An orbital knife including a support structure; a yoke rotatably attached to the support structure constituting a yoke hub and a plurality of yoke arms; one or more rotatable knife rolls securely connected to at least one of the plurality of yoke arms; one or more blades attached to each of the one or more knife rolls and including a cutting element; one or more sun gears rotatably attached to the support structure; an anvil roll rotatably attached to the support structure; and one or more planet gears wherein each knife roll has rotatably attached thereto at least one planet gear and each planet gear is mated with a sun gear.

An orbital knife including a support structure; a yoke rotatably attached to the support structure having a yoke hub and a plurality of yoke arms; one or more rotatable knife rolls connected to at least two of the plurality of yoke arms; one or more blades attached to each of the one or more knife rolls; one or more sun gears rotatably attached to the support structure; an anvil roll rotatably attached to the support structure; one or more idler gears wherein each such idler gear is mated with one of the one or more sun gears; and one or more planet gears wherein each knife roll has rotatably attached thereto at least one planet gear and each planet gear is mated with one of the one or more idler gears, with the sun gear driving the idler gear which in turn drives the planet gear.

Disclosed is a cutting device (1) for fabricating a fiber-based shell (10). The cutting device (1) has a first mandrel (20) which can rotate about an axis of rotation (D1) and on which the fiber-based shell (10) can be arranged. The cutting device (1) has a knife (30) which can rotate about an axis of rotation (M). The axis of rotation (D) of the first mandrel (20) and the axis of rotation (M) of the knife (30) are adjacent to each other.

Disclosed is a cutting device (1) for fabricating a fiber-based shell (10). The cutting device (1) has a first mandrel (20) which can rotate about an axis of rotation (D1) and on which the fiber-based shell (10) can be arranged. The cutting device (1) has a knife (30) which can rotate about an axis of rotation (M). The axis of rotation (D) of the first mandrel (20) and the axis of rotation (M) of the knife (30) are adjacent to each other.

A cartilage cutting device for a bone-in meat according to an embodiment includes a cutting blade disposed on a conveying path for a bone-in meat and an elastic support portion for elastically supporting the cutting blade so that the cutting blade can recede by a reaction force applied to the cutting blade when cutting the bone-in meat. The elastic support portion is configured such that an elastic supporting force of the elastic support portion is switchable between a first elastic supporting force and a second elastic supporting force. The first elastic supporting force is capable of cutting a cartilage adhering to a bone part of the bone-in meat. The second elastic supporting force is smaller than the first elastic supporting force and is incapable of cutting the cartilage.

A method and apparatus for improving processing whole muscle for a thinly slice meat item, such as a meat item for Philly Cheese Steaks. One implementation of the method and apparatus as disclosed and claimed herein includes grounding whole muscle and pumping the ground whole muscle through an in-line rotary multi-blade slicer and further extruding the product from the in-line slicer and pumping the product through a cooking horn. For one implementation of the method and apparatus, the product is pumped through and in-line sheeter before pumping the product through the cooking horn.

A method and apparatus for improving processing whole muscle for a thinly slice meat item, such as a meat item for Philly Cheese Steaks. One implementation of the method and apparatus as disclosed and claimed herein includes grounding whole muscle and pumping the ground whole muscle through an in-line rotary multi-blade slicer and further extruding the product from the in-line slicer and pumping the product through a cooking horn. For one implementation of the method and apparatus, the product is pumped through and in-line sheeter before pumping the product through the cooking horn.

A food processor having an external slicing disc adjustment mechanism is provided. The food processor includes a work bowl and a lid configured to be selectively removable therefrom. The food processor further includes a slicing disc having a disc body and a slicing blade internal to the work bowl, and a mechanism for adjusting a spacing between the disc body and slicing blade. The mechanism includes a rotatable lever accessible form outside the work bowl.

A food processor having an external slicing disc adjustment mechanism is provided. The food processor includes a work bowl and a lid configured to be selectively removable therefrom. The food processor further includes a slicing disc having a disc body and a slicing blade internal to the work bowl, and a mechanism for adjusting a spacing between the disc body and slicing blade. The mechanism includes a rotatable lever accessible form outside the work bowl.

The present invention relates to a portioning machine for dividing a strand-like product into individual portions and a method of controlling such portioning machine. The portioning machine includes a magazine turret attachment for receiving the strand-like product, a pressing unit for pressure-compacting the strand-like product at least in its longitudinal direction, and a portioning and cutting device for portioning and separating individual portions from the strand-like product. The magazine turret attachment has a base segment and a turret segment which have chute portions oriented coaxially with respect to one another for forming at least one reception chute for the strand-like product and which are rotatable about a common axis for positioning the reception chute in a cutting position; and wherein the pressing unit for pressure-compacting the strand-like product has at least one pressure ram and a counter-pressure element. The counter-pressure element is a slide element arranged between the base segment and the turret segment of the magazine turret attachment and is reversibly movable in a direction at least approximately perpendicular to the axis of rotation of the magazine turret attachment between a release position and a closure position for unblocking or closing the reception chute placed in the cutting position.