A conveyor includes a trough with a floor having an upper surface configured to receive items to be conveyed in at least a first direction from a first end to a second end. The conveyor also includes a platform with at least one exciter attached thereto. The at least one exciter has at least one shaft with an eccentric mass attached thereto, the shaft having an axis of rotation about which the mass is rotated. The conveyor also includes a base. At least one first toroidal resilient member is disposed between the trough and the platform, and at least one second toroidal resilient member disposed between the platform and the base.

A conveyor includes a trough with a floor having an upper surface configured to receive items to be conveyed in at least a first direction from a first end to a second end. The conveyor also includes a platform with at least one exciter attached thereto. The at least one exciter has at least one shaft with an eccentric mass attached thereto, the shaft having an axis of rotation about which the mass is rotated. The conveyor also includes a base. At least one first toroidal resilient member is disposed between the trough and the platform, and at least one second toroidal resilient member disposed between the platform and the base.

Horizontal motion conveyors for moving material are disclosed. The horizontal motion conveyor includes multiple drives. The second drive may float relative to the first drive. The conveyor may be made successively longer by including additional floating drives. Each drive may include a motor such as a servomotor that is connected to the driveshaft that drives the horizontal motion of the conveyor. A control system may control the rotation and positioning of the shafts.

Horizontal motion conveyors for moving material are disclosed. The horizontal motion conveyor includes multiple drives. The second drive may float relative to the first drive. The conveyor may be made successively longer by including additional floating drives. Each drive may include a motor such as a servomotor that is connected to the driveshaft that drives the horizontal motion of the conveyor. A control system may control the rotation and positioning of the shafts.

The present invention relates to a method and a vibration separator system for conveying and separating meat pieces and comprising a frame assembly having support columns, a supporting screen box being supported by the frame assembly on elastic suspension elements mounted between the frame assembly and the supporting screen box, a supply trough having an outlet and serving to receive the meat pieces, a vibration motor and a controller. The vibration motor is supported by and connected to the supporting screen box for reciprocating the supporting screen box. The controller is connected to the vibration motor for controlling the reciprocating movement of the supporting screen box. The supporting screen box comprises a first conveying sector for alignment of the meat pieces into a single row and a second conveying sector comprising a chicane for elongating the conveying path of travel as compared to the first conveying sector.

The present invention relates to a method and a vibration separator system for conveying and separating meat pieces and comprising a frame assembly having support columns, a supporting screen box being supported by the frame assembly on elastic suspension elements mounted between the frame assembly and the supporting screen box, a supply trough having an outlet and serving to receive the meat pieces, a vibration motor and a controller. The vibration motor is supported by and connected to the supporting screen box for reciprocating the supporting screen box. The controller is connected to the vibration motor for controlling the reciprocating movement of the supporting screen box. The supporting screen box comprises a first conveying sector for alignment of the meat pieces into a single row and a second conveying sector comprising a chicane for elongating the conveying path of travel as compared to the first conveying sector.

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.

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.

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.