A long run conveyor system is disclosed in which at least a portion thereof traverses a slope sufficiently steep so that tensile force associated with overcoming the effects of the slope is greater per unit length than tensile force per unit length of run due to main frictional resistance of the conveyor system. The long run conveyor system includes an external belt defining a continuous loop traversing an entire route of the conveyor system and is configured to transport material load across the entire route. The conveyor system also includes an internal belt positioned inside the continuous loop of the external belt, which also traverses substantially the entire route. An upper side of the internal belt operably engages an underside of the external belt. The internal and external belts are configured such that each respectively carries an approximately equal amount of belt tension.

The present disclosure provides a conveyor oven with a heating chamber, and a segmented conveyor belt that passes food products through the chamber for heating or cooking. The conveyor can comprise two or more removably connected sections. One of the sections can be sized so that it can be removed through a front of the heating chamber. The sections can be coupled together with a drive transfer device that transfers any motion from one section to another. The sections can also have motors associated therewith, so that motion of each section can be controlled independently of other sections.

Systems, methods, and computer-readable medium containing instructions for operating a conveyor. One method includes receiving, by a controller, a signal from each of a plurality of substations. Each of the plurality of substations provides power to a motor drive unit driving a conveyor belt of the conveyor. The signal received by the controller indicates whether an isolation switch associated with each substation has been manually operated. The method also includes, when the signal received from one of the plurality of substations indicates that the isolation switch associated with the one of the plurality of substations has been manually operated, transmitting, by the controller, a signal to each of the plurality of substations, the signal instructing each of the plurality of substations to isolate the motor drive unit from a power source.

Systems, methods, and computer-readable medium containing instructions for operating a conveyor. One method includes receiving, by a controller, a signal from each of a plurality of substations. Each of the plurality of substations provides power to a motor drive unit driving a conveyor belt of the conveyor. The signal received by the controller indicates whether an isolation switch associated with each substation has been manually operated. The method also includes, when the signal received from one of the plurality of substations indicates that the isolation switch associated with the one of the plurality of substations has been manually operated, transmitting, by the controller, a signal to each of the plurality of substations, the signal instructing each of the plurality of substations to isolate the motor drive unit from a power source.

A conveying device with an extensively extended conveying element that is led in a revolving manner along a conveying direction, is deflected at the head-ends of the conveying device and is laterally enclosed by side closure beams. The conveying device includes a drive device with a drive motor to drive the conveying element. The drive device is arranged between the two head-ends, between the side closure beams, and between the upper conveying section and the lower return section of the conveying element. The drive device includes a drive element that is arranged in a revolving manner about two deflection pivots spaced from one another in the conveying direction, and is driven by the drive motor. The drive element supports the upper conveying section of the conveying element, which is arranged at the top, and with this forms a contact fit for transmitting a drive force onto the conveying element.

A conveying device with an extensively extended conveying element that is led in a revolving manner along a conveying direction, is deflected at the head-ends of the conveying device and is laterally enclosed by side closure beams. The conveying device includes a drive device with a drive motor to drive the conveying element. The drive device is arranged between the two head-ends, between the side closure beams, and between the upper conveying section and the lower return section of the conveying element. The drive device includes a drive element that is arranged in a revolving manner about two deflection pivots spaced from one another in the conveying direction, and is driven by the drive motor. The drive element supports the upper conveying section of the conveying element, which is arranged at the top, and with this forms a contact fit for transmitting a drive force onto the conveying element.

The present invention concerns a method and system for sorting items comprising movable carriages (10) intended to transport the items, and connected to each other by a link (19), along a track having sections located at levels at different heights linked by ascending and descending slopes, a control system and drive units intended to move the carriages (10). Dedicated thrust units, separate from the drive units, are added on the slopes and are controlled individually by the control system so as to deliver a constant force in order to prevent the carriages (10) experiencing tension at the links (19, 20) as a result of the weight of the items and/or the carriages (10) present on the slopes.

The present invention concerns a method and system for sorting items comprising movable carriages (10) intended to transport the items, and connected to each other by a link (19), along a track having sections located at levels at different heights linked by ascending and descending slopes, a control system and drive units intended to move the carriages (10). Dedicated thrust units, separate from the drive units, are added on the slopes and are controlled individually by the control system so as to deliver a constant force in order to prevent the carriages (10) experiencing tension at the links (19, 20) as a result of the weight of the items and/or the carriages (10) present on the slopes.

A spiral conveyor belt system generally includes a rotatable cage, a first drive mechanism for rotating the cage about an axis in a first direction, an endless conveyor belt supported by the cage and a rotatable free wheel. The cage drives the conveyor belt along a helical path in a first direction and the rotatable free wheel rotates about an axis in a second direction opposite the first direction for guiding the endless conveyor belt from the cage along a return path and back to the cage. A second drive mechanism is preferably provided for rotating the free wheel.

A spiral conveyor belt system generally includes a rotatable cage, a first drive mechanism for rotating the cage about an axis in a first direction, an endless conveyor belt supported by the cage and a rotatable free wheel. The cage drives the conveyor belt along a helical path in a first direction and the rotatable free wheel rotates about an axis in a second direction opposite the first direction for guiding the endless conveyor belt from the cage along a return path and back to the cage. A second drive mechanism is preferably provided for rotating the free wheel.