A vibratory conveyor includes a feed tray, an electromagnetic linear actuator and a movable drive train interconnecting the feed tray and the electromagnetic linear actuator such that the electromagnetic linear actuator will move the feed tray during energization of the electromagnetic linear actuator. A sensor assembly is positioned to detect movement of the electromagnetic linear actuator. A controller connected to receive an output of the sensor assembly and connected to control energization of electromagnetic linear actuator, wherein the controller is configured to adjust energization of the electromagnetic linear actuator based upon the output of the sensor assembly. A vibratory conveyor in which the movable drive train includes at least one parallel spring element therealong is also disclosed.

A system for assembly of components, including a vibrating device wherein the components are placed in bulk, which is provided with first and second compartments connected together at their ends by first and second passage zones to form a closed circuit wherein the components can flow, and an articulated gripping arm provided to distribute the components to an automatic assembly installation, the vibrating device including first and second planes inclined in opposite directions included, respectively, in the first and second compartments, the components being able to progress along the first and second inclined planes towards a supply platform on which at least one component can be arranged in advance of its seizure by the articulated gripping arm, the supply platform being located in the second compartment at an exit of the second inclined plane.

A system for assembly of components, including a vibrating device wherein the components are placed in bulk, which is provided with first and second compartments connected together at their ends by first and second passage zones to form a closed circuit wherein the components can flow, and an articulated gripping arm provided to distribute the components to an automatic assembly installation, the vibrating device including first and second planes inclined in opposite directions included, respectively, in the first and second compartments, the components being able to progress along the first and second inclined planes towards a supply platform on which at least one component can be arranged in advance of its seizure by the articulated gripping arm, the supply platform being located in the second compartment at an exit of the second inclined plane.

A work-piece feeding assembly includes a first vibratory parts-transferring assembly, and a second vibratory parts-transferring assembly. The first vibratory parts-transferring assembly is for transferring a work piece along a first travel direction via a common parts-feeding path. The second vibratory parts-transferring assembly is for transferring the work piece along a second travel direction via the common parts-feeding path.

A work-piece feeding assembly includes a first vibratory parts-transferring assembly, and a second vibratory parts-transferring assembly. The first vibratory parts-transferring assembly is for transferring a work piece along a first travel direction via a common parts-feeding path. The second vibratory parts-transferring assembly is for transferring the work piece along a second travel direction via the common parts-feeding path.

A vibratory conveyor includes a feed tray, an electromagnetic linear actuator and a movable drive train interconnecting the feed tray and the electromagnetic linear actuator such that the electromagnetic linear actuator will move the feed tray during energization of the electromagnetic linear actuator. A sensor assembly is positioned to detect movement of the electromagnetic linear actuator. A controller connected to receive an output of the sensor assembly and connected to control energization of electromagnetic linear actuator, wherein the controller is configured to adjust energization of the electromagnetic linear actuator based upon the output of the sensor assembly. A vibratory conveyor in which the movable drive train includes at least one parallel spring element therealong is also disclosed.

The invention relates to a vibratory floor made up of shaker modules protected against the entry of dust, and capable of emptying cohesive products. The inner volume (10) of each module is connected by means of a pipe (14) to an air or clean gas volume (19). Each module past the first row is provided with an anti-pressure device (46) made up of an anti-pressure plate (47) situated above the motor cover (44), supported by two flanges (48) and (49) resting on stationary parts (36) on either side of the module. The modules thus formed are protected against the entry of dust, and effectively emptying any cohesive product from silos, vessels, railroad cars or any other containers, without human or mechanized intervention.

The invention relates to a vibratory floor made up of shaker modules protected against the entry of dust, and capable of emptying cohesive products. The inner volume (10) of each module is connected by means of a pipe (14) to an air or clean gas volume (19). Each module past the first row is provided with an anti-pressure device (46) made up of an anti-pressure plate (47) situated above the motor cover (44), supported by two flanges (48) and (49) resting on stationary parts (36) on either side of the module. The modules thus formed are protected against the entry of dust, and effectively emptying any cohesive product from silos, vessels, railroad cars or any other containers, without human or mechanized intervention.

A system for assembly of components, including a vibrating device wherein the components are placed in bulk, which is provided with first and second compartments connected together at their ends by first and second passage zones to form a closed circuit wherein the components can flow, and an articulated gripping arm provided to distribute the components to an automatic assembly installation, the vibrating device including first and second planes inclined in opposite directions included, respectively, in the first and second compartments, the components being able to progress along the first and second inclined planes towards a supply platform on which at least one component can be arranged in advance of its seizure by the articulated gripping arm, the supply platform being located in the second compartment at an exit of the second inclined plane.

A product speed checking apparatus for attaching to a vibratory conveying system and a method thereof for dispensing product, including a sample pan mounted to capture flow of product between two vibratory conveyors; a first sensor and a second sensor, each placed separately at a predetermined distance from one another and each capable of independently reading product handled by the sample pan; and, a programmable logic controller operatively arranged to calculate an approximate time between the reading of product by the first sensor and the reading of product by the second sensor and computing product speed by dividing distance between two sensors with the travel time between the two sensors.