ITTO970627A1 - IMPROVED SHAFT FOR SUPPORTING CUT SECTIONS OF REEL IN A CUT-REEL MACHINE. - Google Patents

Description

DESCRIPTION of the industrial invention entitled: "Improved shaft for supporting cut sections of reel in a slitter-winder machine"

DESCRIPTION

The present invention relates to a shaft for supporting cut reel sections in a slitter-winding machine and to a slitting-rewinding machine comprising such a shaft.

In the present discussion, the term slitting-winding machine means a machine capable of unwinding a reel of web material, for example paper or plastic film, cutting it perpendicular to its axis into two or more sections and rewinding the cut sections, forming coils of reduced axial extension compared to that of the starting coil.

The cut sections are usually rewound on a pair of distinct shafts, such that contiguous sections in the source reel are rewound over different shafts in a staggered checkerboard arrangement. In particular, the various sections are rewound on respective tubular cores, usually of cardboard, positioned coaxially around the shafts.

More particularly, the present invention relates to a shaft for supporting cut sections of coils, comprising a cylindrical body having on its external surface at least one recess suitable for housing an elastic casing which can be connected to a source of pressurized fluid, for example air. tablet, and a plurality of first annular members arranged along the body coaxially thereto.

According to a known technique described in EP-A-767 130, the first annular members are capable of expanding circumferentially following the inflation of the elastic envelope and of exerting a pressure against the internal surfaces of the cores, on which the cut sections of coil, allowing the transmission of the rotation motion from the shaft to the latter.

However, the circumferential expansion of the first annular members does not guarantee a secure locking in the axial direction of the cut coil sections. It is thus necessary to provide spacers between each pair of sections cut side by side, in order to prevent their sliding in the axial direction. The arrangement of these spacers on the shaft also involves an additional processing step with related costs and complications of the production process.

In order to obviate this drawback, the subject of the present invention is a shaft of the type indicated above and characterized in that it comprises a plurality of second annular members arranged along the body, coaxially with respect to this and in a radially external position with respect to the aforementioned first annular members. , between at least a second and a first annular member there being at least one seat suitable for housing an engagement element capable of protruding radially from the external surface of the second annular member following a relative rotation movement of the first annular member with respect to the second annular member and applying localized pressure to the facing internal surface of one of the cores.

This localized pressure makes the cut section of the reel and the relative core integral with the underlying annular member, avoiding relative sliding both in the circumferential direction and in the axial direction.

A further object of the present invention is a slitting-winding machine comprising at least one shaft of the type indicated above.

Further advantages and characteristics of the present invention will become evident from the detailed description which follows, made with reference to the attached drawings, provided purely by way of non-limiting example, in which:

Figure 1 is a perspective view of a slitting-winding machine comprising a pair of shafts according to the invention,

Figure 2 is a side elevation view of the machine of Figure 1,

Figure 3 is a sectional view of one of the shafts of the invention along the line III-III of Figure 1, e

Figure 4 is a section view along the line IV-IV of Figure 3.

The reference number 10 indicates in Figures 1 and 2 a cutting-winding machine known per se and described here only briefly.

The machine 10 comprises a support frame 12, on which a first shaft 14 is pivoted, which can be rotated and adapted to support a reel 16 of web material to be unwound.

On the frame 12 there are also mounted a plurality of return rollers 18 of the strip 20 unwound from the reel 16 and a cutting shaft 22 which supports longitudinally spaced apart a plurality of knives, not visible in the figures, capable of cutting the strip into several sections. 20 in directions parallel to the length of the latter and perpendicular to the axes of the first shaft 14 and of the deflection rollers 18.

Finally, hinged on the frame 12 is a pair of rewinding shafts 24 provided with means capable of causing their rotation and on which tubular cores 26, usually made of pressed cardboard, are positioned longitudinally spaced from each other. A respective section 28 of cut tape is wound around each core 26, forming a reel of reduced axial extension with respect to the original reel 16.

Each rewinding shaft 24 comprises (Figs. 3 and 4) a cylindrical body 30 which has, on its external surface, a plurality of circumferentially equally spaced recesses 32, of rectangular section and extending rectilinearly and parallel to the axis 34 of the shaft 24.

Each recess 32 houses a respective elastic casing 36 which can be connected in a manner known per se and not illustrated in the figures (for example by means of ducts made in the body 30) to a source of pressurized fluid, for example compressed air.

