CH600012A5 - Multi-feed circular knitter yarn feed - Google Patents

Abstract

Multi-feed circular knitter yarn feed having groups of grips for each yarn to pull yarn through in an overlapping cycle action

Description

  

  
 



   The present invention relates to a method and an apparatus for supplying yarns of indefinite lengths, to a knitting machine in particular, from a source of yarns, and this without any slippage between the yarn and the members of the yarn. wire feed. 



   According to a first characteristic of the present invention, the. A method of feeding a yarn of indefinite length from a yarn source to a knitting machine or the like without slipping, is characterized in that it consists of:
 a) stretching this yarn in its path from a source of yarns to the machine;
 b) feeding the wire into this path via a planar arcuate track;
 c) while bringing this wire in this path by means of said planar arcuate path, in repeatedly performing the operations consisting of:

  :
   I) wedging the wire in a first location of said planar arcuate track in at least one scissor-shaped jaw delimited by an angular rib of a set of ribbed jaws in said planar arcuate track, so as to grip and hold without slipping this yarn preventing it from sliding both with respect to said ribbed jaw and said yarn path;

  ;
 2) while squeezing and holding the wire preventing it from slipping relative to said jaw and said wire path, moving this jaw, at the same time as the wire is tight, downstream along the arched path plane, so as to pull this wire from this source and transport this wire downstream through part of this path, and
 3) disengaging the wire from said ribbed jaws in a location of said planar arcuate track located downstream of the first location, while wedging the wire in said planar archway upstream of the release location and at said first location in at least one other jaw of the set of scissor-shaped jaws delimited by angular ribs;

  ;
 d) overlapping said repeated operations so that the yarn is continuously grasped, held and transported by at least one ribbed jaw so as to continuously maintain the movement of the yarn under the control of the jaws, so that the yarn is fed without slipping by moving jaws;
 e) moving said jaws, during this movement, in synchronism with the operation of the machine. 



   According to a second characteristic of the present invention,
The apparatus for implementing the above method is characterized in that:
 a) at least one wire feed unit comprises a first toothed element and a second toothed element, each element having an axis and a front face;
 b) each front face comprises several teeth for bringing into contact with the wire, spaced at the periphery, facing forward and arranged around the axis;

  ;
 c) the teeth of the first element can mesh with the teeth of the second element to place each tooth of each element in a cooperative relationship with at least one contiguous tooth of the other element so as to define between them the angular ribs cooperating and forming jaw jaws in the form of scissors for gripping, holding and feeding the wire between them without slipping through a planar path at the level of the jaw jaws in the form of scissors;

  ;
 d) a device is provided for coaxially mounting these elements, the faces of the elements being opposite and the teeth meshing to form an assembled flat wire feed unit,
 arcuate, and capable of rotating about the common axis of these elements and to vary, in a selective manner, the axial space between the elements of the assembled unit at least within a selected range of axial spacing;
 e) a device is provided to rotate this assembled unit
 wheat around the axis:

  :
 f) the teeth of the assembled unit mesh at least in an annular region of the assembly and form scissor-shaped jaw jaws, at least in the range of axial spacing;
 g) each of these teeth, at least in the annular zone, is inclined outwards and backwards with respect to each contiguous tooth cooperating with it, so that each of the teeth crosses each tooth cooperating with it, at least in said range of axial spacing, at an outwardly open angle to form a wire receiving path around the assembled unit, said path being arcuate, planar, peripheral, substantially V-shaped and open towards the outside. exterior, the base of this angular path delimiting the scissor-shaped jaw,

   the diameter of the base of the arcuate and planar wire receiving path increasing as the axial spacing between these elements decreases, and vice versa;
 h) a device directs the yarn from the source of yarn into said scissor-shaped jaw of the arcuate and planar yarn receiving path, and around at least a part thereof, and then out of this jaw and in the direction of the machine;
 i) when the assembled unit is rotated, said scissor-shaped jaw delimited by the teeth which coo bead between them comes into contact with the wire, clamps it and holds it in the flat arched way, to draw the wire from it wire source and bring it to the machine without slipping at the jaw between this wire and the assembled unit. 



   Various advantages and characteristics of the present invention moreover emerge from the detailed description below. 



   The invention is shown, by way of non-limiting example, in the accompanying drawings. 



   Fig.  I is a schematic side elevation showing the apparatus according to the present invention installed on the upper part of a knitting machine, only several spools of yarns and several feeders are shown in this figure. 



   Fig.  2 is a partial, schematic cross section taken along line 2-2 of FIG.  1, on a slightly enlarged scale. 



   Fig.  3 is a partial section corresponding to a part of FIG.  2 showing a variant of an embodiment in which the belt which drives the feeders is arranged in a somewhat different manner from that of the embodiment of FIG.  2. 



   Fig.  4 is a cross section taken along line 4-4 of FIG.  2 with parts torn off; this figure shows in detail an embodiment of the device according to the present invention, the embodiment illustrated in this figure being approximately according to the dimension of an actual prototype. 



