CH439037A - Copying machine - Google Patents

Description

  

  



   The present invention relates to. a copseuse machine carrying on a frame, at least one device for unwinding a wire coming from a spool, a roll or any other source and for then placing this wire in the form of a cops or a cocoon, the or each device isusdit comprising a means for feeding the yarn, a braking means for the fill, a medium yarn breaker, a means for distributing or reciprocating translation of the thread, a rotating spindle which is provided with its locking members. control and drive and which is arranged longitudinally being parallel to the path of the part of the latter means effectively driving the wire according to its distribution or alternating translation so as to ensure the reciprocating winding of this wire on a determined portion of the spindle ,

   a forming cone against which the wire is held in its direction of distribution or alternating translation during its winding on the aforesaid portion of the spindle at the start of the formation of the cops and by which the cops, in the process of formation, is pushed back along the spindle, a guide cup which is aligned along the longitudinal axis of the spindle, which receives the end of the cops opposite to the cell adjacent to the forming cone and which is moved by the cops being formed, from a starting position to at an intermediate position for lengthening the cops, a means for spacing the guide cup relative to the forming cone, moving this guide cup parallel to the axis of the rotating spindle,

   from its intermediate position of cutting the cops to length to an evacuation position ensuring the evacuation of the cops formed, a wire cutting means connecting the outer end of the cops formed with the inner end of the following cops, acting when the caps formed is released from the forming cone and. of the guide bowl, and a means for replacing the guide bowl in its starting position from its discharge position.



     There are already machines of this kind.



   In some of these known machines, the cops is formed on a horizontal rotating spindle cooperating with a single forming cone. This rotating spindle is driven by a clutch system controlled by a motor. During its formation, the cap is guided by a movable guide cup along the horizontal axis of the rotating spindle. When the cops has arrived at the desired length, that is to say when the guide cup reaches its intermediate position for lengthening the cops, a device acts mechanically on the clutch system in question in order to disengage the latter. , so as to stop the mechanical connection between the rotating spindle and the control motor, which is otherwise constantly rotating, and so as to stop the spindle.



  On the other hand, after disengaging the clutch system, the spindle is released slowly from the caps formed by being moved axially towards the rear. When this pin is completely withdrawn from the interior of the cops, the latter is gripped by claws or similar gripping parts and is released from the guide cup to be discharged downwards. Then the spindle is slowly replaced in the starting or working position and the wire connecting the formed cops to the next cops is also cut by scissors located below the spindle and is rewound or rewound around it, to ensure the formation of said next cape.



   These known machines have drawbacks.



  The rotary spindle must be stopped for a relatively long time in order to be completely disengaged, by translating its working position and then being replaced in the same way, in this position ;.



   On the other hand, the control of the rotary spindle by a clutch system is a significant source of mechanical damage. Furthermore, the cops formed using a single forming cone risks during its formation being insufficiently tightened and being irregularly t pushed along the spindle.



     Finally, the resumption of the winding or winding of the wire on the spindle to initiate the next cops is not constantly immediate and often results in a slip.
 loosely thread around this pin. Of all this he
 The result is that such known machines make it possible to form relatively irregular and soft cops, according to production rates that have hitherto been normal but reduced by stoppages inherent in their type of construction.



   In other known machines, the cops is formed on a vertical rotating spindle and by a single cone being constantly supported by a vertically displaced guide cup first slowly during the formation of the cops and then rapidly as soon as the cops is at desired length, while the spindle control clutch is not stopped. In addition, at the end of its downward stroke, the guide cup is suddenly tilted to allow the free fall of the body on a tilting device from which it is evacuated. The formed body is therefore lowered vertically and sufficiently to be completely free from the rotating spindle.



  At this time, scissors are brought into the path of the cops formed after passing the latter in order to cut the wire connecting this cops to the next cops. When the wire is cut, a. lever and cam system ensuring the evacuation of the cops, allows the tilting and the upward return of the guide bowl in its upper working position.



   These other known machines have drawbacks.



  They also only use a single cens to form the cops and do not stop the alternate translation of the wire opposite the spindle between two successive cops.



  In addition, they employ a complicated shaped cops evacuation system that generates frequent damage and limits their production rate.



   The present invention makes it possible to remedy the aforementioned drawbacks and drawbacks by having as an object a machine allowing an increase in production rate of 20 to 25 ouzo compared to other machines.



   For this purpose, the or each spindle is individually controlled by an electric motor, while the device further comprises a compensating cone which is disposed vis-à-vis the forming cone with respect to the vertical plane passing through the longitudinal axis of the rotary spindle, which cooperates with this forming cone to size the cops and. pushing the latter in the process of formation along this rotary spindle and which is movable simultaneously with said forming cone.

   On the other hand, the aforesaid means for spacing the guide cup relative to the cones and the aforesaid means for replacing this guide cup in the starting position consist of a pneumatic cylinder, the piston rod of which drives, d 'on the one hand, the guide cup from its intermediate position for cutting the cops to length to its position for discharging the latter and back from this position to its starting position and, on the other hand.

   the two forming and compensating cones of a starting position in which the cops is formed and cut to length at an evacuation position ensuring the evacuation of the formed cops and, in return, from this evacuation position to this position starting, Te displacement of the cones from their starting position being carried out a few moments after that of the guide cup from its position for cutting the cops to length.



   The invention will become apparent from the description of the accompanying drawing which shows schematically and by way of example only one embodiment of the invention.



   Fig. 1 is an elevational view with partial section of an embodiment of a copseuse machine according to the invention shown in the starting position.



   Fig. 2 is a plan view with partial section of the machine in the starting position.



   FIG 3 is a similar elevational view of the machine in the intermediate position for cutting the cops to length.



   Fig. 4 is a corresponding plan view of the machine in the intermediate position for cutting the cops to length.



   Fig. 5 is a similar elevational view of the machine in an intermediate position shortly following the intermediate position of cutting to length of the cops, this view being considered from the side opposite to that relating to FIGS. 1 and 3.



   Fig. 6 is a partial plan view corresponding to the previous one of the machine in the next intermediate position with little lengthening glue of the cops.



   Fig. 7 is a partial elevation view of the machine in the extreme cops discharge position.



