DEVICE FOR CUTTING A SHEET OR LAYER OF MATERIAL

Abstract

A device is described for cutting a sheet or layer of material (C) advancing on a working plane (32). A blade (30) cuts the material moved on the working plane,

To avoid wear or damages to the working plane (32) the blade (30) comprises a cutting edge (38) which is suspended within a cavity (34) formed in the working plane, so that the cutting edge can come out from the material in correspondence of the cavity.

Claims

1. Device for cutting a sheet or layer of material advancing on a working plane, comprising: a working plane on which to advance the material, a blade adapted to cut the material moved on the working plane, the blade comprising a cutting edge which is suspended within a cavity formed in the working plane, so that the cutting edge can come out from the material in correspondence of the cavity.

2. Device according to claim 1, wherein the cavity is a concavity formed in the working plane.

3. Device according to claim 1, wherein the cavity is a pass-through opening of the working plane.

4. Device according to claim 1, wherein the blade is circular.

5. Device according to claim 1, wherein the blade is connected to an electric motor to be set in rotation.

6. Device according to claim 5, wherein the blade is comprised in the rotor of the electric motor.

7. Device according to claim 5, wherein the blade comprises a circular toothing engaged with a pinion connected to the electric motor.

8. Device according to claim 5, comprising a pinion integral with the blade, and a transmission system to transmit rotary motion from a shaft operated by the electric motor to the pinion

9. Device according to claim 8, wherein the transmission system comprises a belt or a chain engaged around the pinion and around the shaft.

10. Device according to claim 8, wherein the transmission system comprises a toothed wheel or a train gear o toothed gears, one of which is keyed on the shaft and one is keyed on, or in substitution of, the pinion.

11. Device according to claim 8, wherein the shaft comprises a smooth cylindrical surface, and the transmission system comprises a train of smooth wheels or clutches, one of which is keyed onor in substitution ofthe pinion and one is mounted in contact with the smooth cylindrical surface to receive rotary motion.

12. Device according to claim 1, wherein the blade is comprised in the rotor of an electric motor.

13. Device according to claim 12, wherein the blade is integrally connected to the rotor of a motor (M) whose stator is mounted movable to move the blade close to or away from the working plane.

14. Device according to claim 1, comprising an element on which the blade is rotatably mounted, the element being movable in direction orthogonal to the working plane so as to move the blade toward a lowered working position toward the working plane or a resting position raised or moved away from the working plane.

15. Device according to claim 1, comprising a vibrator drive adapted to vibrate the blade, e.g. by ultrasound.

16. Device according to claim 15, wherein the vibrator drive is configured to vibrate the blade alternately along its cutting plane and perpendicular to the working plane.

17. Device according to claim 15, wherein the vibrator drive is applied between two mounting shoulders for the blade and a vertical motion actuator for the blade.

Description

[0034] The advantages of the invention will be more apparent from the following description of a preferred embodiment, with reference to the attached drawings wherein:

[0035] FIG. 1 shows a known cutting system,

[0036] FIG. 2 shows a basic diagram of a cutting system according the invention;

[0037] FIGS. 3-6 show variants for a cutting system according to the invention.

[0038] In the figures identical numbers indicate identical or similar parts.

[0039] The cutting system envisages a rotating circular blade 30 adapted to cut a sheet of cardboard C advancing (direction F) over a hard working plane 32. Under the blade 30, the plane 32 has a cavity or depression 34, preferably of circular cross-section, receding in negative compared to a flat portion P on which the cardboard C slides. The distance between the lying position of the plane P and the bottom of the cavity 34 has a maximum of value D2.

[0040] The cutting edge of the blade 30 is kept suspended inside the cavity or depression 34, so that part of its lower edge 38 is located at a maximum distance D1 from the level of the plane P.

[0041] Note that the condition D1<D2 ensures no contact between the edge 38 and the surrounding fixed parts.

[0042] D1 may e.g. be 1 mm. D2 may be e.g. 1.5 mm,

OPERATION

[0043] By constructional geometry, when the cardboard C meets the blade 30 is cut from side to side and pierced through completely, so much that a part of the blade 30, the edge 38, protrudes from the cut cardboard C by a portion approximately D3 long towards and within the cavity 34.

