Abstract: Provided is a method for transporting a component of a wind turbine to a storing position, wherein the component is mounted on a transport frame, including providing a transport arrangement including at least two elongate, height-adjustable, self-propelled transporter units, positioning the transport frame with the component mounted thereon onto the transport arrangement such that the self-propelled transporter units are spaced apart by a predefined lateral distance from each other, using the transport arrangement, rolling the component to a storing position where at least one support device has been positioned, such that at least a part of the at least one support device is located between a pair of the self-propelled transporter units, lowering the self-propelled transporter units such that the transport frame comes to rest on the at least one support device, and removing the transport arrangement from under the supported transport frame.

Abstract: A mobile lifting apparatus is provided for lifting an, in particular flat, transport frame on which a component of a wind turbine is mounted, in particular for removing or placing at least one self-propelled modular transporter below the transport frame, the lifting apparatus including: an upper part having an interface for connecting to a transport frame to be lifted, a lower part for supporting the lifting apparatus on the ground, and a lifting mechanism connecting the lower part to the upper part for linearly vertically moving the upper.

Abstract: Provided is a method for transporting a component of a wind turbine to a storing position, wherein the component is mounted on a transport frame, including providing a transport arrangement including at least two elongate, height-adjustable, self-propelled transporter units, positioning the transport frame with the component mounted thereon onto the transport arrangement such that the self-propelled transporter units are spaced apart by a predefined lateral distance from each other, using the transport arrangement, rolling the component to a storing position where at least one support device has been positioned, such that at least a part of the at least one support device is located between a pair of the self-propelled transporter units, lowering the self-propelled transporter units such that the transport frame comes to rest on the at least one support device, and removing the transport arrangement from under the supported transport frame.

Abstract: Provided is a support structure for a wind turbine blade and a method for manufacturing a support structure for a wind turbine blade The support structure includes a frame structure including a first section and a second section which are spaced apart with respect to each other along a first direction such that a section of a wind turbine blade is arrangeable in-between the first section and the second section. The support structure further includes two seesaw elements being pivotably fixed to a respective section and having a respective pivoting axis parallel to the first direction and four belt elements being fixed with their respective first end to a respective end of the respective seesaw element Furthermore, a respective second end of the respective belt element are each fixed to the respective other section of the frame structure.

Abstract: Provided is a support structure for a wind turbine blade and a method for manufacturing a support structure for a wind turbine blade The support structure includes a frame structure including a first section and a second section which are spaced apart with respect to each other along a first direction such that a section of a wind turbine blade is arrangeable in-between the first section and the second section.

Abstract: Provided are methods and systems for generating nanoparticles from an inorganic precursor compound using a hydrothermal process within at least one CSTR or PFR maintained at an elevated temperature and an elevated pressure and a treatment vessel in which this reaction solution can be applied to one or more catalyst substrates. In operation, the reaction solution may be maintained within the CSTR at a substantially constant concentration and within a reaction temperature range for a reaction period sufficient to obtain nanoparticles having a desired average particle size of, for example, less than 10 nm formation and/or deposition. Variations of the basic method and system can provide, for example, the generation of complex particle size distribution profiles, the selective deposition of a multi-modal particle size distribution on a single substrate.

Abstract: A method for mitigating stress corrosion cracking of a component exposed to a high temperature water in a high temperature water system is provided. The method comprises the steps of lowering corrosion potential conditions to a desired low corrosion potential in the high temperature water environment; and introducing a first material comprising zinc into the high temperature water environment, such that the desired low corrosion potential facilitates transport of the first material into cracks in a structure communicative with the high temperature water environment.

Abstract: A method for mitigating crack initiation and propagation on a surface of a metal component due to susceptibility to corrosion comprises depositing a metallic material on the surface of the component to form a coating, and then converting at least an outer layer of the coating to an electrically insulating material. The deposition of the metallic material is carried out by a method selected from the group consisting of wire-arc spraying, physical vapor deposition, and chemical vapor deposition. Electrochemical corrosion potential less than ?0.23 VSHE based on the standard hydrogen electrode can be achieved with the method of coating of the present invention. This method is applied to produce coated structural components of water-cooled nuclear reactor.

Abstract: The invention relates to a method for determining the spatial concentration of the various components of a mixture, in particular of a gas mixture in a combustion chamber, of a motor for example; a laser beam is hereby directed into the combustion chamber; the laser beam brings the particles of the mixture to radiate, whereas this light of the particles is passed backward through a masked lens and is imaged on a display as a radiating surface and the radial intensity distribution is recorded by an array photodetector, whereas the spatial concentration of individual components of the particle mixture may be measured from the radial intensity distribution.

Abstract: The method for splitting and reflecting beams in a laser scanning microscope which produces a laser beam (1) comprises the steps of: reflecting a beam from a partially reflecting mirror (2); splitting the laser beam (1) with a splitting device into partial beams (5); causing the partial beams to travel in a plane; directing the partial beams to a sample under investigation; providing the partially reflecting mirror (2) with a constant transmission; placing the partially reflecting mirror between two high reflectivity mirrors (3,4); transmitting the laser beam (1) to one of the high reflectivity mirrors (3); reflecting said beam (1) to the other one of the high reflectivity mirrors (4) with basically equal attenuation; repeatedly transmitting the beam to one of the mirrors; and repeatedly reflecting the beam to the other one of said mirrors (4); arranging the partially reflecting mirror and the high reflectivity mirrors (3,4) relative to each other to cause beams (5) reflected by the partially reflecting mirro

Abstract: Method and apparatus for contactless locally resolved instantaneous measurement of the density and/or temperature of a gas in a measurement volume which can have a relatively large area and a relatively small thickness, wherein by laser radiation two rotational transitions of a molecular constituent of the gas excitation in which the excited state has a life time which is substantially shorter than the reciprocal collision frequency in the gas, and wherein the fluorescence intensity or absorption corresponding to the two rotational transitions is measured. From the measured intensities the density and temperature can be calculated.