A method for format adaptation of carriages for the transportation of bottles on a linear motor system and a corresponding linear motor system are described. According thereto, container guides provided on the carriages are adapted to the body cross-section of the bottles by adjusting a guide width in an automated manner between guide jaws of the container guides which in relation to the direction of travel are the leading and trailing ones. There is then no need to replace component parts at the container guides, and the production in filling systems is optimised in terms of staff requirements, resultant production stoppages, and error sources.

A conveyor system includes a rail having one or more channels therein and one or more sleds operatively associated with the rail. A sled can include a body and one or more wheels mounted on the body and configured to move through the one or more channels in the rail. A sled can also include a holding device connected to the body. The holding device can be configured to engage a packaging container to move the packaging container along the rail. Multiple sleds can be used to secure a packaging container therebetween and move the packaging container along the rail. The conveyor system may also include a queue system that dynamically moves packaging containers to packaging stations.

Technology disclosed includes a robotic workstation for unstacking/stacking a multi-layer stack of boards and includes an end effector configured to pick up, move and release a layer of boards. The end effector includes first and second pick up and release members, each being (i) disposed below first and second support members, (ii) transversely arranged with respect to the first and second support members and (iii) attached to both of the first and second support members. The robotic workstation also includes a robotic manipulator connected to an attachment plate of the end effector and capable of moving the end effector. The robotic manipulator is under control of a controller executing stored instructions that perform operations including picking up the layer of boards by orienting the end effector such that each board of the layer of boards is transversely oriented with respect to the first and second pick up and release members.

An apparatus for loading and accumulating semi-finished plate-like pieces, in particular lenses, includes a support structure and a piece warehouse which is associated with the support structure for moving the pieces from a piece inlet portion to a piece outlet portion along a warehouse axis. The warehouse includes augers extending parallel to the warehouse axis along respective longitudinal axes and are arranged around the warehouse axis to jointly delimit transverse seats with respect to the warehouse axis. Each seat accommodates a semi-finished plate-like piece. A system coordinates positioning of the augers for varying a distance of each auger from the warehouse axis to vary a radial dimension of the transverse seats. A system rotates each auger around the relevant longitudinal axis in a synchronized manner to cause movement of the pieces parallel to the warehouse axis from the inlet portion to the outlet portion.

An unloading apparatus for horticultural products such as blueberries and the like, which are conveyed along a predefined advancement path by respective movement units includes at least one dispenser of pressurized fluid, which can be activated on command during the transit of each product in order to send a jet of the pressurized fluid toward the product and consequently cause its fall from the respective movement unit. The apparatus also includes at least one deflector screen arranged facing and proximate to the dispenser, on the opposite side with respect to the predefined trajectory in order to intercept the products struck by the jet. The screen is inclined so as to define, between its face directed toward the dispenser and a vertical plane that passes through the dispenser, a work angle one and ninety degrees configured for the optimum downward deflection of the products.

Apparatus configured for dispensing bedding inside of breeding cages for use in pharmaceutical preclinical research centres, including: a loading hopper located in the upper part of the apparatus, and adapted to contain the bedding to be supplied to the cages; at least one supporting plane adapted to support one or more cages, and positioned under the hopper; an actuator under the hopper, adapted to raise or lower the hopper and the at least one supporting plane; one or more dosing mouths located in the lower part of the loading hopper, and adapted to feed into the cages given quantities of bedding from the hopper; a dispensation system adapted to dispense bedding into the cages through the one or more dosing mouths; a control system adapted to determine the quantity of bedding and to control the actuator; and a base for supporting the apparatus.

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 configurable belt conveyor for manufacturing comprising first belt and an adaptable border adjacent to the belt. The adaptable border having a first configuration in which a first width of the belt is available for supporting a pallet on the conveyor belt, and a second configuration in which a portion of the belt is covered by the adaptable border, such that the second width of the belt is sized for supporting a printed circuit board (PCB). In one embodiment, the configurable belt conveyor may be configured to form a dual stream conveyor.

The invention relates to an apparatus for aligning box-shaped articles of various sizes on a conveyor belt, as well as a printing station, a reading station, and a labelling station including said apparatus. The apparatus comprises an input conveyor belt operable to move transversally with respect to an output conveyor belt conveying direction, to adapt to a transverse size of a transported box-shaped article, and feed said output conveyor belt with corresponding aligned article.

The present disclosure relates to an automatically adjustable smart shelf, a cargo storing method, and an unmanned logistics system. The automatically adjustable smart shelf includes a shelf outer frame and a control unit. A first movable shelf layer and a second movable shelf layer provided on the shelf outer frame and respectively movable along a first direction and a second direction intersecting with each other. A control unit can control the first movable shelf layer and the second movable shelf layer to move along the first direction and the second direction respectively, so as to form various sizes of storage space for storing various cargos accordingly.