CH337104A - Machine for wiring wires - Google Patents

Description

  

      Machine for wiring threads The present invention relates to a machine for wiring threads, for example textile threads. It relates more particularly to a machine for wiring the wires without appreciably modifying the twist of the individual wires.



  In the preparation of wires used for the manufacture of automobile tires, industrial belts and many other articles, it is desirable to wire at least two wires so as to form a cable having a certain length and certain elongation characteristics. , resistance to wear and endurance to repeated flexing. This manufacture is currently carried out, in most cases, by a process comprising multiple operations; in this process, the individual threads are given a Z-twist and then twisted together in an S-shape.

   This process not only requires several operations, but also has another drawback, because the production rate is relatively low, when it is desired to produce high quality cables at a reasonable price. This results from the fact that the production rate is proportional to the speed of the spindle. On the other hand, the economic speed of the spindle or speed of torsion depends on the dimensions of the coil. A relatively small coil size allows high torsion speeds, but introduces a large number of knots and requires machine operators to take longer to lift the coil.

   If the winding has large dimensions and the speed is also high, the energy consumption of the spindle and the cable tension are considerable. The use of high tension torsion equipment causes high winding tensions, which subject the cable to excessively high tension in the winding for considerable periods of time.



  It has been suggested in the past to overcome these difficulties by forming, from a first supply winding, a balloon of one wire around a second supply coil, so as to wire the wires together. in a helical way. Commercial production with these old devices involved the use of a large number of pins, and it was not successful because of the difficulties encountered in obtaining a uniform product in terms of length, elongation and strength. to wear and resistance to repeated bending.



  In the old machines, which were used to twist together threads by rotating a ball of thread, from a first supply winding, around a second supply winding, the two threads were brought together in a axial channel of a fast rotating spindle.

   In the embodiment of the machine according to the invention, which will be described later, the son coming from an outer coil and an internal coil are united for the wiring substantially at the top of the ball; this feature and a tension control exerted on each of the yarns facilitate the maintenance of better control of the speed of advance of the yarns, towards the point where wiring occurs, and better control of the position of the yarn immediately before and during wiring.



  Until now, the location of the wiring point, i.e. the point of intersection of the wires which are to be combined, has been subject to fortuitous changes due to variations in certain conditions, in particular the tension of the threads; these variations caused non-uniform wiring. It has been found that the location of the wiring point can be stabilized regardless of temporary fluctuations in operating conditions; this stabilization is obtained by means of the symmetrical arrangement of the parts, the equalization of the tensions and also the equalization of the speeds of advance of the son.



  One can envisage a wiring of the Y type, in which each wire constitutes a branch of the Y and the combined wire or cable constitutes the foot of the Y; this action results in a better cable with greater breaking strength, lower elongation and relatively smaller diameter.



  It is also possible to equalize the advance of the wires. For this purpose, in one embodiment of the machine, a wire may be projected in a balloon shape around a coil, from which a second wire is drawn to be wired with the first wire. This embodiment may include means for directing each wire to the Y-type wiring point directly from a separate capstan, without any additional winding guide device;

   the individual capstans, around which the respective wires are wound, can be coupled mechanically so as to rotate in synchronism, in order to achieve the same linear advance of the two wires by means of a device for receiving the cable. On the other hand, an overall geometric symmetry can be achieved between the paths followed by the wires up to the wiring point, thanks to the arrangement of the capstans and to the mechanical coupling between them, coupling which allows them to be connected. rotate in both directions relative to each other.

   It is also possible to further reduce the guiding resistance by winding up by aligning at least one of the capstans with the direction of entry of the yarn coming from the balloon.



  One can realize an embodiment of the machine in which the spindle and the receiving device are coupled in synchronism so as to obtain with very high precision the desired number of turns of wiring to be introduced into a given length of the cable.



  A ball tension control device can also be used, to automatically compensate and correct for temporary fluctuations in the tension and configuration of the balloon, and an independent device for controlling the tension of the thread supplied by the internal winding of the ball. balloon, with a view to automatically maintaining at a more constant value the tension of arrival of this wire at its capstan of the advance equalization device.



  The appended drawing represents, by way of example, an embodiment and variants of the machine according to the invention.



  Fig. 1 is a side elevational view of this embodiment. Fig. 2 is a section, on a larger scale, of a set of members shown in FIG. 1.



  Fig. 3 is a section, on a larger scale, of another assembly shown in FIG. 1.



  Fig. 4 is a plan view corresponding to FIG. 3.



  Fig. 5 is a side view, partially in section, of a variant.



  Fig. 6 is a section, on a larger scale, of another variant.



  Fig. 7 is a plan view corresponding to fi-. 6.



  Fig. 8 is a perspective view, on a larger scale, of a member of said embodiment.



  Fig. 9 is a perspective view of the member shown in FIG. 8, in another position. As seen in fi-. 1, said embodiment has a winding of wire 11 which will be called the outer winding hereinafter; this coil is formed on a coil of any type, which is supported by means of an axis 12 so that its longitudinal axis is vertical and the wire unwinds at one of its ends. A pigtail yarn guide 13 is arranged above the coil; a horizontal arm 14 carries several disc tensioning devices 15, which are distributed along a curve along this arm.

