A method for monitoring the compliance of a container having a substantially cylindrical shape includes: rotating the container about its longitudinal axis; illuminating the rotating container with a first light source having a first wavelength, thereby generating a first image representative of any incohesive particles that may be present on an inner and/or outer surface of the container; illuminating the rotating container with a second light source having a second wavelength, thereby generating a second image representative of any defects on the surface of the container; acquiring the first image by means of a first acquisition device; acquiring the second image by means of a second acquisition device; comparing the first image and the second image with reference parameters, and notifying any defects of the container as a function of the comparison; wherein the first light source has a different wavelength than the second light source.

A method of gas cylinder interior cleanliness validation, including placing a volume of liquid on an interior surface of a component of a gas cylinder, measuring a contact angle of the liquid on the interior surface, and estimating from the contact angle the cleanliness of the interior surface with respect to at least one contaminant.

An inspection device (1) includes a light source (10) projecting excitation light to an inner surface of a container (20); an imager (11) capturing a fluorescence image of fluorescence emitted from a foreign substance in response to the excitation light projected; and a detector (13) detecting the foreign substance adhering to the inner surface of the container from the fluorescence image captured by the imager. The foreign substance contains a material emitting fluorescence in response to the excitation light projected to the material. The detector includes a calculator (14) calculating an average brightness value in an inspection target region, and an adjuster (15) adjusting an image-capturing condition where the fluorescence image is captured such that the average brightness value falls within a preset range.

An intermediate data set can be generated based on an image of a set of objects, where each of the set of objects includes a plastic. A predicted chemometric property can be generated by inputting the intermediate data set to a machine-learning model. The chemometric property can be of a physical output pyrolysis oil produced by performing a pyrolysis processing of the set of objects using a pyrolysis reactor. A result associated with the set of objects can be generated, where the result is based on or includes the predicted chemometric property.

A particle detection system includes a light source configured to emit a light beam into a cylindrical glass article when the cylindrical glass article is imaged by the glass particle detection system. The light beam is directed along a beam propagation axis that is perpendicular to a longitudinal axis of the cylindrical glass article. The particle detection system further includes a first polarizer positioned between the light source and the cylindrical glass, a camera configured to capture an image of the light beam reflected from the cylindrical glass article, and an analyzer positioned between the cylindrical glass article and the camera. An optical axis of the camera is perpendicular to the beam propagation axis of the light source.

Inspection of distribution and morphology of a substance applied to a container includes selectively illuminating at least a portion of a surface of a container using a light source, adjusting the light source to create a resolved view of the substance with sufficient contrast to show a layer of the lubricant disposed on the surface of the container, obtaining an image of the resolved view of the illuminated portion of the surface of the container using an image detector, analyzing image data representing the image of the resolved view, using a data processor, to generate a quantity representing a quality of interaction between the lubricant and the surface of the container, and determining whether the container is acceptable based upon the quantity generated.

An optical inspection method for containers. A container is at least partly illuminated or transilluminated with light of an illuminating device and captured from different viewing directions (R4-R6) as a camera image in each case by at least one camera. In a first image analysis step, first image information of a first inspection zone (A) of the container, for example a stain on a container front face, is ascertained from at least two of the camera images by stereoscopically pairing image points. In a second image analysis step, an individual camera image of the two camera images is analyzed, wherein the first image information is first excluded and second image information of a second inspection zone (B) of the container, for example a crack of a container rear face, is then ascertained.

Medical syringe barrels having the inner surface coated with cured silicone oil are used for calibration and detection of silicone oil in medical syringe barrels. Calibration standards as provided in this invention allow for quick determination how well a lubrication system for lubricating medical syringe barrels with silicone oil is working.

An automated visual inspection system for detecting the presence of particulate matter includes an empty, flexible container, a light source, a detector, and an image processor. The light source is configured to transmit light through the container towards the detector, and the detector is configured to receive the light and generate image data. The image processor is configured to analyze the image data, determine whether the empty, flexible container is defective, and generate a rejection signal if the empty, flexible container is defective.

An inspection system for detecting a particle in a transparent cylinder having a longitudinal axis and a diameter includes a light source able to illuminate a transparent cylinder, a mask able to block at least part of the light coming from the light source, the light source and the mask being arranged such that, when the transparent cylinder is positioned in the system for inspection, the light source, the mask and the transparent cylinder are substantially aligned along an inspection axis perpendicular to the longitudinal axis of said transparent cylinder and the mask is interposed between the light source and the transparent cylinder so as to prevent illumination of a first portion of the transparent cylinder having a width smaller than the diameter of the transparent cylinder while allowing illumination of a second portion of the transparent cylinder, the mask being configured to provide a contrast with a particle present in the first portion of the transparent cylinder and illuminated by light refracted by the second portion of the transparent cylinder.