A cutting apparatus includes a cutting unit including a cutting blade that has a cutting edge for cutting a dresser board. An elastic wave detection sensor is disposed in the cutting unit, for detecting an elastic wave produced when the dresser board is cut. The elastic wave detection sensor produces an output signal representing the detected elastic wave when the cutting blade cuts the dresser board and is dressed thereby, the output signal being variable as the cutting blade is progressively dressed by the dresser board. A control unit stores in advance, as a threshold value, the value of the output signal when the dressing of the cutting blade is completed. The control unit stops cutting the dresser board with the cutting blade and finishes the dressing of the cutting blade when the output signal produced by the elastic wave detection sensor reaches the threshold value.

Device for controlling the sharpening state of a blade (2) having a cutting edge (20) delimited by two sides (21, 22) converging towards a plane (X) that contains the cutting edge itself. The device comprises two control surfaces each of which is in contact with a corresponding side (21, 22) of the cutting edge (20) and is connected with a transducer (R4), which produces an electrical displacement signal (S4) proportional to a displacement of the control surface with respect to said plane (X). Furthermore, the device comprises a processing unit (E) that receives said displacement signals (S4) and compares them, emitting an error signal if the comparison produces a value that exceeds a predetermined limit. The control surfaces are the surfaces that delimit an external groove (40) of a roller (4) that is free to translate along an axis (A4) perpendicular to said plane (X) and spaced from the blade (2) by an amount such that said cutting edge (20) passes in said groove (40).

Device for controlling the sharpening state of a blade (2) having a cutting edge (20) delimited by two sides (21, 22) converging towards a plane (X) that contains the cutting edge itself. The device comprises two control surfaces each of which is in contact with a corresponding side (21, 22) of the cutting edge (20) and is connected with a transducer (R4), which produces an electrical displacement signal (S4) proportional to a displacement of the control surface with respect to said plane (X). Furthermore, the device comprises a processing unit (E) that receives said displacement signals (S4) and compares them, emitting an error signal if the comparison produces a value that exceeds a predetermined limit. The control surfaces are the surfaces that delimit an external groove (40) of a roller (4) that is free to translate along an axis (A4) perpendicular to said plane (X) and spaced from the blade (2) by an amount such that said cutting edge (20) passes in said groove (40).

Device for controlling the sharpening state of a blade (2) having a cutting edge (20) delimited by two sides (21, 22) converging towards a plane (X) that contains the cutting edge itself. The device comprises two control surfaces each of which is in contact with a corresponding side (21, 22) of said cutting edge (20) and is connected with at least one transducer (R1, R2, R4), which produces an electrical displacement signal (S1, S2; S4) proportional to a displacement of the control surface with respect to said plane (X). Furthermore, the device comprises a processing unit (E) that receives said displacement signals (S1, S2, S4) and compares them, emitting an error signal if the comparison produces a value that exceeds a predetermined limit. The processing unit is connected to means (101, 102) for supporting and moving sharpening means (100).

Device for controlling the sharpening state of a blade (2) having a cutting edge (20) delimited by two sides (21, 22) converging towards a plane (X) that contains the cutting edge itself. The device comprises two control surfaces each of which is in contact with a corresponding side (21, 22) of said cutting edge (20) and is connected with at least one transducer (R1, R2, R4), which produces an electrical displacement signal (S1, S2; S4) proportional to a displacement of the control surface with respect to said plane (X). Furthermore, the device comprises a processing unit (E) that receives said displacement signals (S1, S2, S4) and compares them, emitting an error signal if the comparison produces a value that exceeds a predetermined limit. The processing unit is connected to means (101, 102) for supporting and moving sharpening means (100).

Cutting assembly for a food product high speed slicing machine, the cutting assembly (1) comprising a cutter (10) which is rotative around a central axis (A) and comprises a support disc (11), connected by its center to a drive unit (20) through a central shaft (21) concentric with the central axis (A), and a blade (30) releasably attached to a periphery of the support disc (11) by a fixation device, the blade (30) having a spiral cutting edge (31) lying in a cutting plane perpendicular to the central axis (A) and coplanar with a product holder (2); wherein the blade (30) is a non-closed curved blade; and the cutter (10) includes at least one blade (30), defining at least one independent continuous spiral cutting edge (31) with a ? ratio of at least thirty in at least most of the spiral cutting edge, so that the cut precision is improved.

Cutting assembly for a food product high speed slicing machine, the cutting assembly (1) comprising a cutter (10) which is rotative around a central axis (A) and comprises a support disc (11), connected by its center to a drive unit (20) through a central shaft (21) concentric with the central axis (A), and a blade (30) releasably attached to a periphery of the support disc (11) by a fixation device, the blade (30) having a spiral cutting edge (31) lying in a cutting plane perpendicular to the central axis (A) and coplanar with a product holder (2); wherein the blade (30) is a non-closed curved blade; and the cutter (10) includes at least one blade (30), defining at least one independent continuous spiral cutting edge (31) with a ? ratio of at least thirty in at least most of the spiral cutting edge, so that the cut precision is improved.

A log saw for cutting convolutely wound logs of web material is disclosed. The log saw comprises a cutting blade operating in a cutting plane, a log saw clamp for the retention of a convolutely wound log of web material such that the convolutely wound log of web material extends in a log advancing path through to the cutting plane, and control means connected to the clamping device.

A log saw clamp for temporarily restraining a convolutely wound log of web material for a log saw is disclosed. The log saw clamp comprises a support structure having a first and second cam disposed therein, a pair of opposed first and second paddles, and a first and second linkage.

A log saw clamp for temporarily restraining a convolutely wound log of web material for a log saw is disclosed. The log saw clamp comprises a support structure having a first and second cam disposed therein, a pair of opposed first and second paddles, and a first and second linkage.