   Fig.  5 is a vertical section taken along line 5-5 of FIG.  4. 



   Fig.  6 is a partial cross section taken along line 6-6 of FIG.  4 according to a scale representing approximately twice that of FIG.  4. 



   Fig.  7 is a cross section taken along line 7-7 of FIG.  6 with parts broken away showing an embodiment of a feed unit according to the present invention in the open position. 

 

   Fig.  8 is a cross section showing a unit similar to that of FIG.  7, but with this unit in the closed position. 



   Fig.  9 is a front elevation of the upper toothed wheel of the embodiment of FIGS.  7 and 8. 



   Fig.  10 is a developed front view looking inward into the feed unit through its mouth. 



   Fig.  1 I is a cross section of another embodiment of the feed unit according to the present invention. 



   Fig.  12 is a perspective view of a guide support. 



   Fig.  13 is a front elevation of the resilient gripper for retaining the guide holder in its desired position.
 The yarn feed apparatus of the present invention is particularly intended for use with a multi-feed circular knitting machine for non-slip feeding, in a so-called positive manner, yarns from a yarn source to the knitting stations. of the machine and will therefore be described in connection with such a machine although it can be used with any other type of knitting machine or the like.  As is well known, a multi-feed circular knitting machine comprises one or more circular needle beds having several knitting stations spaced apart at the periphery into which the yarn is fed and knitted by the needles. 

  Each knitting or yarn feed station, as it is frequently called, includes the needle actuation cams required for that station, a guide device for guiding the yarn to the needles and other suitable elements.  In such machines, the needle bed or beds may be stationary with the needle cams rotating to actuate the needles, or alternatively the needle bed or beds may rotate with the knitting stations being stationary. , the latter type being shown in the embodiment illustrated by way of example. 

  Since the knitting machine can be of any conventional embodiment and an explanation of its detailed structure is not necessary to understand the present invention, the knitting machine and the knitting stations will not be described further. and will only be shown schematically. 



   In fig.  1 to 5, a circular knitting machine 10 with several feeds having one or more beds of circular needles and several knitting stations or thread feeds 10A spaced at the periphery is mounted centrally on a plate 11 which is supported by the frame 12 of the machine, a schematic part of which has been shown.  Several uprights 13 facing upwards, spaced at the periphery, are mounted on the plate around the machine, each upright receiving the inner end of a radial arm 14 facing outwards, the outer ends of these arms being fixed. to a horizontal mounting ring 15 which surrounds the uprights. 

  A plurality of peripherally spaced wire feed assemblies 16 are mounted on ring 15, each assembly having a U-shaped support bracket 17 to support the other members of the assemblies. 



   Each console 17 comprises a vertical central branch 18 from the ends of which extend two opposite side arms, vertically distant 19 and 20, each arm comprising a circular enlargement 21 bored vertically at its free or outer end.  The console also has an inverted L-shaped hook 22 consisting of a horizontal arm 23 extending from the upper end of the central branch in a direction away from the side arm 19 and a vertical arm 24 extending downward from it. end of the horizontal arm, the vertical arm being opposite and spaced from the central leg to provide an opening space 25, facing down, slightly greater than the thickness of the mounting ring 15. 

  Each bracket supporting the other elements of the assembly is suspended from the mounting ring at a selected peripheral location by means of the hook, the mounting ring being received in space 25.  Several sets of screws 26 inserted into horizontal bores of the vertical arm secure the console to the mounting ring in the desired location.  The console may be a single piece of cast metal.  Each hook can be hung from the mounting ring either with the side arms directed toward the knitting machine, as shown, or with the side arms directed away from the machine (not shown). 



   A bearing 27 is housed in the vertical bore in each circular enlargement 21.  The bearings 27 in the opposing arms 19 and 20 are vertically aligned to receive and rotatably mount the vertical shaft 28 of the assembly, the upper end 29 of the shaft extending above the upper surface of the arm 19. .  A pulley 30 is rigidly attached to the upper end.
 29 of the shaft, so that the rotation of the pulley will turn
 ner the tree.  The remaining parts of the power pack
 will be described below. 



   A caliper 31 mounted on the uprights 13 supports a hub 32
 placed in the center of the machine 10.  A verti control shaft
 cal 33 is rotatably mounted in hub 32, the ends of
 the shaft extending above and below the hub, a pulley 34 driving a belt being rigidly attached to the ex
 upper end of the shaft 33 and a toothed wheel 35 being fixed
 rigidly at the lower end of the shaft. 



   The control 36 of the knitting machine, shown schematically, mounted on the frame of the machine is the power source to drive the knitting machine and to drive the positive feed mechanism, i.e. without slipping. between the wire and said mechanism.  As is well known, the knitting machine control operates the machine to knit at the knitting stations.  If the machine is of the type in which the needle beds are stationary and the knitting cams rotate, the machine control causes the cams to rotate and, when the machine is of the type in which the needle beds rotate and cams are fixed, as in the illustrated embodiment, the machine control rotates the needle beds. 

