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.

An apparatus for conveying stickers to lumber stack.

An apparatus for conveying stickers to lumber stack.

A conveyor system and drive element for same include a chain including a plurality of links that hinge with respect to each other and a plurality of moving elements such as balls that freely move in the links. A drive element drives the chain in a conveying direction and includes an elongated body with a surface that has a plurality of planar facets arranged around the longitudinal axis of the body. The facets extend along the body and engage respective links of the chain as the body is rotated to drive the chain. Relief elements are located in each facet and are configured for receiving the moving elements of the chain links engaging the facets so the links lie generally flat on the facets when the chain is driven. Other versions of the drive element are faceted for driving a chain with links but without relief elements.

Apparatus and method for orienting components of a rotary machine, such as a container treatment machine, where the rotary machine comprises a stator and a rotor and also at least one component which is arranged on the stator, wherein the apparatus comprises at least one reference element which is arranged on the stator and a sensor which is arranged on the rotor so as to rotate with it, wherein the sensor is suitable for measuring the distance from the reference element and from the component, and the stator, the rotor and the component can be oriented in relation to one another based on the values measured by the sensor.

A rotational device is provided that reorients a container from a first orientation to a second orientation in a manufacturing line and receives and reorients containers with different dimensions. The rotational device has an enclosed passageway defined by four continuous, turning surfaces that contribute to the ability of the rotational device to receive and reorient containers with different dimensions. In one embodiment, the passageway of the rotational device rotates 90 degrees in a clockwise manner. The bottoms of the different sized container are aligned with a right edge of an entrance of the passageway that corresponds to a surface that turns and defines the bottom edge of an exit of the passageway. Thus, the rotational device can receive containers with different dimensions while reduces the movement or jostling of the containers within the passageway.

A rotational device is provided that reorients a container from a first orientation to a second orientation in a manufacturing line and receives and reorients containers with different dimensions. The rotational device has an enclosed passageway defined by four continuous, turning surfaces that contribute to the ability of the rotational device to receive and reorient containers with different dimensions. In one embodiment, the passageway of the rotational device rotates 90 degrees in a clockwise manner. The bottoms of the different sized container are aligned with a right edge of an entrance of the passageway that corresponds to a surface that turns and defines the bottom edge of an exit of the passageway. Thus, the rotational device can receive containers with different dimensions while reduces the movement or jostling of the containers within the passageway.

A rotary device includes a bracket, a first supporting module, a second supporting module and a driving module. The two supporting modules respectively have a pivot end and a connective end. The two pivot ends are pivotally connected to different and adjacent position of the bracket. The driving module is utilized to reversely rotate the first supporting module and the second supporting module, simultaneously. The driving module includes an actuating component, a first rod and a second rod. The first rod is connected between the first connective end and a side of the actuating component. The second rod is connected between the second connective end and an opposite side of the actuating component. When the actuating component rotates at a first direction, the first rod rotates the first supporting module at a second direction, and the second rod rotates the second supporting module at the first direction.

The invention relates to a method and guide system for the transport of containers or container components, in particular, preforms and/or closure caps, in industrial systems for container production and/or product filling, wherein the containers/container components are transported along at least one guide element. By generating an air cushion between the guide element and the containers/container components by flowing through a microporous layer formed on the guide element, even container components which are lightweight and/or do not slide well can be reliably slidingly transported along the guide elements, and containers can be reliably supplied to dividing worms or similar using dynamic pressure.

The invention relates to a method and guide system for the transport of containers or container components, in particular, preforms and/or closure caps, in industrial systems for container production and/or product filling, wherein the containers/container components are transported along at least one guide element. By generating an air cushion between the guide element and the containers/container components by flowing through a microporous layer formed on the guide element, even container components which are lightweight and/or do not slide well can be reliably slidingly transported along the guide elements, and containers can be reliably supplied to dividing worms or similar using dynamic pressure.