An automated product diverter for a reciprocally movable conveying device generally provides a stationary base; a reciprocally movable conveyor bed supported by the stationary base; a product diverter that moves in an arc along a product transporting surface of the reciprocally movable conveyor; and an actuator carried by the stationary base and which operatively communicates with the diverter arm, and the reciprocal movement of the conveyor bed and the diverter arm is isolated from the actuator carried by the stationary base.

An apparatus that functions as a linear bearing for supporting a reciprocating structure that reciprocates along a linear path includes a first body including a pinion gear with a first diameter and a first number of teeth for engagement with a second number of teeth that is twice the first number and on an interior ring gear of a second body. The interior ring gear is disposed within an interior cavity. The first body also includes a support member connected to the pinion gear with a crank, the support member being aligned with a point at the periphery of the pinion gear so that it will, upon rotation of the pinion gear while engaged with the ring gear, cyclically reciprocate along a linear path. The apparatus can be used to support reciprocating structures such as, for example, a reciprocating conveyor.

An apparatus that functions as a linear bearing for supporting a reciprocating structure that reciprocates along a linear path includes a first body including a pinion gear with a first diameter and a first number of teeth for engagement with a second number of teeth that is twice the first number and on an interior ring gear of a second body. The interior ring gear is disposed within an interior cavity. The first body also includes a support member connected to the pinion gear with a crank, the support member being aligned with a point at the periphery of the pinion gear so that it will, upon rotation of the pinion gear while engaged with the ring gear, cyclically reciprocate along a linear path. The apparatus can be used to support reciprocating structures such as, for example, a reciprocating conveyor.

A conveyor bowl for a vibratory conveyor device includes a main body made of stainless steel and manufactured by primary shaping. The main body has an interface section for coupling to a vibration unit, and a conveyor section for conveying conveyed parts. The main body may be designed as a cast part. The main body may be a precision cast part or an investment cast part. The main body may be made of austenite. The interface section and the conveyor section may be formed in one piece or formed integrally with the main body.

A sensor device which is used to provide a control device with at least one operating parameter of an oscillating conveyor, the control device being used to control a drive device for exciting oscillation of an oscillating rail on the basis of the operating parameter, the sensor device including at least one sensor element for recording the operating parameter or at least one measured value from which the operating parameter can be determined, the sensor device including at least one communication device for wirelessly transmitting the operating parameter to the control device and an energy supply device for supplying the sensor device with operating energy, the energy supply device being used to convert a vibration generated by the drive device and/or electromagnetic radiation into the operating energy.

The vibration device includes a base, a movable bench, a first horizontal excitation unit, a second horizontal excitation unit, and a vertical excitation unit. The vibration device includes a first middle bench and a second middle bench between the base and the movable bench. The vibration device includes first horizontal elastic support units, second horizontal elastic support units, and vertical elastic support units that elastically connect the base, the first middle bench, the second middle bench, and the movable bench sequentially in the first horizontal direction, the second horizontal direction, and the vertical direction. If overall device is supposed as a first mass body, a second mass body, and a third mass body with the first horizontal elastic support units and the second horizontal elastic support units as boundaries, respective barycentric positions of these mass bodies are almost the same in the vertical direction and horizontal direction.

The present invention relates to a flexible reticular structure which comprises a movable surface the movement of which is operated by operating means, and is characterized in that said surface is formed by a plurality of modules linked to one another. Said modules forming the surface are preferably linked to one another by means of attachment rods, each of said rods being housed in holes provided in at least two of said modules. The present invention prevents the need to disassemble and replace the entire movable surface, rather only the affected module or modules, for repair or maintenance.

The present invention relates to a flexible reticular structure which comprises a movable surface the movement of which is operated by operating means, and is characterized in that said surface is formed by a plurality of modules linked to one another. Said modules forming the surface are preferably linked to one another by means of attachment rods, each of said rods being housed in holes provided in at least two of said modules. The present invention prevents the need to disassemble and replace the entire movable surface, rather only the affected module or modules, for repair or maintenance.

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.

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.