  The machine control drives a shaft 37 which in turn drives a variable speed controller 38, shown schematically, having an output shaft 39 which has a toothed wheel 40 mounted on its outer end.  Regulator 38 transmits energy from shaft 37 to output shaft 39 and determines the speed of rotation of shaft 39 relative to that of shaft 37.  The governor allows an operator to adjust or vary the speed of rotation of shaft 39 relative to that of shaft 37, and any conventional variable speed governor can be used, among those which allow adjustment of the speed. relative speed of the two shafts over a continuous range. 



   An endless chain 41 is driven around sprockets 35 and 40 to transmit energy from shaft 39 to drive shaft 33 which in turn drives drive pulley 34. 



  An endless belt 42 is driven around the drive pulley 34 and all of the pulleys 30, so that rotation of the drive pulley causes the belt to drive and rotate each of the pulleys 30 and each of the shafts 28. . 



   The control of the machine therefore drives the knitting machine, and therefore simultaneously the shafts 28 by means of a successive continuous assembly comprising the shaft 37, the variable speed regulator 38, the output shaft 39, the pinion. or toothed wheel 40, chain 41, pinion 35, control shaft 33, control pulley 34, belt 42 and pulleys 30.  In this way, all elements of the power set and shafts 28 are driven synchronously with the operation of the knitting machine.  In other words, starting, accelerating, slowing down or stopping the machine control causes the machine to run and the shafts 28 to rotate, a corresponding start, acceleration, deceleration or stop. . 



   A horizontal plate 43 is supported by two contiguous posts 13, the plate comprising a slot 44 extending longitudinally through it.  An arm 45 is slidably mounted on plate 43 by means of bolts 46 which freely pass through slot 44 and which are inserted into taps on one end of arm 45.  An idle roller 47 is rotatably mounted on the free end of the arm 45, this roller extending in the plane of the belt 42.  The arm can slide along the plate 43 to bring the idler into proper pressure contact with the belt to adjust the tension in the belt, the bolts being tightened to fix the position of the arm when the tension in the belt is. set as desired. 

 

   The belt 42 can be driven around the control pulley 34 and the pulleys 30 in any suitable arrangement, and it is shown in FIGS.  2 and 3 two such embodiments.   



  In both embodiments, the machine control rotates the pulley 34 counterclockwise, as seen in these figures, the main part of the belt driven around the pulleys 30 rotating in the direction. clockwise, as indicated by arrow 48.  In the embodiment shown in FIG.  2, the belt comes into contact with each pulley 30 on the part of its flange remote from the mounting ring 15 and, accordingly, all pulleys 30 rotate clockwise as indicated by the arrow 49. 

  In the embodiment shown in FIG.  3, the belt follows a zigzag path around the pulleys 30, so that it comes into contact with alternating parts of the pulleys 30 on the ledge remote from the mounting ring to rotate these pulleys in the direction of the arrow. 49 and contact the pulleys 30 on the portion of the flange closer to the mounting ring to rotate the pulleys counterclockwise, as shown by arrow 49.  The preferred embodiment of FIG.  3 when it is desired to increase the area of contact between the belt and each pulley 30 to reduce the likelihood of relative slippage therebetween, and this arrangement is therefore preferred when a large number of wire feed assemblies are used. 

  It should be noted that not all of the pulleys 30 need to rotate in the same direction and the control assembly may be provided to rotate the pulley 34 in the same direction as the needle beds or in an opposite direction. . 



   The variable speed governor 38 allows an operator to vary the rotational speed of the belt relative to the rotational speed of the needle bed.  In the event that the governor does not provide a sufficient range of adjustments, further adjustment can be achieved by using as pulley 34 an adjustable diameter pulley such as that illustrated, for example, in U.S. Patent No. 3243091. .  In the embodiment shown, all the pulleys 30 have the same diameter and they therefore rotate their respective shaft 28 at the same rotational speed. 

  As an alternative and as not shown, one or more pulleys 30 may or may have a different diameter than another pulley 30 and, in this way, one or more shafts 28 may or may rotate at speeds different from those of other trees. 



   In addition to the elements described above (bracket 17, bearing 27, shaft 28, and pulley 30), each wire feed assembly 16 also includes one, two, three or more wire feed units 50 (these units specific ones which are described in detail below being identified by an alphabetical suffix such as 50A, 50B, etc. ) mounted on each shaft 28 to rotate about the axis of the shaft and a wire guide support 51 for each power unit.  The power units will be described in detail below.  Although not all sets have the same number of power units, in the illustrated embodiment each power set has two power units 50. 



   Each wire guide support 51 is pivotally mounted on the central branch 18 of the console 17 near its corresponding supply unit to constitute a device for directing or guiding a wire from a source of wires to the unit. feeder and for directing or guiding a yarn from the feed unit to the knitting machine. 



