A vibratory conveyor drive system that can be fitted onto most existing vibratory conveyors. It replaces the conventional vibrational drive and its connections to the trough or trough frame and dramatically increases the longevity of the vibratory conveyor. It is a simple inexpensive retrofit. It has a drive arm with a vibratory drive that is hung from one of its ends and is partially vertically supported underneath by a vertical spring means. The other end of the drive arm is connected to the trough or the trough frame. Between the vibratory drive the drive arm and the trough or frame, there is at least one flexion means to negate the vertical forces of the drive and utilize only the lineal drive forces. The drive arm is at an acute angle with respect to the linear axis of the trough so as to impart an oscillating translational movement to the trough.

A vibratory conveyor drive system that can be fitted onto most existing vibratory conveyors. It replaces the conventional vibrational drive and its connections to the trough or trough frame and dramatically increases the longevity of the vibratory conveyor. It is a simple inexpensive retrofit. It has a drive arm with a vibratory drive that is hung from one of its ends and is partially vertically supported underneath by a vertical spring means. The other end of the drive arm is connected to the trough or the trough frame. Between the vibratory drive the drive arm and the trough or frame, there is at least one flexion means to negate the vertical forces of the drive and utilize only the lineal drive forces. The drive arm is at an acute angle with respect to the linear axis of the trough so as to impart an oscillating translational movement to the trough.

The invention relates to a vibration table (1) comprising a table plate (2) and a drive (3), wherein the drive (3) comprises four scissor mechanisms (41, 42, 43, 44), each having a first (41.1, 42.1, 43.1, 44.1) and a second limb (41.2, 42.2, 43.2 and 44.2) and a hub (41.3, 42.3, 43.3, 44.3), wherein the hubs (41.3, 42.3, 43.3, 44.3) are fastened to the table plate (2) and the first limb (41.1, 42.1, 43.1, 44.1) can be moved independently of the second limb (41.2, 42.2, 43.2, 44.2).

The invention relates to a vibration table (1) comprising a table plate (2) and a drive (3), wherein the drive (3) comprises four scissor mechanisms (41, 42, 43, 44), each having a first (41.1, 42.1, 43.1, 44.1) and a second limb (41.2, 42.2, 43.2 and 44.2) and a hub (41.3, 42.3, 43.3, 44.3), wherein the hubs (41.3, 42.3, 43.3, 44.3) are fastened to the table plate (2) and the first limb (41.1, 42.1, 43.1, 44.1) can be moved independently of the second limb (41.2, 42.2, 43.2, 44.2).

A passive alignment conveyor suitable for elongated bodies including at least one piece of material including an indentation in an alignment direction as an alignment lane, which alignment lane includes at least one slot in the alignment lane in an angle to the alignment direction, at least one means for optical detection, at least one electronic circuit-based control device, wherein least one movable knife mounted shifted from the means for optical detection in the alignment direction, mounted in an angle to the alignment direction and mounted in such a way that it can move within the slot in the alignment lane.

A passive alignment conveyor suitable for elongated bodies including at least one piece of material including an indentation in an alignment direction as an alignment lane, which alignment lane includes at least one slot in the alignment lane in an angle to the alignment direction, at least one means for optical detection, at least one electronic circuit-based control device, wherein least one movable knife mounted shifted from the means for optical detection in the alignment direction, mounted in an angle to the alignment direction and mounted in such a way that it can move within the slot in the alignment lane.

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.

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.

The invention relates to a vibration table (1) comprising a table plate (2) and a drive (3), wherein the drive (3) comprises four scissor mechanisms (41, 42, 43, 44), each having a first (41.1, 42.1, 43.1, 44.1) and a second limb (41.2, 42.2, 43.2 and 44.2) and a hub (41.3, 42.3, 43.3, 44.3), wherein the hubs (41.3, 42.3, 43.3, 44.3) are fastened to the table plate (2) and the first limb (41.1, 42.1, 43.1, 44.1) can be moved independently of the second limb (41.2, 42.2, 43.2, 44.2).

The invention relates to a vibration table (1) comprising a table plate (2) and a drive (3), wherein the drive (3) comprises four scissor mechanisms (41, 42, 43, 44), each having a first (41.1, 42.1, 43.1, 44.1) and a second limb (41.2, 42.2, 43.2 and 44.2) and a hub (41.3, 42.3, 43.3, 44.3), wherein the hubs (41.3, 42.3, 43.3, 44.3) are fastened to the table plate (2) and the first limb (41.1, 42.1, 43.1, 44.1) can be moved independently of the second limb (41.2, 42.2, 43.2, 44.2).