FR2701419A1 - Rotary cutting device. - Google Patents

Abstract

Rotary cutting apparatus comprising a frame supporting, between two parallel vertical uprights (1), two superimposed cutting cylinders (4, 5), characterized in that it comprises, between each pair of upper (9) and lower ( 10), a backpressure stop integral with the upper bearing block (9) and resting on the lower bearing block (10) by means of an elastic means (21) working in compression and constantly exerting upwards, even after heating and expansion of the cylinders, a reaction force (F2) sufficient to ensure permanent engagement of the spindle (4a) of the upper cutting cylinder (4), regardless of the temperature of the cutting cylinders (4, 5) .

Description

The present invention relates to a rotary cutting apparatus which can be used

  more particularly in the printing and shaping lines of

  folding cardboard boxes and self-adhesive labels.

  These devices are generally based on the principle of rolling, one on top of the other, of two superimposed cylinders, of parallel axes, one of which, namely the cutting cylinder proper, carries cutting knives, obtained by engraving, while the other cylinder or "anvil" cylinder is smooth However in certain processes the two cylinders may have complementary engraved cutting knives The rotation drive of the two cylinders, at the same peripheral speed but in the opposite direction l 'from each other, is ensured by connecting gears of the same pitch diameter chosen so that there remains, between the two cutting cylinders, a constant distance, as small as possible, which is necessary to ensure a good cut of the cardboard or paper web passing between them, without there being any contact

  between the metal parts ensuring the cut.

  The smaller this distance, the sharper and cleaner the cut of dust, which is particularly advantageous because cardboard dust, for certain applications such as food packaging or tobacco, is a crippling fact Unfortunately under the effect of cutting reaction, the cylinders flex and then return, by vibration, to a position which is symmetrical with their deformation position, after the passage of the knife,

  which risks damaging the next knife.

  It is therefore necessary to provide an original spacing between the knives and the anvil such that the vibrations due to the elastic deformations of the

  cylinders are unlikely to create metal-to-metal contact.

  This spacing is generally ensured by rollers or raceways which are fixed to the ends of the two cylinders being perfectly concentric with them, and which roll on top of each other The diameter of each of these rollers or raceways is equal to the pitch diameter of the connecting gear We can then apply, on the raceways, the external cutting pressure, which is necessary and sufficient to compensate for the reaction that appears when cutting cardboard. It is obvious that the spacing of origin will be all the greater as the elastic deformation of the cylinders will be important. To compensate for this elastic deformation of the cylinders during the cutting operation, it has already been envisaged to produce cutting cylinders of very large diameter, in order to reduce these elastic deformations and to bring the knives as close as possible to the anvil. This solution leads to very expensive achievements and heavy and difficult mechanisms to

handle.

  It has also been proposed, as described in patent FR-A-2 645 790, to use hydraulic cylinders exerting, on the sliding bearings of the cutting cylinders, a bearing force greater than the cutting reaction , to

  ensure permanent contact between the raceways of the two cylinders.

  The present invention relates to improvements made to a rotary cutting device of the aforementioned type making it possible to very significantly reduce the bending or deflection suffered by the cutting cylinder during a cutting operation and to keep the spindles of the upper cutting cylinder perfectly embedded, even after a warm-up resulting from

  certain working period of the device.

  To this end, this rotary cutting apparatus comprising a frame supporting, between two parallel vertical uprights, two superimposed cutting cylinders, with parallel axes, namely an upper cutting cylinder and a lower cutting cylinder respectively integral with rolling raceways on each other, each cutting cylinder comprising, at each end, a coaxial spindle mounted for rotation in a bearing block which can slide vertically on the two respective uprights, each of the upper bearing blocks being extended at its upper part, towards the inside of the device, by a cantilevered part subjected to the action, downwards, of a vertical pressurizing cylinder mounted at the top of the device, while each of the bearing blocks lower part is extended, at its lower part, towards the inside of the apparatus, by a cantilever part extending above a stop carried by the mount corresponding ant and with which it is in contact, is characterized in that it comprises, between each pair of upper and lower bearing blocks, a counterpressure stop integral with the upper bearing block and bearing on the lower bearing block via an elastic means working in compression and constantly exerting upwards, even after heating and expansion of the cylinders, a sufficient reaction force to permanently ensure the embedding of the rocket of the upper cutting cylinder, whatever

  whatever the temperature of the cutting cylinders.

  An embodiment of the present invention will be described below, by way of non-limiting example, with reference to the appended drawing in which: FIG. 1 is a view in partial vertical section of a following rotary cutting apparatus the invention, in the position in which it is located

  stop, before a shift.

  Figure 2 is a vertical sectional view taken along line 11-Il of the

figure 1.

  FIG. 3 is a view in partial section, on a larger scale, of an embodiment of a counterpressure stop with elastic support, in the

  position it occupies after a certain period of work of the device.

