際際滷

際際滷Share a Scribd company logo

Wind Blade Damage1

Martin Herl淡v
Martin Herl淡v

This case study examines lightning damage to a wind turbine blade at a wind farm in south central Texas. The lightning strike caused internal damage that led to the blade's failure. The lightning temperatures and expansion of internal moisture in the blade from the strike likely overstressed the blade materials. Improved lightning protection system design and reducing interior blade moisture are recommended.

Convert to study materialsBETA

Transform any presentation into ready-made study materialselect from outputs like summaries, definitions, and practice questions.

1 of 6
Downloaded 15 times
Case Study of Lightning Damage to Wind Turbine Blade by Richard Kithil, Founder & CEO National Lightning Safety Institute (NLSI) www.lightningsafety.com June 2008 1.0 Summary We examine a lightning event at a wind farm in south central Texas USA. The region has an approximate flash density of five to six strikes per sq. km. per year. Over a three-year period, about five percent of wind turbines at this facility have experienced some lightning damage to blades. Figure 1: Characteristic lightning signature to blade tip Lightning to Blade No. 4608 at Turbine No. 155 was the proximate cause of its subsequent failure. The National Lightning Detection Network at 08:30.36 on March 6, 2008 reported a 10kA strike in close proximity to the location of this turbine. Subsequent events are described. Our conclusions are based upon May 7-8, 2008 site observations, known lightning behavior, code references and studies by others. 1
2.0 Review of Lightning Physics Tall towers may launch upwards lightning. Not withstanding its stochastic behavior, most lightning leaders seek out elevated grounded objects and impose electric fields upon them. These objects may respond with upwards streamers. When leaders and streamers connect, a high-energy electric circuit (flash) is completed. In addition to electrical and magnetic properties, lightning contains X-Rays, light, an acoustic shock wave (thunder), which can approach some 10 atmospheres and heat where temperatures approach 55,000 F. Each flash may contain, on average, three to four strokes some 50 ms apart. The known consequences of lightning to wind turbine components are well described in the literature. Lightning current Relevant component Effect Endangered parameter of the lightning strike Components =================================================================== peak current I first impulse current potential rise of the nacelle & wind power plant, power plant voltage drop across building, cable shields SCADA -------------------------------------------------------------------------------------------------------------------- specific energy first impulse current electromechanics, blades and W/R heating, bearings evaporation stressed by I -------------------------------------------------------------------------------------------------------------------- charge Q long duration currents, melting blades and first impulse current bearings -------------------------------------------------------------------------------------------------------------------- average current subsequent and super- magnetic SCADA steepness I/T1 imposed impulse currents induction -------------------------------------------------------------------------------------------------------------------- number of subsequent and super- repeated H-field SCADA impulse currents n imposed impulse currents impulses Table 1: Lightning Effects to Components of Wind Turbines (Ref. 7.1) Investigations into effects of thermal expansion of internal blade moisture was considered in this study. Ohmic heating to water vapor can cause a 2.1 X 10-4 increase in unit volume per degree Centigrade. This topic is further described in section 5.0, below. 3.0 Composition of the Turbine Blade with Lightning Protection 3.1 Construction of these 1.5MW turbine generator blades are fibreglas epoxy resin with an exterior gel coat. The blade interior structure is spar-reinforced with rigid polyurethane foam encased in fiberglass. Further interior strength is via sandwich sheets of urethane/fibreglas/urethane/fibreglas in built-up layers. It is not within the scope of this study to examine the cellular nature, sheer strength or 2