   Fig. 8 is a partial plan view, corresponding to the previous one, of the machine in the extreme position of discharge of the cops.



   Fig. 9 is a cross section of the machine taken along the line IX-IX of FIG. 1.



   Fig. 10 is a sectional elevation of the cone-carrying carriage of your machine, taken along the line
X-X of fig. 12 considered below.



   Fig. 11 is a partial plan view of the lower carriage and of a part of the upper carriage carrying the guide cup of the machine in the starting position.



   Fig. 12 is a partial plan section taken along the line XII-XII of FIG. 10.



   Fig. 13 is a transverse view of the lower carriage of the machine, after section taken along the line XIII-XIII of FIG. 11.



   Fig. 14 is a partial elevation view of the lower and upper carriages of the machine in the starting position n, cut along the line XIV-XIV of the following figure.



   Fig. 15 is a transverse view of the carriages after section taken along the line XV-XV of FIG. 14.



   Fig. 16 is a section of a detail of the machine taken along the line XVI-XVI of FIG. 15.



   Fig. 17 is a partial elevational view of two control switches of the machine, taken along the line XVII-XVII of the following figure.



   Fig. 18 is a cross section of this switch taken along the line XVIII-XVIII, of FIG. 17.



   Fig. 19 is a partial schematic section illustrating the third control switch of the machine, section taken along line XIX-XIX of the following figure.



   Fig. 20 is a section taken along line XX-XX of FIG. 19.



   In these different figures, the same reference notations designate identical elements.



   The machine shown serves, on the one hand, to unwind a wire 1 previously wound on a spool 2 and, on the other hand. in placing this yarn 1 in the form of a cops or a cocoon 3. The yarn 1 can be made of jute, linen, hemp, cotton, sisal or another similar threadlike or filamentous textile material , natural or synthetic.



   The machine includes a feed device. 4 which, in the example chosen, may include three supply coils 2 visible in FIGS. 1, 3, 5 and 9. The feed device 4 essentially consists of a plate 5 in the form of a plate, the concavity of which is directed upwards. In order to be able to carry the supply coils 2, the plate 5 is provided with three supports 6 fixed to the upper face of its slightly oblique marginal part. Each of the supports 6 carries a large main spindle 7 and a small auxiliary spindle 8 on which the corresponding supply reel 2 can be fitted.



   The plate 5 is mounted freely to rotate or pivot around a vertical shaft 9 and is supported by a fixed support 10 to which moreover the said shaft 9 is attached.



   To ensure the continuity of the unwinding of the son of the reels 2 placed on the plate 5, the inner end of one of them is connected by a knot, to the outer end of the next reel.



   The wire 1 is conveyed upwards and passes through a guide tube 11, the position of which with respect to the plate 5 is external in the form of embodiment envisaged, this position being able to be centered with respect to said plate 5 in a variant. execution. This curved guide tube 11 extends downward from an upper zone located above the level of the coils 2, substantially in line with the counter of the plate 5, to a lower zone located below the level of the plate 5 or possibly at the level of the central part thereof.



   The lower end of said guide tube 11 is fixed on a support 12 integral with the aforementioned support 10.



   In this way, the wire 1 is guided over a good part of its path separating the spool 2 from which it comes, from the part of the machine which then processes it. In this way, the ballooning of the wire 1 is avoided along this part of its path.



   At the exit, from the guide tube 11, the wire 1 is brought to a rotating spindle 13 serving to completely form the cops 3.



   Before reaching said pin 13, the yarn is caused to pass successively through a braking device 14, a yarn breaker device 15 and an ailternative distribution or reciprocating translation device 16 of the yarn 1 capable of alternately moving this yarn. 1 opposite a well-determined portion of the length of the rotary spindle 13.



   The cheese device 14 consists essentially of at least one braking disc 17 having a circumferential edge in the form of a groove through which the wire 1 passes.



   For example, the brake disc 17 is rotatably mounted on a fixed pivot rod 18, one end of which is carried by a support 19 fixed to the aforesaid support 12 and is provided with a friction ring 20 and the other of which threaded end carries a washer 21 retained by two nuts 22.



   To ensure the braking of the brake disc 17 in rotation around the pivot rod 18, this disc 17 is constantly urged to bear and to rub laterally against the friction ring 20, thanks to the action of a spring 23 spiroidal or possibly helicotidal, compressed between said brake disc 17 and said washer 21.



   The thread-breaking device 15 consists, in turn, of at least one tensioning disc 24 mounted freely to rotate around a pivot 25 fixed to the end of a lever 26.



  The latter pivots around a fixed pivot 27 aligned in the extension of the pivot rod 8. The lever 26 is resiliently biased by conventional means, not shown, so as to constantly tension the wire 1 under a relatively low predetermined tension. . The wire 1 is guided by passing through the groove of the edge of the tensioning disc 24. When this wire 1 breaks, the lever 26 rotates under the action of the aforementioned means around the fixed pivot 27. This rotation of the lever 26 causes a rotation equal to an extra thickness or a cam 28 presented by the upper end of the lever 26 surrounding the pivot 27.

   When the wire is not broken, the extra thickness 28 is in contact with the free end of the lever 29 of a contactor 30 carried by a small support 31 fixed to a connecting bar 32 of the pivot 27 to the. part of the machine below it. This extra thickness 28 then ceases to be engaged when the wire breaks and produces a movement of this lever 29 sufficient to ensure the tripping of this contactor 30 thus stopping the motor 33 for controlling the rotary spindle 13.



   The distribution device. alternative 16 comprises, for its part, a hook 34 located at the end of a rod 35 perpendicular to the rotary spindle 13 and driven by an alternative translational movement. This movement of the hook 34 or of the rod 35 is provided by a motor member which is preferably the motor 33 for controlling the rotary spindle 13, and by the intermediary of transmission members comprising, among other things, a gear reducer 36 driving an eccentric 37 actuating a connecting rod 38 alternately moving a pivoting crank 39, one end of which is mounted around a pivot 40 fixed to the frame or to the frame of the machine and of which the another end post the aforementioned rod 35.

