Provided is an apparatus for processing containers and in particular for reshaping plastic preforms into plastic containers, including a transport device which transports the containers along a predetermined transport path, wherein this transport device has a movable support, on which a plurality of processing stations are arranged, which in each case are suitable and intended for processing the plastic preforms, with a clean room, which surrounds at least portions of the transport path of the plastic preforms and which is delimited by at least one wall relative to the environment. Further, the apparatus has at least one inspection device for inspecting the containers, wherein this inspection device has an image capturing device, wherein this image capturing device is arranged at least partially outside the clean room and monitors at least one region of the containers through at least one wall of the clean room.

A method can include: irradiating a container with a measuring beam of an irradiation device at measurement points along a measurement direction, wherein a signal indicative of the wall thickness of the container at each measurement point is obtained by means of an optical detector, wherein by means of an evaluation device, the measurement points are compared with a reference curve that specifies the wall thickness of a reference container along the measurement direction, wherein if the comparison results in agreement between the measurement points and the reference curve it is determined that the wall thickness of the container corresponds to a predefined wall thickness and wherein if the comparison does not result in said agreement it is determined that the wall thickness of the container does not correspond to the predefined wall thickness.

A method and a system are disclosed for detecting the features of a water layer in layered enclosures of single unit dose products. Thanks to the method and the system of the invention, the layered enclosures may be manufactured to higher specifications and quality owing to real time control of the features of the water layer between the enclosure layers. The technical advantage of the method of the invention consists in the possibility to detect the features after formation of the layered enclosure is complete—hence inspecting the finished product—and to feed back the detected information to the very water laying device for a real time adjustment of the features of the water layer at the areas where acceptance criteria are not met.

The purpose of the present invention is to increase accuracy of a specific test using an electronic microscope and improve work efficiency. Provided is a system that identifies test recipe information corresponding to an object to be tested on the basis of attribute information about a testing sample, and analyzes and evaluates the object to be tested contained in the testing sample by checking image data and element analysis data that are acquired by a measuring device in accordance with a control program for the test recipe information, against reference image data and reference element analysis data that are used as evaluation references for the object to be tested.

A method for an automatic inspection of a plurality of plate-like plastic carriers, whereby each plastic carrier is closed by a cover and has a unique identification code and a culture medium. A storage container including a multiplicity of plastic carriers is provided, and a computer-controlled handling unit including an optical inspection system is provided. While performing the automatic inspection in an inspection routine, a plastic carrier is removed from the storage container with the aid of the handling unit, the cover of the plastic carrier is subsequently removed, the plastic carrier is supplied to the inspection system, the identification code is read, and at least one image of the plastic carrier, including the surface of the culture solution is recorded. The image is evaluated for a growth of germs and/or faults in the plastic carrier and the result of the evaluation is stored for each plastic carrier.

The invention provides a method and a near infrared indexer for recycling plastic objects. The method includes illuminating the plastic objects with a light source for detecting the presence, obtaining spectra in the near infrared region in respect of each of the plastic objects detected, comparing the obtained spectra with a database having spectra of known plastic types and sorting the plastic objects based on the comparison obtained. The accuracy of sorting of the plastic objects is above 95%. The method utilizes near infrared range of 600 nm-1000 nm. The indexer includes a first optical chamber. A second optical chamber is coupled to the first optical chamber. A sorting arrangement having an exit chamber is positioned proximal to the second optical chamber. The exit chamber is provided with a first collection chute and a second collection chute.

An apparatus (1) for the inspection of parisons (2) comprises: an inspection zone (10), configured to receive an unordered plurality of parisons (2); an illuminator (3), configured to emit a beam of light directed at the plurality of parisons (2); a detector (4) comprising a camera (41) configured to capture an image of the plurality of parisons (2), wherein the inspection zone is interposed between the illuminator (3) and the detector (4); a control unit (5) configured to process the image captured by the camera (41) to derive an item of diagnostic information regarding the defectiveness of one or more parisons (2) of the plurality of parisons (2), wherein the illuminator (3) includes an emission-polarizing filter (32) and the detector (4) includes a receiving polarizing filter (42).

An apparatus (1) for inspecting an object, where the object is made up of a first layer of plastic material and a second layer of EVO or EVOH and has a base wall (A) and a side wall (B) which is inclined relative to the base wall (A), comprises: an inspection zone (10) in which the object can be placed for inspection; a conveyor (12) for feeding the object to the inspection zone (10) along a feed plane (P); an imaging device (14) configured to view the object positioned in the inspection zone (10) and to generate an image (143) of the object; a processor (151), configured to process the image (143), to inspect the second layer. The conveyor (12) is configured to dispose the object in the inspection zone (10) with the base wall (A) positioned according to a predetermined orientation relative to the feed plane (P).

An apparatus (1) and a method for optical inspection of parisons (2) made of thermoplastic material comprises: a conveyor (3) comprising a pair of lateral, under-flange guides 31A for holding each parison by its flange, and configured to transport the parisons (2) in succession along an inspection path; an inspection station (41, 42, 43, 51, 52), located along the inspection path and including at least one inspection camera (410, 411, 412, 413, 421, 431, 510, 511, 520, 521, 522), configured to capture image data of a parison (2) positioned in the inspection station (41, 42, 43, 51, 52), wherein the conveyor (3) has a first operating configuration for transporting parisons (2) of a first size and a second operating configuration for transporting parisons (2) of a second size, different from the first size, the conveyor (3) including at least one adjustment actuator (7), configured to move the conveyor (3) between the first and the second operating configuration.

Disclosed is a method analysing plastic preforms, wherein plastic preforms are transported along a predetermined transport path by a transport device and an infrared absorption coefficient is determined in at least one region of the plastic preform, wherein, in order to determine the infrared absorption coefficient of the plastic preform, infrared radiation is applied to the plastic preform by a first radiation device and radiation passing through the plastic preform is received by at least one receiving device and an infrared absorption behaviour of the plastic preform is determined from this received radiation, wherein the radiation device acts upon the plastic preforms with infrared radiation in a predetermined wavelength range and an evaluation device evaluates the radiation as a function of its wavelength in a wavelength range from 1500 nm to 2000 nm.