Using a Hybrid Cost-FMEA Analysis for Wind Turbine Reliability Analysis
Abstract
:1. Introduction
- -
- Average annual failure rates of wind turbines sub-systems;
- -
- Main cause of failure;
- -
- Expected failure costs;
- -
- Critical components of wind turbine system (criticality). Criticality is calculated as the total expected failure costs times the relative failure rate.
2. The Failure Mode and Effects Analysis (FMEA) Methodology
2.1. Introduction
2.2. State of the Art
2.3. Discussion: Criticality Assessment
- Windstats data of 7000 wind turbines, from Denmark and Germany [52];
- LWK data of 650 wind turbines, from Germany;
- WMEP data of 1500 wind turbines, from Germany [53];
- Vindstat (VPC) data of 80 wind turbines, from Sweden [54];
- VTT data of 105 wind turbines, from Finland [55];
- Former Garrad Hassan energy consultancy data collected from 14 GW wind farms [56].
- Failure modes;
- Failure causes;
- Failure consequences;
- Annual average failure rate
- Failure effects on sub-system and on global system
- Failure detection techniques.
3. Wind Turbine System Model
4. Failure Mode and Effects Analysis (FMEA) Results
4.1. Failure Distribution in Wind Turbine Sub-Systems
4.2. What Other Large Surveys in Europe Say
4.3. The Main Cause of Failure
4.4. Expected Failure Cost
4.5. Criticality of Sub-Systems
4.6. Gearbox—A Reliability Overview
4.7. Rotor-Blades Sub-System—A Reliability Overview
- Manufacturing issues (waving and overlaid laminates)
- Bad bonds
- Delamination
- Voids
- Leading edge erosion/trailing edge splits
- Scorching and split (due to lightning)
4.8. Failure Detection
4.9. Failure Effects
5. Conclusions
- Wear is the main and most common cause of failure in wind turbine systems. The system environment is the main reason for this issue. Wear can cause a variety of operational problems including misalignment and system vibrations. Abrasive and corrosive wear seem to be the most frequent wear type noticed, whereas fatigue influences more external components such as blades.
- Control and electric sub-systems have the highest failure rates in a wind energy system on the one hand. On the other hand, sub-systems such as gearboxes and rotor-blades have low failure rates, but cause high downtimes to the system.
- Expected failure costs were calculated for main wind turbine sub-systems. The study proved that gearboxes and rotor-blades are the critical sub-systems. A general overview of these sub-systems’ reliability was presented
- Failure detection techniques were presented. CMS is accurate to prevent failures and minimize downtimes in wind turbine system.
Acknowledgments
Author Contributions
Conflicts of Interest
Appendix A
Sub-System | Component | Failure Mode | Failure Causes | Failure Consequences | LWK Failure DATA | Failure Rate 134 Wind Turbines 1.5 MW | ISET Germany Failure DATA, 1500 WT aver 15 Years [9] | LWK Failure DATA, 5800 WT over 2 Years |
Gearbox | Toothed shaft | Fatigue & fracture | Irregular grooving/welding defect/non alignment | Shaft cracks/non alignment | 4% | 3.26% | 4% | 8% |
Lubricant system | Loss of function | Presence of water or debris in the system/aged oil/pump failure | Overheating/wear | |||||
Gears/gearing | accelerated wear/premature failure | Poor lubrication/presence of corrosive elements/presence of water in the lubricant oil/shocks | Damages in the system | |||||
Pipes | Leakage | Wear/excessive pressure in pipes | Loss of precision/Overheating | |||||
Blade –rotor | Blades | Fouling | Climate/snow/hail/dust/insects/environmental debris | Loss of aerodynamic properties/blades are not optimal for wind energy saving | 7% | 1% | 7% | 10% |
Hub | Fatigue/crack | Overload/delamination/extreme wind conditions/lightening | Crack evolution/rotor stop | 5% | 3.25% | 5% | 5% | |
Swedish Power Plants Failure DATA, over 4 Years | WMEP FAILURE DATA, 1435 WT Over 2 Years | Windstats Denmark Failure DATA | Windstats Germany Failure DATA | EPRI California Failure DATA, 290 WT Over 2 Years | Reliawind RELEX Failure DATA | Failure Effects on the Sub-System | Failure Effects on the System | Failure Detection Methods |
10% | 5% | 7% | 3% | 3% | 5% | Main shaft vibration/Generator vibration Noise/Gearbox life time reduction | Emergency stop activation | Vibration sensors/Oil & heat sensors |
13% | 12% | 8% | 6% | 7% | 1% | Vibration/crack evolution/crack evolution on rotor | Emergency stop activation | Blade sensors/vibration sensors in hub/emergency stop activation/ visual inspection in maintenance operations |
- | 2% | - | 3.20% | 3.40% | 1.9% | Visual inspection/rotor Sensors |
Sub-System | Failure Rate (N/year) [21,63] | Annual Reliability | Average Replacement Cost (€) (Including Crane + Labor) [66,67,68] | Average Downtime per Hours [63,64] | Average Cost of Loss of Production; Selling Tariff 0.082 (€/kWh) | Expected Cost of Failure (€) | Criticality (€/kWh) | ||