other physical characteristics of urethane foam. However, crude experiments at the wind farm showed water was absorbed into urethane samples. 3.2 Lightning protection consists of several exterior copper receptor air termination discs, which are fastened to interior aluminum conductors running the length of the blade. Conductors are fastened to the blade and to one another with steel bolts. Near the blade root a portion of the conductor is imbedded into the fibreglas. The conductor transitions from the blade root area via bonding to the hub and thence to a ground reference. Other components of the lightning protection systems were examined briefly. The manufacturer provided satisfactory surge protection for sensitive electronics. Grounding requirements were completed per manufacturers specifications by the installation contractor. Figure 2: Damaged blade showing internal spars and lightning conductors 3
4.0 Codes and Standards Compliance 4.1 Compliance with information contained in NFPA-780 Standard for the Installation of Lightning Protection Systems, v. 2008. 4.1.1 Section 4.5 - Aluminum is acceptable in place of copper as a conductor. 4.1.2 Section 4.5.3 - An aluminum conductor shall not be installed in a location subject to excessive moisture. The presence of moisture promotes corrosion on aluminum. 4.1.3 Section 4.10.2 - No combination of materials shall be used that will form an electrolytic couple of such a nature that, in the presence of moisture, corrosion will be accelerated. The aluminum conductors are secured to the blade using steel bolts. Steel is not compatible with aluminum. Copper receptors are fastened to the aluminum conductor. Copper is not compatible with aluminum. Aluminum is the anode. Steel and copper are the cathodes. 4.2 Compliance with IEC 61400-24 (2008), Wind Turbine Generator Systems, Lightning Protection. This document is in draft document stage and has not been distributed in final form. It was not consulted for this study. 5.0 Problem of Moisture Inside Blades 5.1 Condensation processes are dependant upon humidity, pressure and temperature. Changes in ambient conditions create differentials in water vapor pressure from outside-to-inside materials. Water vapor can condense on blade interior surfaces. Polyurethane foams used as structural spars and as honeycombed sandwich layers between fibreglas sheets may have varying degrees of absorption and permeability. 5.2 Moisture penetrating different locations of the blade interior may cause imbalances. 5.3 Moisture can penetrate blades via previous structural cracking or as a result of surface damage caused from previous lightnings. 5.4 Blade repairs that result in surface porosity may lead to future water ingress. 5.5 The combination of lightnings high temperatures (50,000 F) and residual internal moisture can lead to energetic events where accumulated moisture suddenly is phased into steam pressure expansion. Consequential damage can be some or all of: de-lamination; burst bonding; residue compromise; trailing edge cracking; detached blade pieces; de-bonding; longitudinal cracks; spar separation; fires due to presence of hydraulic fluids/lubricants; or partial or complete blade destruction. 4
5.6 Wind turbine blade failures create expensive repairs and loss of electric power production. Figure 3: Removal of damaged blade root by crane 6.0 Conclusion The lightning conductor did not conduct as designed. Lightning created an internal shock wave from air or moisture expansion, or both. Lightning temperatures may have caused interior moisture to transition to an expansive state (steam). In turn, over-pressures stressed the blade to subsequent failure. Further research into wind turbine blade interior air/moisture expansion issues is needed. 7.0 References 7.1 Wiesinger J: 1996, Lightning Protection of Wind Power Plants, Proc., ICLP, Florence Italy, Sept 1996. 7.2 Breakdown Tests of Glass Fibre Reinforced Polymers (GFRP) as a Part of Improved Lightning Protection of Wind Turbine Blades: Madsen, S.F., et al, Sept 2004, Electrical Insulation 2004, Conference Record of the 2004 IEEE International Symposium on. Available as ISBN 0-7803-8447-4. 5
7.2 Lightning Strike Protection for Composite Structures: Ginger Gardiner, Composites World, July 2006. On the web at: www.compositesworld.com/hpc/issues/2006/July/1366/3. 7.3 GE Energy Maintenance Manual, 06 1.5 Serie_OM_allComp_PartC_blades.ENxx.00.doc , section 6.3.1 External Inspection, pp 25-32. 7.4 Economic Benefits of Scheduled Rotor Maintenance: Kanaby, G., AWEA Windpower 2006. On the web at: www.kcwind.com/rotor_maintenance.aspx. 7.5 Physics of Lightning Flash & Its Effects: Thottappilli, R., 161st CSO Meeting, 15-16 March 2006. 7.6 NFPA-780 (2008), Standard for the Installation of Lightning Protection Systems, NFPA Quincy MA. 6

