An apparatus and method for compacting bulk material in an open container having a compacting device including a poker compactor, the poker compactor having an outer wall and being suitable to be inserted into an open container to cause the outer wall of the poker compactor to contact the bulk material and to degas and compact the bulk material in the open container. The outer wall of the poker compactor is at least partially formed by a gas-permeable, outer suction wall of a suction device and the poker compactor includes a vibration exciter to support degassing the bulk material by way of vibrating motion of the poker compactor generated by the vibration exciter. The vibration exciter is radially surrounded by a tube device and the suction wall surrounds the tube device.

An apparatus and method for compacting bulk material in an open container having a compacting device including a poker compactor, the poker compactor having an outer wall and being suitable to be inserted into an open container to cause the outer wall of the poker compactor to contact the bulk material and to degas and compact the bulk material in the open container. The outer wall of the poker compactor is at least partially formed by a gas-permeable, outer suction wall of a suction device and the poker compactor includes a vibration exciter to support degassing the bulk material by way of vibrating motion of the poker compactor generated by the vibration exciter. The vibration exciter is radially surrounded by a tube device and the suction wall surrounds the tube device.

A vibrating device (14) ensures the ordered rearrangement of folding boxes (3) in a receptacle (2) for an evacuation conveyor (8), provided with driving elements (12) whose vertices define a horizontal transport plane (S2). The device comprises: a movable support (15) able to support a receptacle (2) loaded with folding boxes (3), the support (15) having a contact surface (S1) designed to be in contact with the receptacle (2), and at least one controllable actuator (16a, 16b, 16c, 16d) comprising a displaceable end connected to the support (15) and able to displace the support (15) between: a retracted position in which the contact surface (S1) is positioned beneath the horizontal transport plane (S2), allowing a contact between the receptacle (2) and the driving elements (12), and a deployed position in which the contact surface (S1) is positioned above the horizontal transport plane (S2), preventing the contact between the receptacle (2) and the driving elements (12),
the actuator (16a, 16b, 16c, 16d) being likewise designed to cause the support (15) to vibrate about the deployed position in order to reorder the disposition of the folding boxes (3) contained in the receptacle (2).

A vibrating device (14) ensures the ordered rearrangement of folding boxes (3) in a receptacle (2) for an evacuation conveyor (8), provided with driving elements (12) whose vertices define a horizontal transport plane (S2). The device comprises: a movable support (15) able to support a receptacle (2) loaded with folding boxes (3), the support (15) having a contact surface (S1) designed to be in contact with the receptacle (2), and at least one controllable actuator (16a, 16b, 16c, 16d) comprising a displaceable end connected to the support (15) and able to displace the support (15) between: a retracted position in which the contact surface (S1) is positioned beneath the horizontal transport plane (S2), allowing a contact between the receptacle (2) and the driving elements (12), and a deployed position in which the contact surface (S1) is positioned above the horizontal transport plane (S2), preventing the contact between the receptacle (2) and the driving elements (12),
the actuator (16a, 16b, 16c, 16d) being likewise designed to cause the support (15) to vibrate about the deployed position in order to reorder the disposition of the folding boxes (3) contained in the receptacle (2).

Devices and methods for compaction of an asymmetric load are disclosed herein. In some embodiments, a movable upper structure is connected to a stationary base structure through front end pivot linkages and rear end pivot linkages. One or more actuators impart motion to the upper structure. The motion of the upper structure is controlled by adjusting the length and position of the pivot linkages. In other embodiments, the pivot linkages are attached to a pull arm that is attached to an actuator, and the pull arm imparts motion to the upper structure.

A shaker table for settling randomly oriented items in a generally rectangular container with sidewalls prone to bulge at lower portions thereof, including a pan with a generally horizontal bottom for supporting the container and an underlying pallet while being shaken, a power drive for shaking the pan, container, and pallet, and side restraints limiting lateral movement of the container during shaking movement.

The present disclosure provides a peanut whole-process production line and a method. The peanut whole-process production line includes a peanut cleaning system, a shell breaking system, a skin removing system, a peanut kernel classification system, an ultra-fine pulverization system and a classification packaging system; a first procedure is cleaning and impurity removal of peanuts, breaking of peanut shells is performed after the cleaning and impurity removal of peanuts, removal of peanut kernel skins and ultra-fine pulverization of the peanut shells are respectively performed after the breaking of peanut shells, classification of peanut kernels is performed after the removal of peanut kernel skins, and classification packaging of ultra-fine peanut shell powder is performed after the ultra-fine pulverization of the peanut shells; whole-process processing of peanuts is completed by using the peanut whole-process production line, and peanut resources are fully utilized.

The present disclosure provides a peanut whole-process production line and a method. The peanut whole-process production line includes a peanut cleaning system, a shell breaking system, a skin removing system, a peanut kernel classification system, an ultra-fine pulverization system and a classification packaging system; a first procedure is cleaning and impurity removal of peanuts, breaking of peanut shells is performed after the cleaning and impurity removal of peanuts, removal of peanut kernel skins and ultra-fine pulverization of the peanut shells are respectively performed after the breaking of peanut shells, classification of peanut kernels is performed after the removal of peanut kernel skins, and classification packaging of ultra-fine peanut shell powder is performed after the ultra-fine pulverization of the peanut shells; whole-process processing of peanuts is completed by using the peanut whole-process production line, and peanut resources are fully utilized.

A powder filling method includes introducing a tube into a can so that the lower end of the tube is near the bottom of the can. The powder in the can is introduced through the tube. The proximity of the lower end of the tube to the powder is controlled by retracting the tube as the powder fills the can.

A wrapped food product, the food product being preferably in the form of an infusion product, in particular in the form of a material in the form of powder, granules or pieces, such as tea, camomile, coffee or other, wrapped in a respective wrapper; the wrapper being made of biodegradable and/or organic film, which is wrapped around and closely connected, or adherent, to the material.