   It is easily understood that any rotation of the eccentric 37 causes a pivoting tilting of the crank 39 and practically an alternating translation of the rod 35 and of the hook 34 opposite the rotary spindle 13.



   In order to be able to vary the amplitude of the pivoting tilting of the crank 39, the end of the connecting rod 38 connected to this crank 39 can be adjusted in position with respect to the pivot axis of the latter, or to the axis of the pivot 40, thanks to the fact that this extremity carries a finger 41 fdédaçable in a suitably arched groove 42 presented pan-said crank 39. The couQissement of the finger 41 in the groove 42 can still be carried out beforehand, through the intermediary of a micrometric screw in order to obtain a fine adjustment of the diameter of the formed body.



  On the other hand, to be able to adjust the position of the hook 34 or of the rod 35 relative to the rotary spindle 13, and that for a well-determined position of the finger 41 of the connecting rod 38 in the groove 42 of the crank 39, the end of this rod 35, opposite the hook 34. can slide in a suitable groove 43 of the free end of the crank 39 and be fixed there after adjusting its position.



   The wire 1 is engaged in the hook 34 and is thus moved alternately opposite the corresponding portion of the rotary spindle 13.



   The rotary spindle 13 is mounted on the output shaft of the speed reducer 36 co. nmf to the aforementioned motor 33 and fixed to the frame of the machine. In the embodiment shown, the spindle 13 is inclined so as to form with a horizontal plane an angle of between 40O and 600, and preferably an angle of approximately 550. However, the invention extends to the case where the pin 13 is differently inclined or is even horizontal.



   The spindle 13 is only driven by a rotation about its axis and is stationary along it. It preferably consists, on the one hand, of a part with a constant circular section located on the side of the reducer 36 and of a part with a square section that tapers towards the opposite side.



   The portion of the rotary spindle 13 vis-à-vis which the wire 1 is alternately moved by the aforesaid device 16 for alternating distribution, is located opposite its square section part.



   To begin the operation of forming the cops 3 on the corresponding portion of the rotary spindle 13, the wire 1 is wound by hand around this portion of the spindle so as to make a few turns there. Then, the drive motor 33 is started and the spindle 13, by rotating, ensures the reciprocating winding of the wire 1 on its portion considered above.



   The formation of the cops 3 is further ensured by two cones 44 and 45 mounted on a first carriage or lower carriage 46.



   The first carriage or lower carriage 46 is movable along two guide rods 47 and 48 mutually parallel and parallel to the axial direction of the rotary spindle 13. These guide rods 47 and 48 are fixed to the frame or to the frame. of the machine.



   The lower carriage comprises a transverse main support 49 which has a lateral notch 50 in which the guide rod 47 is constantly engaged.



  The main support 49 is integral with a first slide or lower slide 51 sliding along the other guide rod 48. Furthermore, the main support 49 carries, on the side of its notch 50, a bracket 52 which is fixed by bolts 53 screwed into a projection of said support.



   The lower carriage also comprises two auxiliary supports 54 and 55 in the form of an angle iron. These auxiliary supports 54 and 55 are mounted on the main support 49 by one of their wings and are arranged on either side of the vertical plane of symmetry passing through the longitudinal axis of the rotary spindle 13. Said auxiliary supports 54 and 55 carry, by their other wings, respectively two shafts, for example in the form of bolts 56 and 57 on which the two cones 44 and 45 are respectively mounted and around which these two cones can rotate freely.



   In general, the two auxiliary supports 54 and 55 and, consequently, the two cones 44 and 45, are arranged symmetrically with respect to the aforementioned plane of symmetry.



   The adjustment of the relative position of the cones 44 and 45 can be obtained thanks to the construction; following particular:
 Each of the auxiliary supports 54 and 55 in the form of an angle iron can, pivot around, a pivot, 58 respectively 59 fixed to the main support 49. This pivot 58 or 59 preferably consists of a screw whose shank has, d. 'on the one hand, an end part threaded and screwed into a tapped hole of the main support 49 and, on the other hand, a remaining smooth part, the height of which is slightly greater than the thickness of the corresponding lower flange of the support considered auxiliary 54 or 55, this wing being thus placed between the main support 49 and the head of the screw constituting the pivot 58 or 59.



   In general, the two pivots 58 and 59 are arranged symmetrically with respect to the aforesaid vertical plane of symmetry of the machine.



   The pivoting of the two auxiliary supports 54 and 55 in. angle iron are simultaneous and are made in opposite directions, so that these supports 54 and 55, and consequently the cones 44 and 45 which they carry, then remain constantly symmetrical with respect to the aforesaid vertical plane of symmetry of the machine.



   The approximation. ment, respectively the distance. ement, ds two auxiliary supports 54 and 55 or the two cones 44 and 45 is provided by a micrometric screw system with reverse pitch essentially consisting of a micrometric screw 60 having two fine end threads, one with left pitch and the other not straight. The threaded parts of this screw 60 engage respectively in two nuts 61 and 62 suitably threaded forming lower projections reported from the auxiliary supports 54 and 55. After. adjustment, the screw 60 is blocked or prevented from rotating in these nuts 61 and 62, for example, by virtue of not shown against nuts bearing against them.

   One of the threaded parts of the screw 60 also has, on its edge, a groove intended to receive the tip of a screwdriver with a view to rotating the screw 60 itself after release. The nut 61, respectively 62, slides in a groove 63 respectively 64 suitably arcuate and suitable presented by the main support 49.



   In this way, it is easy to understand that any rotation of the micrometric screw 60 with double thread causes a corresponding moving away or coming together of the auxiliary supports 54 and 55 and of the cones 44 and 45, ensuring the symmetrical distribution of these elements on both sides. other side of the vertical plane of symmetry of the machine. More generally, the aforementioned micrometric screw can, for the same purpose, cooperate with two other projecting parts of the auxiliary supports in the form of an angle.



   When the adjustment of the relative position of the cones 44 and 45 is ensured for a production of cops 3 of determined dimensions, it is possible to lock the auxiliary supports 54 and 55 of the cones 44 and 45, in their respective position. The locking of such an auxiliary support is obtained by a small locking screw 65 which, by its threaded rod, is engaged through a corresponding short suitably arched groove 66 presented by the lower flange of said auxiliary support 54 or 55 and is screwed into a corresponding threaded hole of the main support 49. This small locking screw 65 clamps, by its head, said lower wing of this auxiliary support against this main support.