   The guide support 51 (see fig.  4, 5, 6 and 12) is shaped in such a way that it can be easily produced by cutting and bending from a single piece of metal.  The support 51 is made up of two opposing guide arms 52A and 52B connected by a spacer 53 generally at the center of the length and width of the guide arms, which provides a cutout 52A 'on the guide arm 52A below. of the spacer and a cutout 52B 'on the guide arm 52B above the spacer.  The inner ends of the guide arms are disposed on opposite sides of the central leg 18 and are attached to the ends of a horizontal pivot 54 mounted in a horizontal bore through the central leg so that the guide bracket can pivot around of the pivot axis 54. 

  The guide arms extend toward the wire feed unit and the inner edge 53A of the spacer is spaced from the inner surface of the center leg.  Each guide arm 52A and 52B ends in a free or external end 55A and 55B respectively, each free end being inclined at a distance from that of the opposite arm.  At least one thread guide or eyelet 56A is mounted in the free end 55A and at least one thread guide or eyelet 56B is mounted in the free end 55B. 



   The wire guide support is selectively pivotable about the axis of the pivot 54 between an operational or feed position which, in the illustrated embodiment, is the lower position shown in solid lines in FIG.  4 and a neutral or inactive or without power position which, in the illustrated embodiment, is the upper position shown at 51 'in broken lines in FIG.  4.  Any suitable device can be provided for selectively and releasably maintaining the support either in the operational position or in the neutral position, as desired.  In the illustrated embodiment, this device consists of a pawl or resilient gripping member 57 made from a flat steel part (see also in FIG.  13). 

  The lower part 57A of the gripping member is wider than the upper part 57B to provide this member with shoulders 58 extending laterally at the junction of the upper and lower parts.  The width of the upper part 57B does not exceed the spacing between the opposing guide arms 52A and 52B of the guide support, while the width of the lower part 57A exceeds the space between the guide arms.  The lower end of the gripper is secured to the inner surface of the central branch of the console with the gripper extending upward. 

  The shoulder 58 is arranged such that when the guide support is in the lower or feed position, the lower edges 53 'and 53 "of the support rest on the shoulders of the gripper for the. prevent pivoting to a lower position.  The upper part 57B passes upwards between the guide arms and between the spacer 53 and the central branch. 



  The elasticity of the gripper constantly pushes the upper part away from the central branch and against the inner edge 53A of the spacer.  In this way, the elasticity of the gripper constantly pushes the guide support downwards in abutting contact with the shoulders 58 when the guide support is in the feed position.  In this way, the guide support is held rigidly in the feed position. 



   On the upper part 57B, the gripping member 57 is provided with an elbow forming a recess or pocket 59 extending laterally.  The pocket 59 is positioned such that when the guide support is moved to an upper neutral or non-feeding position (as shown at 51 '),
The spacer 53 will be received in this pocket and the guide support will therefore be held releasably in the neutral position.  From the previous description, it emerges that the guide support can be easily adapted from its lower position to its upper position and vice versa. 

 

   It should be noted that the free end 55A is inclined approximately at an angle of 45 with respect to its arm 52A and that the free end 55B is curved at an angle of approximately 909 with respect to its arm. arm 52B.  As is readily apparent from the
 fig.  5, this places the guide 56A closer to the power unit
 tation of threads than guide 56B.  As described below, the yarn from the yarn source passes through guide 56A before passing through the feed unit and guide 56B, so that guide 56A is the upstream guide.  The best results are obtained when the upstream guide is close to the feed unit, the proximity of the downstream guide is not important. 

  As seen in fig.  5, the guide 56A is clockwise relative to the guide 56B and the power unit rotates clockwise.  If it is desired to rotate the power unit counterclockwise, the guide 56A should be disposed counterclockwise with respect to the guide 56B.  In other words, the relative positions of the guides 56A and 56B should be reversed with respect to those illustrated in FIG.  5.  The guide support 51 is made in such a way that this reversal is easily obtained by removing the pivot 54, reversing the support and then putting the pivot back. 



   The foregoing description describes the wire feed apparatus as a whole.  Any suitable arrangement can be used as a source of yarns and such an embodiment is illustrated in fig.  1.  A wire support ring 60 is attached to and around the uprights 13 above the endless belt 42, this ring supporting several radial arms 61 extending outwardly and supporting vertical wire supports 62, and an individual source of threads in the form of a bobbin or spool 63 is placed in each holder.  The uprights 13 support a stirrup 64 above the control pulley 34, this stirrup supporting an upright 65 generally placed centrally on the knitting machine.  The upright carries several guide arms 66 extending radially, each guide arm comprising several wire guides or eyelets 66A. 

  A guide ring 67 having multiple wire guides or eyelets 67A is mounted on the post above the guide arms 66.  Near the top of the post there is a stop movement mounting ring 68 which supports several stop boxes 69 shown schematically.
 Each end of the yarn Y moves downstream in its successive path from its respective spool 63 through its respective guide 66A, its respective stop box 69, its respective guide 67A to the upstream guide 56A of its respective guide support 51 around its respective feed unit 50 and through the downstream guide 56B and this guide support in the direction of its knitting station or thread feed 10A. 

