security of Wind Farms 95
    4.4.2. Global Annual Revenue by Segment and Region 96
    4.4.2.1. Wind Turbine Inspection 97
    4.4.2.2. Environmental impact assessment of wind farms 97
    4.4.2.3. Feasibility Analyses, On-Site Wind Farm Evaluation and Technical Due Diligence 98
    4.4.2.4. Surveillance and security of wind farm 99
    5. DRONE (UAV) TECHNOLOGY OVERVIEW 101
    5.1. Brief Drone (UAV) Technology Overview 101
    5.2. Comprehensive Configuration of Drone (UAV) for Inspection of On-Shore and Off-Shore Wind Turbines and Other Associated Services 101
    5.3. Drone (UAV) Guidance, Navigation and Control Systems 103
    5.4. Photogrammetry and LiDAR 103
    5.5. Data Transmission and Data Acquisition 104
    5.6. Payload (Sensors and Optics) Selection for Inspection of Wind Blades and Lighting Receptor Testing 104
    5.7. Constraints for Use of Drones (UAVs) for Wind Turbine Inspection and Other Associated Services 106
    6. KEY INDUSTRY VENDORS COMPETITIVE LANDSCAPE 108
    6.1. Drone (UAV) Vendors Active in Wind Power Market (16 companies included) 108
    6.2. Drone (UAV) Inspection and Associated Services Providers (25 companies included) 113
    6.3. Other Providers of Drone (UAV) Services Related to Wind Power Industry (12 companies included) 121
    7. KEY INNOVATIONS 125
    7.1. Ultra-Light LiDAR systems for drone (UAV) applications 125
    7.2. Counter Drone (Anti-Drone) System Providers 128
    7.3. Top Drone (UAV) Startups and Funding 129
    8. DRONE (UAV) INTEGRATION WITH INTERNET OF THINGS (IOT) AND SMART CITIES 132
    8.1. Drone (UAV) in Wind Power Sector and Integration with Internet of Things (IOT) 132
    8.2. Drone (UAV) in Wind Power Sector and Integration with Smart Cities 134
    9. SWOT ANALYSIS OF DRONES (UAVs) IN WIND POWER INDUSTRY 136
    10. RISK ANALYSIS AND RISK MITIGATION 137
    10.1. Safety Risk and Hazard Risk 137
    10.1.1. Phase I – Safety Hazard Identification. Definition of Safety Hazards 139
    10.1.2. Phase II – Drone (UAV) Safety Risk Assessment 140
    10.1.3. Phase III – Drone (UAV) Safety Risk Mitigation 143
    10.1.4. Phase IV – Drone (UAV) Safety Documentation & Management 144
    10.2. Regulatory Risk 145
    10.3. Social Risk 146
    10.4. Hacker’s (Cyber) Attacks and Theft of Drones (UAVs) 146
    10.5. Insurance protection 148
    11. CONCLUSIONS 150
    12. RECOMMENDATIONS 154
    12.1. Recommendations for Owners and Asset Managers of Wind Farms 154
    12.2. Recommendations for Drone (UAV) Inspection Companies Targeting Wind Power Market 155
    13. LIST OF ABBREVIATIONS 157
    14. COMPANY DIRECTORY 162
    15. REFERENCES 166
    16. DISCLAIMER AND COPYRIGHT 169
  • MAP 1: World Lighting Flashes Map: 2018 9
    MAP 2: Restricted (No Fly) Drone (UAV) Zones in North America: 2018 37
    MAP 3: Restricted (No Fly) Drone (UAV) Zones in Europe: 2018 43
    MAP 4: Restricted (No Fly) Drone (UAV) Zones in Asia - Pacific: 2018 65
    MAP 5: Restricted (No Fly) Drone (UAV) Zones in Latin America: 2018 73
    MAP 6: Restricted (No Fly) Drone (UAV) Zones in South Africa: 2018 82

    Figure 1: Leading Edge Erosion of Wind Turbine Blade 18
    Figure 2: Wind Turbine Blade Damage by Lighting Strike 19
    Figure 3: Damage in wind rotor blade by adhesive failure 20
    Figure 4: Damage in wind rotor blade by debonding (delamination) of layers 21
    Figure 5: Lighting protection system of wind turbine and rotor blades 105

    Chart 1: Global Cumulative Wind Turbine Units Installed and Available for Inspection by Drones (UAVs): 2018 – 2027; Source: DRONE MARKET WATCH 15
    Chart 2: NYSE Bloomberg Wind Energy Index 2018 26