   It should be noted that the homologous points of the cones 44 and 45 located closest to one another are practically immobile and located at one of the limits of the displacement of the aforementioned hook 34.



   The wire 1 previously wound by hand to form a few turns on the spindle 13, is mechanically more so during the rotation of the spindle 13.



   One of the cones, namely the forming cone 44, effectively cooperates with the spindle 13 to form the start of the cops 3 which is then in a toric shape with a triangular section since, on the side of the drive motor 33, the coiled wire the side of this forming cone 44 is retained and even pushed back by the latter on the other side, as the diameter of the beginning of the cops 3 increases. The inclination of this forming cone 44 and the amplitude of the reciprocating hook 34 together determine the final height of the triangular representative of the start of the cops 3, measured perpendicular to the axis of the rotating spindle 13 and thus define the external diameter of the cops 3.



   The other cone, namely the compensator 45, serves mainly to balance the radial component of the oblique thrust exerted on the body 3 by the forming cone 44 and to transfer the longitudinal component of this thrust onto said body 3 in order to facilitate the release of the latter. - along the rotary spindle 13.



   Advantageously, provision may be made for a slight difference in the angles formed respectively by the axes of the cones 44 and 45 with the axis of the rotary spindle 13, or better still a slight offset of the pivot axis of the compensating cone with respect to the cone. former. This difference or this offset combined with the practically immutable position of the aforementioned points of the sides located one opposite the other, ensure a constant winding of the wire 1 on the rotating spindle 13 at the starting point of the end of the nose of the barrel 3 or, in other words, ensure that this end remains at a constant height on the spindle 13 during winding or forming the cops 3.



   During its formation, the cops 3 extends more and more obliquely upwards, reaches and then exceeds the end square part of the rotary spindle 13.



  When the cops 3 is formed to the desired length, it surrounds the rotating spindle 13 over its entire length and still exceeds the latter by about a quarter or a third of this length.



   The anterior point of the cops 3, that is to say that which is directed upwards and opposite to the aforementioned cones 44 and 45, is engaged in a guide bowl 67 in the form of a hollow funnel, coaxial with the rotating spindle 13 as soon as the cops 3 extends upwards along the spindle 13 after having been brought to a suitable external diameter by the action of the cones 44 and 45. This guide cup 67 which helps in the ejection of the finished cops , is carried by a second carriage or by an upper carriage 68.



   The upper carriage 68 comprises a transverse main support 69 having a lateral notch 70 in which the guide rod 47 is constantly engaged. This main support 69 carries the guide cup 67 at its upper part of a side of glue.



  Furthermore, the main support 69 is integral with a second slide or upper slide 71 sliding along the other guide rod 48.



     On the other hand, the upper slide 71 also has a stop or a lateral lug 72 perpendicular to the guide rods 47 and 48 as well as a stop 73 for actuating the main parts of the machine. The role of this stop and of this actuating lug is explained below.



   The actuating stop 73 in question is mounted on a pivot 74 disposed between two tabs 75 fixed to the upper slide 71 of the upper carriage 68. The arrangement of this stop 73 and of this pivot 74 relative to the upper slide 71 is such that said stop 73 can pivot freely around said pivot 74 only upwards or on the side opposite to the cones 44 and 45 or to the body 3, from its normal position in which it is directed downwards while being however perpendicular to the guide rods 47 and 48 aforementioned.



   The lower 46 and upper 68 carriages are movable along the guide rods 47 and 48, between a lower position or X starting position and an upper position or discharge position, and vice versa.



   During the formation of the cops 3, the lower carriage 46 is maintained in its lower position, while the upper carriage is moved from its lower starting position to an intermediate position for cutting the cops to length, under the upward thrust of the latter. this.



   The lower carriage 46 is held in its lower position, in particular by its own weight, thanks to the support of its main support 49 on a tubular stop 76 surrounding the guide rod 47 and. resting against the frame or the frame or against the reduction gear 36.



   The upper carriage 68 is in the lower starting position, leaning under the effect of its own weight against another bu. te galemnt tubu'laire 77 surrounding the same guide rod 47 and bearing against the previous stop 76, in particular by a helical res sort:! shock absorber 78.



   When the upper carriage 68 reaches its intermediate position of lengthening the cops, its tilting stop 73 almost instantly actuates two micro intenrupteuTs 79 and 80, the roles of which are explained below.



   Said tilting stop 73 encounters on its path a retractable stop formed by uneroulette 81 or a ball bearing. This'roulette 81 or this bearing is mounted at the end of a wing of an angled arm 82 pivoting in its middle about a fixed pivot 83. The end of the other wing of this angled arm 82 carries , towards the bottom, a small plate 84 which actuates the two aforementioned microswitches 79 and 80.

   To this end, the plate 84 in question is supported, during the downward tilting of its supporting wing, on a small rod 85 terminated by a plate 86 surmounting the two JevieM 87 and 88 of these microswitches 79 and 80, the The height position can be adjusted respectively by small screws 89 and 90 screwed into a bottom part 91 provided in the housing of these microswitches and held in position by nuts 92 applied against this housing. As a result, the first microswitch 79 can operate a few moments before the second microswitch 80. This delay in operation between the two microswitches 79 and 80 may be, for example, of the order of a few 1 liòmes. second.



  The return to position of the roller 81 and of the angled lever 82 is ensured by a small helical spring 93 which bears internally against the housing of the microswitches and above against a lug 94 fixed to the rod 85.



   It should be noted that the position of the roller 81 or of the ball bearing and of the housing of the microswitches 79 and 80 mounted on the frame or the chassis, by means of an auxiliary support formed of a sheet 95 and a , flat 96 fixed to the frame, can be adjusted in particular according to the direction of the guide rods 47 and 48 or according to that of the rotary spindle 13.



   The first microswitch 79 is wired in series in an electric circuit which controls that of the supply to the control motor 33 ensuring the rotation of the spindle 13. The actuation of this first microswitch 79 produces the opening. of the latter circuit and thus stops said motor 33 and said pin 13.