A plurality of first annular members 38 are arranged along the body 30 coaxially with respect thereto. Furthermore, a plurality of second annular members 40 is arranged along the body 30, coaxially with respect to this and in a radially external position with respect to the first annular members 38. Each second annular member 40 is arranged around a first annular member 38, so that the two associated annular members 38, 40 are symmetrically arranged with respect to a plane perpendicular to the axis 34 of the shaft 24.

Respective rolling bearings 42 are interposed between the pairs formed by a second 40 and a first 38 annular member associated and axially arranged in series, comprising an outer ring 44 and an inner ring 46 between which a crown of balls 48 is interposed.

Each second annular member 40 has a T-shaped section with wings 50 projecting laterally and resting on the respective outer rings 44 of the adjacent bearings 42.

Between each first annular member 38 and the associated second annular member 40 which surrounds it, a plurality of circumferentially spaced seats adapted to house a respective engagement element 52 shaped in the form of a sphere and susceptible, as will be explained in detail in the following description of operation, to protrude radially from the outer surface of the second annular member 40.

Each seat is formed by a radial hole 54 with a conical section made in the second annular member 40 and by a portion cut 56 along a chord of the outer circumference of the first annular member 38 and radially aligned with respect to the associated hole 52.

A tooth 58 protrudes radially outward from each first annular member 38 into a circumferentially extending slot 60 which is made in the second associated annular member 40.

A respective lamina 62 of friction material is also arranged between each elastic casing 36 and the facing internal surfaces of each first annular member 38.

In the operation of the machine 10 (figs. 1 and 2), the strip 20 which is unwound by hand from the reel 16 is cut into several sections perpendicular to the axis of the reel 16 by the knives mounted on the shaft 22.

Then the cut sections 28 of the tape 20 form coils of reduced axial extension as a result of their rewinding around a respective core 26 positioned on one of the shafts 24, which are made to rotate around their own axis.

The engagement between the cores 26 and the relative shaft 24 is determined following the inflation of the envelopes 36 which causes a pressure of the foils 62 against the internal surface of the first annular members 38 which are thus driven into rotation by friction together with the body 30 The second annular members 40, on the other hand, remain at first immobile, until the tooth 58 of the respective first annular member 38 which rotates abuts against one of the lateral surfaces of the slot 60 made in the second annular member 40. The tooth 58 and the associated slot 60 thus constitute means capable of limiting the relative rotation movement of the first annular member 38 with respect to the second annular member 40 which surrounds it.

This relative rotation - which can advantageously be of the order of about 15 ° - causes the balls 52 to be projected outside the holes 54, since in correspondence with their lower part it is no longer located (contrary to what is illustrated in the figures 3 and 4) a cut portion 56 along a chord of the outer circumference of the first annular member 38, but a solid curved portion.

The balls 52 - whose complete exit from the holes 54 is prevented by the conical shape of the latter - are thus able to apply a localized pressure to the facing internal surface of the associated core 26, making it integral with the underlying annular member 40 both in the axial direction than in the circumferential direction.

In this way the rotation of the body 30 of the shaft 24 is transmitted through the annular members 38, 40 to the cores 26, around which the relative cut sections 28 of the coil begin to wind.

For this operation to be carried out correctly, it is also necessary to ensure that the tangential speed and therefore the tension to which the various sections 28 are subjected are at all times equal to an optimal value, the same for all sections 28.

The tangential speed is given by the product of the angular speed of rotation by the radius of the section 28 which is being wound. This latter value can, however, vary between the various cut sections 28, if the thickness of the material constituting the original reel 16 is not constant over the entire width of the tape, for example due to manufacturing imperfections.

Therefore, to keep the tangential velocity of the various sections 28 constant, the respective angular velocity for each of these must be varied in such a way as to compensate for the variations in the length of the beam due to anomalous variations in the thickness of the material constituting the original coil 16.

Since the angular velocity of the shaft 24 is evidently the same in correspondence with all the cut sections 28, it is necessary that the latter can possibly slide circumferentially with respect to the shaft 24, independently of each other, to allow a variation of their angular velocity .

According to the invention, this sliding can take place between the body 30 of the shaft 24 and the surrounding first annular members 38, each of which is integral together with the associated second annular member 40 with a single cut section 28. The body 24 and the first annular members 38 are in fact held together only by the friction forces exchanged at the laminae 62 and not by protruding elements which engage an abutment surface.

