ES2632119T3 - Treadmill device for winding sheet cutting machine - Google Patents

Abstract

It comprises a support bar (10) on which a treadmill (20) is rotatably mounted composed of a plurality of adjacent tread segments (25), each with a cylindrical outer surface (21) facing a coil (30). It includes some guide means for guiding movements of the tread segments (25) in a radial direction with respect to said support bar (10) and pushing means to independently push each tread segment (25) guided in the guide means against the coil (30). With this, the cylindrical outer surfaces (21) of the tread segments (25) are susceptible to being offset with respect to a central line (15) of the support bar (10) with different eccentricities determined individually by the contact of the cylindrical outer surface ( 21) of each treadmill segment (25) with the coil (30).

Description

Treadmill device for winding sheet cutting machine

Technical field

The present invention concerns a treadmill device applicable to a winding sheet cutting machine, useful in the graphic arts industry to compensate for fluctuations in the thickness of the sheet material being cut and wound and to prevent lateral sliding of sheet materials with a low coefficient of friction.

Prior art

Cutting-winding machines are known which have means for making one or more longitudinal cuts in a flexible sheet material, unwound from a single coil, and means for rewinding the two or more resulting bands in corresponding pick-up coils. of smaller width arranged coaxially. In this type of machines it is known to have a single treadmill associated with a pusher device to press the various pickup coils as the cut material is wound. However, this unique roller is not able to adapt to small differences in diameter of the pickup coils due to variations in the thickness of the cut material, so it cannot guarantee that the pressure actually applied to each coil is the same.

It is also known to have several independent sets of treadmill and pusher device to be able to give substantially equal pressures independently to each of the various pickup coils. In this case, each assembly comprises an articulated arm that supports the axis of the treadmill and a pneumatic cylinder disposed between a bench and the articulated arm to push the roller towards the corresponding pickup coil. However, the mechanical assembly of the different tread rollers requires leaving separation distances between them that limit the minimum width of the pickup coils and make it difficult to adapt the tread roller system to coils of different widths. Moreover, this arrangement results in a relatively complex construction, with high manufacturing and maintenance costs.

Patent application US-A-2004075011 discloses a treadmill device having the characteristics set forth in the preamble of claim 1.

Exhibition of the invention

The present invention contributes to overcoming the foregoing and other inconveniences by providing a treadmill device for winding sheet cutting machine, which together comprises a support shaft on which a treadmill consisting of a plurality of adjacent tread segments is rotatably mounted. , each of said tread segments having a cylindrical outer surface facing a cylindrical outer surface of at least one coil; guide means adapted to guide movements of the tread segments in a radial direction with respect to said support axis; and a pushing means adapted to push each and every step of the guided segment in said guide means against said reel, which is at least one, so that the cylindrical outer surfaces of the tread segments are susceptible to being offset from a line center of the support bar, with different eccentricities determined individually by the contact of the cylindrical outer surface of each treadmill with the cylindrical outer surface of the coil.

According to the invention, said pushing means comprise a common expandable element for all the tread segments driven by a pressurized fluid to individually push the tread segments with a common pressure.

With this construction, the device of the present invention ensures that the same pressure will be applied to each coil, which provides a uniform degree of compaction or hardness in all coils.

The treadmill device of the present invention has the advantages in terms of performance of a separate individual roller construction of a known type, and yet, thanks to being mounted on a common support bar, it can be supported in a structure of Support as simple as that used for a single roller trader of the prior art.

In addition, the device of the present invention allows to increase the production time of the cutting machine, since it does not have the need to make roller changes to pass, for example, from a single treadmill to individual treadmills, or to make movements axial of the different tread rollers to adapt the cutting machine to different coil widths.

The treadmill device of the present invention, including individual tread sectors, admits a smaller coil width smaller than previously known devices.