   The second microswitch 80 is wired in series in an electrical circuit controlling an electromagnetic valve.



   The actuation of this second microswitch 80 ensures the opening of this valve, which is also connected to the compressed air supply circuit, of a pneumatic cylinder 97, from a source generating such a fluid. . This cylinder 97 comprises, inside, a double-acting piston, the piston rod 98 of which extends upwards, parallel to the aforementioned guide rods 47 and 48. The electromagnetic valve in question makes it possible to 'feed the cylinder 97 only on the side of its piston opposite to the piston rod 98, that is to say only vens the bottom.



   Thus, as soon as the upper carriage has arrived in its intermediate position for lengthening the cops, the aforementioned tilting stop 73 causes the bent arm 82 to tilt which successively actuates the first and second micro-switches 79 and 80.



   This therefore results, on the one hand, in an interruption of the power supply to the motor 33 controlling spindle 13 producing its brief stopping or at least its slowing down and, on the other hand, an intake of compressed air. in the lower part of the cylinder 97. This admission causes a very rapid rise of the piston in the cylinder 97 and of the piston rod 98 outside the latter.



   This drives with it the two carriages 46 and 68 as follows:
 The piston rod 97 carries a first stop or lower stop 99 which is constantly included between the two wings of the caliper 52 integral with the lower slide 51 of the lower carriage 46. In the forming position of the body 3, this lower stop 99 is against the lower wing of the caliper 52 or in the vicinity thereof. During the ascent of the piston rod 98, the lower stop 99 meets on its path the upper wing of this caliper 52 and drives it obliquely upwards.

   In this way, the piston rod 98 can move the lower carriage 46 carrying the cones 44 and 45 from its starting position or lower position to its discharge position or upper position for which the cops 3 which follows the movement of the lower carriage 46 is completely disengaged from rotating spindle 13.



   The piston rod 97 is also provided with a second stop or upper stop 100 which carries a special hook 101 capable of hooking the lateral stop 72 on said joint with the upper slide 71 of the upper carriage 68. In the normal position, the hook 101 extends longitudinally. in the direction of this guide rod 47. The hook 101 can pivot about an axis located near the upper stop 100.



  The lower end of this hook located on the side of the pin 13 forms a beak 102 oriented downwards, while the upper end 103 of said hook is connected by a small coil spring 104, to that of an arm 105 fixed to the upper end of the stop su, upper 100 and directed perpendicular to the latter. Between its two ends. the hook 101 has a boss 106directed downward.



   In normal position. the hook 101 which is arranged parallel to the arm 105 or to the guide rods 47 and 48 can pull the upper carriage upwards from its intermediate position for cutting the cops to length in its discharge position. Advantageously, the upper edge of the part of the hook 101 situated upwards beyond the upper stop 100 normally bears against the lower edge of the arm 105.

   In addition, these edges are relatively flattened so as to present the largest possible mutual laying surfaces, having regard to the other dimensions of these parts, in order to obtain the strongest possible adhesion between said edges and thus avoid returns. or internal positive twists of the hook 101 as soon as the latter has returned to its normal position and when it is no longer forced to leave the latter.



   In the lower position, damslaquelle the hook 101 remains stationary during the formation of the cops 3, the spout 102 of the hook is however raised. The hook 101 and the upper carriage 68 no longer have a mutual drive link.



   In order to be able to be raised in this way, the hook 101 cooperates via its boss 106 with a ball bearing 107 rotating freely around a pivot 108 mounted on an auxiliary support 109 fixed to the frame or to the frame of the machine. This ball bearing 107 which is on the path or the displacement path of the boss 106 and not on that of the nose 102 of the hook thanks to the bending of the latter well illustrated in the figures in plan, forces this boss 106 to rise somewhat when the hook 101 descends in the vicinity of its starting position or lower position.

   This lifting of the boss 106 causes a stronger lifting of the spout 102 which then ceases to be in contact with the said lateral abutment 72 of the lower carriage. It should be noted, however, that the lower limit position of the boss 106 is such that the point of contact thereof on the side surface of the ball bearing 107 is on the side opposite to the spindle 13 with respect to the plane passing through the. pivot axis of this bearing 107 or by the axis of the pivot 108 perpendicular to the direction of the guide rods 47 and 48. Therefore, it is also not enough for a fewmstants for the hook 101 to reach its normal position starting from its lower raised position .



     It should also be noted that the lower limit position of the boss 106 of the hook 101 on the ball bearing 107 can be adjusted by virtue of the possible movement of the unwinding 107 parallel to the plane of the longitudinal axes, of the guide rods 47 and 48. A To this end, the auxiliary support 109 of this ball bearing 107 is advantageously fixed to the frame or frame by screws 110 screwed into tapped holes thereof and engaged in longitudinal grooves or slots 111 of said auxiliary support 109, s 'extending parallel to the guide rods 47 and 48.



   The oMic upward movement of the formed body 3 and the ejection of these loops are therefore ensured by the upward oblique movement of the piston rod 98 to which the lower drive stops 99 and upper 100 are connected.



   From the starting position or lower position, the upper stop 100 directly drives the hook 101. The latter immediately descends into its normal position following the very rapid release of its boss 106 from the ball bearing 107. In addition, beak 102 of the hook 101 hooks the side stop 72 of the upper slide 71 so. to drive the entire upper carriage 68 upwards and in particular the guide cup 67 in which the upper end of the formed body is then located 3. The attachment of the lateral stop 72 by the spout 102 of the hook 101 is achieved a little before the lower stop 99 comes into contact with the upper wing of the caliper 52 of the lower carriage 46.

   In this way, the lower carriage 46 carrying cones 44 and 45, pushing! Ecopsformé3, is oblique upwards a little after the upper carriage 68. It follows that the distance separating the cones 44 and 45 and the guide cup 67 becomes larger than that existing at the start of this simultaneous movement of the carriages when the lower carriage 46 is in its starting position and when the upper carriage 68 is in its intermediate position for lengthening the body 3.

