A vibratory drum includes a tubular drum having a longitudinal axis, and first and second vibratory generators disposed laterally relative to the longitudinal axis and opposite each other across the tubular drum. The drum also includes a frame to which the first and second vibratory generators are attached; and a plurality of resilient elements attached at a first end to the tubular drum and at a second end to the frame, whereby the vibratory motion of the generators is transferred to the tubular drum to impart a circular motion to material disposed in the tubular drum.

A vibrating machine including a first machine part that vibrates in operation, a second machine part connected to an installation area of the vibrating machine, and a vibratory drive. A resilient bearing is arranged between the machine parts and has at least one air spring per support point and at least one compressed air reservoir fluidically connected to the air spring. A throttle is switched intermediate the air spring and the compressed air reservoir. The first machine part bearing has a resonant or natural frequency lower than an operating frequency of the vibrating machine. The bearing system has a frequency-dependent lower stiffness level with high damping at low frequencies, an upper stiffness level with low damping at higher frequencies, and a transition zone at an intermediate transitional frequency. The throttle is dimensioned such that the transitional frequency is close to, preferably slightly above, the resonant or natural frequency.

A vibratory drive system comprises a rotatable drive shaft and an out-of-balance wheel that is coaxial with and rotatable relative to the drive shaft. A rotary transmission system couples the drive shaft to the wheel in order to transmit rotational movement of the drive shaft to the wheel. The rotary transmission system comprises a shaft gear, a wheel gear, and intermediate gears coupling the shaft gear to the wheel gear. The intermediate gears are carried by a gear carrier that is rotatable relative to the drive shaft, and are rotatable with respect to the gear carrier. The arrangement allows the phase angle of the out-of-balance wheel to be adjusted with respect to the drive shaft.

A vibratory drive system comprises a rotatable drive shaft and an out-of-balance wheel that is coaxial with and rotatable relative to the drive shaft. A rotary transmission system couples the drive shaft to the wheel in order to transmit rotational movement of the drive shaft to the wheel. The rotary transmission system comprises a shaft gear, a wheel gear, and intermediate gears coupling the shaft gear to the wheel gear. The intermediate gears are carried by a gear carrier that is rotatable relative to the drive shaft, and are rotatable with respect to the gear carrier. The arrangement allows the phase angle of the out-of-balance wheel to be adjusted with respect to the drive shaft.

Bi-directional vibratory conveyor apparatuses comprise an elongated horizontal conveying surface, a vibration inducing motor, and vertically-disposed legs under the horizontal conveying surface, the deflection of which via one or more deflector in conjunction with vibrations of the horizontal conveying surface by the vibration inducing motor induces directional travel of parts on the horizontal conveying surface based on the direction of deflection of the legs therebeneath. Methods of using the same are further provided.

Bi-directional vibratory conveyor apparatuses comprise an elongated horizontal conveying surface, a vibration inducing motor, and vertically-disposed legs under the horizontal conveying surface, the deflection of which via one or more deflector in conjunction with vibrations of the horizontal conveying surface by the vibration inducing motor induces directional travel of parts on the horizontal conveying surface based on the direction of deflection of the legs therebeneath. Methods of using the same are further provided.

In an operation control method capable of securely reducing required motor capacity and power consumption, a threshold based on load size is preset, and after a driven or rotated state of each of two rotating shafts becomes steady, and if the load size is smaller than the threshold, conveyance of a rotating drive to one of the two rotating shafts is stopped and the one of the two rotating shafts with the conveyance of the rotating drive stopped is interlocked and rotated together with the other of the two rotating shafts by vibration generated by a rotating drive of the other of the two rotating shafts, and if the load size becomes larger than the threshold, the conveyance of the rotating drive to the one of the two rotating shafts with the conveyance of the rotating drive stopped is started so as to drive or rotate the two rotating shafts.

In an operation control method capable of securely reducing required motor capacity and power consumption, a threshold based on load size is preset, and after a driven or rotated state of each of two rotating shafts becomes steady, and if the load size is smaller than the threshold, conveyance of a rotating drive to one of the two rotating shafts is stopped and the one of the two rotating shafts with the conveyance of the rotating drive stopped is interlocked and rotated together with the other of the two rotating shafts by vibration generated by a rotating drive of the other of the two rotating shafts, and if the load size becomes larger than the threshold, the conveyance of the rotating drive to the one of the two rotating shafts with the conveyance of the rotating drive stopped is started so as to drive or rotate the two rotating shafts.

A vibratory system for a screening and/or feeder machine, the vibratory system including shaft lines, each shaft line having an unbalance module, the vibratory system also having a drive device configured to drive the shaft lines in rotation in synchronous manner and in the same direction. The vibratory system also includes an angle modifier device configured to modify the angular position of the unbalance module of one shaft line relative to the angular position of the unbalance module of the other shaft line or of one of the other shaft lines.

A vibratory system for a screening and/or feeder machine, the vibratory system including shaft lines, each shaft line having an unbalance module, the vibratory system also having a drive device configured to drive the shaft lines in rotation in synchronous manner and in the same direction. The vibratory system also includes an angle modifier device configured to modify the angular position of the unbalance module of one shaft line relative to the angular position of the unbalance module of the other shaft line or of one of the other shaft lines.