Therefore, if an anomalous tangential speed occurs in a cut section 28 with a rewinding tension higher than the desired value, for example, the latter is able to overcome the frictional forces exerted between the body 30 and the first annular member 38 associated with this section 28. A relative sliding is therefore determined with respect to the body 30 of the cut section 28, to which the annular members 38, 40 remain integral, with a variation of its angular velocity such that the tangential velocity and consequently the rewinding assume the desired value.

This avoids the drawbacks connected to a too loose or too compact rewinding of the sections 28, which would be caused by incorrect rewinding voltages.

Thanks to the bearings 42, present in the just described preferred embodiment of the present invention, it is possible to adjust with extreme precision the sliding of the first annular members 38 with respect to the body 30 of the shaft 24, which depends on the friction forces exchanged at the foils 62.

In fact, since the weight of the cut sections 28 is almost entirely supported by the bearings 42, the magnitude of the aforementioned friction forces substantially depends on the inflation pressure of the elastic shells 36 alone. Therefore, by acting on this variable which is very controllable accurately, it is possible to adjust the sliding of the annular members 38 with respect to the body 30 of the shaft 24 and consequently the winding tension of the cut sections 28.

Naturally, the principle of the invention remaining the same, the details of construction and the embodiments may vary widely with respect to the glove described and illustrated purely by way of example, without thereby departing from its scope.

In particular, the axial extension of each second annular member 40 and therefore their number for a given shaft length 24 can be selected bearing in mind that at least one annular member 40 is required for each coil section 28. Obviously, the greater the number is chosen. of the annular members 40, the greater the flexibility of use of the shaft 24 will be, allowing to rewind around a number at the corresponding limit of cut sections 28.

Claims (11)

CLAIMS 1. Shaft (24) for supporting in a slitting-winding machine (10) cut sections of reel (28) wound around a respective core (26), said shaft (24) comprising: - a cylindrical body (30) having on its external surface at least one recess (32) suitable for housing an elastic casing (36) which can be connected to a source of pressurized fluid, and - a plurality of first annular members (38) arranged along the body (30) coaxially with respect to this, said shaft (24) being characterized in that it comprises a plurality of second annular members (40) arranged along the body (30), coaxially with respect to this and in a radially external position with respect to said first annular members (38), between at least one second (40) and a first (38) annular member being provided at least one seat suitable for housing an engagement element (52) capable of protruding radially from the external surface of the second annular member (40) following a relative rotation movement of the first annular member (38) with respect to the second annular member (40) and to apply a localized pressure to the facing internal surface of one of the cores (26). 2. Shaft (24) according to claim 1, characterized in that said seat is formed by a radial hole (54) made in the second annular member (40) and by a cut portion (56) along a chord of the outer circumference of the first annular organ (38). Shaft (24) according to claim 2, characterized in that said hole (54) has a conical section and said engagement element (52) is shaped like a sphere. Shaft (24) according to any one of the preceding claims, characterized in that each second annular member (40) is arranged around an associated first annular member (38), the two associated annular members (38, 40) being symmetrically arranged with respect to a plane perpendicular to the axis (34) of the shaft (24). 5. Shaft (24) according to any one of the preceding claims, characterized in that it comprises means capable of limiting the relative rotation movement of the first annular member (38) with respect to the second annular member (40) which surrounds it. 6. Shaft (24) according to claim 5, characterized in that said means comprise at least one tooth (58) which protrudes radially outside the first annular member (38) within a circumferentially extending slot (60) made in the second member ' annular (40). 7. Shaft (24) according to any one of the preceding claims, characterized in that between each first annular member (38) and the second annular member (40) that surrounds it, a plurality of circumferentially spaced seats suitable for housing a respective element is obtained commitment (52). 8. Shaft (24) according to any one of the preceding claims, characterized in that a respective lamina (62) of friction material is arranged between each elastic casing (36) and the facing internal surfaces of each first annular member (38) . Shaft (24) according to any one of the preceding claims, characterized in that between pairs formed by a second (40) and a first (38) annular member located one around the other, and axially arranged in series are interposed respective rolling bearings (42), on which the weight of the cut sections (28) of coil wound around the shaft (24) is discharged. Shaft (24) according to claim 9, characterized in that each second annular member (40) has a T-shaped section with laterally projecting wings (50) which rest on an outer ring (44) of a respective bearing (42) adjacent to each side of the second annular member (40). 11. Slitter-rewinder machine (10) comprising a shaft (24) according to any one of the preceding claims.