The vibration feeder has a drive unit comprising a vibration drive, a carrier arrangement comprising a feeding element for the material to be conveyed and a control for the vibration drive, wherein an acceleration sensor is arranged on the drive unit, which when the vibration feeder is operating, detects the actual acceleration of the drive unit, and wherein the control is configured to use the actual acceleration signal of the acceleration sensor for generating a regulating variable for the vibration drive such that the carrier arrangement vibrates essentially within its resonance frequency (f.sub.res). This makes it possible, during operation, to detect the acceleration of a drive unit of the vibration feeder and to generate therefrom a regulating variable for a vibration drive such that a carrier arrangement of the vibration feeder vibrates closer to its resonance frequency (f.sub.res) or is brought back again to the same. In addition the inventive control may be used to also regulate the amplitude of the carrier arrangement and the associated mass flow m to a required value.

In a method for calculating a bulk material conveying rate or a bulk material load of a vibratory conveyor machine, in which method raw measured data from the vibratory conveyor machine are acquired at at least two times with different load states by at least one acceleration, speed or travel sensor and raw measured data are then processed to give at least one vibration data feature from the list: amplitude, frequency and phase, provision is made to create and to store feature datasets consisting of at least one vibration data feature and to create a regression model on the basis thereof. Based on the created regression model and at least one current feature dataset, the current actual load or bulk material conveying rate of a vibratory conveyor machine is then ascertained and displayed.

In a method for calculating a bulk material conveying rate or a bulk material load of a vibratory conveyor machine, in which method raw measured data from the vibratory conveyor machine are acquired at at least two times with different load states by at least one acceleration, speed or travel sensor and raw measured data are then processed to give at least one vibration data feature from the list: amplitude, frequency and phase, provision is made to create and to store feature datasets consisting of at least one vibration data feature and to create a regression model on the basis thereof. Based on the created regression model and at least one current feature dataset, the current actual load or bulk material conveying rate of a vibratory conveyor machine is then ascertained and displayed.

A vibrating screen feed conveying apparatus for conveying and separating sticky “moisture laden bulk solids” which are sticky and wet flowing onto a vibrating screening feeder and into a hopper. The apparatus includes a bed on which material is conveyed, a longitudinal counterbalance supported on a plurality of isolation springs, a plurality of inclined drive springs extending between the bed and the longitudinal counterbalance, and a plurality of stabilizers for controlling movement of the drive springs along their central axes. A plurality of vibratory motors, each having rotatable eccentric weights are attached to the rear end of the longitudinal counterbalance. The eccentric weights rotate in phase with one another to vibrate the bed at a vibration frequency.

A vibrating screen feed conveying apparatus for conveying and separating sticky “moisture laden bulk solids” which are sticky and wet flowing onto a vibrating screening feeder and into a hopper. The apparatus includes a bed on which material is conveyed, a longitudinal counterbalance supported on a plurality of isolation springs, a plurality of inclined drive springs extending between the bed and the longitudinal counterbalance, and a plurality of stabilizers for controlling movement of the drive springs along their central axes. A plurality of vibratory motors, each having rotatable eccentric weights are attached to the rear end of the longitudinal counterbalance. The eccentric weights rotate in phase with one another to vibrate the bed at a vibration frequency.

An oscillating conveyor having a conveying apparatus and a drive device that, upon actuation by a control device, excites an oscillation of the conveying apparatus with respect to a base of the oscillating conveyor to convey objects supported by a conveying surface of the conveying apparatus. The control device includes a communication interface for communication with an external communication device. The control device is designed so as, upon receiving a communication message including address and control information, to use the communication interface to check an addressing condition, the meeting of which is dependent on the address information, and only if the addressing condition is met to alter the actuation of the drive device based on the control information and/or to set an internal control parameter on which at least one chronologically subsequent actuation of the drive device by the control device is dependent to a value that is dependent on the control information.

An oscillating conveyor having a conveying apparatus and a drive device that, upon actuation by a control device, excites an oscillation of the conveying apparatus with respect to a base of the oscillating conveyor to convey objects supported by a conveying surface of the conveying apparatus. The control device includes a communication interface for communication with an external communication device. The control device is designed so as, upon receiving a communication message including address and control information, to use the communication interface to check an addressing condition, the meeting of which is dependent on the address information, and only if the addressing condition is met to alter the actuation of the drive device based on the control information and/or to set an internal control parameter on which at least one chronologically subsequent actuation of the drive device by the control device is dependent to a value that is dependent on the control information.

According to one method, bulk materials are conveyed in a metered quantity on at least one plate element and are lifted up from the plate element in order to organize the bulk materials by a movement oriented approximately perpendicularly to the plate element. The plate element is moved up and down at least transversely to the plate element support surface by at least one pulse, preferably two successive pulses, such that the bulk materials located on the plate element are lifted up from the plate element for a short time during each pulse, thus allowing an efficient and highly productive conveyance of the bulk materials.

According to one method, bulk materials are conveyed in a metered quantity on at least one plate element and are lifted up from the plate element in order to organize the bulk materials by a movement oriented approximately perpendicularly to the plate element. The plate element is moved up and down at least transversely to the plate element support surface by at least one pulse, preferably two successive pulses, such that the bulk materials located on the plate element are lifted up from the plate element for a short time during each pulse, thus allowing an efficient and highly productive conveyance of the bulk materials.

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.