    A pulley 15a is aligned with the axis of a wiring pin 16, which is mounted on a frame 17 and whose axis is slightly inclined relative to the vertical.



  As best seen on <B> <U> fi-. </U> </B> 2, the wiring pin is carried by a cylindrical support 18 passing through an opening 20 of the frame 17; this support 18 comprises, near its upper end, a flange 21, directed outwards, which is applied against the marginal parts of the frame 17 and which is fixed to them by screws 22. Inside of the cylindrical support 18 are mounted two bearings 24, 26 with low friction, one of which is placed on a shoulder 27, formed on the internal surface of the support 18, and can therefore support a vertical load.

   A shaft 28 extends through these bearings; locking nuts prevent it from moving along its axis relative to the bearings. The lower end of the shaft 2.8 extends beyond the cylindrical support 18 and carries a toothed wheel 30, which is wedged by means of a nut 32 so as to rotate with this shaft. The rotation of the toothed wheel 30, and consequently of the shaft 28, is ensured by the shaft 34 of an electric motor 35, by means of a chain 36 (FIG. 1).



  The shaft 28 has an axial channel 38 extending from the base of the spindle and terminating in a substantially radial portion 40 terminating in an orifice 42 formed in the wall of a sleeve 44 closely surrounding the shaft 28, immediately at the bottom. -above the cylindrical support 18.



  The part 40 of the channel and the orifice 42 are limited downwards by an insert and grooved member 41 for guiding the thread, the details of which are shown in FIGS. 8 and 9. This part 40 of the channel and the orifice 42 are limited upwards by a curved slot, which extends radially and inwardly through the sleeve 44, then at a certain radial distance inside. of the shaft 28, so as to communicate with the axial channel 38. A worm ring 43, surrounding the lower end of the sleeve 44 and preferably tightened by contraction thereon, holds the attached member in place 41.



  If we refer to fig. 8 and 9, it can be seen that the attached member 41 has, when viewed in horizontal section, the general shape of a T, a transverse and rounded part 230 of which has a radius of curvature equal to that of the sleeve 44 and of which a quadrant-shaped core 232 is disposed symmetrically and at right angles to part 230. A channel 234, the bottom of which is rounded, is cut into the marginal and circular edge of the core 232 and extends through through the upper end of the cross section 230. A channel 236 of the same shape is provided near the upper end of the section 230; it is perpendicular to the channel 234 and intersects the latter.

   It can therefore be seen that the channel 234 constitutes a rounded guide surface, on which a wire can be drawn from the axial channel 38 to the outside of the sleeve 44. The transverse channel 236 makes it possible to direct this wire laterally, in the 'one or the other direction depending on the direction of rotation chosen by the spindle. The intersecting surfaces of the channels 234, 236 are rounded and polished at 238 so as to provide a smooth surface to the wire.

   At its upper end, the sleeve 44 has a lip 45 projecting laterally; on the latter is fixed the inner and peripheral edge of a metal and annular sheet member 46, which is widely flared. The sleeve 44 and the member 46 together constitute a cup-shaped fin. The outer cylindrical surface of the sleeve 44, at the level of the orifice 42 in the transverse direction, is eccentric with respect to the axis of the shaft 28, so as to form a device for storing the wire by winding, of which the role will be explained later. A variant could present a storage device comprising two rungs or floors.



  An extension 48 of shaft 28 extends beyond the upper end of sleeve 44; on this extension are mounted, by means of nuts and shoulders, the inner raceways of two spaced ball bearings 50 and 51. The outer races of these ball bearings are press-fitted into the bore 52 a man chon 54, the general exterior configuration of which is frustoconical; these raceways are applied against shoulders 53, 53 'provided for this purpose in the bore 52.

   The sleeve 54 is fitted into the tapered central opening of the cone 56 of a wire coil 58 (hereinafter referred to as the inner wire coil pressure). A cylindrical housing 60 surrounds the inner coil of wire over at least a substantial part of its vertical dimension; this housing comprises at its lower end an annular end wall 61 and a short extension 62 of a considerably reduced diameter. This extension 62 is tightly fitted to a flange 63 formed at the lower end of the sleeve 54.

   The upper and marginal part of the casing 60 is provided with a gasket 64 made of flexible material, for example chloroprene, on which a lip 66 of a cover 67 of the casing 60 is applied. This cover 67 is articulated on the casing 60. by means of a folding strip 68 made of rubber or a similar material; it is held in place against the casing by a friction latch 69, diametrically opposed to the band 68. The side walls of the cover 67 extend approximately the side walls of the casing 60, while its upper wall 70 tilts progressively towards the bottom. high to a top pierced with an orifice 71.

    This orifice is provided with a part 71a made of a material resistant to wear and provided with a bore diverging towards its two ends; the edges of the orifices of this bore are smooth and rounded so as to prevent wear of the wire. To prevent the rotation of the inner coil 58 and the housing 60 during the operation of the spindle, a weight 60a (fig. 1) is attached to the housing, eccentrically with respect to the axis of the spindle, to keep the housing in position. rest. The general principle of operation is analogous to that used in 2/1 ratio torsion pins.



