IT201900005498A1 - "MOVABLE BLADE HOLDER OF A MACHINE FOR CUTTING EXPANDED POLYURETHANE" - Google Patents

Description

Description of the patent application for industrial invention entitled:

"Mobile blade holder column of a polyurethane foam cutting machine"

The invention, object of the present invention, belongs to the category of machines for cutting numerically controlled polyurethane foam.

The machines for cutting and shaping polyurethane foam, of the horizontal blade type, are generally made from a mobile frame, inside which one or more blocks of polyurethane to be cut are positioned, this frame, generally consisting of a base and by an upper table necessary to press the polyurethane, it is surmounted by a vertical bridge which is also movable, this latter containing the horizontal blade and its relative sliding mechanism.

The mobile frame which releases the block is able to move longitudinally on suitable tracks, while the mobile bridge moves vertically; the resulting combination of the relative displacements between the frame and the mobile bridge, controlled by a CNC, allows the horizontal blade, in continuous sliding, to be able to create the desired shapes in the polyurethane block.

The circular cutting blade is mounted on two pairs of pulleys, housed inside the casings positioned at the lateral ends of the mobile bridge, these motorized pulleys keep the blade under tension and determine its advancement.

The portion of the blade that protrudes from the lower end of the mobile bridge is guided by two heads placed at the free ends of the blade itself.These heads have the task not only of guiding the blade, but at the same time are able to rotate synchronously, by an angle of ± 180 ° to allow the blade, by putting it in torsion, to originate complex cutting profiles in the block to be shaped.

A drawback of known polyurethane cutting machines, which arises during shaping, consists in the fact that the blade can bend, making a cut that is not perfectly straight and assuming an undesired curvature, this drawback occurs due to the excessive free space of the blade. , which, in order to remain perfectly straight, requires high tensions, necessary to overcome the shear resistance generated in the blocks to be shaped.

This preceding drawback, during cutting, occurs especially in the shaping of denser plastic materials or with reticular structures which develop greater resistance to shear by friction.

A solution adopted by known horizontal-blade polyurethane cutting machines is to equip the mobile bridge with large diameter pulleys capable of developing considerable tangential tensions so that the sliding blade remains inflected during the cutting process.

A further solution adopted by known vertical polyurethane cutting machines is to equip the mobile bridge with a central column, which supports the sliding blade, drastically reducing the bending moment to which it is subjected during the cutting process.

However, this last solution has the drawback consisting in the fact that this central column, having to cross the upper table of the mobile frame containing the block, in order to slide along the surface of said table, the latter must necessarily be equipped with a complex system of movable windows, affecting economically and with technological burden on the structure of the movable frame.

A further drawback of the column provided by the known art depends on the fact that the adoption of a central guide column of the fixed type with respect to the mobile bridge forces it to be used even during light operations that do not require any support for the blade, thus making said central column is a permanent geometric obstacle during the block shaping process cycle.

The main purpose of the present industrial invention is to solve the problems of the known art and in particular of the machines for cutting the polyurethane foam which provide a fixed central column and, more particularly, to make the telescopic column translate along the upper upright of the mobile bridge, avoiding to equip the mobile frame with an upper table with additional components and complex geometry necessary to make the mobile column pass.

A further object of the present invention is to provide a translating column which allows to carry out extremely precise shaping on partial portions of the base, perhaps on blocks which occupy only a part of the movable frame.

Another object achieved by the mobile column, according to the present invention, consists in the possibility of twisting the supported blade at an angle of ± 180 ° by means of a complex gear mechanism with which the mobile column itself is equipped at its lower end.

These and further purposes are achieved by the movable blade-holding column of a machine for cutting polyurethane foam, of the present invention, described hereinafter in a preferred, non-limiting embodiment of further developments in the field of the patent, with the help of the attached drawing tables illustrating the following figures:

Fig. 1, an overall isometric view of the polyurethane cutting machine with the mobile column in a generic position;

Fig. 2, a front view of the mobile bridge in a generic position of the mobile column;

Fig. 3, a top view of the mobile bridge and the mobile column;

Fig. 4, a side view of the mobile column;

Fig. 5, a detailed view of the gears of the reduction unit;

Fig. 6, a sectional view of the transmission ring meshing with the satellite, of the bevel crown assembled to the pinion and of the blade guide bushing.