  During machine operation, each end of the wire moves downstream in the direction of the arrows.     The words upstream and downstream, when used in connection with features or locations, are relative terms and refer to the relative distances along the path of the wire travel, upstream meaning closer to the wire source and downstream. meaning closer to the knitting station.  As an example, the guide 67A is upstream of its respective feed unit 50, as the yarn from the spool of yarn travels through the guide 67A before moving into the feed unit. feed 50, although this feed unit 50 may actually be closer (outside the wire path) to the spool of wire than guide 67A.  Conversely, the supply unit 50 is downstream with respect to the guide 67A. 



   The illustrated wire source arrangement is a simple and conventional arrangement for this kind of technique.  Obviously, we can use other embodiments which are more complex.  By way of example, the spools of threads can be mounted on a rack (not shown) in place of the thread support, and it does not matter whether a rack or a thread support is used; the wire, in its path towards its guide support, must pass through one or more guides, tensioning devices, additional stop devices, etc.  (not shown).  Likewise, the yarn in its path from its guide support to the knitting station must pass through various conventional members of a knitting machine such as guides, tensioning devices, stop devices, etc. etc.  (not shown). 



   A specific embodiment of the wire feed unit 50 is described in detail below (see fig.  4 and 6 to 10), with reference to the specific power supply units 50A and 50B. 



  Unit 50A is the same as unit 50B except that unit 50A is shown in the open feed position and unit 50B is shown in the closed feed position. 



   Each power supply unit 50 consists of two elements
 teeth which cooperate, these two toothed elements of each
 unit 50A and 50B being toothed wheels or discs 70 and 71. 



   The toothed wheel 70 has a practical annular body 72
 frustoconical, flared towards the front, surrounding and hanging from the ex
 inward and forward from the periphery of the front end
 a central axial hub 73 extending rearward and having
 an axial bore 74 for slidably receiving the shaft 28,
 this annular body, this hub and this bore being coaxial.  A practically frustoconical annular lift 75, flared towards the rear,
 coaxial with the annular body, surrounds and hangs outwards and
 rearwardly from the outer periphery of the annular body.  The
 front face 76 of the lip terminates in the front face 77 of the body
 annular on the outer edge 78 of the front of the annular body. 

  The
 periphery 79 of the lip may be circular or may present
 any suitable shape, but it is preferably polygonal,
 in particular octagonal, as shown in FIGS.  6 and 9.  Enjoyed
 uprights 80 spaced at the periphery, uniform, tapering towards
 back, extend from the posterior surface of the lip
 near its outskirts but a short distance inland from
 the latter, an amount being provided on each peripheral vertex. 



   A ring 80 'is fixed on the rear end of the upright 80,
 the outer periphery of the ring overhanging the uprights towards
 outside. 



   The flat front surface of the hub 73 consists of a
 shoulder or annular internal part 81 surrounding the bore and
 of an annular outer part 82 concentric therewith.  Many
 ribs 83 spaced at the periphery, extending radially,
 flared outwards, coming into contact with the wires extending
 forward, are arranged around the axis of the wheel and hang
 forward from the front face 77 and an outer part 82. 



   Each rib begins at the outer periphery of the shoulder
 ment 81 and extends outward to the outer edge 78.  The
 inner side 84 of each rib extends forward into
 a direction practically parallel to the axis of the periphery
 of the shoulder and ends at the level of the plane defined by
 edge 78.  The circular network of inner sides 84 surrounding
 the axis defines a space 85 coaxial with the bore 74 and in front of
 this one. 



   The front or anterior face 86 of each rib extends
 radially and flares outward from the anterior edge of the
 inner side 84 up to the outer edge 78 and preferably ends
 In this one.  The front faces 86 extend into an annu surface
 substantially flat surface and define such a practical surface
 ment perpendicular to the axis.  When, as shown in
 sin, the inner sides 84 of the ribs end in the plane
 defined by the outer edge 78 and the front faces of the ribs
 extend in this plane, the area determined by the front faces
 ribs is a plane and is perpendicular to the axis. 

  However,
 the inner sides 84 may extend slightly forward of the
 plane defined by the outer edge of the annular body (not shown
 felt) or may end slightly behind the defined plane
 thus (not shown), the front faces of the ribs in one or
 the other case being slightly oblique with respect to this plane.  In
 such an embodiment, the area determined by the front faces of the
 veins is slightly frustoconical, or convex (flared towards
 the rear), or concave (flared towards the front), this surface being
 nevertheless considered to be essentially flat and essential
 ment perpendicular to the axis. 

 

   From the above, it should be noted that the
 longitudinal profile of each rib 83, as shown in
 fig.  7 and 8, is defined by the front face of the annular body, the side
 internal ribs and the front face of the ribs, and corresponds
 practically to a right triangle whose hypotenuse defines
 the back or base of the rib and whose longest branch
 defines the front face 86 facing forward.  The height of the ner
 vure or any part thereof at any location
 particular over its length is the distance between the front face of the
 annular body and the front face of the rib measured in a
 direction parallel to the axis. 

