A method and device detect defects in the closure of encapsulated vials. The method includes scanning a profile of the capsule and of the vial using a profilometer, thus obtaining a point cloud. From the point cloud obtained, calculating at least one of the following parameters: diameter or radius of the closure circumference of the capsule; angle of intersection between the lower skirt and the side of the capsule; length of the lower skirt; and/or a distance from the end of the lower skirt to the neck of the vial. The method determines whether any of the parameters calculated in the previous step exceeds a predetermined value. The device detecting defects in the closure of encapsulated vials includes a profilometer configured to scan a profile of the capsule and of the vial and a control device configured to execute the method.

A continuous quality control device for containers in a roto-revolutionary movement consists of making said containers pass in front of lighting means, capturing by at least one single sequential image capturing device each of said containers in rotation, obtaining an optical reconstruction of said containers and controlling their quality according to said optical reconstruction, characterised in that said lighting means is equipped with stroboscopic control means that allows the illumination of said containers in counterphase from at least two different angles of incidence and the capturing of at least two overlapping images in the same angular rotation position of said container in its own housing with respect to said image capturing device.

An inspection device calibration method includes mounting a laser-operated calibration device to a calibration fixture including an adjustable target having alignment indicia; illuminating the adjustable target with laser light from the calibration device; adjusting the adjustable target to operatively align the alignment indicia with the laser light; removing the calibration device from the calibration fixture; mounting to the calibration fixture, an inspection device including one or more adjustable features; and operating the optical inspection device, including adjusting the inspection device to operatively align the inspection device with the adjustable target.

A method and device detect defects in the closure of encapsulated vials. The method includes scanning a profile of the capsule and of the vial using a profilometer, thus obtaining a point cloud. From the point cloud obtained, calculating at least one of the following parameters: diameter or radius of the closure circumference of the capsule; angle of intersection between the lower skirt and the side of the capsule; length of the lower skirt; and/or a distance from the end of the lower skirt to the neck of the vial. The method determines whether any of the parameters calculated in the previous step exceeds a predetermined value. The device detecting defects in the closure of encapsulated vials includes a profilometer configured to scan a profile of the capsule and of the vial and a control device configured to execute the method.

Implementations disclose methods and devices for closure control of containers. A method includes performing, by an inspection apparatus, optical 3D measuring of a closed container, the closed container comprising a closure coupled to the container; generating, by the inspection apparatus, 3D data based on the optical 3D measuring; and processing, by an evaluation device, the 3D data to determine at least one of tightness or correct seating of the closure relative to the container.

An inspection line comprises: at a finish inspection station, a finish inspection installation capable of detecting without contact, by light rays, check-type defects in the neck of the containers; at a base inspection station, a base inspection installation capable of detecting without contact, by light rays, check-type defects in the base of the containers; and at a radiographic measuring station, a radiographic installation for automatically measuring linear dimensions of at least one region to be inspected of containers. The three installations are each arranged at stations distinct from each other along a trajectory of displacement of the containers. In each installation, a section of the transport device ensures, in the inspection area of the installation, the transport of the containers along a rectilinear portion of the trajectory (T) in a horizontal conveying plane (Pc) perpendicular to the central axis of the containers.

A method for inspecting containers with closures with a cap portion and a circumferential edge extending around the mouth of the containers. The containers are transported along a transport path by a transport device. During transport, the mouth regions of the containers with closures are illuminated by an illumination device, and at least one image recording device records at least one image of the mouth regions of the containers with closures, and records at least one spatially resolved image of a portion of the circumferential edge and one structure on the circumferential edge is detected, and, at least one value of this structure, a value characteristic of a relative position of the closure relative to the container and/or relative to the rotationally symmetrical element and/or of the closure is determined.

Methods and systems for detecting and monitoring defects in a sealing region of a container, including imaging at least part of the sealing region of the container using a camera operative at a wavelength in the range of about 0.76 m-14 m; during and/or after the filling of the container with a filling material and prior to sealing of the container being completed; and identifying, based on at least one frame obtained from the imaging, defects in the sealing region.

A continuous quality control device for containers in a roto-revolutionary movement consists of making said containers pass in front of lighting means, capturing by at least one single sequential image capturing device each of said containers in rotation, obtaining an optical reconstruction of said containers and controlling their quality according to said optical reconstruction, characterised in that said lighting means is equipped with stroboscopic control means that allows the illumination of said containers in counterphase from at least two different angles of incidence and the capturing of at least two overlapping images in the same angular rotation position of said container in its own housing with respect to said image capturing device.

An inspection device includes: an irradiator that radiates, before content is placed into the pocket, ultraviolet light toward one face of the container film; imaging devices that take images of the container film from another face side of the container film; and a processor that determines, based on the images, whether the pocket includes a pinhole, at least two of the imaging devices being each disposed on respective sides of the container film in a width direction such that the pocket is placed between the two imaging devices, and while the container film is being conveyed along a conveyance path, the two imaging devices take images of the pocket at a timing when the pocket is located at an upstream-side position, a middle-side position, and a downstream-side position of the conveyance path.