  A support 72 is carried by the inclined upper wall 70 of the cover 67. This support comprises an annular base 73, which is deformed so as to rest exactly against the wall 70 on which it is fixed, for example by screws, two. feet 76 inclined upwards and inwards, which are fixed at their lower ends on the base 73 at points on its periphery spaced 900 apart, and finally a clamping sleeve 77 fixed on the upper ends of the 76 feet.

   Several disc tensioning devices 78 are distributed over a portion of the base 73, preferably over an arc of about 1800 on the side opposite the feet 76; these devices 78 have their vertical axes (at right angles to the plane of the upper wall 70) and allow a given tension to be added to the wire coming out of the orifice 71. As can be seen in FIG. 1, a longitudinal slit 79 is cut along the entire length and one side of the sleeve 77, while an ear 80 forms an integral part of the sleeve on either side of the slit.

    Coincidence holes, one of which is threaded, are drilled in the ears 80, and a screw 82 screwed into the threaded hole passes through the two holes in coincidence. By turning this screw, we naturally close the ears to reduce the effective diameter of the sleeve. The sleeve 77 comprises, at its lower end, a flange 84 comprising flats 86 at spaced points corresponding to the spacing of the feet 76 with respect to the base 73; the upper ends of the feet 76 can be easily fixed on these flats.



  A device 88 for equalizing the advance of the wires, the details of which are shown in FIGS. 3 and 4, is supported by the clamping sleeve of the support 70. This device comprises a shaft 90, comprising at its upper end an enlarged part 92 having two flat and opposite faces 93, which are inclined upward and downward. inside. At its lower end, the shaft 90 is press-fitted in the inner raceways of two ball bearings 94, 96, held apart from each other by a tube 98.

   The outer raceways of the bearings 94, 96 are press fitted into the ends of a sleeve 100, which is held by friction in the clamping sleeve 77. The shaft 90 can thus rotate freely about its longitudinal axis. . In each of the flat and opposite faces of the widened part 92 is formed an orifice 102, the axis of which is perpendicular to the plane of the face and which is threaded to receive the threaded end 104 of a short shaft 106. Each shaft 106 carries a flange 108, against one end of which rests the inner raceway of a ball bearing 110; this bearing is held on the short shaft 106 by a nut 112 screwed onto the free end of this shaft.

   The outer race of the bearing 110 is press-fitted into the bore 114 of a hollow capstan 116 or 116 ', which can thus freely rotate around the shaft 106. The peripheral surface of the capstan has a deep groove 118. The lower end of capstan 116 carries an extension 120 in the outer surface of which a peripheral series of conical teeth 122 is cut. An idler toothed wheel 126 with conical toothing is carried by the shaft 90 so as to be able to rotate freely on the latter by means of an anti-friction bearing 124. This toothed wheel 126 is located between the sleeve 100 and the enlarged part 92; its teeth are engaged with the toothed wheels 122 of the cabes tans 116, 116 '.

   To achieve the necessary clearance between the sleeve 100 and the idler toothed wheel 126, a spacer washer 128 is interposed between the bearings 124 and 94. The longitudinal assembly is held by means of a nut 129, screwed onto the extremity. lower moth of shaft 90.



  An axial channel 130, the axis of which coincides with that of the shaft 28 and of the orifice 71, extends over the entire length of the shaft 90 and of the widened part 92. One end of a guide- wire 132, in the form of a channel, is press-fitted into the upper end of channel 130; this end of the yarn guide 132 projects upwards and laterally towards the cabes tan 116 ', from the upper end of the channel 130, and terminates in a lip 134, which extends tangentially to the peripheral surface of throat 118.

   The lateral part of the thread guide 132 carries a support 133, in the form of a vertical blade, on which is fixed a winding tension pin <B> 1.35, </B> which extends transversely above this lateral part for a purpose which will be explained later. On the widened part 92 is fixed one end of a pigtail thread guide 136, the axis of the eyelet 158 of which extends more or less tangentially to the peripheral surface of the groove 118 of the capstan 116.



  If we refer again to fig. 1, it can be seen that a driven pulling reel 144 and a cooperating groove idle reel 146 are arranged above the equalizing device 88 for advancing the wires and are supported by an element of the frame (not shown). ). The idle coil 146 is arranged so that its first groove, being on the right side in FIG. 1, or aligned tangentially with the axis of the shaft 90 of the device 88.

   Above the take-up spools is a common receiving device comprising a crossbar 148, which carries a yarn guide 150, and a take-up spool 152 driven in the usual manner by a surface contact roller 154.



  A rotational connection is made between the receiving device and the wiring pin; for this purpose, a rotation is transmitted by a toothed wheel 160 (fig. 1), fixed on the shaft 34 of the motor 35, and by means of a chain 162, to a toothed wheel 164 carried by one end of 'a vertical shaft 166. At the other end of this shaft is mounted a bevel gear 168 meshing with another bevel gear <B> 170 </B> carried by a shaft 172 extending perpendicular to the shaft 166. A spur gear 174 is also mounted on shaft 172 and transmits rotation, via an idler gear 176, to a spur gear 178.