More Related Content

Wind Blade Damage1

  • 1. Case Study of Lightning Damage to Wind Turbine Blade by Richard Kithil, Founder & CEO National Lightning Safety Institute (NLSI) www.lightningsafety.com June 2008 1.0 Summary We examine a lightning event at a wind farm in south central Texas USA. The region has an approximate flash density of five to six strikes per sq. km. per year. Over a three-year period, about five percent of wind turbines at this facility have experienced some lightning damage to blades. Figure 1: Characteristic lightning signature to blade tip Lightning to Blade No. 4608 at Turbine No. 155 was the proximate cause of its subsequent failure. The National Lightning Detection Network at 08:30.36 on March 6, 2008 reported a 10kA strike in close proximity to the location of this turbine. Subsequent events are described. Our conclusions are based upon May 7-8, 2008 site observations, known lightning behavior, code references and studies by others. 1
  • 2. 2.0 Review of Lightning Physics Tall towers may launch upwards lightning. Not withstanding its stochastic behavior, most lightning leaders seek out elevated grounded objects and impose electric fields upon them. These objects may respond with upwards streamers. When leaders and streamers connect, a high-energy electric circuit (flash) is completed. In addition to electrical and magnetic properties, lightning contains X-Rays, light, an acoustic shock wave (thunder), which can approach some 10 atmospheres and heat where temperatures approach 55,000 F. Each flash may contain, on average, three to four strokes some 50 ms apart. The known consequences of lightning to wind turbine components are well described in the literature. Lightning current Relevant component Effect Endangered parameter of the lightning strike Components =================================================================== peak current I first impulse current potential rise of the nacelle & wind power plant, power plant voltage drop across building, cable shields SCADA -------------------------------------------------------------------------------------------------------------------- specific energy first impulse current electromechanics, blades and W/R heating, bearings evaporation stressed by I -------------------------------------------------------------------------------------------------------------------- charge Q long duration currents, melting blades and first impulse current bearings -------------------------------------------------------------------------------------------------------------------- average current subsequent and super- magnetic SCADA steepness I/T1 imposed impulse currents induction -------------------------------------------------------------------------------------------------------------------- number of subsequent and super- repeated H-field SCADA impulse currents n imposed impulse currents impulses Table 1: Lightning Effects to Components of Wind Turbines (Ref. 7.1) Investigations into effects of thermal expansion of internal blade moisture was considered in this study. Ohmic heating to water vapor can cause a 2.1 X 10-4 increase in unit volume per degree Centigrade. This topic is further described in section 5.0, below. 3.0 Composition of the Turbine Blade with Lightning Protection 3.1 Construction of these 1.5MW turbine generator blades are fibreglas epoxy resin with an exterior gel coat. The blade interior structure is spar-reinforced with rigid polyurethane foam encased in fiberglass. Further interior strength is via sandwich sheets of urethane/fibreglas/urethane/fibreglas in built-up layers. It is not within the scope of this study to examine the cellular nature, sheer strength or 2
  • 3. other physical characteristics of urethane foam. However, crude experiments at the wind farm showed water was absorbed into urethane samples. 3.2 Lightning protection consists of several exterior copper receptor air termination discs, which are fastened to interior aluminum conductors running the length of the blade. Conductors are fastened to the blade and to one another with steel bolts. Near the blade root a portion of the conductor is imbedded into the fibreglas. The conductor transitions from the blade root area via bonding to the hub and thence to a ground reference. Other components of the lightning protection systems were examined briefly. The manufacturer provided satisfactory surge protection for sensitive electronics. Grounding requirements were completed per manufacturers specifications by the installation contractor. Figure 2: Damaged blade showing internal spars and lightning conductors 3