[0044] Variants

[0045] The cavity or depression 34 may be advantageously (simple solution) a concave zone in correspondence of which the working plane 32 has a recess with respect to the surrounding plane P contacting the sheet or layer of material C. The concave zone may have shape the e.g. of a spherical cap or a linear slot or have cylindrical cross-section.

[0046] The bottom of the cavity or depression 34 may be parallel to the plane P or curved, to reproduce an offset complementary profile of the edge 38 of the blade 30. In particular, the cross-section of the cavity 34 may have a radius of curvature approximately equal to that of the cutting edge of the blade 30.

[0047] It is possible, however, to also use a slot or a pass-through opening with respect to the plane 32.

[0048] The blade 30 may be [0049] mounted idle or rotating through an operator drive and/or vibrating; and/or [0050] not necessarily circular, i.e. a linear blade, preferably moved alternately, or a tip.

[0051] To prevent jamming or bending of the cardboard C below the blade 30, and too much advancing drag for the cardboard C, it is preferable to maintain the cavity 34 of contained size.

[0052] One embodiment is illustrated in FIG. 3, wherein a blade 30 is set into rotation through a pinion 40 which is integral with the blade 30 itself, preferably in a coaxial manner. The pinion. 40 (or the rotation axis of the blade) is e.g. connected to a support 60, e.g. in the form of one or two movable shoulders or an oscillating element (preferably a fork on which the blade is rotatably engaged). The support 60 is movable in the direction orthogonal to the working plane 32, by means of an actuator, so as to move the blade 30 to a working position (lowered toward the working plane 32) or a resting position (raised or moved away from the working plane 32).

[0053] The pinion 40 is preferably connected to a motor or an actuating means, so as to receive rotary motion and transfer it to the blade 30 to make it rotate. Preferably the rotary motion is taken from a shaft 50 coaxial to the pinion 40 and the blade 30, the shaft 50 thereby allowing to operate also several blades 30 placed parallel to each other on side-by-side supports 60.

[0054] The transmission system for transmitting rotary motion from the shaft 50 (or from an output shaft of a generic electric motor) to the blade 30 and/or to the pinion 40 may vary.

[0055] Such transmission system may comprise e.g.: [0056] a belt or chain 52 (FIG. 3) which engages around the pinion (or spool) 40 and around a disk 54 keyed on the shaft 50 or around the shaft 50 itself; and/or [0057] a toothed wheel 62 or a train of gears or sprockets 62 (FIG. 4), of which one is keyed on the shaft 50 and one is keyed on (or in substitution for) the pinion 40; and/or [0058] a train of smooth wheels or clutches 72 (FIG. 5), one of which is keyed on the shaft 50 and one is keyed on (or in substitution for) the pinion 40. In this variant, the shaft 50 may also be a smooth shaft and a smooth wheel or friction may be simply mounted in contact with the smooth shaft to receive rotary motion. The use of friction wheels or smooth wheels has the advantage that the possible rotation blockage of a single blade does not influence the others, and that the meshing of the same wheels, in the case of single motor embodiment, is not influenced by the mutual position of the teeth.

[0059] Another preferred solution, which ensures compactness, is that the blade 30 is comprised in the rotor of an electric motor (e.g. a brushless and/or synchronous or asynchronous motor). See the example of FIG. 6. The blade 30 is integrally connected with the rotor 80 of a motor M whose stator 82 is preferably connected with a movable support like the said vertically movable support 60. The advantage of this variant resides in the elimination of mechanical links or transmission shafts, thereby making the system much more compact and flexible for various types of cutting.

[0060] The motion of the blade 30 needs not necessarily be rotational. Another variant provides that such motion is generated by a sonotrode applied to the blade. In particular the sonotrode may be applied between two shoulders for mounting the blade and a vertical-movement actuator, or between said support 60 and its actuator. The cutting energy in this case is supplied by high-frequency vibrations generated by the sonotrode (ultrasound.).