   This wheel 178 is mounted on the shaft 180 of the draw spool 144 and meshes with another toothed wheel 182 wedged on the shaft 184 of the drive roller 154. So that the cable collected on the spool 152 is wound on this with a substantially constant tension, on the shaft 182 is mounted a friction clutch consisting of two friction discs 186, 186 ', the adjacent faces of which are applied against each other by a compression spring 188 , disposed between the disc 186 'and a flange 189 adjustable along the shaft 184.



  The transmission ratio between the sprockets 178 and 182 is chosen so that the surface of the drive roller 154 tends to move slightly faster than the surface of the take-off spool 144, thereby producing a slip between. the two friction discs 186, 186 '. Under these conditions, the clutch transmits a constant torque and consequently allows the cable to be rolled on the spool 152 with a constant tension. By adjusting the position of collar 189 axially with respect to disk 186 ', spring 188 is given the necessary tension to achieve the torque which provides the desired winding tension.

    This arrangement therefore achieves a selective winding tension of the cable in a range extending between a value less than the twist or wiring tension and a value greater than this tension.



  Therefore, any desired value can be given to the transmission ratio between the receiving device and the wiring pin, by correctly choosing the dimensions of the various gears, chain sprockets, etc., of the transmission elements of the device. reception ; this ratio remains constant for any particular arrangement of these elements, and thus ensures a high degree of precision in the number of turns of torsion introduced into the cable per unit of length thereof.



  We will now explain how the mechanism works. A wire X coming from the winding 11 passes through the pigtail guide 13 and passes between the discs of the tension arrangements 15. By means of a snake, or semi-flexible threading device, the wire X is passed through. the axial orifice 38 of the shaft 28, and it is made to exit through the aligned radial orifices 40, 42.

   It is then passed to one side of the casing 60 and of the casing cover 67 to introduce it into the eyelet 158 of the yarn guide 136 associated with the equalizer device for advancing the yarns. Then, one or more turns of the wire X is wound in the peripheral groove of the capstan 116, then several turns of the wire are made on the pulling spools 144, 146. The wire is then passed through the guide 150 and finally it is l 'wound several times on the receiving reel 152.



  As regards the wire Y coming out of the internal winding 58, it is first necessary to place the cover in its open position, by releasing the latch 69, in order to access the winding 58. The cover being open, one makes pass the wire Y through the bore of the part 71a, after which the cover is closed again and it is locked.



  The wire is then passed between the discs of the tension devices 78, then upwards through the axial orifice 130 of the shaft 90 using a ser pent; then the thread is passed through guide 132 and it is made to make several turns on the peripheral groove of capstan 116 '. To complete the installation of the wire Y, it suffices to keep the end of this wire in contact with the wire X and to start the drive motor; the two ends of the yarns X and Y begin to move on the draw spools 144, 146, so as to automatically complete the operation of placing the yarns.



  When the engine 35 is started, the shaft 28 and the vane 44, 46 rotate like the receiving device. As a result of the rotation of these elements, the wire X turns, forming a ball, around the casing 60 and the cover 67. In forming the ball, the wire takes substantially the shape of a sinusoid.

   The tension of the yarn at the exit of the balloon, as well as the dimensions and the configuration of the balloon, are controlled by a winding wire storage surface 47; this surface at the lower end of the fin sleeve 44 receives the yarn under a primary tension produced by the disc tensioners.

   The primary tension supplied by the devices 15 is chosen so that, for a given yarn, a certain speed of the spindle and a determined configuration of the wound storage surface, the friction of the air or drag of the balloon produces a determined angular winding of the yarn on the surface 47. If the input tension of the yarn X increases, the drawing speed being constant, the result is an increase in the overall tension and consequently a contraction of the balloon.

   The contracted balloon is subjected from the air to a lower friction, because its circumferential speed has decreased, and the yarn can therefore accelerate its movement by decreasing the length of winding of the yarn on the storage surface. . Decreasing the winding length reduces the tension and the balloon can therefore resume its normal configuration and normal dimensions.



  If the input voltage decreases, the balloon increases its dimensions, and consequently its circumferential speed; this results in greater air friction and consequently an increase in the length of winding of the yarn on the storage surface. This increase in the rolling length is accompanied by a corresponding increase in tension, which brings the dimensions of the balloon back to the required values.

   Thus, the device for storing the yarn, by cooperating with a primary tension, acts as a regulator and supplies the balloon with the necessary quantity of thread to maintain its configuration and to maintain constant the tension of the thread at the outlet of the balloon.



  To facilitate better regulation of the configuration of the balloon, for a wide range of yarns of different types and different weights, the yarn storage surface is preferably of the so-called lateral and helical type with spiral grooves; in such a storage surface, the two series of grooves have opposite pitches and gradually increasing radii.