  The height of the rib therefore decreases
 gradually from a maximum near its end
 internal towards a minimum at its external end where the rib
 leads to the front face of the annular body. 



   Each rib has side sides 87A and 87B espa
 cés at the periphery which are arranged practically radially and
 which extend in front of the front part 77 of the annu body
 up to the front face 86, the junction of the sides 87A and 87B
 with the front face of the rib forming side edges 88A and
   88B spaced at the periphery, arranged substantially radially. 



   The width of the rib at any particular location on its
 length is defined by the spacing between the sides or side edges
 raux in this location.  When viewed in front elevation
 (as shown in fig.  9), side 87B and side edge 88B of
 each rib are arranged in a clockwise direction
 shows relative to side 87A and side edge 88A of this
 rib and, conversely, the side 87A and the side edge 88A of
 each rib are arranged in the opposite direction to that of the
 clockwise from side 87B and side edge
 ral 88B of this rib. 

  Therefore, side 87A and
 edge 88A will be called the turned side and edge respectively
 counterclockwise, and side 87B and edge 88B will be referred to as the clockwise turned side and edge, respectively.  The sides are
 extend forward from the front face of the annular body in a direction substantially parallel to the axis, so that the cross section of each rib at any location along its length is substantially rectangular, this cross section increasing in width but decreasing in height at as it is closer to the outer end of the rib. 



   The front face of the toothed wheel 70 is provided with a plurality of radially extending forwardly extending slots or spaces 89, spaced at the periphery, equal in number, to the ribs 83, the slots being formed by the peripheral spacing of the ribs. , so that each pair of contiguous ribs defines a slot between them, the ribs and the slots alternating at the periphery around the axis of the wheel.  Therefore, the lateral sides distant from each slot are formed by the side 87B of the rib on the side of the slot facing counterclockwise, and the opposite side 87A of the rib on the side. of the slot rotates clockwise,
The spacing between these opposite sides of each pair of adjoining ribs defining the width of the slot. 

  If we put it another way, we can say that when seen in front elevation, the lateral side turned counterclockwise of each slot is formed by a side 87B and the lateral side of the clockwise rotated slot is formed by a side 87A.  All of the ribs 83 are the same size and shape, and all of the slits 89 are the same size and shape.  The inner end of each slot communicates with the space 85 and the outer end of each slot terminates at the outer edge 78 of the front face of the annular body. 



   Since the sides and lateral edges extend essentially radially, the shape of each rib and slot, i.e. the shape which is seen in front elevation, is that of a flared edge towards the side. 'outside or more precisely practically that of a sector of a torus.  In the illustrated preferred embodiment, the peripheral spacing of the sides 87A and 87B is such that the angle formed by the contiguous sides 87A and 87B (or edges 88A and 88g), when they define the width of a rib, is slightly less than the angle formed by the contiguous sides 87B and 87A when defining the width of a slot. 

  Each rib is therefore slightly narrower than each slit; in other words, the width of the rib is slightly less than the width of the slot at any particular radial distance from the axis. 



   The toothed wheel 71 comprises a substantially planar annular body 90 surrounding a central axial means 91 coaxial with it and hanging outwardly, the annular body being perpendicular to the axis.  The hub 91 has a rear cylindrical boss '92 extending rearwardly from the annular body and a coaxial front cylindrical hub 93 extending forwardly of the annular body, the diameter of the front hub being slightly smaller than that of the hub. space 85 of the wheel 70.  The hub comprises an axial bore 94 intended to receive, in a sliding manner, the shaft 28. 



  A rearwardly flared, substantially frustoconical annular lip 95 coaxial with the annular body surrounds the outer periphery of the annular body and hangs outward and rearward.  The front or anterior face 96 of the lip connects and terminates in the front face 97 of the annular body on the outer edge 98 of the front face of the annular body, the diameter of the outer edge 98 being approximately that of the outer edge 78 of the lip. front face of the annular body of the wheel 70.  The periphery of the lip 95 may be of any suitable shape and is illustrated as circular and having a diameter approximately equal to that of the periphery 79 of the lip of the wheel 70. 



   Several ribs 99 spaced at the periphery, extending radially, flared outwards, coming into contact with the wires extending towards the front, equal in number, to the ribs 83 of the wheel 70, are arranged around the axis and hang forward from the front face 97 of the ring body.  Each rib hangs outwardly from the periphery of the front hub 93 to approximately the outer edge 98 of the annular body. 



  The inner side 100 of each rib extends in a direction substantially parallel to the axis of the periphery of the front hub 93 to extend in front of its front face 101.  The circular array of internal sides 100 of ribs surrounding the axis defines a space 102 coaxial with and forward of the axial bore 94. 



   The front or anterior face of each rib is formed by three branches or segments, the first branch being the segment 103 extending outwardly from the end facing outwardly of the internal side 100, the second branch being the segment of guard 104 or offset segment extending rearwardly in a direction substantially parallel to the axis from the outer end of segment 103, and the third branch being the main inclined segment 105 extending obliquely outward and outward. rearward from the posterior end of the guard segment to the outer edge 98 and preferably terminating therein. 

