An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

A conveyor system to convey objects is described, in which a conveyor belt moves while having a controlled speed to advance the objects, arranged in a row one after the other at a distance one from the other, toward a first rotating disc that rotates at a controlled speed in an independent manner from the speed of the conveyor belt and that has, on a perimeter thereof, a plurality of first cavities arranged mutually spaced apart angularly to receive the objects from the conveyor belt, a second rotating disc being arranged to receive the objects from the first rotating disc.

A retention and movement unit of at least one component and at least one container is described. The unit has a moving retention member including, in turn, a frame and a first gripping device with a first retention element, the gripping device having a first configuration for selectively retaining the at least one component by the first retention element. In a first alternative, the first gripping device has a second configuration, different from the first configuration, for selectively retaining the at least one container. In the second alternative, the moving retention member further includes a second gripping device, including a second retention element, the second gripping device having a second configuration, different from the first configuration, for selectively retaining said at least one container.

The present invention relates to a transport wheel arrangement for handling cylindrical bodies, comprising a base body (104), a negative pressure source which is intended to provide a negative pressure for holding the cylindrical bodies, a disc-shaped wheel body (102) which is rotatably mounted about its central axis (R1) on the base body (104), a drive device which is designed to set the wheel body (102) in rotary motion, at least one receiving assembly (112) for holding a cylindrical body, comprising a shaft (114) which receives a line (120) for conducting the negative pressure, a contact member (116) provided radially outside the shaft (114) which is designed to present a contact surface for a held cylindrical body, and a suction cup member (116) which is connected to the line (120) for conducting the negative pressure and is designed to hold a cylindrical body by means of this negative pressure; and a control unit which is designed to control the operation of the drive device and, if necessary, the vacuum source, wherein the transport wheel arrangement further comprises a displacement apparatus (122) which is designed to displace the contact element (116) and the suction cup element (118) of the receiving assembly (112) or at least one of the plurality of receiving assemblies (112) in a coordinated manner with respect to the wheel body (102).

A machine for automatically positioning objects is disclosed. The machine has one inlet conveyor to transport objects in a lying position; a detector system to identify the orientation and/or shape of the objects; a robotic collection device to collect and position the objects according to information received by the detector system; a transfer conveyor having transfer fasteners arranged in fixed positions along a periphery of the transfer conveyor defining a closed loop around a tilted axis; an outlet conveyor to receive and transport the objects in an upright position; and a transfer fastener seat for the objects at each transfer fastener. The conveyor moves the fasteners seats because of the movement of the transfer conveyor between an upper receiving position, in which the object is held in a lying position, and a lower delivery position, in which the object is held in an upright position. The transfer conveyor and the outlet conveyor are synchronized.

A method of supplying pouches intended for containing liquid, viscous, or granular products to a carousel includes the steps of: positioning pouches along a first zone that is part of a first feeding component for feeding the pouches to the carousel; moving the pouches in the first zone as far as the carousel; and picking up the pouches from the first zone via the carousel; The method further includes positioning pouches along a second zone that is part of a second feeding component for feeding the pouches to the carousel. The step of positioning pouches along the second zone occurs in part simultaneously with picking up the pouches from the first zone; moving the pouches located in the second zone as far as the carousel queuing the pouches behind the pouches located in the first zone; and picking up the pouches from the second zone via the carousel.

A system for conveying a substrate includes a noncontact support platform for supporting the substrate. A vacuum wheel is located adjacent to the support platform. A rim of the vacuum wheel includes perforations that open between an exterior of the rim and an interior of the vacuum wheel. A fixed suction surface is interior to the vacuum wheel and includes an opening of a conduit that is connectable to a suction source. A chamber is formed by the suction surface, walls of the vacuum wheel, and a section of the peripheral rim that is adjacent to the suction surface and that extends outward from the support platform. When suction is applied to the conduit, the suction is applied via the chamber to the perforations in the rim section so as to exert a pull on the substrate toward the rim such that rotation of the vacuum wheel conveys the substrate.

A part-processing machine having, in series, consecutive parts on a belt (2) moving same along a main conveying line. Selectively identified non-compliant parts are removed from the conveying line, into a transfer device (1) by pickup tools (8) supported on the periphery of a rotating drum (6) mounted transversely to the conveying line and arranged to rotate about itself so as to pass over the belt, enabling the non-compliant parts to be picked up by the pickup tools and released once the parts have been transported away from the conveying line. The pickup tools have pneumatic gripping heads, more particularly for example suction cups. The pneumatic gripping heads are depressurized relative to the surrounding air by a low-pressure chamber provided inside the drum, to which each head is connected by a tube inside a tool support arm.

The present disclosure relates to assembling, advancing, reorienting, and/or transferring stretched elastic parts during the assembly of absorbent articles. As described herein, a transfer assembly reorients a stretched elastic part from a first orientation, wherein the direction of stretch is generally parallel to the machine direction, to a second orientation, wherein the direction of stretch is generally perpendicular to the machine direction. The reoriented elastic part is then transferred to a carrier while maintaining the stretched condition of the elastic part. The orientation and/or configuration of vacuum apertures in a carrier surface relative to the direction of stretch of the elastic part and relative to the machine direction helps to prevent the elastic part from contracting, while at the same time helps to allow the elastic part to slide off the carrier surface without snagging and/or sticking to aperture perimeter edges.

A machine for automatically positioning objects is disclosed. The machine has one inlet conveyor to transport objects in a lying position; a detector system to identify the orientation and/or shape of the objects; a robotic collection device to collect and position the objects according to information received by the detector system; a transfer conveyor having transfer fasteners arranged in fixed positions along a periphery of the transfer conveyor defining a closed loop around a tilted axis; an outlet conveyor to receive and transport the objects in an upright position; and a transfer fastener seat for the objects at each transfer fastener. The conveyor moves the fasteners seats because of the movement of the transfer conveyor between an upper receiving position, in which the object is held in a lying position, and a lower delivery position, in which the object is held in an upright position. The transfer conveyor and said outlet conveyor are synchronized.