   A yarn storage surface, which approximately satisfies the requirements stated above, can be formed by using an eccentric surface or several eccentric surfaces whose dimensions gradually increase. There is shown in FIG. 2, by way of example, a storage surface 47 of the type with two eccentric steps; on this surface, the lower step has a cylindrical surface eccentric with respect to the axis of the spindle, while the upper step has a cylindrical surface, which is axially offset from the previous surface, but which connects to this one;

   this upper step has a greater radius of curvature than that of the lower step, but it is also eccentric with respect to the axis of the spindle. This two-grain storage surface allows the wire to be wound over radial distances which gradually increase from the axis of the spindle. The operation can therefore be selected by choosing for driving the ball the lever arm best suited to the control requirements of the particular yarn used.



  The preceding arrangements make it possible to control the shape of the balloon with sufficient precision to prevent the thread of the latter from coming into contact with the support of the internal winding or the external separating members. If a wire, for example of thermoplastic material, moving at high speed, came into contact with such surfaces, the result would be wear of the wire and a decrease in its strength.



  The tension of the yarn Y, as it approaches its capstan 116 ', is largely determined by the adjustment of the tension devices 78 mounted on the base 73 of the support 72. It has been observed that the displacement of a low yarn breaking strength, such as rayon yarn, at a relatively high speed, gives rise to filament debris as a result of the twist introduced into the yarn between the capstan <B> 116 '</B> and the clamping devices. tension 78.

   Such a yarn can be handled, while avoiding this filament debris, if additional tension is introduced into the yarn Y, immediately before it comes into contact with the capstan 116 '. This additional tension is provided by the tension axis <B> 135, </B> which is disposed above the yarn guide 132 and around which the yarn Y can be wound. By increasing in this way the tension of the yarn Y near the capstan 116 ', the tension supplied by the devices 78 in the twist zone can be reduced and thus the breakage of filaments in the yarn is avoided.

   Thus, by maintaining a relatively high tension in the Y yarn, the relatively high spindle speed required to produce a tension in the X yarn of the balloon equal to the tension of the Y yarn allows the spindle to be rotated at considerable speeds achieving high speeds. high production rates.



  Rotation of the yarn, as it forms the ball around the inner winding and housing, produces a corresponding rotation of the equalizer 88 as a result of the engagement of the yarn in the yarn guide 136. As the device 88 rotates , the capstans 116, 116 'guide their respective wires along substantially fixed converging paths, until the wires combine into a single cable. It should be noted that the toothed wheel 126 functions mainly as an idle wheel and can rotate freely with respect to the shaft 90 and the sleeve 100.

   However, it provides an energy component to the capstans 116, 116 ', to at least partially oppose the positive resistance presented by the bearings of the capstans, as will be explained later. The actual advance of the yarn through the mechanism is effected by the draw spools 144, 146. This advance, however, causes the capstans 116, 116 'to rotate, as a result of the frictional engagement of their respective yarns with their. respective peripheral surfaces. Since the capstans 116, 116 'are interconnected by gears, the rotation of one of them must produce a corresponding rotation of the other.

   Therefore, assuming the threads are properly seated, it is impossible for one of the threads to advance through the mechanism at a higher linear speed than the other thread.



  Device 88, through which yarn Y passes as explained, so as to produce an S-twist, rotates counterclockwise (looking at Fig. 4). The configuration of capstans 116, 116 'and idler gear 126 is calculated so that the advance of the X and Y wires, within a desired margin of wiring twist, causes the capstans to rotate at speed. intended to drive the idler gear, also counterclockwise, but at a resulting speed slightly slower than the equalizer.

   The idler toothed wheel 126 is subjected to the friction of the air, which produces a resistant torque tending to oppose its rotation. This resistive torque is produced in large part by the friction of the air on the teeth of the wheel 126, but it is increased by means of fins 140 arranged at the periphery of the body of this toothed wheel.



  This resistant torque tending to oppose the rotation of the wheel 126 is directed so as to facilitate the rotation of the capstans <B> 116, </B> 116 'meshing with the wheel 126. This assistance provided by this torque to the rotation of the capstans is preferably calculated so as to achieve a negative resistance energy component, which is equal to the positive resistance exhibited by the bearings of the capstans. As the operating speed of the spindle is between 6000 and 10,000 rpm, the centrifugal forces exerted on the bearings of the capstans can reach 1000 to 3000 g and thus considerably increase the friction of these bearings.

   A large resistance of the bearings tends to cause slippage of the wire, which would result in less effective action of the tans to maintain an equal advance of the two wires to the point of wiring. The arrangement described above overcomes these difficulties and ensures optimum cable quality.



  The machine described makes it possible to form, by a true symmetrical Y twist, a cable having improved characteristics from the point of view of resistance, elongation, resistance to wear and endurance to repeated bending. On the other hand, the symmetrical arrangement of the capstans 116, 116 'and the fact that they are coupled together, so as to rotate in synchronism, eliminate the need to precisely control the tension of each of the wires X, Y at their. approach of the cabes tans; this control would otherwise be necessary to obtain a uniform product, if equalizer capstans were not used.



