A drive assembly for a food product slicing apparatus is provided which slices food products into slices. The drive assembly is mounted on a frame of the food product slicing apparatus and includes lower and upper conveyor assemblies coupled to the frame which move food products relative to the frame. The upper conveyor assembly is configured to move upward and downward relative to an upper plane defined by the lower conveyor assembly, and is further configured to pivot relative to the lower conveyor assembly to firmly grip the food products as they pass therebetween.

A front end conveyor includes a frame having a first side and a second side, a lower deck and an upper deck. The lower deck includes a plurality of sheet supports, and upper portions of the sheet supports lie in a first plane. The upper deck includes a plurality of sheet guides that define with the sheet supports a sheet transport path through the front end conveyor. A chad wall extends transversely to the sheet transport direction and has a top edge located below the sheet transport path and a front surface facing in the upstream direction and a plurality of fingers projecting from the front surface in the upstream direction. The top edge of the chad wall is positioned relative to the sheet transport path such that hanging chads depending from the sheets will impact the chad wall.

A front end conveyor includes a frame having a first side and a second side, a lower deck and an upper deck. The lower deck includes a plurality of sheet supports, and upper portions of the sheet supports lie in a first plane. The upper deck includes a plurality of sheet guides, and the plurality of sheet supports and the plurality of sheet guides define therebetween a sheet transport path for moving sheets in a sheet transport direction toward the downstream end of the front end conveyor. A transverse scrap conveyor is mounted below the lower deck to carry scrap in a direction perpendicular to the sheet transport direction. The transverse scrap conveyor is secured to and supported by the frame such that the transverse scrap conveyor is movable with the frame as a unit.

A front end conveyor include a lower deck having a plurality of lower sheet supports, an upstream upper deck having an upstream end at the upstream end of the front end conveyor, a downstream end and a plurality of first upper sheet guides and a downstream upper deck having an upstream end, a downstream end at the downstream end of the front end conveyor, and a plurality of second upper sheet guides. The lower sheet supports and the upper sheet guides define a sheet transport path for moving sheets of material though the conveyor. The downstream end of the upstream upper deck and the upstream end of the downstream upper deck are independently pivotably mounted to the frame such that the upstream end of the upstream upper deck and the downstream end of the downstream upper deck shiftable toward and away from the lower deck.

A front end conveyor includes a frame having a first side and a second side, a lower deck including a plurality of sheet supports and an upper deck including a plurality of sheet guides. Upper portions of the sheet supports lie in a first plane, and the plurality of sheet supports and the plurality of sheet guides define therebetween a sheet transport path for moving sheets in a sheet transport direction toward the downstream end of the front end conveyor. At least one helical brush is positioned at the sheet transport path and is configured to engage scrap material on the plurality of sheets. The conveyor also includes a drive configured to rotate the helical brush.

A front end conveyor includes a frame having a first side and a second side, a lower deck having a plurality of sheet supports and an upper deck having a plurality of sheet guides. Upper portions of the sheet supports lie in a first plane. The plurality of sheet supports and the plurality of sheet guides define therebetween a sheet transport path for moving sheets in a sheet transport direction toward the downstream end of the front end conveyor, and the front end system includes at least one blower directed at the sheet transport path and configured to dislodge scrap material from the sheets.

A loading apparatus for loading food products onto and/or into a slicing apparatus, in particular a high-speed slicer, comprises at least one magazine unit that includes a conveying means that endlessly circulates along a running direction. The conveying means is configured to lift the products to a transferring height at which the products can be transferred to the slicing apparatus and includes several product support surfaces, the product support surfaces being oriented essentially perpendicular to the running direction and positioned subsequently along the running direction with a space between each other. At least one product is loadable onto a respective product support surface for lifting the product to the transferring height.

A cutting apparatus for cutting an essentially V-shaped strip from meat products fed in a transport direction has a knife carrier to which two knife units are assigned. Each knife unit has a circular knife and a drive for rotationally driving the circular knife about a central axis of rotation. The two circular knives are set substantially in a V-shape to each other in a position enclosing an angle. An adjustable arrangement of the knife units provides for setting of the size of the angle. The offset of the two central axes of rotation to each other is equal to zero in the transport direction and the two knife units are adjustable exclusively synchronously with each other. A corresponding apparatus and method for cutting an essentially V-shaped strip from meat products fed in transport direction is also provided.

A food processing machine (10) and a method of cutting slices or portions from a food product (60, 70, 72, 74) in a food processing machine are described. The food processing machine comprises a cutter (30) to cut portions from a food product and a sensing apparatus (43, 45) configured to sense a profile of the food product. The machine is arranged to control sensing and cutting feed rates independently.

A system 10 for analyzing and trimming pork bellies and other three-dimensional food and non-food products which are to be subsequently portioned or sliced so as to achieve an optimum harvest of slices from the food product bearing in mind achieving a maximum yield together with a desired quality level of the portions/slices. The system 10 includes a conveyor 12 for carrying the workpieces (WP) to be trimmed prior to subsequent slicing of the workpiece past a scanning system 14 for scanning the workpiece WP to ascertain the physical characteristics of the workpiece, including, for example, its three-dimensional shape as well as its position on the conveyor. A cutting station 16 trims the workpiece WP into a desired two-dimensional shape which represents an optimum shape for the workpiece that seeks to maximize the harvest of slices from the workpiece while maintaining a desired quality level for the slices. A slicing station uses high speed cutters or slicers for portioning/slicing the workpiece into portions/slices which have been simulated by a processing system 18 employing a processor or computer 20.