A front end feeding device 23 between a cutter 10 and a fixed-length feeding hand 30 that feeds a strip member 5 on an upstream side of the cutter 10 feeds a front end of the strip member 5 a short distance to a downstream side of the cutter 10, a front end grasping hand 60 on the downstream of the cutter 10 holds the front end of the strip member 5 fed the short distance, the fixed-length feeding hand 30 holds a part of the strip member 5 fed the short distance on the upstream side of the cutter 10, the front end grasping hand 60 and the fixed-length feeding hand 30 synchronously feed the strip member 5 a long distance to the downstream side, and the cutter 10 cuts the strip member 5 having been fed the long distance.

A front end feeding device 23 between a cutter 10 and a fixed-length feeding hand 30 that feeds a strip member 5 on an upstream side of the cutter 10 feeds a front end of the strip member 5 a short distance to a downstream side of the cutter 10, a front end grasping hand 60 on the downstream of the cutter 10 holds the front end of the strip member 5 fed the short distance, the fixed-length feeding hand 30 holds a part of the strip member 5 fed the short distance on the upstream side of the cutter 10, the front end grasping hand 60 and the fixed-length feeding hand 30 synchronously feed the strip member 5 a long distance to the downstream side, and the cutter 10 cuts the strip member 5 having been fed the long distance.

A guidance system provides step-wise, real-time or near real-time video guidance to a cutting machine operator to efficiently cut up a lift into multiple products, where determining an efficient sequence of steps is laborious for an ordinary operator. The display can advantageously show the operator where to temporarily store various logs that are cut off from the lift, and how and when to reinsert them into the cutting machine for further cuts, whether by themselves, in side-by-side manner, and/or in stacks. Camera feedback can be used to ensure that the operator is properly positioning and orienting the lift/logs. The display can alternatively or additionally use simulation to guide the operator.

A powered cutter for strap includes a housing, a power supply mounted to the housing, a motor positioned at least in part in the housing and a drive train operably connected to the motor. A cutting head includes a plunger, a cutting blade operably mounted to the plunger, a hold-down biasedly mounted to the plunger, a foot and a shear edge. The drive train is operably connected to the plunger. The plunger moves toward the foot to move the hold-down into contact with the strap, securing the strap against the foot, and as the hold-down secures the strap, the cutting blade contacts and cuts the strap at the shear edge.

A food product slicing apparatus for slicing food products into slices is provided. A frame mounts a drive assembly which is configured to move the food products relative to the frame, a side strapping assembly which side straps a side of the food product, and a slicing blade configured to slice the food products into slices. The side strapping assembly is mounted to the frame proximate to the drive assembly. The side strapping assembly includes a releasable clamp which couples a blade of the side strapping assembly to the frame. The clamp can be released without the use of tools.

A food product slicing apparatus for slicing food products into slices is provided. A frame mounts a drive assembly which is configured to move the food products relative to the frame, a side strapping assembly which side straps a side of the food product, and a slicing blade configured to slice the food products into slices. The side strapping assembly is mounted to the frame proximate to the drive assembly. The side strapping assembly includes a releasable clamp which couples a blade of the side strapping assembly to the frame. The clamp can be released without the use of tools.

A food slicing includes a forward conveyor assembly located proximal to the blade assembly and a rearward conveyor assembly configured to transport the food product to the forward conveyor assembly. The rearward conveyor assembly is located immediately upstream from the forward conveyor assembly and gap is formed laterally between the forward conveyor assembly and the rearward conveyor assembly, in the longitudinal direction. An upper scanner unit proximal the gap scans an upper surface of the food product while a lower scanner unit located below the forward and rearward conveyor assemblies scans a lower surface of the food product as the food product passes across the gap, to obtain contour information of the lower surface of the food product.

A food slicing includes a forward conveyor assembly located proximal to the blade assembly and a rearward conveyor assembly configured to transport the food product to the forward conveyor assembly. The rearward conveyor assembly is located immediately upstream from the forward conveyor assembly and gap is formed laterally between the forward conveyor assembly and the rearward conveyor assembly, in the longitudinal direction. An upper scanner unit proximal the gap scans an upper surface of the food product while a lower scanner unit located below the forward and rearward conveyor assemblies scans a lower surface of the food product as the food product passes across the gap, to obtain contour information of the lower surface of the food product.

A food slicing system includes a hub fixedly secured to a drive shaft and configured to rotate with the drive shaft. The hub has a central pilot projection coaxial with the drive shaft, and flat, blade contacting surface surrounding the pilot projection. A counterweight is eccentrically mounted to the hub and rotatable between a first position and an second position relative to the hub. Wherein when the counterweight is in a first position, the counterweight is in axial alignment with pilot projection, and permits the blade to be attached to or removed from the hub via movement of the blade in the axial direction. When the counterweight is in the second position, the counterweight is eccentric to the pilot projection and is offset from the axis of rotation, to provide a predetermined amount of weight offset from the axis of rotation to counterbalance the weight of the blade.

A food slicing system includes a hub fixedly secured to a drive shaft and configured to rotate with the drive shaft. The hub has a central pilot projection coaxial with the drive shaft, and flat, blade contacting surface surrounding the pilot projection. A counterweight is eccentrically mounted to the hub and rotatable between a first position and an second position relative to the hub. Wherein when the counterweight is in a first position, the counterweight is in axial alignment with pilot projection, and permits the blade to be attached to or removed from the hub via movement of the blade in the axial direction. When the counterweight is in the second position, the counterweight is eccentric to the pilot projection and is offset from the axis of rotation, to provide a predetermined amount of weight offset from the axis of rotation to counterbalance the weight of the blade.