  An improved cable can be produced by using the machine described above, but it is desirable, when ultimately a balanced twisting action is desired, to regulate the tension of the yarn Y as it reaches the end. capstan 116 'of the equalization device 88. To this end, in a variant, the tensioning devices 78 with discs are replaced by a compensating tensioning device shown as a whole at 190 in FIG. 6.

   In fig. 6 and 7, 192 denotes a plate mounted on the annular base 73, this plate 192 comprising two vertical bolts 194, 196, each of which is provided with a ceramic sleeve 197 and extends upwards through two discs of tension 198, 200 cooperating together and perforated at their centers. A support plate 202 is attached to the upper ends of bolts 194, 196, between nuts 203. The right edge of plate 202 is provided with a hinge 204, to which a pressure plate 206 is attached.

   This plate 206 extends partially above the tension discs 198, 200; it has orifices 208 in coincidence with bolts 194, 196; these orifices have a diameter greater than that of the lower nuts 203 and sufficient to allow the plate 206 to pivot without coming into contact with the nuts. An annular support member 210 is fixed to the underside of the plate 206, symmetrically with respect to each of the orifices 208. A washer 212, made of felt or other suitable elastic material, is arranged between each key tension disc 200 and its member. corresponding annu lar 210.

   A control arm 214, attached to the pressure plate 206, extends therefrom and terminates in a downwardly extending lip 216, on which a guide pulley 218 is mounted.



  The arm 214 has, between its ends, a hole 220 intended to receive with play a vertical bolt 222, which is fixed at its lower end on the plate 192 so as not to rotate. The free end of bolt 222, which extends through and beyond arm 214, is surrounded in the order shown below by a tension spring 224, a washer 226, and a nut. adjusting knurled 228.

   Thus, it can be seen that by adjusting the nut 228 so as to bring it closer to or away from the arm 214, it is possible to vary the force with which the tension disks 198 and 200 are pushed towards one another. 'other; it is therefore possible, by means of a particular adjustment of the nut 228, to add a given tension to a thread moving between these discs. During operation, the Y wire coming out of the coil 58 passes through the part 71a, then a guide 193, then goes between the two discs 198 and 200, and finally passes under the guide pulley 218 to go upwards and arrive at the equalization device 88.

   It should be noted that the tension added to the wire by the discs 198, 200 exerts on the arm 214 a force directed upwards and opposite to the force supplied downwards by the tension spring 224; for a given adjustment of the nut 228, with a constant input voltage of the tensioning device 190, a resulting output voltage is therefore obtained which is substantially constant.

   If the input voltage of device 190 increases, the tendency to produce an increase in the output voltage is detected by control arm 214, which responds to it. a greater force against the tension of the spring 224, thereby reducing the pressure between the discs 198, 200 to restore the original tension. A decrease in the input voltage causes the device 190 to react in an analogous manner, but in the opposite direction, in order to replace the lower input voltage with an additional voltage and thereby restore the primary voltage.

   By suitably choosing and calculating the parts, it is therefore possible to make the device 190 so as to maintain a constant input voltage in the wire Y when it enters the positive equalizer device 88.



  Any tendency of the control arm 214 to oscillate or exert an exaggerated control action, under conditions of rapid changes in tension, is largely eliminated by means of a damping device, in the form of a damper. a dash-pot 215 supported by the base 73 and containing a viscous liquid. A plunger 217 capable of being immersed in the liquid com carries a rod 219 articulated at its upper end on the arm 214 at 221. This device performs the necessary damping action, without harming the sensitivity of the tensioning device.



  It can be seen that a voltage compensating device, such as that described here, has the advantage not only of maintaining a more constant voltage in one of the wires to be wired, but also of offering an extremely efficient means of adjusting the voltage. tension so as to equal that held in the balloon by the other wire. By adjusting the position of the adjusting nut 228 of each pin, in a multi-pin installation, there is an easy way to quickly achieve a tension adjustment which facilitates obtaining a more uniform cable.



  In the embodiment which has just been described, the son advance equalizer is fixed to the cover of the housing of the internal winding and can therefore move as a single unit with this housing. In some cases, this arrangement can be disadvantageous and present difficulties in particular for threading. There is shown in FIG. 5 a variant which allows to reduce such difficulties in addition during the equalizer to the frame of the machine.

   In this variation, a sleeve 250 is supported above the inner coil housing, in axial alignment with the shaft 28 and at a suitable point on the frame, by means of an arm 252. A low friction bearing 253 is provided. press-fitted into the sleeve bore 250 near each end thereof. A hollow, rotating shaft 254 passes through these bearings and extends downward. A portion 256 of the shaft 254, extending below the sleeve 250, has a larger diameter and has a diametrical slot which passes completely through it, except at the upper corners, at 258, and at the lower portion 260.

   The internal edges of the solid parts 258, 260 must be rounded and smooth to avoid any risk of wear of the wire. At the lower end of the slotted portion 256 is an extension 262, which carries a freely and independently rotatable idle gear 264, and a small support plate 266 having slanted side faces 268; this plate is joined to the extension 262 by means of a screw 270, so as to rotate with this extension.



