Disclosed is a line catcher-type waterjet cutting apparatus in which a workpiece is subjected to the waterjet processing in a state of being clamped by a workpiece edge clamping device and a separate driving unit for the workpiece edge clamping device is provided, and in which the workpiece is clamped by the workpiece edge clamping device during the waterjet processing, while the workpiece is easily decoupled from the workpiece edge clamping device after the waterjet processing is completed, so that the waterjet processing is carried out while reciprocally conveying the workpiece in an X-direction, thereby increasing the processing accuracy of the waterjet processing and easily automating the waterjet processing.

Disclosed is a line catcher-type waterjet cutting apparatus in which a workpiece is subjected to the waterjet processing in a state of being clamped by a workpiece edge clamping device and a separate driving unit for the workpiece edge clamping device is provided, and in which the workpiece is clamped by the workpiece edge clamping device during the waterjet processing, while the workpiece is easily decoupled from the workpiece edge clamping device after the waterjet processing is completed, so that the waterjet processing is carried out while reciprocally conveying the workpiece in an X-direction, thereby increasing the processing accuracy of the waterjet processing and easily automating the waterjet processing.

Disclosed is a line catcher-type waterjet cutting apparatus in which a workpiece is subjected to the waterjet processing in a state of being clamped by a workpiece edge clamping device and a separate driving unit for the workpiece edge clamping device is provided, and in which the workpiece is clamped by the workpiece edge clamping device during the waterjet processing, while the workpiece is easily decoupled from the workpiece edge clamping device after the waterjet processing is completed, so that the waterjet processing is carried out while reciprocally conveying the workpiece in an X-direction, thereby increasing the processing accuracy of the waterjet processing and easily automating the waterjet processing.

Disclosed is a line catcher-type waterjet cutting apparatus in which a workpiece is subjected to the waterjet processing in a state of being clamped by a workpiece edge clamping device and a separate driving unit for the workpiece edge clamping device is provided, and in which the workpiece is clamped by the workpiece edge clamping device during the waterjet processing, while the workpiece is easily decoupled from the workpiece edge clamping device after the waterjet processing is completed, so that the waterjet processing is carried out while reciprocally conveying the workpiece in an X-direction, thereby increasing the processing accuracy of the waterjet processing and easily automating the waterjet processing.

A fruit cutting apparatus includes an appliance housing having a bottom wall a body portion extending upwardly therefrom. A cutting chamber is coupled to the appliance housing and includes a continuous side wall defining an open top and bottom. A rotating platform assembly is coupled to the appliance housing and has a second portion extending upwardly into the cutting chamber, the rotating platform assembly including a support surface having a plurality of prongs configured to impale and secure the fruit piece. A cutting blade is positioned in the body portion and is slidably movable between deployed and retracted configurations. An input assembly enables selection of a cutting style, each selection being associated with programming instructions that cause a processor to selectively actuate the blade to deploy, orient its blade tip, and actuate the rotating platform to rotate the fruit piece as it is cut as selected.

A fruit cutting apparatus includes an appliance housing having a bottom wall a body portion extending upwardly therefrom. A cutting chamber is coupled to the appliance housing and includes a continuous side wall defining an open top and bottom. A rotating platform assembly is coupled to the appliance housing and has a second portion extending upwardly into the cutting chamber, the rotating platform assembly including a support surface having a plurality of prongs configured to impale and secure the fruit piece. A cutting blade is positioned in the body portion and is slidably movable between deployed and retracted configurations. An input assembly enables selection of a cutting style, each selection being associated with programming instructions that cause a processor to selectively actuate the blade to deploy, orient its blade tip, and actuate the rotating platform to rotate the fruit piece as it is cut as selected.

A paper toweling dispenser for dispensing paper toweling from a roll of paper toweling including a top roller located between the paper roll and the drum of the dispenser which moves in radial cams along the outer circumference of the drum as a pulling force is applied to the leading edge of the paper toweling by a user.

A system for processing a line of material along a path and a tear-assist apparatus. The tear-assist comprising a driving portion that drives the line of material along the path, a sensing unit that detects pulling of the line of material in a first direction along the path away from the driving portion, and a cutting member for cutting the line of material. The driving portion can also be configured to drive the line of material in the first direction along the path to dispense the material.

A system for processing a line of material along a path and a tear-assist apparatus. The tear-assist comprising a driving portion that drives the line of material along the path, a sensing unit that detects pulling of the line of material in a first direction along the path away from the driving portion, and a cutting member for cutting the line of material. The driving portion can also be configured to drive the line of material in the first direction along the path to dispense the material.

A mechanical part-stream sampler includes a housing positionable over a conveyor belt from which material is to be sampled. The housing encases one or more cutter arms and adjustable cutters. The cutter arms rotate 360 degrees such that the cutters extract a sample of material from the conveyor belt and deposit the sample in a discharge chute in the housing for later analysis. A programmable logic controller and human machine interface screen can be used to operate the sampler and to control the timing and speed of the cutter arms.