Abstract: A differential impulse conveyor system including detectable markers disposed in a series on a moving component of the conveyor system. A stationary sensor disposed in close proximity to the markers generates a signal when the moving component is in a first range of motion to dispose the markers proximal to the sensor, and the sensor either fails to generate a signal when the moving component is not within the first range of motion. The sensor signal causes a current conditioning device to condition current from a current source to operate a motor to power the conveyor tray at a first rate of acceleration in a first mode, and the lack of the signal causes the current conditioning device to operate the motor to power the conveyor tray at a second rate of acceleration in a second mode. Markers may be positionable to optimize the timing of the current modes.

Abstract: A differential impulse conveyor system including detectable markers disposed in a series on a moving component of the conveyor system. A stationary sensor disposed in close proximity to the markers generates a signal when the moving component is in a first range of motion to dispose the markers proximal to the sensor, and the sensor either fails to generate a signal when the moving component is not within the first range of motion. The sensor signal causes a current conditioning device to condition current from a current source to operate a motor to power the conveyor tray at a first rate of acceleration in a first mode, and the lack of the signal causes the current conditioning device to operate the motor to power the conveyor tray at a second rate of acceleration in a second mode. Markers may be positionable to optimize the timing of the current modes.

Abstract: A tumble drum for recovering at least some flavoring material dispensed onto food portions processed within the tumble drum, the tumble drum having an interior mixing chamber, a first set of apertures in a wall of the tumble drum, a circumferential cavity surrounding the interior mixing chamber, an exterior section in the wall, and a second set of apertures in the exterior section, wherein a receiver coupled to a suction source can engage the exterior section to draw air from within the interior mixing chamber, through the first set of apertures, into the circumferential cavity, through the second set of apertures and into the receiver, and at least some airborne flavoring material is deposited onto food portions through which the air passes on it path. The exterior section may be in an anterior wall surrounding an inlet of the tumble drum or a circumferential portion of the exterior.

Abstract: A rotary to linearly reciprocating motion converter includes a case, a closure member engaging an opening of the case to dispose a pinion gear rotatably coupled to the closure member, the pinion gear having half the diameter as an interior ring gear of the case, and further includes a pinion shaft connected to the pinion gear on a first side of the closure member and to an inboard end of a crank arm on a second side of the closure member, the outboard end of the crank arm having a force transfer member aligned with a point on the periphery of the pinion gear. Rotation of the closure member relative to the case results in the force transfer member moving in a linearly reciprocating mode. The force transfer member may be coupled to a conveyor to reciprocate the conveyor as the closure member rotates.

Abstract: An apparatus that functions as a linear bearing for supporting a reciprocating structure that reciprocates along a linear path includes a first body including a pinion gear with a first diameter and a first number of teeth for engagement with a second number of teeth that is twice the first number and on an interior ring gear of a second body. The interior ring gear is disposed within an interior cavity. The first body also includes a support member connected to the pinion gear with a crank, the support member being aligned with a point at the periphery of the pinion gear so that it will, upon rotation of the pinion gear while engaged with the ring gear, cyclically reciprocate along a linear path. The apparatus can be used to support reciprocating structures such as, for example, a reciprocating conveyor.

Abstract: A rotary to linearly reciprocating motion converter includes a case, a closure member engaging an opening of the case to dispose a pinion gear rotatably coupled to the closure member, the pinion gear having half the diameter as an interior ring gear of the case, and further includes a pinion shaft connected to the pinion gear on a first side of the closure member and to an inboard end of a crank arm on a second side of the closure member, the outboard end of the crank arm having a force transfer member aligned with a point on the periphery of the pinion gear. Rotation of the closure member relative to the case results in the force transfer member moving in a linearly reciprocating mode. The force transfer member may be coupled to a conveyor to reciprocate the conveyor as the closure member rotates.