  Each of the faces 268 is drilled and tapped to receive the threaded end of a short shaft 272, which supports a capstan 274 rotating freely; the geometric axis of this short shaft and of the capstan is perpendicular to the plane of the face 268. The capstans comprise, at their lower ends, bevel gears 276 taken in the mass, which mesh with the idler gear 264.

   Below the plate 266, a block 278 is fixed to the extension 262 so as to rotate therewith, and a thread guide 280 extends laterally on each side of the block; the eyelets of these thread guides are substantially aligned tangentially and respectively with opposite points on the periphery of the tans 274. At the end of the extension 262 is an L-shaped or U-shaped thread guide 282, which is directed down.



  The placement of the wire in this variant follows in a more or less obvious way from the description of the first embodiment. After passing the wire X through the wiring pin, it is threaded through the eyeleton of one of the pigtail guides 280, and it is wound several turns around one of the capstans. 274. Then, it is passed through the slot in the shaft portion 256 and brought up through the bore of the shaft 254, after which it can be passed into the receiving device as it is. 'explained previously.



  After having passed through the hole in the cover of the housing the wire Y supplied by the internal winding, this wire is introduced through the guide 282, then through the other guide 280, and it is made to make several turns on the Another capstan 274. Next, the wire 91 is passed through the slot in the shaft portion 256, then into the bore of the shaft 254, and finally over the receiving device.



  In both embodiments, it is essential that the wires are engaged by traction on the surfaces of the capstans and do not slip on these surfaces. Such engagement of the wires is generally obtained if the capstans are entirely metallic and if a sufficient number of turns of wire are wound on them. The peripheral surfaces of the tans must obviously be smooth and their speeds must be equal.



  It will be appreciated that the action of the wiring pin does not change the twist of the individual wires, except for a negligible increase or decrease resulting from the pulling of the wire from one end of the winding.



  The preceding description relates to a single wiring pin and to itself, associated receiving mechanism, but it is easily understood that the arrangement of the parts, shown schematically in FIG. 1, is ideal for the parallel operation of any suitable number of spindles arranged on a common frame and driven by a common source of motive power.



  The terminology used above and including in particular the terms above, below, is only used to describe the positions of certain elements in relation to other elements when the machine is in its normal vertical position, but it is understood that this terminology does not limit the location of the different elements to precise positions.

 

Claims (1)