    Chart 3: World Total Installed Cumulative Wind Capacity 1997 – 2018   26
    Chart 4: World Total Installed Cumulative Offshore Capacity 2005 – 2018  28
    Chart 5: World New Installed Wind Capacity 1998 – 2018 29
    Chart 6: Top 10 Countries by Installed Cumulative Wind Capacity in 2018  30
    Chart 7: Shares in New Installed Wind Capacity by Continents (in % and in MW) in 2018  31
    Chart 8: World Cumulative Wind Power Installations in GW for 1997 - 2027, DRONE MARKET WATCH 32
    Chart 9: World Installed Renewable Energy Capacity by 2040 in GW4 33
    Chart 10: Global Annual Wind Turbine Units Installed and Available for Inspection by Drones (UAVs) by Region: 2018 – 2027 88
    Chart 11: Global Annual Wind Turbine Units Inspected by Drones (UAVs) by Region: 2018 – 2027 89
    Chart 12: Wind Turbine Cumulative Units Quantified by Country, North America: 2018 89
    Chart 13: Wind Turbine Cumulative Units Quantified by Country, Europe: 2018 90
    Chart 14: Wind Turbine Cumulative Units Quantified by Country, Asia – Pacific: 2018 91
    Chart 15: Global Cumulative Revenue of Drones (UAVs) in Wind Power Sector by Region (in Millions USD): 2018-2027 91
    Chart 16: Global Cumulative Revenue for Drone (UAV) Units and Services for Wind Turbine Inspection by Region (in Millions USD): 2018-2027 92
    Chart 17: Global Cumulative Revenue for Drone (UAV) Units and Services for Environmental Impact Assessment of Wind Farms by Region (in Millions USD): 2018-2027 93
    Chart 18: Global Cumulative Revenue for Drone (UAV) Units and Services for Feasibility Analyses, On-Site Wind Farm Evaluation and Technical Due Diligence by Region (in Millions USD): 2018-2027 94
    Chart 19: Global Cumulative Revenue for Drone (UAV) Units and Services for Surveillance and Security of Wind Farms by Region (in Millions USD): 2018-2027 95
    Chart 20: Global Annual Revenue of Drones (UAVs) in Wind Power Sector by Region (in Millions USD): 2018-2027 96
    Chart 21: Global Annual Revenue for Drone (UAV) Units and Services for Wind Turbine Inspection by Region (in Millions USD): 2018-2027 97
    Chart 22: Global Annual Revenue for Drone (UAV) Units and Services for Environmental Impact Assessment of Wind Farms by Region (in Millions USD): 2018-2027 98
    Chart 23: Global Annual Revenue for Drone (UAV) Units and Services for Feasibility Analyses, On-Site Wind Farm Evaluation and Technical Due Diligence by Region (in Millions USD): 2018-2027 99
    Chart 24: Global Annual Revenue for Drone (UAV) Units and Services for Surveillance and Security of Wind Farms by Region (in Millions USD): 2018-2027 100
    Chart 25: Drone (UAV) Investment Activity 2012 - 2018 131
    Chart 26: Drone (UAV) Safety Management Process 145

    Table 1: Flight classification of drone (UAV) types in USA 38
    Table 2: Flight classification of drone (UAV) types in Canada 41
    Table 3: Drone (UAV) Risk Categories: EASA 2015 46
    Table 4: Flight classification of drone (UAV) types in Austria 48
    Table 5: Flight classification of drone (UAV) types in Belgium 48
    Table 6: Flight classification of drone (UAV) types in Bulgaria 49
    Table 7: Flight classification of drone (UAV) types in Czech Republic 49
    Table 8: Flight classification of drone (UAV) types in Denmark 50
    Table 9: Flight classification of drone (UAV) types in France 51
    Table 10: Flight classification of drone (UAV) types in Germany 52
    Table 11: Flight classification of drone (UAV) types in Greece 53
    Table 12: Flight classification of drone (UAV) types in Hungary 53
    Table 13: Flight classification of drone (UAV) types in Ireland 54