As illustrated in the attached figures, the movable blade-holding column of a machine for cutting polyurethane foam, hereinafter simply referred to as the movable column 1, consists of two brackets 2, 3 facing each other and capable of sliding parallel to each other. , the first minor bracket 2 is capable of being able to translate along the upper upright 41 of the mobile bridge 4 of the polyurethane cutting machine M, while a second major bracket 3 is equipped at its lower end with a reduction unit 5 capable, both for engage the cutting blade 6 and twist it at an angle of ± 180 °.

As illustrated in FIG. 1, the movable frame 7 of the cutting machine M, translating longitudinally with respect to it, is constituted by an upper table 71 equipped in turn with a series of longitudinal beams 711, parallel and separated from each other by free spans 712 inside the which the mobile column 1 can slide when engaged on the cutting blade 6.

As illustrated in Figures 2 and 3, the first minor bracket 2, of the mobile column 1, is equipped at its upper end with a pair of shoes 8a, of the recirculating ball type, necessary to slide said minor bracket 2 along a guide horizontal 9 constrained to the upper upright 41 of the mobile bridge 4. A second pair of shoes 8b, rotated by 90 ° with respect to the first pair 8a, are constrained to the internal part of the minor bracket 2 to allow vertical sliding between the minor bracket 2 and the major bracket 3, along a vertical guide 10 constrained internally to the major bracket 3.

The vertical sliding between the major bracket 2 and the minor bracket 3, as illustrated in fig. 4, is controlled by a pneumatic cylinder 11, internally constrained to said major bracket 3. Said pneumatic cylinder 11 is fixed to the major bracket 3 by means of two bolts 12 fixed to the ends of the liner 111 of the pneumatic cylinder 11 with threaded connections, while the The end of the rod 112 of the cylinder 11 is constrained to the minor bracket 2 by means of an angular plate 13, which is in turn always constrained with threaded connections.

The translation stroke of the minor bracket 2, and consequently of the mobile column 1 along the horizontal guide 9 constrained to the upper upright 41 of the mobile bridge 4, as illustrated in fig. 3, is allowed by a further pair of pneumatic cylinders 14, 15 opposite each other and mutually constrained to the ends of their stems by means of an internally threaded connection bushing 16. Of said opposed pneumatic cylinders 14, 15, necessary for the horizontal translation of the mobile column 1, a first cylinder 15 is constrained to one end of the upper upright 41 of the mobile bridge 4, by means of bolts fixed with screws, and, a second pneumatic cylinder 14 is constrained exclusively to the upper end of the minor bracket 2. The use of said pair of opposite cylinders 14, 15 is necessary in order to be able to increase the translation stroke along the horizontal extension of the upper upright 41 of the mobile bridge 4.

As illustrated in FIG. 4, a reduction unit 5 is constrained to the lower end of the major bracket 3, necessary to engage on the cutting blade 6 in correspondence with a blade-guide bushing 17, inside said reduction unit 5, equipped with a radial cut 171 necessary to accommodate the cutting blade 6.

Said blade-guide bushing 17 is necessary to twist the cutting blade 6 by an angle of ± 180 °, in synchrony with the rotations of the guide heads T placed at the free ends of the blade 6. Said guide heads T are each in turn controlled by brushless motors in order to be able to create complex cutting profiles, set by the logic of the CNC of the cutting machine for polyurethane foam.

This ± 180 ° rotation of the blade guide bushing 17, as visible in figs. 5 and 6, is controlled by a complex gearing consisting of four main toothed couplings, activated at the input by a brushless motor, mounted above the reduction unit 5 managed by the logic set by the CNC.