  The rotary cutting device which is partially shown in Figure 1, comprises a frame consisting of two parallel lateral uprights 1, interconnected by horizontal crosspieces not shown One side of the device is shown in Figure 1, l 'other side being symmetrical with the preceding Each upright 1 is notched, in its upper part, with an opening 3 extending vertically, of rectangular shape and opening into the upper horizontal face of the upright In the two opposite openings 3 is engaged a device interchangeable cutting consisting essentially of two upper 4 and lower 5 cutting cylinders, with horizontal axes

  parallel, between which a sheet of paper or cardboard to cut must pass.

  The upper cutting cylinder 4 is extended, at each of its ends, by a coaxial spindle 4 a, and it is integral with two raceways 4 b located at a distance from the two front faces of the cutting cylinder 4 and between which is the engraved part of the cylinder 4 In the same way the cutting cylinder

  lower 5 is extended, at each of its ends, by a coaxial rocket 5 a.

  The upper raceways 4 b, having the same diameter which is slightly greater than that of the upper cutting cylinder 4, roll on the periphery of the lower cylinder 5 if the latter is smooth, thus constituting an "anvil" cylinder, or of course on the raceways 5b of the lower cylinder if the latter is also engraved Between the two cylinders 4 and 5 is thus kept constant a small interval necessary to ensure a good cut of the sheet of cardboard or paper passing between them, without there being any contact between the metal parts ensuring the cut The diameter of the upper raceways 4 b is equal to that of the lower raceways 5 b and the pitch diameter of the connecting gears 7.8, respectively attached to rockets 4 a, 5 has cutting cylinders 4,5, outside the upright 1 These link gears 7,8 are engaged with each other and are driven in

  rotation from the general control of the device.

  The rockets 4 a and 5 a of the cutting cylinders 4,5 are respectively mounted for rotation in superimposed blocks forming bearings, namely upper blocks 9 and lower bearings 10, engaged closely in the openings 3 and

  that can slide vertically in them.

  Each upper bearing block 9 is extended, at its upper part, towards the interior of the apparatus, by a cantilever part 9 a extending above the end part of the upper cutting cylinder 4 De in the same way each lower bearing block 10 is extended, at its lower part, towards the interior of the apparatus, by a cantilever part 10 a which extends below the end part of the cutting cylinder lower 5 and above a fixed added stop 11 This stop 11 is fixed, by means of screws, to the internal face of the corresponding upright 1 so that its upper horizontal face is situated at a level slightly higher than that o finds the lower edge of the opening 3 Therefore the internal cantilever part 10 a of each lower bearing block is normally supported on the upper face of the added stop 11 and the lower face of this lower bearing block 10 is slightly away from lower edge of the opening 3. At the upper part of the rotary cutting apparatus is provided a pressurizing frame 12 which comprises a central cross member 13 carrying, at each of its ends, a vertical pressurizing cylinder 14 The rod of this cylinder extends downward, and its lower end is located just above

  the cantilever part 9 a of the upper bearing block 9 and in contact with the latter.

  Each vertical pressurizing cylinder 14 is mounted on the cross member 13 of the pressurizing frame 12, so that the vertical axis of the jack 14 is contained in a vertical and transverse plane P passing through the lower stop 11 and located between the vertical and transverse median plane Pl of the neighboring upper raceway 4b and the neighboring upper bearing block 9 Furthermore, at least one counterpressure stop 15, integral with the upper bearing block 9, of adjustable height, is interposed between each pair upper 9 and lower 10 bearing blocks This counterpressure stop 15 is located substantially in the vertical and transverse median plane P 2 common to the two upper bearing blocks 9

  and lower 10 of the same pair of blocks.

  Means are provided for adjusting, as desired, the height of the adjustable counterpressure stop (s) 15 These means can comprise, for example, two vertical rods 16, passing from top to bottom each upper bearing block 9, on either side other of the spindle 4 a of the upper cutting cylinder 4, and of which at least the lower parts 16 a are threaded and screwed into corresponding tapped holes provided in the lower part of the upper block 9 The two lower parts I 6 have rods 16 constitute the counterpressure abutment by bearing, by their lower front faces, on the upper face of the lower bearing block 10 At their upper ends the two rods 16 are integral with respective pinions 17 engaged with a common central pinion 18 integral with a vernier 19 It is thus possible, by rotating this vernier 19,

  to adjust the height of which the lower parts 16 has rods 16 protrude

  below the bearing block 9 and consequently the spacing between the two blocks 9 and 10. When the rotary cutting device according to the invention is set in pressure, the pressurizing frame 12 extends horizontally and when each cylinder 14 is put under pressure, its rod is pushed down, against the upper bearing block 9 The force F produced by the jack 14 is exerted downward in the vertical and transverse plane P passing through the axis of the corresponding jack 14 and it is collected by the fixed stop 11 The external pressure force F, directed downwards, opposes a first reaction force F1, directed upwards, acting between the raceways 4 b and 5 b , and to a second reaction or counterpressure force F 2, directed upwards, acting between the two rockets 4 a and 5 a and tending to separate them from one another These forces are applied in such a way the reaction forces Fl and F 2 are equal if bie n as a result, for the two cylinders 4 and 5, a zero bending moment and consequently zero deformation Each rocket 4a of the cylinder 4 is thus kept embedded, together with the end part of the cylinder 4 extending to the raceway 4 b Due to this embedding, the bending or deflection that the upper cutting cylinder 4 undergoes, during a cutting operation, leaves from the raceway 4 b and it is much weaker than when it there is no embedding due to the absence of

back pressure stops 15.

