Abstract: An optical surface roughness measurement-enabling arrangement and method are disclosed for enabling measurement of the surface roughness of a material. The arrangement comprises an optical radiation source for generating a beam of collimated radiation along a first axis for illuminating the surface of the material with the radiation directed along the first axis, a refractive optical element optically alignable with the beam of radiation for refracting the beam along a second axis which is non-parallel with the first axis, for illuminating the surface of the material with the radiation directed along the second axis and a detector which is arranged to detect the radiation, incident upon the surface along the first axis and second axis, which becomes reflected off the surface of the material. An optical surface roughness measuring arrangement and method are also disclosed for providing a measurement value of the surface roughness.

Abstract: An optical surface roughness measurement-enabling arrangement and method are disclosed for enabling measurement of the surface roughness of a material. The arrangement comprises an optical radiation source for generating a beam of collimated radiation along a first axis for illuminating the surface of the material with the radiation directed along the first axis, a refractive optical element optically alignable with the beam of radiation for refracting the beam along a second axis which is non-parallel with the first axis, for illuminating the surface of the material with the radiation directed along the second axis and a detector which is arranged to detect the radiation, incident upon the surface along the first axis and second axis, which becomes reflected off the surface of the material. An optical surface roughness measuring arrangement and method are also disclosed for providing a measurement value of the surface roughness.

Abstract: A method of detecting defects in a welded metal structure, comprising mounting an ultrasonic transducer at or adjacent to a weld seam, and emitting ultrasonic signals so that the signals are propagated in the weld seam acting as a wave guide, and detecting reflections of the signals that may be indicative of defects in or adjacent to the weld seam. Waveguiding occurs within the weld principally because it is thicker than the plate, and thus the phase velocity in the plate is greater than that in the weld. This results in total internal reflection within the weld. In addition, an evanescent wave propagates in a region adjacent to the weld. The common problem with non destructive testing of excitation and reception of unwanted modes is greatly reduced, since it has been found that for certain frequency regions, transmitted waves will propagate only in a single mode at a predetermined frequency. As preferred the fundamental symmetric Lamb wave mode S0 is employed.

Abstract: Improved fabricated adhesive microstructures and methods of fabricating adhesive microstructures incorporating deformable materials are provided. The fabricated adhesive microstructures exhibit significantly improved adhesion strengths at least at smooth surfaces such as glass, as compared to known fabricated adhesive microstructures. The adhesion strengths of fabricated microstructures of the invention for a range of smooth glass contact surfaces may be in the range of between about 125 kPa and 220 kPa in air at one atmosphere pressure and in the range of between about 25 kPa and 120 kPa in vacuum. Synthetic elastomers are used in the invention. A method of fabricating new adhesive microstructures having multiple levels of compliance with a surface has been proposed. Methods of fabricating new double-sided adhesive microstructures via moulding have further been proposed.

Abstract: A method of detecting defects in a welded metal structure, comprising mounting an ultrasonic transducer at or adjacent to a weld seam, and emitting ultrasonic signals so that the signals are propagated in the weld seam acting as a wave guide, and detecting reflections of the signals that may be indicative of defects in or adjacent to the weld seam. Waveguiding occurs within the weld principally because it is thicker than the plate, and thus the phase velocity in the plate is greater than that in the weld. This results in total internal reflection within the weld. In addition, an evanescent wave propagates in a region adjacent to the weld. The common problem with non destructive testing of excitation and reception of unwanted modes is greatly reduced, since it has been found that for certain frequency regions, transmitted waves will propagate only in a single mode at a predetermined frequency. As preferred the fundamental symmetric Lamb wave mode S0 is employed.