A method and an apparatus are provided for the grouped arrangement, orientation and packaging of stacked food products like patty stacks. The method includes feeding a food product by a first feed belt in the direction of a first X-axis, and then ejecting the food product onto a second feed belt to form stacked food products. The method also includes transporting the stacked food products by the second feed belt along a Y-axis generally perpendicular to the X-axis and in the direction of an orientation mask which is arranged above the second feed belt. The stacked food products are oriented by contacting the orientation mask. The oriented food products may therefore be grouped together in oriented rows for packaging when further moved along the Y-axis by the second feed belt. The method and apparatus enable rapid orienting of various types of food products that are typically stacked and packaged.

The invention provides a delivery system and layered stacking device for paper packages. The layered stacking device comprises a upper layer mechanism, a lower layer mechanism, and a pushing mechanism. The upper layer mechanism protrudes to an outlet of a delivery device to receive at least two paper packages. The paper packages will be stacked and neatly arranged on the upper layer mechanism. When the lower layer mechanism is raised to a first height and therefore close to the outlet, the upper layer mechanism will be withdrawn from the outlet of the delivery device, thereby the lower layer mechanism will receive the stacked paper packages that are dropped from the upper layer mechanism. Afterwards, when the lower layer mechanism is fallen to a second height, the pushing mechanism will push the stacked paper packages on the lower layer mechanism to a feeding device next the lower layer mechanism.

The invention provides a delivery system and layered stacking device for paper packages. The layered stacking device comprises a upper layer mechanism, a lower layer mechanism, and a pushing mechanism. The upper layer mechanism protrudes to an outlet of a delivery device to receive at least two paper packages. The paper packages will be stacked and neatly arranged on the upper layer mechanism. When the lower layer mechanism is raised to a first height and therefore close to the outlet, the upper layer mechanism will be withdrawn from the outlet of the delivery device, thereby the lower layer mechanism will receive the stacked paper packages that are dropped from the upper layer mechanism. Afterwards, when the lower layer mechanism is fallen to a second height, the pushing mechanism will push the stacked paper packages on the lower layer mechanism to a feeding device next the lower layer mechanism.

Techniques for product-stacking and case-packing are particularly adapted for product that is packaged in envelopes or flexibly-sided containers. Such products include may different types, such as foodstuffs, books, boxed goods, etc. In an example, a product-stacking and case-packing system may include a product-stacking assembly and a case-packing assembly. In the example, the product-stacking assembly may be configured with a plurality of pairs of flights, each pair of flights programmed to move according to operation of an associated pair servo motors, and programmed to receive and down-stack incoming product items into groups. In the example, the case-packing assembly may include a robotic arm and end-of-arm tool configured to grasp one or more groups of stacked product items, when pushed from the product-stacking assembly, and place each group of stacked product items in a case (e.g., a cardboard box).

Some manufacturing processes include forming stacks of manufactured objects for handling and/or processing. While some such manufactured objects are consistent in thickness, other are more irregular. Some manufactured objects are generally flat, but are also generally thicker along one edge. When objects having these characteristics are stacked, the cumulative effect of such inconsistent thickness results in an unbalanced stack. The disclosed apparatus and method utilize a novel rotating stacker that rotates the stack of manufactured objects as each new object is added to the stack, thereby distributing the thickness inconsistency of individual objects throughout the stack, producing a more uniform stack without manual intervention.

Some manufacturing processes include forming stacks of manufactured objects for handling and/or processing. While some such manufactured objects are consistent in thickness, other are more irregular. Some manufactured objects are generally flat, but are also generally thicker along one edge. When objects having these characteristics are stacked, the cumulative effect of such inconsistent thickness results in an unbalanced stack. The disclosed apparatus and method utilize a novel rotating stacker that rotates the stack of manufactured objects as each new object is added to the stack, thereby distributing the thickness inconsistency of individual objects throughout the stack, producing a more uniform stack without manual intervention.

In one aspect, a sheet interleaver for a slicing machine having a slicing station for slicing a food product is provided. The sheet interleaver includes a feed device for providing a sheet material between slices of the food product and an electrostatic charging system configured to generate an electrostatic charge. The electrostatic charge generates a force urging the sheet material to move in a direction toward the food product. In one aspect, a method for coupling a sheet material to a food product configured to be sliced by a slicing machine is provided. The method includes feeding a sheet material for positioning between slices of the food product and generating an electrostatic charge to generate a force urging the sheet material to move in a direction toward the food product.

The present invention relates to a stacker module for a folder-gluer machine, the stacker module being located downstream of a transfer module in a direction of transportation of the folder-gluer machine and configured to receive folding boxes from a conveyor in the transfer module. The stacker module comprises a loading surface configured to receive a plurality of folding boxes in order to form a stack and to descend vertically as the number of folding boxes on the loading surface increases, and a linearly movable ejector configured to eject the stack from the loading surface. A front abutment guide configured to move between an abutment and a clearing position to retain and release the stack.

The present invention relates to a stacker module (28) for a folder-gluer machine (1). The stacker module comprises a loading surface (90) configured to receive a plurality of folding boxes and to descend vertically as the number of folding boxes on the loading surface increases, and a linearly movable ejector (76) configured to be moved from a retracted position (RP) to an extended position (DP). The stacker further comprises an upper guide (110), configured to move between a clearing position (CP) which is vertically distant from the upper surface of the stack, and a guiding position (GP), in which the upper guide is located closer to the upper surface of the stack, and wherein the upper guide is in the guiding position when the ejector is moved from the retracted position to the evacuation position.

An assembly (10) to dispatch bags (14). The assembly (10) includes a conveyor (12) that provides rows of bags (14), with the rows of bags (14) supported on a first delivery assembly (18) that moves each row downward to form stacks (47) of bags (14) on a second delivery assembly (34). Stacks (14) of the bags (14) are then moved downward to be moved into containers or boxes.