  It therefore emerges that the longitudinal profile of each rib 99, as shown in FIGS.  7 and 8, is defined by the front face of the annular body, the internal side and the front face of the rib, this profile being practically that of a right triangle with the hypotenuse facing forward, and there is a small tab 106 extending forward on the inner end of the hypotenuse formed by the guard segment, the first segment and the front end of the inner side.  The surface determined by the front face of the rib is a convex or rearwardly flared, substantially frustoconical surface having a small annular front extension on its inner and front end formed by the tongue 106. 



   Each rib 99 includes lateral sides 107A and 107B disposed substantially radially, spaced at the periphery, extending forwardly from the front face 97 of the annular body to the front face of the rib, the junction of the sides 107A and 107B. with the front face of the rib forming side edges 108A or 108B disposed substantially radially, spaced at the periphery.  In front elevation, sides 107A and edges 108A are the sides and edges turned counterclockwise, respectively, and sides 107B and edges 108B are respectively sides and edges turned counterclockwise. the direction of the ballot box clockwise.  

  The width of the ribs at any particular location along their length is defined by the spacing between the sides or side edges at that location.  The sides extend forward from the front face of the annular body in a direction substantially parallel to the axis, so that the cross section of each rib at any location along its length is substantially rectangular with the cross section increasing. in width but decreasing in height as it is viewed nearer the outer end of the rib. 



   The front face of the toothed wheel 71 is provided with a plurality of slots 109 or forward opening spaces extending radially, spaced at the periphery, equal in number, to the ribs 99, the slots being formed by the peripheral spacing of the ribs, so that each pair of adjoining ribs defines a slot between them, the ribs and slots alternating peripherally around the wheel axle.  Therefore, the lateral sides distant from each slot are formed by the side 107B of the rib on the side of the slot facing counterclockwise and the opposite side 107A of the rib on the side of the slot. the slot rotated clockwise, the spacing between these opposite sides of each pair of adjoining ribs defining the width of the slot. 

  If we put it another way, we can say that when seen in front elevation, the lateral side of each slit facing counterclockwise is defined by a side 107B and the lateral side of the clockwise rotated slot is formed by a side 107A.  All of the ribs 99 are of the same shape and size and all of the slits 109 are of the same shape and size. 



   The elements of the wheels 70 and 71 which are functional or operative in taking and feeding the wire are called teeth. 



  As explained below, the front faces 86 of the ribs 83 including the side edges 88A and 88B and the main inclined segments 105 of the front face of the ribs 99 including the side edges 108A and 108B cooperate to engage and feed the yarn.  Accordingly, in the illustrated embodiment, each front face 86 of a rib defines a radially extending, forward-facing wire contacting tooth 86 having side edges 88A and 88B, and each segment main slant 105 defines a radially extending forward facing wire contacting tooth 105 having side edges 108A and 108B. 

  The front face of each wheel therefore comprises several teeth facing forward, spaced at the periphery, arranged around the axis of the wheel, the spaces between the teeth of each wheel forming their slots. 



   The peripheral spacing of sides 107A and 107B of wheel 71 is the same as that of sides 87A and 87B of wheel 70. 



  Therefore, the face shape, that is, the shape seen in front elevation in a direction parallel to the axis of each rib, each tooth and each slot of the wheel 71 is essentially the same. than that of each rib, tooth and slot of the wheel 70.  As a result, the ribs and teeth of the wheel 70 are slightly narrower than the slots of the wheel 71, and the ribs and teeth of the wheel 71 are slightly narrower than the slots of the wheel 70. 

  Because of these dimensions, the ribs and teeth of each wheel can mesh with the ribs and teeth of the other wheel when the wheels are mounted coaxially with their opposing front faces and with the ribs and teeth of each wheel. superimposed and aligned with the slots of the other wheel, i.e. when each rib 83 and each tooth 86 of the wheel 70 are opposed to a slot 109 of the wheel 71 and when each rib 99 and each tooth 105 of the wheel 71 are opposed to a slot 89 of the wheel 70. 

  When the wheels are mounted in this way, the axial spacing between the wheels can be reduced so that the ribs and teeth of each wheel are at least partially received deep into the slots of the other wheel so that the ribs and teeth. teeth of each wheel mesh with those of the other wheel to a greater or lesser degree, depending on the axial spacing. 



   The wheels can be made of any suitable material, for example plastic or metal, or from combinations thereof.  The material can be homogeneous throughout an entire wheel, as in the illustrated embodiment, or it can vary across a wheel.  For example, parts subject to greater wear can be made of a material harder than other parts.  They can be produced by usual machining operations, but they are preferably obtained by molding and, during the molding operation, one can provide, in any conventional way, insertions of different materials. 