   The increase in this distance allows the body 3 pushing and obliquely upwards by the cones 44 and 45, to free itself especially from the guide bowl 67 and then to fall by gravity into a discharge chute not shown at the base of which is for example a receptacle or a box or a conventional transporter.



     The lower 46 and upper 68 carriage wings are very quickly brought into the upper position by the piston rod 98. These upper positions cannot be exceeded thanks to the escape of the pressurized fluid in the cylinder 97 and having acted on the lower face of the cylinder. piston and thanks to the admission of such a fluid into the upper part of this cylinder 97, intended to act on the other face of this piston in order to very quickly bring the piston rod 98 downwards.



   Such an admission of pressurized fluid into cylinder 97 can also be controlled by the aforesaid electromagnetic valve from a third microswitch 112 inserted in the electrical control circuit of this valve. This third microswitch 112 can be similar to the previous two and is actuated by the lower carriage in the example chosen.



  This microswitch 112 is like the previous ones mounted in a box fixed to the frame or to the frame of the machine. It is actuated by one of the wings of an angled arm 113 pivoting in the middle around a fixed pivot 114, the other wing of this angled arm 113 carrying a roller bearing or a small caster 115 freely rotating around its own. pivot. Said bent lever 113 is tilted under the action of the upward thrust, for example of the lower slide 51 of the lower carriage 46.

   The third microswitch 112 is carried by a support 116 mounted on the frame or frame, the position of this support 116 being adjustable in particular parallel to the plane formed by the axes of the aforementioned guide rods 47 and 48.



   Thus, as soon as the lower slide 51 encounters the bearing relating to the third micro-switch 112, this slide 51 actuates the latter which ensures the return movement and obliquely downwards of the piston rod 98 to its lower position. It should be noted that during this return movement of the piston rod 98, the upper drive stopper 100 releases the hook 101 from its contact connection with the upper carriage 68 which falls by its own weight along the rods. guide 49 and 50 from its discharge position to its starting position.



   Upon impact of the upper carriage 68 with the distancing element referred to or more precisely with the end of the tube 77, the shock produced on impact by such a fall is damped by the helical spring constituting this distancing element 78.



   When moving back the piston rod 98, the lower drive stop 99 ceases to be applied against the upper wing of the caliper 52 integral with the lower carriage 46 and comes into contact with the lower wing of this caliper 52. De in this way, by'sa lower drive stop 99, h piston rod 98 returned the lower carriage 46 'to its lower position initially considered.



   It should be noted that during the return movement of the upper carriage 68, the tilting stop 73 carried by the latter hits the roller 81 of the bent arm 82 actuating the microswitches 79 and 80 without tilting these arms since upon contact from this stop with this roller 81, said stop is tilted without difficulty backwards with respect to its direction of movement.



   On the other hand, lo ,, rs of the return movement of the lower carriage 46, the latter actuates a fourth contactor or a fourth microswitch 117 which can be identical to the microswitches 79, 80 and 112 and which can be mounted from the same way as these, on the frame or the frame of the machine. In this way, the microswitch 117, per, puts the electric current back into operation and starts the control motor 33 of the rotary spindle 13.



     According to) a very important characteristic of the machine, the stopping of the motor 33 is not completely unstable following the actuation of the first micro-switch 79. By its inertia,! rotor of this motor 33 still performs a few revolutions during the removal or release of the formed capsule 3, delabroche 13. It follows that the fill 1 which connects the lower end of the formed coil 3 to the coil 2 of the feed device 4 , is wound on spindle 13 by a few turns before this spindle 13 starts rotating again following the activation of the control motor 33.

   These few turns of the wire 1 existing on the spindle 13 before your restarting the latter, facilitates the start of formation of the next cops and ensures the continuity of the operations of the machine.



   To reduce as much as possible the idle times of the machine between two successive cops, the operations of microswitches 79 and 80 are very close to each other, while the ejection speed or that of the outward and return movement of the trolleys 46 and 68 is significantly high.



     As described previously, the formed cap 3 is driven upwards by the movement of the carriages 46 and 68 and is evacuated by gravity following the separation thereof. To release the cops evacuated from the next cops, the wire is cut by a movable guiMotinc 118 which is driven upwards by the upper carriage 68, by tirdesapositioninférieurepourlaquelle it cooperates with a fixed knife 119.



   In order to be able to be driven by the upper carriage 68, the aguillotine 118 has a lug 120 upwards, the stop face of which is directed towards the cones. This lug 120 cooperates with the beak 121 of another particular hook 122 which pivots around a pivot 123 fixed to an elbow support 124 mounted on the main support 69 of the upper carriage 68, by a bolt 125. In the normal position, the hook 122 s 'extends longitudinally while being parallel to the guillotine 118 or to the guide rods 47 and 48. It is in this position thanks to a thrust spring 126 which tends to make it tilt until against a stop 127 integral with the elbow support 124.



   Furthermore, this hook 122 remains in its normal position until the vicinity of its position; upper where its end opposite the nose 121 and inclined upwards meets a roller 128 or the like freely pivoting about a fixed pivot 129 mounted on the frame or the frame of the machine.

   This roller 128 forces the hook 122 to swing against the spring 126 and forces the beak 121 of this hook to rise and free itself from the lug 120 of the guillotine 118, the latter, thus arriving in its position. upper, continues its rise somewhat until it hits a fixed transverse stop 130 against which it rebounds to move back down by gravity, however benefiting from the impact energy produced by it against said stop 130 It should be noted that this stopper 130 has a groove in which the end of the hook I22 is lowered by the roller 128.



   The knife 119 is V-shaped, the tip of which carries a small blade 131 perpendicular to the direction of movement of the upper carriage 68.



   The guillotine 118 has a corresponding V shape with the top crushed perpendicular to this direction. In the lower position, the wings of the V of the guillotine 118 rest against these V of the knife 119, while the crushed top of the guillotine 118 is against the blade 131.



   When the formed body 3 falls into the discharge chute above the knife 119 and below the guillotine 118 then raised, the wire 1 is engaged between the airas of the V of the knife 119 and against the blade 131 of the latter. this. During the fall of the guillotine 118 the wire is cut between the point of the guillotine 118 and the blade 131. It should also be noted that the guillotine 118 can also possibly remain; rli. ee to the upper carriage 68 laying down part of its movement downwards.


