A single drive dual hopper conveyor system is presented having a center conveyor system and a pair of side conveyor systems that are connected to one another. A single motor is connected to the center conveyor system and drives movement of a belt within the center conveyor system. The connection of the center conveyor system to the side conveyor system causes the belts of the side conveyor systems to be simultaneously driven as the belt of the center conveyor system is driven. This arrangement eliminates the need for multiple motors. A guide at the center of the belts is configured to guide the belts through the center of the housings and prevent the buildup of grain within a cut-out section of the flights of the belt that is needed to allow access to the links of the belts to facilitate driving of the belts.

A drive module for a linear transport system comprises a housing and a stator, wherein a conveying device of the linear transport system with a magnet arrangement can be arranged on the housing. The stator is arranged in the housing, wherein the stator comprises at least one coil arrangement having at least one coil with at least one stator tooth. The coil arrangement is designed to switchably provide a magnetic traveling field, wherein the magnetic traveling field exits from the coil arrangement at the end faces and passes through the housing shells in order to enter into operative connection with the magnet arrangement of the conveying device of the linear transport system on the outer side of the housing for the purpose of forming a magnetic coupling.

A drive module for a linear transport system comprises a housing and a stator, wherein a conveying device of the linear transport system with a magnet arrangement can be arranged on the housing. The stator is arranged in the housing, wherein the stator comprises at least one coil arrangement having at least one coil with at least one stator tooth. The coil arrangement is designed to switchably provide a magnetic traveling field, wherein the magnetic traveling field exits from the coil arrangement at the end faces and passes through the housing shells in order to enter into operative connection with the magnet arrangement of the conveying device of the linear transport system on the outer side of the housing for the purpose of forming a magnetic coupling.

An endless conveyor device comprises a conveyor unit having at least one endless conveyor, which is configured to convey items; a drive roller assembly, which is drivable by a drive belt and configured to drive the endless conveyor and has a support element; a deflecting roller assembly and an intermediate body, disposed between the drive roller assembly and the deflecting roller assembly, as well as between a conveying strand and a return strand of the endless conveyor. The endless conveyor device further comprises a drive unit comprising the drive belt, a motor and a support device, which is configured to engage with the support element. The drive belt is relaxable by pivoting the conveyor unit relative to the drive unit about a rotation axis of the drive roller assembly in a first direction. A method for removing a conveyor unit from an endless conveyor device is also provided.

A conveying system for shock-sensitive items, in particular eggs, comprises a plurality of conveying devices in which the items are transferred from one conveying device to another. More particularly, the items are transferred from a conveying device oriented in a substantially horizontal direction to an adjacent conveying device oriented in a substantially vertical direction, without the risk of being damaged. The advancing movement of the conveying device having a substantially horizontal orientation is not movement at constant speed but, on the contrary, it is a movement at variable speed, sometimes accelerated and sometimes decelerated, and the transfer of the conveyed item from the conveying device to the conveying device having a substantially vertical orientation takes place when the advancement speed of the conveying device having a substantially horizontal orientation is at its minimum value.

A conveying system for shock-sensitive items, in particular eggs, comprises a plurality of conveying devices in which the items are transferred from one conveying device to another. More particularly, the items are transferred from a conveying device oriented in a substantially horizontal direction to an adjacent conveying device oriented in a substantially vertical direction, without the risk of being damaged. The advancing movement of the conveying device having a substantially horizontal orientation is not movement at constant speed but, on the contrary, it is a movement at variable speed, sometimes accelerated and sometimes decelerated, and the transfer of the conveyed item from the conveying device to the conveying device having a substantially vertical orientation takes place when the advancement speed of the conveying device having a substantially horizontal orientation is at its minimum value.

Disclosed is a conveying apparatus and method for conveying a tire layer, wherein the conveying apparatus includes a swivel conveyor with at least one endless belt or wire, a first pulley, a second pulley and a third pulley that define a minimal loop (L) for guiding the endless belt or wire along a conveying run and a return run, wherein the third pulley is arranged between the conveying run and the return run, and is swivable about a swivel axis (X) between a first swivel position and a second swivel position. The pivot position is chosen such that the length of the minimal loop when the third pulley is in the first swivel position is the same within a tolerance of less than 1 percent with respect to the length of the minimal loop when the third pulley is in the second swivel position.

A gearmotor assembly for use with a conveyor system has a rotatable conveyor roller extending laterally between spaced conveyor side rails. The gearmotor assembly includes an electric motor with a rotatable motor output shaft. The gearmotor assembly further includes a gear train drivingly connected to the motor output shaft. The gear train includes a train output shaft axially offset from the motor output shaft, with the train output shaft being drivingly connectable to the conveyor roller, so that rotation of the motor output shaft produces corresponding rotation of the conveyor roller.

A gearmotor assembly for use with a conveyor system has a rotatable conveyor roller extending laterally between spaced conveyor side rails. The gearmotor assembly includes an electric motor with a rotatable motor output shaft. The gearmotor assembly further includes a gear train drivingly connected to the motor output shaft. The gear train includes a train output shaft axially offset from the motor output shaft, with the train output shaft being drivingly connectable to the conveyor roller, so that rotation of the motor output shaft produces corresponding rotation of the conveyor roller.

A conveying system for shock-sensitive items, in particular eggs, is provided and comprises a plurality of conveying devices in which items are transferred from one conveying device to another. In particular, the conveying system comprises a motion transmission assembly which ensures synchronism between the advancement of a first conveying device and the advancement of a second conveying device, so as to optimize the transfer of items carried by the first to the second conveying device and allow the items to be transferred in the smoothest possible way.