  Such a rocket embedding device 4a works satisfactorily at the start of a work period but after a certain time, the cutting cylinder 4 and the anvil cylinder 5 heat up and the expansion which as a result causes the axes of these two cylinders 4 and 5 to be spaced apart. This spacing is absorbed without problem by the vertical jack 14, the rod of which retracts somewhat, but because the axis of the upper cutting cylinder 4 moves upwards. relative to the axis of the lower anvil cylinder 5 kept fixed, each upper bearing 9 moves upward relative to the lower bearing remaining fixed and the lower front face of the backpressure stop 15 moves away from the upper face of support of the lower bearing block 10, so that this backpressure stop no longer plays its role and that the backpressure force F 2 decreases To remedy this drawback, means are provided according to the invention. elastic 21 working in compression and which is interposed between the counterpressure stop 15 and the lower bearing 10 This elastic means 21 which can be composed, for example, of Belleville washers or of an elastomer block, is housed in a hollow 22 formed in the upper face of the lower bearing block 10 The elastic means 21 bears on the bottom 23 of the recess 22, the bottom to which the lower front face 16 b of each rod is normally applied 26 Preferably the threaded lower part 16 has each rod 16 is extended downwards by an end portion of smaller diameter 16 c which extends to the lower front face 16 b of the rod 16 The elastic means 21 (Belleville washers or block of annular elastomer) surrounds the extreme part of small diameter 16 c and it abuts up against the annular shoulder 24 formed between the part

  lower threaded 16 a of the rod 16 and the end portion 16 b of small diameter.

  When the rotary cutting device is at a standstill, its constituent elements therefore being relatively cold, and it is locked in pressure, each rod 16 is adjusted so that its lower front face 16 b is G in contact with the bottom 23 of the recess 22, as shown in FIGS. 1 and 2 In this position the elastic means 21 is strongly crushed After a certain working time the cutting cylinders 4 and 5 have become heated and expanded and the axis of rotation of the upper cylinder 4 has moved upwards, thus moving the lower front face 16b away from the counterpressure stop 15 from the bottom 23 of the recess 22, as shown in FIG. 3 However the characteristics of the elastic means 21 are chosen such that this elastic element 21 continues to exert upward a reaction or counterpressure force F 2 which allows the embedding of the rocket 4 a to be preserved of the upper cutting cylinder 4 As a result, the initial setting is maintained

  practically constant whatever the temperature of the cutting cylinders.

Claims (4)

  1 rotary cutting apparatus comprising a frame supporting, between two parallel vertical uprights (1), two superimposed cutting cylinders (4,5), with parallel axes, namely an upper cutting cylinder (4) and a cutting cylinder lower (5) respectively integral with raceways (4b, 5b) rolling on each other, each cutting cylinder (4,5) comprising at each end a coaxial spindle (4a, 5a) mounted to rotate in a bearing block (9, 10) which can slide vertically on the two respective uprights (1), each of the upper bearing blocks (9) being extended at its upper part, towards the interior of the apparatus, by a door part -to- false (9 a) subjected to the action, downwards, of a vertical pressure cylinder (14) mounted at the top of the device, while each of the lower bearing blocks (10) is extended, at its bottom, towards the inside of the device, by a part e in overhang (1 I a) extending above a stop (11) carried by the corresponding upright (1) and with which it is in contact, characterized in that it comprises, between each pair of upper (9) and lower (10) bearing blocks, a counterpressure stop integral with the upper bearing block (9) and bearing on the lower bearing block (10) by means of an elastic means (21) working in compression and constantly exerting upwards, even after heating and expansion of the cylinders, a reaction force (F 2) sufficient to permanently ensure the embedding of the rocket (4 a) of the upper cutting cylinder (4),   whatever the temperature of the cutting cylinders (4,5).   2. Apparatus according to claim 1 characterized in that the elastic means (21) bears on the bottom (23) of a recess (22) formed in the face   upper of the lower bearing block (10).   3. Apparatus according to any one of the preceding claims   characterized in that the counterpressure stop (15) consists of the lower part (16 a) of a rod (16) for adjusting the height of the stop, the lower part (16 a) of the rod (16) is extended downwards by an end portion of smaller diameter (16 c), delimiting between them an annular shoulder (24), and the elastic means (21) surrounds the end portion of small diameter (16 c)   and abuts up against the annular shoulder (24).   4. Apparatus according to claim 3 characterized in that the elastic means (21) consists of Belleville washers or an elastomer block   ring surrounding the end of small diameter (16 c) of the rod (16).