A non-contact non-destructive testing method includes spatially and/or temporally controlling a laser excitation light based on a predetermined pattern. The laser excitation light is projected onto a surface of a test object to generate acoustic waves on the test object. The acoustic waves apply stress loading to the test object. The method also includes imaging the test object with and without stress loading using shearography imaging, and analyzing shearography imaging data to determine a presence of a defect in the test object.

Systems and methods include a computer-implemented method for providing a photonic sensing system to perform an automated method to characterize displacement of equipment surfaces and monitor changes in real-time. A three-dimensional (3D) point cloud of one or more objects is generated by an analysis and presentation system using light information collected through structured light illumination by an array of structured-light sensors (SLSes) directed toward the one or more objects. Generating the point cloud includes defining points of the 3D point cloud that are relative to reference points on the one or more objects. Real-time contactless 3D surface measurements of the one or more objects are performed using the 3D point cloud. Changes in one or more parts of the one or more objects are determined by the an analysis and presentation system by analyzing the real-time contactless 3D surface measurements.

A compact displacement sensor comprises a light intensity pattern object, a micro-lens array and an imaging device including a light-intensity measuring surface. The micro-lens array is disposed between the light intensity pattern object and the imaging device such that each micro-lens focuses a corresponding sub-image making up a portion of the light-intensity pattern on the light-intensity measuring surface to create thereupon an image of the object comprising an array of focused sub-images. The displacement sensor can provide high resolution measurements of displacement of the light intensity pattern object from a reference position by registering subsequent images captured after a change in relative position between light intensity pattern object and the imaging device to a reference image based on pattern portions in the focused sub-images.

An example system for in-situ inspection of a composite structure includes a surface-strain imaging apparatus and a controller. The surface-strain imaging apparatus is configured to image an area of an outer surface of the composite structure while a temperature of the composite structure warms to thermal equilibrium with a surrounding environment and a temperature gradient exists within the composite structure. The controller includes a processor and a memory, and is configured to detect, using data received from the surface-strain imaging apparatus, an out-of-plane displacement of the outer surface in the area caused by the temperature gradient. The controller is also configured to determine that the out-of-plane displacement satisfies a threshold condition and, based on determining that the out-of-plane displacement satisfies the threshold condition, flag the area of the outer surface for further inspection.

A method for fitting contact lenses. More specifically, methods of fitting scleral or corneo-scleral lenses utilizing data or patterns observed on a corneal topography examination to improve the fit of scleral lenses or corneo-scleral lenses. The method may use quadrant specific fitting set lenses or regular toricity in unusual portions of the lens to define which patients may most benefit from such lenses.

The invention relates to an overhead conveyor system (1a . . . 1d) with hanging bags (2, 2a . . . 2d), which are adjustable between a transport position and a loading position and which are designed for transporting articles (4, 4a . . . 4i), with a loading station (5a . . . 5d), at which a hanging bag (2, 2a . . . 2d) can be loaded with an article (4, 4a . . . 4i), and with an overhead conveying device (6, 6a . . . 6d) for transporting a hanging bag (2, 2a . . . 2d) into the loading station (5a . . . 5d) and for transporting the hanging bag (2, 2a . . . 2d) out of the loading station (5a . . . 5d). The overhead conveyor system (1a . . . 1d) further comprises a measuring device (11a . . . 11d), by means of which an expansion (a) of the bag body (3) in a transport direction of the loaded hanging bag (2, 2a . . . 2d) is determined in the transport position of the bag body (3). Moreover, the invention relates to a method for operating such an overhead conveyor system (1a . . . 1d).

A pallet is housed while being supported from below by a pair of shelf-side support surfaces. The shelf-side support surfaces extend in a second direction and are separate from each other in a first direction by a predetermined separation distance. A pallet inspection device includes a first lift member, a second lift member, a raising and lowering mechanism, and an inspection unit. The first lift member has a first support surface. The second lift member has a second support surface. The first support surface and the second support surface extend in a width direction and are separate from each other in a transportation direction by a predetermined setting distance. The setting distance corresponds to the separation distance between the pair of shelf-side support surfaces. The inspection unit inspects the pallet for bending while the first support surface and the second support surface are at a projecting position.

A sensing apparatus includes a base substrate; a plurality of sensing units on the base substrate, a respective one of the plurality of sensing units including a first component configured to emit light and a second component configured to detect light; and an elastic layer on a side of the plurality of sensing units distal to the base substrate and configured to undergo a deformation upon a touch, at least a portion of light emitted from the first component being reflected by a surface of the elastic layer. The second component is configured to detect light reflected by the surface of the elastic layer and output a sensing signal, an intensity of which being correlated to a degree of the deformation of the elastic layer at a local position.

A method for calculating an earth pressure load on a tunnel includes the following steps: (1) taking interaction between external soil and a tunnel structure in an actual operation condition as an earth pressure load acting on the tunnel structure; (2) establishing a physical model for the tunnel structure; (3) designing, on the basis of the physical model for the tunnel structure, a plurality of structural loads in different operation conditions to obtain a plurality of different structural deformations; and (4) drawing an inference according Betti's theorem, and establishing a physical model for an original structure, such that a load on the original structure, namely an earth pressure load on the tunnel, can be directly calculated according to a load-deformation relationship of the physical model and deformation of the original structure. The above method can determine distribution and size of an actual earth pressure load on a tunnel.

An example system for in-situ inspection of a composite structure includes a surface-strain imaging apparatus and a controller. The surface-strain imaging apparatus is configured to image an area of an outer surface of the composite structure while a temperature of the composite structure warms to thermal equilibrium with a surrounding environment and a temperature gradient exists within the composite structure. The controller includes a processor and a memory, and is configured to detect, using data received from the surface-strain imaging apparatus, an out-of-plane displacement of the outer surface in the area caused by the temperature gradient. The controller is also configured to determine that the out-of-plane displacement satisfies a threshold condition and, based on determining that the out-of-plane displacement satisfies the threshold condition, flag the area of the outer surface for further inspection.