Brief description of the drawings

The foregoing and other advantages and features will be more fully understood from the following detailed description of an exemplary embodiment with reference to the accompanying drawings, in which:

Fig. 1 is an isometric view of one end of a treadmill device for winding sheet cutting machine according to an embodiment of the present invention;

Fig. 2 is a cross-sectional view of the roller device of Fig. 1 with an expandable element contracted and a treadmill in a retracted position relative to a support bar;

Fig. 3 is a cross-sectional view similar to Fig. 2, but with the expanded expandable element and the tread segment in an extended position relative to the support bar; Y

Fig. 4 is a longitudinal sectional view of the treadmill device of Fig. 1.

Detailed description of an embodiment example

Referring first to Fig. 1, the treadmill device for winding sheet cutting machine comprises, in accordance with an exemplary embodiment, a support bar 10 on which a compound treadmill 20 is rotatably mounted by a plurality of adjacent tread segments 25, very close to each other. Each of said tread segments 25 has a cylindrical outer surface 21 facing a cylindrical outer surface of at least one coil 30 (indicated by dashed lines in Figs. 2 and 3). In general, the cutting machine incorporates several pick-up coils 30 for collecting and winding respective bands of material cut from a wider band from a single input coil (not shown). The various pickup coils 30 are coaxial with respect to an axis parallel to a central line 15 of the support bar 10, and each treadmill segment 25 may correspond to one of the pickup coils 30, or there may be several treadmill segments 25 for each of the various pickup coils 30. The cutting machine has means for moving the support bar 10 towards the pickup coils 30 to bring the tread segments 25 into contact with them.

The device of the present invention further comprises guide means adapted to guide movements of the tread segments 25 in a radial direction relative to said support bar 10, and thrust means adapted to individually and independently push each guided tread segment 25 in said guiding means against said coil 30, which is at least one. Thus, the cylindrical outer surfaces 21 of the tread segments 25 are likely to be offset from a central line 15 of the support bar 10 to compensate for differences in diameter in the various pickup coils 30 produced by possible fluctuations in the thickness of the material. laminar that is being cut and wound. The pressure exerted by the tread segments 25 on the pick-up coils 30 also serves to provide a certain degree of compaction or hardness to the coils and to prevent lateral sliding of sheet materials with a low coefficient of friction. The degree of eccentricity of each of the tread segments 25 is determined individually by the contact of the cylindrical outer surface 21 of each tread segment 25 with a cylindrical outer surface of the coil 30. However, thanks to said thrust means comprising an expandable element 60 driven by a pressurized fluid, common to all the tread segments 25, the tread segments 25 are pushed individually against the pick-up coils 30 with a single pressure common to all of them.

As best shown in Figs. 2 and 3, the support bar 10 is generally cylindrical in shape and has two flat outer faces 11 diametrically opposite, parallel to each other and parallel to the center line 15 of the support bar 10. These two flat outer faces 11 are in sliding contact with corresponding parallel flat inner faces 41 formed in a cavity 42 of a core 40 on which the tread segment 25 rotates, so that said core 40 together with the tread segment 25 can be displaced radially with respect to the bar of support 10. The flat outer faces 11 of the support bar in conjunction with the aforementioned flat inner 41 of said core 40 constitute the guiding means referred to above. Said pushing means comprise, in addition to said expandable element 60, at least one pushing member 50 for each tread segment 25. This pushing member 50 is located between the support bar 10 and the core 40 of the corresponding tread segment 25, and the expandable element 60 is located along the support bar 10 between the support bar 10 and all the pushing members 50. The said pressurized fluid is preferably pressurized air, although it could be any other gas or even a liquid.

In the situation shown in Fig. 2, the expandable element 60 is substantially empty of fluid and adopts a contracted shape, whereby the pusher member 50 is retracted and the tread segment 25 can also assume a retracted position relative to the bar of support 10.

In the situation shown in Fig. 3, the expandable element 60 is filled with fluid at a certain pressure, so it is expanded to some extent. The expansion of the expandable element 60 individually pushes all the pushing members 50 against the respective cores 40 and these move radially together with the respective tread segments 25 to an extended position in relation to the support bar 10, in which the cylindrical outer surfaces of the tread segments 25 are in contact with the corresponding pick-up coils 30. During operation, the expansion of the expandable element 60 allows the degree of extension of each of the different tread segments 25 to be adapted to the particular diameter of the corresponding pick-up coil 30 and, however, the pressure exerted by the expandable element 60 is common and uniform for all tread segments 25.

