A method for bonding large modules with the following steps, a large module is fed to a bonder from behind in a loading plane by means of a feeder unit. The large module is passed from the feeder unit to a first transverse conveyor unit, and is brought by the same to a first buffer position provided in the bonder, wherein the first buffer position is provided in a loading plane of the bonder. The large module is brought from the first buffer position into a first receiving position in the loading plane via the first transverse conveyor unit and is passed there to a vertical conveyor unit.

A method for bonding large modules with the following steps, a large module is fed to a bonder from behind in a loading plane by means of a feeder unit. The large module is passed from the feeder unit to a first transverse conveyor unit, and is brought by the same to a first buffer position provided in the bonder, wherein the first buffer position is provided in a loading plane of the bonder. The large module is brought from the first buffer position into a first receiving position in the loading plane via the first transverse conveyor unit and is passed there to a vertical conveyor unit.

A transport system for transporting capsules within a machine for preparing capsules for producing capsules. Housings, wherein each housing is configured to house a capsule for producing beverages, and wherein the housings comprise at least a first housing for holding a first capsule and a second housing for holding a second capsule, wherein the second capsule is different in size and/or shape from the first capsule. Seats are configured to receive one of the housings with each seat configured to receive either the first housing or the second housing. An extractor extracts the first housing from a seat in which it is received. An insertor inserts the second housing into the seat. A machine for preparing capsules for producing beverages in which such a transport system is implemented is also presented.

A drive system for a net cleaner to produce efficient propulsion without damage to the cage net. The drive system includes flexible engagement stumps protruding from a base of a driving belt with tips or studs mounted on an end of the stumps. The tips or studs engage the net and propel the net cleaner. The stumps flex to insure that, if excessive pressure is applied to a stud, the stump will bend and the net will release without damage. A guard prevents the stump from directly engaging a cage net. A track belt produces efficient propulsion without damage to the cage net. The track belt includes flexible engagement stumps protruding from a base of a driving belt with tips or studs mounted on an end of the stumps.

Embodiments of product handling systems facilitate transfer of individual product items from incoming bulk form into dedicated trays for inspection, sorting, selection, and packaging. Inspection may comprise interrogation of product items within a tray by electromagnetic (e.g., optical, hyperspectral) or other (e.g., physical, acoustic, gas sensing, etc.) techniques. Prior to packaging, product items disposed within the tray may be stored in a moveable carousel responsible for controlling environmental factors such as temperature, humidity, illumination, ambient gases, product-to-product interactions, and/or others. Movement of product items from a carousel's transfer station to an outside staging position may be accomplished using robots and/or conveyor belts. Embodiments may allow rapid, low-cost consumer selection of specific individual product items based upon their accompanying metadata (e.g., source, identifier), in combination with the results of inspection (e.g., visual appearance). Embodiments may receive product items pre-packaged in tray format to expedite inspection, sorting, selection, and packaging.

A method for transferring conveyed items from at least one feed conveyor onto an outgoing conveyor, in a transfer region, wherein the at least one feed conveyor includes a conveying member that is driven along a feed conveying stretch, for conveying conveyed items into the transfer region, and the outgoing conveyor includes conveying containers that are movable along a transfer conveying stretch for taking over the conveyed items that are delivered by the at least one feed conveyor. The conveyed items that lie on the conveying member are accelerated relative to the conveying member along the feed conveying stretch towards the transfer region via an acceleration device and for the purpose of delivery of the conveyed items are brought into a cyclically synchronous side-by-side conveying with a conveying container of the outgoing conveyor.

An accumulating conveyor includes upper and lower runs which form upper and lower tracks, reverse sections connecting the upper and lower runs, and a deflecting element connected to a first motor. Endless tension elements engaged with a deflecting element circulate a pallet in the upper and lower runs. A stop element is on the underside of the pallet, and a stopping element is arranged between the upper and lower runs and driven by a second motor. The stopping element has a locking position with the stop element for stopping the pallet and a release position with the stop element for conveying the pallet. The stopping element is guided in sections around the stop element on a curved path during movement from the locking position to the release position to release the pallet for further conveying.

A shuttle for logistics includes a vehicle body, a supercapacitor, a straight wheel, a straight motor, a transverse wheel, a transverse motor, a synchronous belt, a position sensor, a charging contact, a lifting motor, a lifting frame, a second synchronous belt, an encoder, a PLC controller, a lifting cam, a lifting position sensor, a telescopic fork, a finger, a telescopic fork position sensor, a telescopic fork motor, an antenna, and a controller. A bottom of the vehicle body is provided with the straight wheel and the transverse wheel, and a level of the straight wheel is lower than that of the transverse wheel. The straight motor and the transverse motor are arranged on the vehicle body, respectively. The straight motor is linked to the straight wheel, and the transverse motor is linked to the transverse wheel. The supercapacitor is arranged on the vehicle body.

An automatic cart transport system. A track located in a factory working floor provides a trackway for an endless flexible conveyor chain. A plurality of chain units including a first chain portion having vertical rollers and a second chain portion having horizontal rollers are flexibly coupled, and the chain is advanced along the trackway by a drive motor. The chain units support thereabove, but within the track, a coupling plate having therein an aperture for accepting and capturing a chain connection shaft which is detachably connected to a cart. The cart is automatically towed along a defined pathway on the working floor of a factory by the chain, when connected to the coupling plate on the endless flexible conveyor chain.

Pallet for a conveyor system comprising a conveyor track, where the pallet comprises a housing having an upper side adapted to support an object, and an underside opposite to the upper side, where the underside is adapted to bear on a conveyor track, where the housing comprises a front side, a rear side, a right side and a left side, where the pallet comprises a rechargeable power source, a control unit, a wireless communication means and a plurality of actuating means arranged to be controlled by the control unit, where the actuating means are adapted to extend out of the housing or to retract into the housing by a control signal from the control unit. The advantage of the invention is that a self-contained pallet is provided, which can navigate through a conveyor system without the need of dedicated diverters.