Acoustic emission monitoring of a wind turbine blade during a fatigue test

Beattie, A.G.

doi:10.2514/6.1997-958

Cited by 49 publications

(43 citation statements)

References 1 publication

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“…Additional applications of standard and non-standard NDT and NDE techniques to wind turbine components, in both laboratory and field environments, have been explored [209,210,214,215].…”

Section: Nondestructive Testingmentioning

confidence: 99%

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On the Fatigue Analysis of Wind Turbines

Sutherland¹

1999

168

146

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“…Additional applications of standard and non-standard NDT and NDE techniques to wind turbine components, in both laboratory and field environments, have been explored [209,210,214,215].…”

Section: Nondestructive Testingmentioning

confidence: 99%

“…General descriptions of techniques and applications exist in the literature [206,207]. A well as applications of these techniques to wind turbines [208][209][210].…”

Section: Nondestructive Testingmentioning

confidence: 99%

On the Fatigue Analysis of Wind Turbines

Sutherland¹

1999

168

146

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“…At this stage, it is believed that the technique could benefit blade development and manufacturing, as well as inspection and maintenance. Future experiments will develop upon the testing procedures shown, as well as introducing other aspects such as acoustic emissions (AE) monitoring, which has been receiving a lot of attention from research groups experimenting in the wind turbine field recently, [11][12][13]. What has been demonstrated generally is that AE is capable of giving early indication of some damage in a composite structure, with potentially some indication of the type of damage incurred.…”

Section: Discussionmentioning

confidence: 99%

Non-Destructive Evaluation of Damage Mechanisms in Composite Sandwich Structure

Puri

Fergusson

Palmer

et al. 2008

AMM

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This paper presents the experimental results obtained of flexurally loaded wind turbine blade cross section material. All material was extracted from a wind turbine blade box girder and testing was conducted in four point configuration. The aim was to gain an understanding of the structural integrity of this lightweight material as it deforms in flexure. To allow for thorough analysis, digital image correlation (DIC) was used to produce full field strain maps of the deforming specimens. Results highlight the capability of the DIC technique to identify regions of failure, as well as the aspects responsible for them. Overall, the results present a foundation for tests on larger substructure, and eventually integration into manufacturing and maintenance aspects of the industry.

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“…8 Although this is not standard practice at NREL, SNL is often invited to join tests if it is of mutual benefit to the laboratories and the blade client. Sensors placed along the blade measured high frequency emissions that may be related to incipient blade damage during the test.…”

Section: Acoustic Emissionsmentioning

confidence: 99%

Comprehensive testing of NedWind 12-meter wind turbine blades at NREL

Larwood

Musiał

2000

2000 ASME Wind Energy Symposium

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This paper describes the structural testing of two NedWind 25, 12-m blades at the National Renewable Energy Laboratory (NREL). The tests were conducted under the Standards, Measurement and Testing (SMT) Program in conjunction with tests conducted by four European laboratories to develop a common database of blade testing methods. All of the laboratories tested duplicate copies of blades taken from series production. Blade properties, including weight, center of gravity, natural frequencies, and damping were determined. Static load tests were performed at 110% of the extreme design load for strain verification. NREL performed single-axis and two-axis fatigue tests using "businessas-usual" testing practices.The single-axis test combined equivalent life loading for the edge and flap spectra into a single resultant load. The two-axis test applied the edge and flap components independently at a phase angle of 90°. Damage areas were observed at (1) the trailing edge, which cracked near the maximum chord; (2) between the steel root collar and the composite, where circumferential cracking was noted; and (3) along the top of the spar between the 2500-mm and 4200-mm stations, where a notable increase in acoustic emissions was detected. NREL observed that the onset of visible damage occurred earlier in the single-axis test.

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Acoustic emission monitoring of a wind turbine blade during a fatigue test

Cited by 49 publications

References 1 publication

On the Fatigue Analysis of Wind Turbines

On the Fatigue Analysis of Wind Turbines

Non-Destructive Evaluation of Damage Mechanisms in Composite Sandwich Structure

Comprehensive testing of NedWind 12-meter wind turbine blades at NREL

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