A dosage hybrid inspection system includes a plurality of cameras selectively installed in sides of a rotating plate and a counter-rotating plate configured to vacuum suction a dosage along a circumference thereof. The cameras include a first camera unit including one or more camera arranged in the side of the rotating plate to photograph a top surface of a tablet when a bottom surface of the tablet is suctioned to the rotating plate, a second camera unit including a plurality of cameras arranged in the side of the rotating plate to photograph a portion of a circumferential surface of the tablet when the bottom surface of the tablet is suctioned to the rotating plate, a third camera unit including one or more camera arranged in the side of the counter-rotating plate to photograph the bottom surface of the tablet when the top surface of the tablet is suctioned to the counter-rotating plate, a fourth camera unit including a plurality of cameras arranged in the side of the counter-rotating plate to photograph another portion of the circumferential surface of the tablet when the top surface of the tablet is suctioned to the counter-rotating plate, wherein one or more camera of the second and fourth camera units is configured to photograph both edges of a capsule when a side surface of the capsule is suctioned to the rotating plate, and one or more camera of the first and third camera units is configured to photograph a circumferential surface of the capsule, and fifth and sixth camera units including a plurality of cameras further provided in the sides of the rotating plate and the counter-rotating plate to photograph another portion of the circumferential surface of the capsule which has not been photographed by the first and third camera units.

This invention discloses a system and method for detecting a cover with an abnormal condition. The system includes a transport track for defining a sliding direction of at least one cover with a detection surface. The transport track has a detection area and a cover removal area, and includes a pair of bottom rails and a pair of side rails. The pair of bottom rails support the cover at an inclination angle so that the cover slides on the pair of bottom rails. The cover is located between the pair of side rails, and the sliding direction of the cover is defined by the pair of side rails. The detection area is used for detecting the detection surface of the cover, and the cover removal area has an outlet for removing a cover with an abnormal condition determined based on a detection result of the detection surface thereof.

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.

Embodiments of the present disclosure address problems presented by contaminants, such as dirt and debris, by providing an optical apparatus with techniques and methodologies for self-cleaning. In that regard, embodiments of the present disclosure employ techniques and methodologies for maintaining a very thin (e.g., few microns thick) layer of liquid, such as a non-stick liquid, on an optical window of an optical body that shields or protects an optical device.

Provided is a can inner surface-coating apparatus with which inspection of bottomed cylinders can be favorably performed in parallel without being affected by the coating process. In the can inner surface-coating apparatus, inspection cameras to be used for inspection following coating of the inner surface of a bottomed cylinder that will become the body of a can or bottle-shaped can are disposed above spray devices that are used for coating the inner surface of bottomed cylinders. Moreover, the coating area including the spray devices and the inspection area including the inspection cameras are covered with a cover. By supplying air inside the cover from the upper part (air supply port) of the inspection area and discharging the air out of the cover from the lower part (coating mist collection duct) of the coating area, an air flow is formed from the upper part of the inspection area to the lower part of the coating area.

A glass vial illumination and inspection system may be provided with a light source and a stand. The stand may have an internal cavity configured to receive at least a portion of the light source. A recess may be located in the stand and configured to receive at least a portion of a glass vial. The stand may be configured to aim the light output from the light source toward the glass vial to illuminate the vial. The stand may be configured to position the vial such that an inspector can manually inspect the illuminated vial for defects. Methods of use are also disclosed.

A distributed device for the detection of a substance is disclosed, comprising: a distributed optical excitation source (21) including a first optical fiber (22) having a plurality of extraction regions (24), each extraction region (24) being adapted to extract part of the light carried by the first optical fiber (22) from said fiber; and a distributed acoustic sensor (25) including a second optical fiber (26).

Embodiments of the present disclosure address problems presented by contaminants, such as dirt and debris, by providing an optical apparatus with techniques and methodologies for self-cleaning. In that regard, embodiments of the present disclosure employ techniques and methodologies for maintaining a very thin (e.g., few microns thick) layer of liquid, such as a non-stick liquid, on an optical window of an optical body that shields or protects an optical device.

The automatic inspection machine for containers and contents thereof, comprises a serial horizontal conveyor line of the containers oriented with a vertical axis through at least one inspection station comprising lighting means of the containers, at least one television camera for acquiring images of the illuminated containers, the lighting means comprising a first, a second and at least a third lighting device.

Systems, methods, devices, and apparatus for detecting sample defects in blood samples processed in automated processing systems are described herein. One aspect describes an automated blood sample processing apparatus having a pre-analytic specimen integrity monitoring device. Another aspect describes devices, systems, and methods for identifying blood components and properties in blood samples. Further aspects relate to systems and methods for setting reference ranges for sample defects and interference in blood samples. Additionally, devices, systems, and methods for identifying defective samples are described.