  • 4. 4.0 Codes and Standards Compliance 4.1 Compliance with information contained in NFPA-780 Standard for the Installation of Lightning Protection Systems, v. 2008. 4.1.1 Section 4.5 - Aluminum is acceptable in place of copper as a conductor. 4.1.2 Section 4.5.3 - An aluminum conductor shall not be installed in a location subject to excessive moisture. The presence of moisture promotes corrosion on aluminum. 4.1.3 Section 4.10.2 - No combination of materials shall be used that will form an electrolytic couple of such a nature that, in the presence of moisture, corrosion will be accelerated. The aluminum conductors are secured to the blade using steel bolts. Steel is not compatible with aluminum. Copper receptors are fastened to the aluminum conductor. Copper is not compatible with aluminum. Aluminum is the anode. Steel and copper are the cathodes. 4.2 Compliance with IEC 61400-24 (2008), Wind Turbine Generator Systems, Lightning Protection. This document is in draft document stage and has not been distributed in final form. It was not consulted for this study. 5.0 Problem of Moisture Inside Blades 5.1 Condensation processes are dependant upon humidity, pressure and temperature. Changes in ambient conditions create differentials in water vapor pressure from outside-to-inside materials. Water vapor can condense on blade interior surfaces. Polyurethane foams used as structural spars and as honeycombed sandwich layers between fibreglas sheets may have varying degrees of absorption and permeability. 5.2 Moisture penetrating different locations of the blade interior may cause imbalances. 5.3 Moisture can penetrate blades via previous structural cracking or as a result of surface damage caused from previous lightnings. 5.4 Blade repairs that result in surface porosity may lead to future water ingress. 5.5 The combination of lightnings high temperatures (50,000 F) and residual internal moisture can lead to energetic events where accumulated moisture suddenly is phased into steam pressure expansion. Consequential damage can be some or all of: de-lamination; burst bonding; residue compromise; trailing edge cracking; detached blade pieces; de-bonding; longitudinal cracks; spar separation; fires due to presence of hydraulic fluids/lubricants; or partial or complete blade destruction. 4
  • 5. 5.6 Wind turbine blade failures create expensive repairs and loss of electric power production. Figure 3: Removal of damaged blade root by crane 6.0 Conclusion The lightning conductor did not conduct as designed. Lightning created an internal shock wave from air or moisture expansion, or both. Lightning temperatures may have caused interior moisture to transition to an expansive state (steam). In turn, over-pressures stressed the blade to subsequent failure. Further research into wind turbine blade interior air/moisture expansion issues is needed. 7.0 References 7.1 Wiesinger J: 1996, Lightning Protection of Wind Power Plants, Proc., ICLP, Florence Italy, Sept 1996. 7.2 Breakdown Tests of Glass Fibre Reinforced Polymers (GFRP) as a Part of Improved Lightning Protection of Wind Turbine Blades: Madsen, S.F., et al, Sept 2004, Electrical Insulation 2004, Conference Record of the 2004 IEEE International Symposium on. Available as ISBN 0-7803-8447-4. 5
  • 6. 7.2 Lightning Strike Protection for Composite Structures: Ginger Gardiner, Composites World, July 2006. On the web at: www.compositesworld.com/hpc/issues/2006/July/1366/3. 7.3 GE Energy Maintenance Manual, 06 1.5 Serie_OM_allComp_PartC_blades.ENxx.00.doc , section 6.3.1 External Inspection, pp 25-32. 7.4 Economic Benefits of Scheduled Rotor Maintenance: Kanaby, G., AWEA Windpower 2006. On the web at: www.kcwind.com/rotor_maintenance.aspx. 7.5 Physics of Lightning Flash & Its Effects: Thottappilli, R., 161st CSO Meeting, 15-16 March 2006. 7.6 NFPA-780 (2008), Standard for the Installation of Lightning Protection Systems, NFPA Quincy MA. 6