Abstract

Abstract. There has been a substantial growth in the wind energy power capacity worldwide, and icing difficulties have been encountered in cold climate locations. Rotor blade icing has been recognized as an issue, and solutions to mitigate accretion effects have been identified. Wind turbines are adapting helicopter rotor and propeller ice protection approaches to reduce aerodynamic performance degradation related to ice formation. Electro-thermal heating is one of the main technologies used to protect rotors from ice accretion, and it is one of the main technologies being considered to protect wind turbines. In this research, the design process required to develop an ice protection system for wind turbines is discussed. The design approach relies on modeling and experimental testing. Electro-thermal heater system testing was conducted at the Adverse Environment Rotor Test Stand at Penn State, where wind turbine representative airfoils protected with electro-thermal deicing were tested at representative centrifugal loads and flow speeds. The wind turbine sections tested were half-scale models of the 80 % span region of a generic 1.5 MW wind turbine blade. The icing cloud impact velocity was matched to that of a 1.5 MW wind turbine at full power production. Ice accretion modeling was performed to provide an initial estimate of the power density required to de-bond accreted ice at a set of icing conditions. Varying icing conditions were considered at −8 ∘C with liquid water contents of the cloud varying from 0.2 to 0.9 g/m3 and water droplets from 20 µm median volumetric diameter to 35 µm. Then, ice accretion thickness gradients along the span of the rotor blade for the icing conditions were collected experimentally. Given a pre-determined maximum power allocated for the deicing system, heating the entire blade was not possible. Heating zones were introduced along the span and the chord of the blade to provide the required power density needed to remove the accreted ice. The heating sequence for the zones started at the tip of the blade, to allow de-bonded ice to shed off along the span of the rotor blade. The continuity of the accreted ice along the blade span means that when using a portioned heating zone, ice could de-bond over that specific zone, but the ice formation could remain attached cohesively as it is connected to the ice on the adjacent inboard zone. To prevent such cohesive retention of de-bonded ice sections, the research determined the minimum ice thickness required to shed the accreted ice mass with the given amount of power availability. The experimentally determined minimum ice thickness for the varying types of ice accreted creates sufficient tensile forces due to centrifugal loads to break the cohesive ice forces between two adjacent heating zones. The experimental data were critical in the design of a time sequence controller that allows consecutive deicing of heating zones along the span of the wind turbine blade. Based on the experimental and modeling efforts, deicing a representative 1.5 MW wind turbine with a 100 kW power allocation required four sections along the blade span, with each heater section covering 17.8 % span and delivering a 2.48 W/in.2 (0.385 W/cm2) power density.

Highlights

  • Conventional energy like coal, natural gas and oil has gradually become a source of concern due to its environmental impacts

  • The liquid water content (LWC) and median volumetric diameter (MVD) affect the thickness of the ice shape, while temperature and droplet impact velocity affect the surface roughness and adhesion strength of the ice

  • Icing scaling laws modify the ice accretion time, the water droplet size, the liquid water content of the cloud and the environment temperature to ensure matching ice shapes. The applicability of these scaling laws to rotor blades was experimentally demonstrated by Palacios et al (2012) in the Adverse Environment Rotor Test Stand (AERTS) chamber

Read more

Summary

Introduction

Conventional energy like coal, natural gas and oil has gradually become a source of concern due to its environmental impacts. The LWC and MVD affect the thickness of the ice shape, while temperature and droplet impact velocity affect the surface roughness and adhesion strength of the ice. Icing envelopes for wind turbine regions have not been officially established. Icing conditions on wind turbines have led to research in various anti-icing and deicing ice protection systems (IPSs). For anti-icing systems requires about 5 times more energy to operate, rendering it too expensive for wind turbines. In addition to electrothermal deicing, the aviation industry has used active ice protection systems and is working on developing passive techniques. The conducted research relies on experimental data obtained for an electro-thermal deicing IPS to determine heater zones and required ice accretion times to promote ice shedding with assistance of centrifugal loads which must overcome cohesive forces between the accreted ice in adjacent heater zones

Objectives
Facility overview
Blade configuration
Testing methodology
Other assumptions
Deicing IPS design overview
Ice accretion thickness
Minimum ice thickness for shedding – ice cohesion prevention
Power density variation
Controller design
Findings
Conclusions and future work

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.