 

Claims (1)

CLAIM Copseuse machine carrying on a frame at least one device for unwinding a thread coming from a spool, a roll or any other source and then placing this thread in the form of a cops or a cocoon, the or each aforesaid device comprising a wire feed means, a wire braking means, a wire breaker means, a means for distributing or alternating translation of the wire, a rotary spindle which is provided with its control and drive members and which is arranged longitudinally being parallel to the path of the workpiece of the latter means effectively driving the following wire with its distribution or alternative translation so as to ensure winding alternative of this wire on a determined portion of the spindle, a forming cone against which the wire is held in its direction of distribution or translational alternative during its winding on the aforesaid portion of the spindle at the beginning of the formation of the cops and by which the cops , in the process of formation, is pushed back along the spindle, a guide cup which is aligned along the longitudinal axis of the spindle, which receives the end of the cops opposite to that adjacent to the forming cone and which is moved by the cops being formed, by a position starting up to an intermediate position of lengthening of the body, a means for spacing the guide cup relative to the former, moving this guide cup parallel to the axis of the rotating spindle, from its intermediate position length of the cops to an evacuation position ensuring the evacuation of the cops formed, a wire cutting means connecting the outer end of the cops formed with the inner end of the following cops, acting when the formed body is released from the forming cone and from the guide cup, and a means for replacing the guide cup in its starting position from its discharge position, characterized in that the or each spindle is individually controlled by an electric motor , in that the device further comprises a compensating cone which is arranged vis-à-vis the forming cone with respect to the vertical plane passing through the longitudinal axis of the rotary spindle, which cooperates with this forming cone to size the cops and push the latter in the process of formation along this rotating spindle and which can be moved simultaneously with said forming cone, in that the aforesaid means for spacing the guide cup relative to the cones and the aforesaid means for replacing this guide cup in the starting position consist of a pneumatic cylinder whose piston rod drives, on the one hand , the guide cup from its intermediate position of cutting to length of the cops to its evacuation position thereof and, in return, from this position to its starting position and, on the other hand, the two cones for mator and compensator of a starting position in which the bulk is thinned and cut to length in an evacuation position ensuring evacuation of the formed material and, in return, from this evacuation position to this starting position, the displacement of the cones from their starting position being carried out a few moments after the guide cup from its position of cutting the cops to length. SUB-CLAIMS 1. Machinecopseuses according to the claim, charac ter. sée, in that the rotary spindle rotating during the formation of the cops is slowed down as soon as the latter is cut to length and is accelerated to its normal working speed as soon as the forming and compensating cones are put back into, position, of departure. 2. Copseuse machine according to sub-claim 1, characterized in that the rotary spindle is stopped after cutting to length of the cops and is restarted and accelerated as soon as the forming and compensating cones are returned to the starting position. 3. Copseuse machine according to one of the claims 1 or 2, characterized in that the rotary spindle is. directed obliquely with respect to a horizontal plane, the axis of this spindle along which the cones and the guide cup are moved making, with such a plane, an angle of for example between 40 "and 60, the position of, the aforesaid start of cones and of the guide cup being the lower position of these elements, while the discharge position of these cones and of this guide cup is their upper position. 4. Copying machine according to claim, charac terized in that the aforementioned forming and compensating cones are mounted on a first carriage, respectively a lower carriage, while the aforesaid guide cup is placed on a second carriage, respectively an upper carriage. , these two carriages being movable along guides parallel to the longitudinal axis of the rotary spindle. 5. Copying machine according to sub-claim 4, characterized in that the guides of the carriagesus those consist of two guide rods parallel to the longitudinal axis of the rotary spindle. 6. Copying machine according to sub-claim 5, characterized in that the first carriage carrying the cones comprises a transverse main support having a lateral notch in which one of the aforesaid guide rods is constantly engaged, a first slide integral with the main transverse support. - her. and sliding along the other guide rod, two auxiliary supports in the form of an angle, mounted on the main support by one of their wings and arranged on either side of the vertical plane passing through the longitudinal axis of the rotary spindle, and two shafts carrying the cones respectively and mounted respectively on the other wings. auxiliary supports. 7. Copseuse machine according to claim, charac- terized in that the angle formed by the conesfonnator and compensator and determinant. the angle of one of the ends of the body is adjustable, however, without ceasing to be divided, by the vertical plane passing through the axis. longitudinal of the spindle, in two equal or slightly unequal half-angles depending on the nature or the constitution of the treated wire. 8. Copseuse machine according to sub-claim 7, characterized in that each auxiliary support in the form of an angle can. pivot around a pivot that is attached to the. main support and which is located substantially near the top of the cone, carried by this auxiliary support, in that each auxiliary support in the form of an angle bar carries a projection engaged through an arcuate and suitable slot of the main support and having beyond this slot a threaded opening, in that. the openings relating to the two projections have threads the threads of which are respectively equal but with reverse pitch, and in that the threaded openings respectively receive the parts of an advantageously micrometric screw, threaded in a corresponding manner. therefore also with threadsrespectively equal but with reverse pitch, the rotation of this rod around its axis in the openingsdessaBliess said thus producing the spacing or mutual approximation,; if multane and identical of the two auxiliary supports and thus of the two cones. 9. Copseuse machine according to sub-claim 7, characterized in that at least one of the auxiliary supports in the form of an angle can be worm. rusted or blocked on the main support, after having re-adjusted in position. 10. Copying machine according to sub-claim 8, characterized in that the pivot relative to the auxiliary support in the form of an angle of the compensating cone is slightly offset towards the base of the cones relative to the pivot relative to the analogous auxiliary support of the forming cone. 11. Machinecopseuse according to claim 4, characterized in that the second carriage carrying the guide cup comprises a transverse main support having a lateral notch in which one of the said guide rods is constantly removed, a second slide integral with the main support and sliding along the longdel Another guide rod, an upper rod mounted on the main support and serving to fix the guide cup thereon. 