CLAIM Machine for wiring wires, characterized in that it comprises an external wire winding, an internal wire winding, a device (40, 42) driven in rotation and arranged to rotate the wire supplied by the external winding on a orbit surrounding the inner coil, a first member (116) capable of rotating freely and arranged to engage by traction the wire rotating on said orbit, a second member (116 ') capable of turning freely and arranged to engage by traction the wire supplied by the internal winding, a support part (90, 92) capable of rotating freely independently of said device, around the same axis as the latter and carrying said members, this support piece being driven in rotation only by the rotation of the wire on said orbit, means connecting said members so that the rotation of one of them causes a corresponding rotation of the other, and means for pulling the cabled son. SUB-CLAIMS 1. Machine according to claim, characterized in that the axes of said members (116, 116 ') are inclined relative to the axis of said support part and intersect this axis. 2. Machine according to sub-claim 1, characterized in that said members are arranged to engage the wires respectively at fixed and separate points, these two points being spaced laterally by the same distance relative to the axis of the orbit and lying substantially in a common plane perpendicular to that axis, and to give the wires the same linear speed along symmetrical paths and from said fixed points to a common point on the orbit axis, where the wires are wired together. 3. Machine according to sub-claim 1, characterized in that said device forms a balloon with the first thread, and in that it comprises a first capstan (116) on the path of the balloon, below the top of the latter , engaged by rubbing with this thread and following the latter on a circular path while it forms the ball, a second capstan (116 ') capable of moving on the same circular path as the first capstan, with a certain offset in relation to this one, engaged by friction with the other wire and guiding it along a path cutting the path of the balloon wire to allow the two wires to be cabled together, the capstans being able to rotate individually around their respective axes and being coupled in synchronism, so that the linear advance of one of the threads produces a corresponding linear advance of the other thread. 4. Machine according to sub-claim 3, charac terized in that it comprises a rotary vane (40, 42, 46) intended to form the balloon with the first yarn, the internal winding being arranged inside the balloon, the two capstans being identical and arranged symmetrically with respect to the axis of the balloon, in the vicinity of the top thereof, and mounted so as to rotate simultaneously around their respective axes while moving with a movement of translation around the axis of the balloon, the peripheral surface of each capstan being engaged without sliding with one of the threads to guide it along a fixed path symmetrical with that of the other thread, up to a point of intersection with the path of the another wire, the two wires being cabled together at this point, and a capstan coupling device whereby the rotation of one of the capstans along a given arc and in a certain direction causes the rotation of the capstan. the other capstan along an equal arc and in the same direction, said cabled son pulling means driving these son with a substantially constant linear speed. 5. Machine according to sub-claim 4, in which the translational movement of the two capstans around the axis of the balloon is produced by the first wire forming the balloon, characterized in that it comprises a device for coupling the capstans arranged for transmitting from the balloon a torque to each capstan in a direction opposite to the torque due to the resistance tending to oppose the rotation of the capstans around their respective axes. 6. Machine according to sub-claim 3, characterized in that it comprises a rotating spindle having an axial channel terminating in a radial hole through which passes the wire coming from the outer winding, a wire feed plate supported by in a non-rotating manner by the spindle, this plate carrying the inner winding, said support piece being supported above the inner winding coaxially with the spindle and having an axial channel through which passes the wire of the inner winding, the wire of the outer winding forming the ball around the inner winding between the radial orifice and the corresponding capstan, during the rotation of the spindle, the capstan being intended to receive at least one turn of the outer coil wire and the other capstan at least one turn of the inner coil wire, the capstans guiding the wires along converging and symmetrical paths to a cabling point located on the spindle axis, a guide device supported below the wiring point coaxially with the spindle axis, and a receiving spool for pulling the cabled wires. 7. Machine according to sub-claim 6, charac terized in that it comprises a coupling between the two capstans arranged so that the rotation of one causes a corresponding rotation of the other. 8. Machine according to sub-claim 7, characterized in that said coupling comprises a toothed wheel associated with each capstan so as to rotate therewith and an idler toothed wheel sup carried by said support part and meshing with the toothed wheels of the capstans. 9. Machine according to sub-claim 8, charac terized in that it comprises a device arranged to apply to the idler toothed wheel a torque resis both to its rotation, so that a negative resistance is applied to the capstans in opposition to the positive resistance tending to oppose the rotation of the capstans around their respective axes. 10. Machine according to sub-claim 9, characterized in that said device applying a resisting torque to the idler toothed wheel comprises at least one fin extending radially and outwardly from the periphery of said wheel. 11. Machine according to sub-claim 6, characterized in that it comprises a channel-shaped wire guide extending from the end of the axial channel of said support part to a point adjacent to the periphery of one of the capstans. 12. Machine according to sub-claim 11, characterized in that it comprises a thread tension amplifier arranged near the channel-shaped thread guide to increase the tension of the thread immediately before the latter comes into contact with the capstan corresponding. 13. Machine according to sub-claim 6, characterized in that it comprises a cylindrical casing which encloses the internal winding and presents an axial orifice for the passage of the wire of this winding, and a wire tension device on which engages said wire and supported by the casing, between the latter and said support part. 14. Machine according to sub-claim 13, characterized in that said tension device comprises an adjustable regulator to selectively maintain a substantially constant tension in the second wire, at the moment when the latter comes into contact with the corresponding capstan. 15. Machine according to sub-claim 13, characterized in that it comprises a support carried at one of its ends by the housing and which rotatably supports said support part at its other end. 16. Machine according to sub-claim 6, characterized in that said support piece com takes a thread engaging element projecting laterally. 17. Machine according to sub-claim 6, characterized in that said spindle has, at its radial orifice, a thread storage surface which is eccentric with respect to the axis of the spindle and which automatically controls the ball thread tension. 18. Machine according to sub-claim 6, characterized in that the spindle comprises a radial slot the upper surface of which is rounded and communicates with the axial channel of the spindle so as to define said radial orifice, and an attached member disposed in this slot and having a channel extending inwardly along a rounded face of said member, this channel cooperating with said rounded surface of the slot to define a passage of the wire from the axial channel to said radial orifice, a locking ring being arranged around the spindle to fix said attached member. 19. Machine according to sub-claim 18, characterized in that the attached member comprises a transverse channel extending inwardly from its outer surface, so as to cut the channel extending along the rounded face of said member and to produce a guide channel for the wire in one and the other circumferential direction, on the outer surface of the spindle. 20. Machine according to sub-claim 1, characterized in that it comprises a first rotary spindle comprising an axial channel terminating in a radial orifice, an extension of this spindle extending beyond said orifice, a supply plate made of wire supported non-rotatably by said extension, a second rotary spindle pierced with an axial channel and supported above said plate, coaxially with the first spindle, short shafts carried by the second spindle with their axes inclined with respect to the axis thereof, identical capstans rotatably mounted on said short shafts, and a draw spool mounted above the second spindle. 21. Machine according to sub-claim 1, characterized in that it comprises a frame, an outer winding on the frame, a spindle rotatably mounted on the frame above the outer winding, this spindle comprising an axial channel s 'Extending over a substantial part of its length and terminating in a radial orifice through which passes the wire of the outer winding, an inner winding supported by the spindle, above said radial orifice, so as to rotate with respect to the spindle, a member capable of rotating freely and supported by the frame above the internal winding in axial alignment with the spindle, this body com carrying a diametrical slot which passes through it completely and extends over a. part of its length, and an axial channel which communicates with this slot and extends upwards over the rest of the length of this member, two rotating and independent capstans, carried symmetrically by said member, below the split part, with their axes inclined with respect to the axis of said member and having at least one point common to said axis and to themselves, one of the capstans being capable of receiving at least one turn of the wire of the outer winding and the other head tan at least one turn of the wire of the internal winding, the capstans guiding the wires along converging and symmetrical paths to a wiring point located inside the split part of said member, and a receiving device for pulling the wires from the wiring point through the axial channel of said organ.