A vibratory drive system, suitable for a material screening apparatus, includes rotatable drive shafts each having a centre of mass offset from its rotational axis. A respective drive mechanism is coupled to each drive shaft and is controlled by a controller. The controller adjusts the relative rotational speed of the drive shafts to adjust the relative angular position of the respective centre of mass of the drive shafts. This adjustment allows the vibratory characteristics of the drive system to be changed without having to halt the drive system.

A method and system for an automatic parts conveying system includes a parts feeder configured to receive parts from a receiving bin, a linear conveyor for conveying parts away from the parts feeder to an installation robot. The installation robot includes a robot arm controlled by a controller and a parts handling device coupled to a distal end of the robot arm. The automatic parts conveying system also includes one or more vibrating elements positioned along at least one of the linear conveyor, the parts feeder, and the receiving bin to impart vibratory motions to the at least one of the linear conveyor, the parts feeder, and the receiving bin for stimulating the parts into motion. The automatic parts conveying system also includes an air assist portion configured to provide pressurized fluid to the parts to facilitate moving parts through the automatic parts conveying system.

A method and system for an automatic parts conveying system includes a parts feeder configured to receive parts from a receiving bin, a linear conveyor for conveying parts away from the parts feeder to an installation robot. The installation robot includes a robot arm controlled by a controller and a parts handling device coupled to a distal end of the robot arm. The automatic parts conveying system also includes one or more vibrating elements positioned along at least one of the linear conveyor, the parts feeder, and the receiving bin to impart vibratory motions to the at least one of the linear conveyor, the parts feeder, and the receiving bin for stimulating the parts into motion. The automatic parts conveying system also includes an air assist portion configured to provide pressurized fluid to the parts to facilitate moving parts through the automatic parts conveying system.

A conveyor for separating, singulating or conveying bulk material comprises a conveying plate, a substructure and a pulse generator for generating an oscillation. The substructure stands on a base surface. The conveying plate is arranged on the substructure at a distance from the base surface. The pulse generator is fixed on the substructure and is/can be brought into an operative connection with the conveying plate. The oscillation generated by the pulse generator can be transmitted to the conveying plate and a force is exerted on the substructure by the oscillation. The conveyor comprises an equalising pulse generator which is fixed on the substructure and creates a counter-oscillation. A counter-force which is in an opposite direction to the force is exerted on the substructure by the counter-oscillation. A resultant force which results from the force and the counter-force and which acts on the substructure is reduced by the counter-force.

A conveyor for separating, singulating or conveying bulk material comprises a conveying plate, a substructure and a pulse generator for generating an oscillation. The substructure stands on a base surface. The conveying plate is arranged on the substructure at a distance from the base surface. The pulse generator is fixed on the substructure and is/can be brought into an operative connection with the conveying plate. The oscillation generated by the pulse generator can be transmitted to the conveying plate and a force is exerted on the substructure by the oscillation. The conveyor comprises an equalising pulse generator which is fixed on the substructure and creates a counter-oscillation. A counter-force which is in an opposite direction to the force is exerted on the substructure by the counter-oscillation. A resultant force which results from the force and the counter-force and which acts on the substructure is reduced by the counter-force.

Implementations of the present invention relate to devices, systems, and methods for isolating electronic components from input vibrations. The vibration isolation device may passively isolate the housed electronics from substantially all input vibrations. The vibration isolation device may include elastic members to suspend the electronic components within a support frame such that input vibrations are unable to directly influence the electronic components.

Methods and systems for controlling a vibratory feeder are disclosed. In some embodiments, the methods and systems include the following: a controller module including a graphical user interface for selecting operating parameters to be communicated to a bowl drive that causes a feeder bowl to move, monitoring algorithms stored in non-transitory memory for processing motion data to monitor motion of the feeder bowl, and adjustment algorithms stored in non-transitory memory for determining and automatically adjusting the operating parameters, and a motion sensor module configured to mount with and sense motion of the bowl drive, the motion sensor module including an accelerometer, a digital signal processor (DSP) microcontroller, and a transmitter. The DSP microcontroller samples output data from the accelerometer, determines motion data of the motion of the bowl drive, and transmits the motion data via the transmitter to the controller module.

Methods and systems for controlling a vibratory feeder are disclosed. In some embodiments, the methods and systems include the following: a controller module including a graphical user interface for selecting operating parameters to be communicated to a bowl drive that causes a feeder bowl to move, monitoring algorithms stored in non-transitory memory for processing motion data to monitor motion of the feeder bowl, and adjustment algorithms stored in non-transitory memory for determining and automatically adjusting the operating parameters, and a motion sensor module configured to mount with and sense motion of the bowl drive, the motion sensor module including an accelerometer, a digital signal processor (DSP) microcontroller, and a transmitter. The DSP microcontroller samples output data from the accelerometer, determines motion data of the motion of the bowl drive, and transmits the motion data via the transmitter to the controller module.

Horizontal motion conveyors for moving material and methods for reversing such horizontal motion conveyors are disclosed. In some embodiments, the horizontal motion conveyor includes a motor such as a servomotor that is connected to the driveshaft that drives the horizontal motion of the conveyor. In some embodiments, the speed profile of the pan may be changed to reverse direction of the flow of material on the pan without slowing or stopping the drive motor.

The invention relates to a vibratory feeder comprising a support arrangement (8), for carrying out a vibrational movement when in operation, for a feeder element in which material (12) which is to be fed is fed, also comprising a drive arrangement (5) for the support arrangement (8) and a bearing arrangement (3) which initiates vibrational oscillations of the vibratory feeder (1, 30, 40, 60, 90, 100) reducing in the base (2). Means which suppress a movement of the vertical components due to the vibratory movement of the front end (10a) of the feeder element from that of the rear end (10b) when the vibratory feeder (30, 40, 60, 90, 100) is in operation are provided. The mass flow emitted by the vibratory feeder (30, 40, 60, 90, 100) can be easily changed without a time delay which can therefore improve the control of the vibratory feeder.