Vibratory conveyors, vibratory conveyor systems, and related methods are disclosed. An exemplary vibratory conveyor includes a support frame; a pan configured to receive a conveyed material, the pan mounted for cyclic movement relative to the support frame, the pan having a pan axis generally aligned with a conveying direction; and at least two linear servomotors operatively coupled to move the pan relative to the support frame, the at least two linear servomotors comprising a first linear servomotor and a second linear servomotor. The first linear servomotor defines a first linear servomotor actuating axis, the second linear servomotor defines a second linear servomotor actuating axis, and the first linear servomotor actuating axis is oriented obliquely relative to the second linear servomotor actuating axis.

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 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.

There is provided an apparatus for taking out a molded product, the apparatus being capable of suppressing displacement vibration of an attachment mounted at a leading end of an approach frame by means of active control using an electromagnetic actuator that has necessary power. One or more electromagnetic actuators are disposed at a portion of the approach frame, positioned opposite to the attachment with respect to a movable base. An active vibration suppressing system suppresses the displacement vibration of the attachment by causing the one or more electromagnetic actuators to generate a vibration in the same phase as the displacement vibration of the attachment.

There is provided an apparatus for taking out a molded product, the apparatus being capable of suppressing displacement vibration of an attachment mounted at a leading end of an approach frame by means of active control using an electromagnetic actuator that has necessary power. One or more electromagnetic actuators are disposed at a portion of the approach frame, positioned opposite to the attachment with respect to a movable base. An active vibration suppressing system suppresses the displacement vibration of the attachment by causing the one or more electromagnetic actuators to generate a vibration in the same phase as the displacement vibration of the attachment.

There is provided an apparatus for taking out a molded product, the apparatus being capable of suppressing displacement vibration of an attachment mounted at a leading end of an approach frame by means of active control using an electromagnetic actuator that has necessary power. One or more electromagnetic actuators are disposed at a portion of the approach frame, positioned opposite to the attachment with respect to a movable base. An active vibration suppressing system suppresses the displacement vibration of the attachment by causing the one or more electromagnetic actuators to generate a vibration in the same phase as the displacement vibration of the attachment.

Vibrating apparatus (10) for automatically conveying objects (11) from a first position (12) to a second position (13) by means of vibration, comprising one or more conveying members (15) and a movement member (18), which is configured to be driven according to a vibrational motion in order to make said one or more conveying members (15) vibrate to cause a consequent forward motion by vibration of the objects (11).

Vibrating apparatus (10) for automatically conveying objects (11) from a first position (12) to a second position (13) by means of vibration, comprising one or more conveying members (15) and a movement member (18), which is configured to be driven according to a vibrational motion in order to make said one or more conveying members (15) vibrate to cause a consequent forward motion by vibration of the objects (11).

An electromagnetic drive mechanism for use in powering vibratory equipment is provided. As one example, a drive mechanism may include a plurality of deflectable elastomeric springs in a configuration that allows the auxiliary springs to achieve a vertical, non-linear spring rate increase.

An electromagnetic drive mechanism for use in powering vibratory equipment is provided. As one example, a drive mechanism may include a plurality of deflectable elastomeric springs in a configuration that allows the auxiliary springs to achieve a vertical, non-linear spring rate increase.