As detailed in fig. 5, the input angular motion is imparted by the brushless motor B to a first pinion 18 of a bevel pair 18-19, the crown 19 of said bevel pair 18-19 by means of a second cylindrical pinion 20 with straight teeth and integral with crown 19, transfers the rotation motion, modifying the transmission ratio, to a toothed return crown 21 meshing on two return satellites 22, of the straight tooth type, which in turn transfer the angular motion, with different transmission ratio , to the blade guide bushing 17 with which the return satellites 22 engage on a toothed profile 172 with which the blade guide bushing 17 is externally equipped.

Claims (9)

CLAIMS 1. Mobile blade-holding column of a machine for cutting expanded polyurethane (1) comprising a first minor bracket (2), and a second major bracket (3), mutually facing each other, said first minor bracket (2) being provided of a first pair of recirculating ball shoes (8a), placed at its upper end and of a second pair of shoes (8b), oriented at 90 ° with respect to the first pair (8a), placed on the internal face of said minor bracket (2), and said second major bracket (3) being equipped, at its upper end, with a vertical guide (10) and at its lower end with a reduction unit (5), having as its last kinematic wheel a guide-blade bushing (17), said mobile column (1) characterized in that it can translate both longitudinally along the horizontal guide (9), constrained to the upright (41) of the mobile bridge (4), and vertically, through the openings (712) of at least a pair of parallel beams (711), with which l to the table (71) of the mobile frame (7), to engage on the cutting blade (6), and to be able to twist it according to an angle of ± 180 °. 2. Movable blade-holding column of a machine for cutting the polyurethane foam (1) according to claim 1, characterized in that the movable column (1) is telescopic. 3. Mobile blade-holding column of a machine for cutting polyurethane foam (1) as per the preceding claims, characterized in that the guide for the translation of the minor bracket (2) along the horizontal guide (9) fixed to the upright ( 41) of the mobile bridge (4) occurs by means of the sliding of the shoes (8a) constrained at the top to the minor bracket (2). 4. Mobile blade-holding column of a machine for cutting polyurethane foam (1) as per the preceding claims, characterized in that the blade-guide bushing (17), belonging to the reduction unit (5), is equipped with a cut radial (171) adapted to receive the cutting blade (6) and to twist it through an angle of ± 180 °. 5. Mobile blade-holding column of a machine for cutting polyurethane foam (1) as per claims 1 and 4, characterized in that the blade-guide bushing (17), inside the reduction unit (5), is equipped externally of a toothed profile (172) adapted to receive the transmission of angular motion of ± 180 ° from the gearing (18-19, 20-21, 21-22, 22-162) inside the reduction unit (5). 6. Movable blade-holding column of a polyurethane foam cutting machine (1) as per claims 1 and 5, characterized in that the angular speed of the blade guide bush (17) is the result of the exchanged gear ratios by four toothed couplings: the first in the bevel gear (18-19) whose bevel pinion (18) receives motion from the motor B, the second between the straight tooth pinion (20) integral with the bevel crown (19) and the wheel (21), the third meshing between the return wheel (21) and the return satellites (22) and finally the fourth meshing between the return satellites (22) and the toothed profile (172) of the guide bushing. blade (17). 7. Mobile blade-holding column of a machine for cutting polyurethane foam (1) as per the preceding claims, characterized in that the kinematic mechanism of the reduction unit (5), imposed on the blade-guide bushing (17), is suitable for in torsion the blade (6) by an angle of ± 180 °, is synchronous to the rotations of the guide heads T, positioned at the free ends of the cutting blade (6). 8. Mobile blade-holding column of a machine for cutting the polyurethane foam (1) as per the preceding claims, characterized in that the translation of the mobile column (1) along the upper upright (41) of the mobile bridge (4 ), is implemented by means of runners (8a), engaged to a guide (9) with motion imposed by a pair of opposing cylinders (14, 15) and mutually constrained on the side of their rods. 9. Mobile blade-holding column of a machine for cutting polyurethane foam (1) as per claim 1, characterized in that the translation motion between the minor bracket (2) and the major bracket (3) occurs at by means of a pneumatic cylinder (11) having the jacket (111) constrained on the lower front face of the minor bracket (2) and its stem (112) constrained, by means of an angular strap (13), to the lower end of the minor bracket (2).