---|---|---|---|---|---|---|---|---|---|
2 MW | 3 MW | Average | |||||||
Structure | 0.09 | 0.913 | 682,386.00 | 97.00 | 4772.40 | 7158.60 | 5965.50 | 628,983.92 | 56,608.55 |
Gearbox | 0.1 | 0.904 | 528,253.33 | 260.50 | 12,816.60 | 19,224.90 | 16,020.75 | 493,561.76 | 49,356.18 |
Rotor-blades | 0.17 | 0.843 | 305,873.33 | 146.53 | 7209.44 | 10,814.16 | 9011.80 | 266,863.02 | 45,366.71 |
Main shaft | 0.05 | 0.951 | 199,170.00 | 181.77 | 8942.92 | 13,414.38 | 11,178.65 | 200,589.32 | 10,029.47 |
Generator | 0.1 | 0.904 | 189,908.00 | 126.13 | 6205.76 | 9308.64 | 7757.20 | 179,434.03 | 17,943.40 |
Yaw system | 0.18 | 0.835 | 199,990.00 | 67.93 | 3342.32 | 5013.48 | 4177.90 | 171,169.55 | 30,810.52 |
Converter | 0.24 | 0.786 | 81,272.00 | 90.00 | 4428.00 | 6642.00 | 5535.00 | 69,414.79 | 16,659.55 |
Electrical system | 0.55 | 0.576 | 33,980.00 | 72.93 | 3588.32 | 5382.48 | 4485.40 | 24,057.88 | 13,231.83 |
Control system | 0.41 | 0.663 | 28,388.00 | 55.20 | 2715.84 | 4073.76 | 3394.80 | 22,216.04 | 9108.58 |
Hydraulic system | 0.23 | 0.794 | 23,300.00 | 41.47 | 2040.16 | 3060.24 | 2550.20 | 21,050.40 | 4841.59 |
Mechanical Brake | 0.13 | 0.878 | 8560.00 | 65.60 | 3227.52 | 4841.28 | 4034.40 | 11,550.08 | 1504.51 |
Others | 0.11 | 0.895 | 5000.00 | 105.60 | 5195.52 | 7793.28 | 6494.40 | 10,969.40 | 1206.63 |
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Methodology | Phases of Project | Nature of Results | Subjective/Objective | Data | Accuracy | ||
---|---|---|---|---|---|---|---|
Qualitative | Quantitative | Hybrid | |||||
Probabilistic risk assessment (PRA) [17,18] | 1-2-3-7 | √ | - | √ | Subjective | Less detailed | Low |
Checklists [19] | 1-2-3-4-5-6-7 | √ | - | √ | Subjective | Less detailed | Low |
What if [11,14] | 1-3-4-5-6-7 | √ | - | √ | Subjective | Less detailed | Low |
HAZOP [20] | 3-4-5-6-7 | √ | - | √ | Subjective | Less detailed | Low |
Fault tree analysis (FTA) [21,22] | 1-2-3-4-5-6-7 | √ | √ | √ | Objective | More detailed | High |
FMEA [23,24,25] | 1-2-3-4-5-6-7 | √ | √ | √ | Objective | More detailed | High |
Petri-nets [26,27] | 2-3 (if used with another method) | √ | - | √ | Subjective | Less detailed | Low |
Cause-consequence analysis (CCA) [28] | 4-5-6-7 | √ | √ | - | Objective | More detailed | Low |
Criticality | Component Downtime | Failure Rate | Failure Probability of Occurrence | Cost Consequence of a Failure | Fault Detection Possibility | Severity Rating Scale | Occurrence Rating Scale | Detection Rating Scale | RPN | CPN |
---|---|---|---|---|---|---|---|---|---|---|
[36] | √ | - | - | - | - | - | - | - | √ | - |
[23] | - | - | √ | √ | √ | - | - | - | - | Based on failure costs consequences and probabilities of failure |
[24] | - | - | √ | √ | √ | - | - | - | - | Based on cost of failures and number of failures |
[37,38,39,40,46,47,48,49,50] | - | - | - | - | - | √ | √ | √ | √ | - |
[41,51] | - | - | - | - | - | Fuzzy approach | Fuzzy approach | Fuzzy approach | √ | - |
[42,43] | - | - | - | - | - | Expert approach | Expert approach | Expert approach | √ | - |
This study | √ | √ | - | √ | - | - | - | - | - | Based on component failure rates, its average downtimes and expected costs of failure |
Type of Generator | Turbine Concept | Gearbox/Gearless | Converter |
---|---|---|---|
Single cage induction generator (SCIG) | Fixed speed | Gearbox (multiple stage) | No |
Variable speed | Gearbox (multiple stage) | Yes (full scale) | |
Permanent magnet synchronous generator (PMSG) | Variable speed | Gearless | Yes (full scale) |
Variable speed | Gearbox (single or multiple stage) | Yes (full scale) | |
Doubly fed induction generator (DFIG) | Variable speed | Gearbox (multiple stage) | Yes (partial scale) |
Electrically exited synchronous generator (EESG) | Variable speed | Gearless | Yes (partial & full scale) |
Wound rotor induction generator (WRIG) | Limited variable speed | Gearbox (multiple stage) | Yes (partial scale) |
Brushless Doubly Fed Induction Generator (BDFIG) | variable speed | Gearbox (multiple stage) | Yes (partial scale) |
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Tazi, N.; Châtelet, E.; Bouzidi, Y. Using a Hybrid Cost-FMEA Analysis for Wind Turbine Reliability Analysis. Energies 2017, 10, 276. https://doi.org/10.3390/en10030276
Tazi N, Châtelet E, Bouzidi Y. Using a Hybrid Cost-FMEA Analysis for Wind Turbine Reliability Analysis. Energies. 2017; 10(3):276. https://doi.org/10.3390/en10030276
Chicago/Turabian StyleTazi, Nacef, Eric Châtelet, and Youcef Bouzidi. 2017. "Using a Hybrid Cost-FMEA Analysis for Wind Turbine Reliability Analysis" Energies 10, no. 3: 276. https://doi.org/10.3390/en10030276
APA StyleTazi, N., Châtelet, E., & Bouzidi, Y. (2017). Using a Hybrid Cost-FMEA Analysis for Wind Turbine Reliability Analysis. Energies, 10(3), 276. https://doi.org/10.3390/en10030276