It should be noted that, although in Figs. 2 and 3 the retracted and extended limit positions have been represented, respectively, during actual operation the tread segments 25 will oscillate between intermediate retracted and extended positions without reaching, except in exceptional situations, the aforementioned retracted and extended limit positions.

The support bar 10 has along it a housing 12 in the form of a groove with a longitudinal opening located between said two flat outer faces 11 of the support bar 10. Each of the pushing members 50 comprises a guide portion 51 inserted in said housing 12 of the support bar 10 so that it can slide outwardly and inwardly therein in a direction parallel to the two flat outer faces 11 of the support bar 10. The pusher member 50 also it comprises an protruding portion 52 having an end adapted to press against an inner surface of said cavity 42 of the core 40 of the tread segment 25 when the pusher member 50 is displaced out of the housing 12. The expandable element 60 is in the form of a expandable sleeve 60 disposed along the housing 12 from one end to the other of the support bar 10, between a bottom surface of the housing ent 12 and an end surface of each of said guide portions 51 of the pusher members 50. The expandable sleeve 60 can be connected to a source of pressurized fluid through valve means associated with the support bar 10, and said valve means may be closed to retain a quantity of fluid at a predetermined pressure within the expandable sleeve 60.

At opposite edges of the longitudinal opening of the housing 12 of the support bar 10 are formed flanges directed towards each other that interfere with projections 53 formed next to an inner end of the guide portion 51 of each pusher member 50 Thanks to this, the pushing members 50 are retained in the housing 12 with the possibility of limited sliding due to the interference of the flanges of the housing 12 with the protrusions 53 of the pushing members 50. The support bar 10 has protruding ends. of the treadmill 20, and, at least one of these protruding ends of the support bar 10 (shown in Fig. 1), the longitudinal opening of the housing 12 has a widening 13 of sufficient size to allow the passage of the projections 53 of the guide portions 51 of the pusher members 50. Thus, for mounting the treadmill device of the present invention, the mi Push rods 50 can be introduced one after the other through said widening 13 and then slid along the housing 12 to its operative position. Inside a portion of the housing 12 located at the protruding end of the support bar 10 and facing said widening 13, a stop 14 is fixed whose purpose is to make a retention of the pushing members 50 inside the housing 12 of the support bar 10 once inserted, preventing their displacement in the direction of the center line 15.

Referring now to Fig. 4, each tread segment 25 comprises a cover 21a, of a material suitable for providing the cylindrical outer surface 21, fixed on a structural sleeve 29, which is rotatably mounted on its corresponding core 40 by means of a pair of bearings 26, which are of a type adapted to further effect a retention of the tread segment 25 on its corresponding core 40 against a displacement in an axial direction. Between each two adjacent tread segments 25, one or more spacers 27 are arranged in the form of plugs of a low friction coefficient material fixed to the core 40 of one of the two adjacent tread segments 25 by means of screws 42. Each of these separators 27 are in sliding contact with a lateral surface of the core 40 of the other of the two adjacent tread segments 25 to allow displacements of the tread segments 25 in the radial direction along the guiding means described above while guarantee a minimum clearance clearance between adjacent tread segments 25. Next to each of the two tread segments 25 located at the ends of the tread roller 20 (only one of which is shown in Fig. 4) one or more stops 28 are fixed to one of the flat outer faces 11 of the support bar 10 by means of screws 16. These stops 28 are in sliding contact with a lateral surface of the core 40 of the corresponding tread segment 25 and effect a retention of the set of tread segments 25 that make up the treadmill 20 in the face of displacements in the axial direction while allowing displacements of the tread segments 25 of the ends in the radial direction.

One skilled in the art will be able to introduce variations and modifications in the exemplary embodiment shown and described without departing from the scope of the present invention as defined in the appended claims.