    Table 14: Flight classification of drone (UAV) types in Italy 54
    Table 15: Flight classification of drone (UAV) types in Netherlands 55
    Table 16: Flight classification of drone (UAV) types in Poland 55
    Table 17: Flight classification of drone (UAV) types in Portugal 56
    Table 18: Flight classification of drone (UAV) types in Romania 56
    Table 19: Flight classification of drone (UAV) types in Russia 57
    Table 20: Flight classification of drone (UAV) types in Serbia 57
    Table 21: Flight classification of drone (UAV) types in Slovakia 58
    Table 22: Flight classification of drone (UAV) types in Spain 58
    Table 23: Flight classification of drone (UAV) types in Sweden 59
    Table 24: Flight classification of drone (UAV) types in Switzerland 61
    Table 25: Flight classification of drone (UAV) types in Turkey 62
    Table 26: Flight classification of drone (UAV) types in Ukraine 62
    Table 27: Flight classification of drone (UAV) types in the United Kingdom 64
    Table 28: Flight classification of drone (UAV) types in Australia 66
    Table 29: Flight classification of drone (UAV) types in China 67
    Table 30: Flight classification of drone (UAV) types in Hong Kong 68
    Table 31: Flight classification of drone (UAV) types in India 69
    Table 32: Flight classification of drone (UAV) types in Japan 70
    Table 33: Flight classification of drone (UAV) types in South Korea 71
    Table 34: Flight classification of drone (UAV) types in Thailand 72
    Table 35: Flight classification of drone (UAV) types in Taiwan 72
    Table 36: Flight classification of drone (UAV) types in Brazil 74
    Table 37: Flight classification of drone (UAV) types in Chile 75
    Table 38: Flight classification of drone (UAV) types in Mexico 75
    Table 39: Flight classification of drone (UAV) types in Egypt 76
    Table 40: Flight classification of drone (UAV) types in Israel 77
    Table 41: Flight classification of drone (UAV) types in Saudi Arabia 77
    Table 42: Flight classification of drone (UAV) types in United Arab Emirates (UAE) 78
    Table 43: Flight classification of drone (UAV) types in Morocco 80
    Table 44: Flight classification of drone (UAV) types in South Africa 81
    Table 45: Drone (UAV) Unit Cost for Wind Turbine Inspection in 2018 84
    Table 46: Drone (UAV) Unit Cost for Environmental Impact Assessment of Wind Farms in 2018 85
    Table 47: Drone (UAV) Unit Cost for Feasibility analyses, On-site Wind farm Evaluation and Technical Due Diligence in 2018 85
    Table 48: Drone (UAV) Unit Cost for Surveillance and Security of Wind Farms in 2018 86
    Table 49: Drone (UAV) Services Cost for Wind Turbine Inspection in 2018 86
    Table 50: Drone (UAV) Services Cost for Environmental Impact Assessment of Wind Farms in 2018 87
    Table 51: Drone (UAV) Services Cost for Feasibility analyses, On-site Wind farm Evaluation and Technical Due Diligence in 2018 87
    Table 52: Drone (UAV) Services Cost for Surveillance and Security of Wind Farms in 2018 88
    Table 53: Recommended Sensor Selection for Inspection in Wind Power Industry 106
    Table 54: Top 10 Early Stage Drone Startups 130
    Table 55: SWOT Analysis of Drones (UAVs) in Wind Power Industry 136
    Table 56: Phases of Drone (UAV) Safety Risk Assessment 138
    Table 57: Drone (UAV) Safety Risk Probability 140
    Table 58: Drone (UAV) Safety Risk Severity 141
    Table 59: Drone (UAV) Safety Risk Matrix I 142
    Table 60: Drone (UAV) Safety Risk Matrix II 142
    Table 61: Drone (UAV) Safety Risk Mitigation 143
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