The invention relates to a device for moving portions each comprising at least one slice separated from a food product, in particular by a slicing device, in particular by a high-speed slicer, having a plurality of individually movable transport movers for transporting portions, having a track system for the transport movers, in which the transport movers can be moved along at least one specified track in a transport direction and having a control device for controlling the movements of the transport movers in the track system, wherein the transport movers each comprise at least one runner cooperating with the track system and at least one portion carrier mounted on the runner, wherein for at least one sub-section of the track, in particular a section at risk of contamination, a discharge device is provided which is designed to at least intermittently discharge next to the section, contamination and/or incorrect portions originating from the foods, in particular occurring when cutting the food products and/or during handling of the portions.

A cutting mechanism is provided for a dunnage conversion machine 10 that selectively cuts dunnage sheet stock drawable through the cutting mechanism. The cutting mechanism includes a frame and a pair of opposed cutting blades through which the sheet stock is drawable. The cutting blades include a driven blade and a biased blade, each supported relative to the frame for movement into and out of contact with one another. The driven blade is movable towards the biased blade to cut the sheet stock. The biased blade is biased against movement away from the driven blade to allow for self-adjustability to counter wear of one or both of the opposed blades. Contact of the opposed blades with one another causes the biased blade to be deflected away from the driven blade.

A cutting mechanism is provided for a dunnage conversion machine 10 that selectively cuts dunnage sheet stock drawable through the cutting mechanism. The cutting mechanism includes a frame and a pair of opposed cutting blades through which the sheet stock is drawable. The cutting blades include a driven blade and a biased blade, each supported relative to the frame for movement into and out of contact with one another. The driven blade is movable towards the biased blade to cut the sheet stock. The biased blade is biased against movement away from the driven blade to allow for self-adjustability to counter wear of one or both of the opposed blades. Contact of the opposed blades with one another causes the biased blade to be deflected away from the driven blade.

Disclosed are a control device for a power tool and a power tool provided with the control device. The control device includes an operation control interface which is provided with a manually operated controller; an impedance-measuring safety interface, wherein the impedance-measuring interface includes a first manual contact electrode and a second manual contact electrode which are electrically isolated from each other, and wherein the manual contact electrodes are provided on the controller and extend over a manual bearing surface of the controller. The device is suitable for controlling and ensuring the safe use of power tools, especially electrical tools, such as pruning shears.

A bread cutting machine has a circular blade that is moveable in a guide gap through an extension gap of a machine housing from a waiting position into a cutting space. When the blade is in the waiting position, the guide gap is coverable by a rocker displaceable away from the guide gap simultaneously with the extension of the blade from the waiting position, whereby the guide gap is opened. A cover plate is rigidly fastened to a side surface of the rocker, projects vertically away from the rocker, and covers the extension gap whenever the blade is in the waiting position. By a positive guide, the cover plate is moveable away from the extension gap simultaneously with the movement of the rocker, whereby the extension gap is opened.

Disclosed is an apparatus for mechanically splitting materials, including a body with a cutting element arranged relative thereto. The cutting element includes at least one cutting surface oriented vertically. The splitting apparatus includes the cutting element applying an upward pressure against the material which is split when a separate downward force is applied to the material. The body of the splitting apparatus also includes a safety element to protect the user from the cutting element; an elongate supporting element to distance the safety element from either or both the cutting element and a surface on which the splitting apparatus is used; a stabilizing element to stabilize the splitting apparatus relative to a surface on which the splitting apparatus is used; and optionally a deflecting element to deflect split materials away from the cutting element and container element to contain therewithin split materials produced during the splitting.

Disclosed is an apparatus for mechanically splitting materials, including a body with a cutting element arranged relative thereto. The cutting element includes at least one cutting surface oriented vertically. The splitting apparatus includes the cutting element applying an upward pressure against the material which is split when a separate downward force is applied to the material. The body of the splitting apparatus also includes a safety element to protect the user from the cutting element; an elongate supporting element to distance the safety element from either or both the cutting element and a surface on which the splitting apparatus is used; a stabilizing element to stabilize the splitting apparatus relative to a surface on which the splitting apparatus is used; and optionally a deflecting element to deflect split materials away from the cutting element and container element to contain therewithin split materials produced during the splitting.

In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

In a slicer, in which a number of service operations, such as cleaning operations, maintenance operations, etc., are to be carried out before and after slicing operation, it is possible according to the invention for the operator to switch from a normal slicing mode to a service mode, within which a control unit automatically and triggered by a specific start event initiates defined actions, for example after opening a specific protective door as a start event, to move moving working parts located behind it, such as a feed conveyor, into a cleaning and changing position.

In a slicer, in which a number of service operations, such as cleaning operations, maintenance operations, etc., are to be carried out before and after slicing operation, it is possible according to the invention for the operator to switch from a normal slicing mode to a service mode, within which a control unit automatically and triggered by a specific start event initiates defined actions, for example after opening a specific protective door as a start event, to move moving working parts located behind it, such as a feed conveyor, into a cleaning and changing position.