Claims (4)

1.-Trampler roller device for winding sheet cutting machine, which includes: a support bar (10) on which a treadmill (20) is rotatably mounted composed of a plurality of adjacent tread segments (25), each of said tread segments (25) having a cylindrical outer surface (21) facing a cylindrical outer surface of at least one coil (30); guide means adapted to guide movements of the tread segments (25) in a radial direction with respect to said support bar (10) where said guide means comprise two flat outer faces

(eleven)

parallel formed in the support bar (10) and in sliding contact with corresponding parallel flat inner faces (41) formed in a cavity (42) of a core (40) on which the treadmill (25) rotates, so that said core (40) together with the tread segment (25) can be displaced radially with respect to the support bar (10); Y

pushing means adapted to individually and independently push each tread segment (25) guided in said guide means against said coil (30), which is at least one, whereby said cylindrical outer surfaces (21) of the tread segments ( 25) are susceptible to being offset from a central line (15) of the support bar (10) with different eccentricities determined individually by the contact of the cylindrical outer surface (21) of each treadmill segment (25) with an outer surface cylindrical of the coil (30), wherein said pushing means comprise an expandable element (60) driven by a pressurized fluid to individually push the tread segments (25) with a common pressure, and where said pushing means further comprise, for each tread segment (25), at least one pusher member (50) located between the support bar (10) and the core (40) of the tread segment (25), said element being expansible

(60)

located along the support bar (10) between the support bar (10) and said pushing members (50) to individually push the pushing members (50) against the corresponding cores (40) with a common pressure, and with this radially displacing the corresponding tread segments (25) with respect to the support bar (10), and where said expandable element (60) is in the form of an expandable sleeve (60) arranged in said housing (12) along the support bar (10) between a bottom surface of the housing (12) and an end surface of each of said guide portions (51) of the pusher members (50), said expandable sleeve (60) being capable of being connected to a source of pressurized fluid through valve means associated with the support bar (10).

wherein the support bar (10) has along it a housing (12) having a longitudinal opening located between said two flat outer faces (11), and each of the pushing members (50) comprises a guide portion (51) inserted in said housing (12) of the support bar (10) so that it can slide out and into it in a direction parallel to the two flat outer faces (11) of the bar of support (10), and an projecting portion (52) adapted to press against an inner surface of said cavity (42) of the core (40) of the tread segment (25) when said pusher member (50) is moved out of the housing (12); characterized because the pusher member (50) has projections (53) formed next to an inner end of the guide portion (51), and said longitudinal opening of the housing (12) of the support bar (10) has flanges that interfere with said projections (53), whereby the pusher member (50) is retained in the housing (12) with the possibility of limited sliding, and at at least one end of the support bar (10) protruding from the tread roller (20), the longitudinal opening of the housing (12) has a widening (13) of sufficient size to allow the passage of the guide portions

(51)

of the pusher members (50), in a direction perpendicular to a central line (15) of the support bar (10).

2. Device according to claim 1, wherein within a portion of the housing (12) facing said widening (13) a stop (14) is fixed for a retention of the pusher members

(fifty)

inside the housing (12) of the support bar (10) facing a displacement in the direction of the center line (15).

3. Device according to claim 2, wherein each treadmill segment (25) is rotatably mounted on its corresponding core (40) by means of a pair of bearings (26), which are further adapted for make a retention of the treadmill segment (25) on its corresponding core (40) against an offset in an axial direction. 4. Device according to claim 3, wherein at least one separator (27) attached to the core (40) of one of the two adjacent tread segments (25) is arranged between each two adjacent tread segments (25) and in sliding contact with a lateral surface of the core (40) of the other of the two adjacent tread segments (25). 5. Device according to claim 4, wherein next to each of the two tread segments (25) located at the ends of the treadmill (20) at least one stop (28) fixed to a of the flat outer faces (11) of the support bar (10) and in sliding contact with a lateral surface of the core (40) of the corresponding treadmill segment (25).