12. Copying machine according to claim, charac- terized in that the piston rod of the aforesaid pneumatic cylinder drives the cones via a drive stop which is carried by this rod and which is constantly engaged between the cones. wings of a side bracket fixed to the first carriage carrying these cones so as to abut against one or the other of these wings in order to move this carriage in the corresponding direction. 13. Copying machine according to claim, charac- terized in that the piston rod of the aforesaid pneumatic cylinder drives the guide cup by means of a particular drive hook which is carried on its side, which hooks onto a stopper. side integral with the second carriage carrying this guide cup in order to move this carriage to its evacuation position. 14. Copseuse machine according to sub-claim 13, characterized in that the particular hook is mounted on a transverse support secured to 11a piston rod of the pneumatic cylinder, being able to tilt upwards on the side of the cones or of the cops and towards the on the opposite side, around an axis on or near this support. 15. Copying machine according to sub-claim 14, characterized in that the particular relatively elongated hook extends normally parallel to the longitudinal axis) of the spindle and presents, on the one hand, its end situated on the side of the cones which is in the form of a spout. hook directed downwards and cooperating with the lateral stopper and, on the other hand, its opposite end which is elastically biased to bear constantly against an arm fixed to the transverse support and directed. of. preferably along the axis of the spindle. 16. Copseuses machine according to sub-claim 13, characterized in that the drive hook in particular of the second carriage has a boss directed downward and located between these two ends, this boss cooperating with a stationary stop so as to raise the spout. hook and disengage it from its connection with the aforementioned lateral stop of the second carriage, only when this carriage is in the immediate vicinity of its intermediate position of the upper length. 17. Copying machine according to isous-r. evendicationn 16, characterized in that the aforesaid stationary stop has an adjustable position parallel to the direction of movement of the second carriage or to that of the longitudinal axis of the rotary spindle. 18. Copying machine according to sub-claim 4, characterized in that the second carriage is moved a little before the first carriage back that the pneumatic cylinder operates to move the carriages respectively from their intermediate position and from depatrt in order to ensure the ' evacuation of the ops. 19. Copying machine according to claims 12, 13 and 18, characterized in that the drive stop carried by the piston rod, of the pneumatic cylinder meets the corresponding wing of the lateral caliper, ral fixed to the first carriage after the nose of the hook particular has hooked the side stop of the second carriage. 20. Copseuse machine according to sub-claim 4, characterized in that the aforesaid pneumatic cylinder is actuated by the second carriage carrying the guide cup a few moments after this cup has arrived in. its intermediate position of lengthening the body. 21. Copseuse machine according to daa sows-claim 20, characterized in that the aforesaid pneumatic cylinder is supplied with compressed air, capable of moving its piston and the rod thereof to drive the carriages to their discharge position, pa. r by means of a solenoid valve controlled from a switch or contactor for starting the pneumatic cylinder actuated by the second carriage. 22. Copse machine according to sub-claim 21, characterized in that the aforesaid pneumatic cylinder is supplied with compressed air capable of moving its piston and the rod thereof to drive the first carriage and, optionally, the second carriage towards their. starting position, by means of a solenoid valve controlled from a switch or limit switch preferably actuated by the first carriage. 23. Copseuse machine according to claim 1, characterized in that the rotary spindle is slowed down as soon as the cops is cut to length thanks to the slowing down of its electric control motor, by the intermediary of a switch or contactor. of rail which is actuated by the second carriage carrying the guide cup, a few moments, preferably a few thousandths of a second, before the actuation of the switch or contactor for starting the pneumatic cylinder. 24. Copseuse machine according to the sub-claim; 23, characterized in that the time interval separating the operation of the start switch or contactor of the pneumatic cylinder can be adjusted. 25. Copying machine according to sub-claim 23 or 24, characterized in that the rotary spindle is accelerated to its nominal speed of rotation, thanks to the corresponding acceleration of its electric control motor, through the intermediary of an acceleration switch or contactor for this motor which is actuated by the first carriage carrying the cones when the latter arrives or reaches its starting position. 26. Machinecopseuse according to claim!, Charac terized in that the aforesaid means for cutting the wire connecting the outer end of the cops formed and released from the cones and the guide cup with the inner end of the next cops, comprises a guillotine flowing. e which is placed against a fixed knife in a starting position and which is separated from this knife between lateral guides by the second carriage, from this starting position to an evacuation position sufficiently distant to allow the passage of the cops formed between this knife , these guides and this guiZiotine, so that the wire in question is placed between the knife and the guillotine when the latter returns to its starting position and. is cut by this guillotine cooperating with this knife in the latter position. 27. Copseuse machine according to sub-claim 26, characterized in that the a guitllotine and the aforesaid knife have, seen in plan, a V-shaped configuration, the wings of the V of the guillotine bearing against those of the knife in the position of. departure, while the respective points of the Vs of the guillotine and of the knife are chipped perpendicular to the common axis of the Vs, the point of the knife also carrying a sharp-edged cutting blade cooperating with the crushed point of the guillotine . 28. Copying machine according to the sub-claim 26, characterized in that the sliding path of the guillotine is rectilinear and parallel to the direction of movement of the second carriage or to that of the longitudinal axis of the rotary spindle. 29. Machine copsouse according to the sub-claim 26, characterized in that the guillotine rebounds against a fixed stop shortly after being released from the second carriage so as to be able to move in the opposite direction towards its starting position, from this stop under the effect of the shock produced and of gravity. 30. Copying machine according to claim, characterized in that the means for distributing or alternating transla- tion of the yarn comprises a hook in which the yarn is engaged, this hook being displaced alternately and substantially pafalilalement. the portion of the rotating spindle s. ur daqueïle the wire is wound and constituting the end of a rod carried by a pivoting crank, connected to a connecting rod controlled by the rotating spindle control motor by means of an eccentric. 31. Copseuse machine according to sub-claim 30, characterized in that the end of the linkage to the crank can be adjusted in position relative to the pivot axis thereof, so that the dead center of the reciprocating movement hook ,. located on the side of the tops of the cones' remains in the same position. regardless ! I'a, mplitude of this reciprocating displacement of the hook. 32. Copseuse machine according to sub-claim 30, characterized in that the rod of the aforesaid hook can be adjusted in positions over the crank, parraipportà the rotary spindle.