   In the preceding description, it has been indicated that the sides of the ribs extend essentially forward, parallel to the axis.  Ideally, they can be precisely parallel to the axis, but this can make it difficult to remove the wheels from the mold.  To reduce these difficulties, the sides of each rib are preferably tilted slightly forward towards each other so that the cross section of the ribs is, in effect, that of a forward tapering trapezoid. rather than a rectangle, and the cross section of the slits is that of an outwardly flared trapezoid.  Further, the surfaces 86 and 105 do not need to be precisely planar and they may be slightly convex or concave in longitudinal cross section and / or in cross section. 

  However, the above slight variations in shape are considered to be tolerances within the description of the shapes of ribs, slots and the like given above. 



   Two cooperating toothed elements are assembled in a wire feed unit with the help of the device for coaxially mounting these elements with their opposite front faces, in order to have an assembled wire feed unit capable of rotating around the wire. common axis and to vary the axial spacing between the elements of the unit, at least according to a selected or predetermined wire feed range according to which the teeth of the elements mesh; this device will be described below. 



  At the start of this chosen range, the axial spacing is such that the elements are in an open wire feed position in which the teeth of the elements mesh to a predetermined degree to feed the wire at a predetermined speed and, at the end of the range, the axial spacing is such that the elements are in a closed wire feed position in which the teeth mesh to a greater extent than the predetermined degree of wire feed. a speed faster than this predetermined speed. 



   In fig.  4, 7 and 8, the wheels 70 and 71 of each feed unit are mounted coaxially with their opposite front faces on the shaft 28 to rotate about the axis of the shaft, the shaft passing through the aligned axial bores. 74 and 94 of the respective wheels. 



  In the illustrated embodiment, the power units 50A and 50B constitute a part of the same assembly 16 and, therefore, the wheels 70, 71 of the two units are mounted on the same shaft.  The wheel 70 is fixed to the shaft with respect to a relative axial movement therewith by a transverse pin 110 force-fitted in the transverse bores aligned in the shaft and the hub 73.  Impeller 71 is slidably and adjustably mounted on the shaft for axial movement thereon in a direction toward and away from the fixed impeller to selectively vary the spacing. axial between the wheels.  

  In the illustrated embodiment, the wheel 70 is the upper wheel and the wheel 71 is the lower wheel, but the power unit can be mounted on the shaft in an inverted position (not shown), the adjustable wheel 71 being in this case the upper wheel, and the fixed wheel 70 being in this case the lower wheel. 



   A helical compression spring 111 surrounding the shaft is disposed between the two wheels in opposing spaces 85 and 102, one end of the spring being housed on the face 81 of the wheel hub 70 and the other end being housed against the face front 101 of the hub of the wheel 71, the length of the spring being such that it continuously pushes the axially movable wheel away from the fixed wheel at least when the axial spacing between the wheels is in the range wire feed. 



   An externally threaded collar 112 having a diameter smaller than that of the rear boss 92 of the wheel 71 and having a front face 113 is mounted on the shaft behind the boss 92 and is attached to the shaft to rotate with it. ; it is retained against axial movement by the transverse pin 114 passing through the aligned transverse bores in the thread collar and the shaft, The impeller 71 can be moved axially away from the impeller 70 until the rear face 115 of the boss 92 abuts against the front face 113 of the collar, this abutment preventing further movement and providing a stop means defining the position of the maximum axial spacing between the wheels. 

  Preferably, in this position, the ribs of the wheels are nevertheless in contact with each other.     Preferably, in the position of maximum axial spacing, the axial spacing of the wheels is such that the teeth of the wheels mesh to a measurement defining the start of the wire feed range, i.e. the open position.  The languor of the spring is preferably such that the spring is nevertheless under compression in the position of maximum axial spacing. 



   An internally threaded nut 116 is inserted over the externally threaded collar 112 until the front face 117 of the nut abuts against the rear face 115 of the box when the wheels are in the maximum axial spacing position. .  Since the wheel 71 is capable of sliding axially along the shaft, the rotation of the nut in the appropriate direction will move the latter towards the wheel 70, and the stopper of the front face 117 of the nut and of the face 115 of the rear boss will push the wheel 71 towards the wheel 70 against the force of the spring 111, therefore reducing the axial spacing between the wheels. 

  The nut can be turned enough to move the wheel 71 at least over the entire feed range, i.e. at least enough to reduce the axial spacing from that representing the start of the range (open position) until the one representing the end of the range (closed position).  Preferably, the end of the range coincides with the position of the minimum axial spacing which is the position in which further movement of the wheel 71 towards the wheel 70 is prevented by the stopper. 



  In the illustrated embodiment (see fig.  8), the stop device is formed by the stop of segment 103 of tongue 106 against face 81 of hub 73.  Alternatively, the elements of the wheels may be of such a size that other surfaces (not shown) abut to prevent further reduction in axial spacing.  The spring 111 may act as the stopper if it is of such a dimension that its winding stops to prevent further reduction in axial spacing when the wheels are in the position of minimum axial spacing. 



   Rotating the nut 116 in the reverse direction will allow the spring to push the wheel 71 away from the wheel 70 to increase the axial spacing between the wheels; The axial location of the nut therefore determines the axial spacing between the wheels. 



  The nut, by means of a suitable rotation, can be positioned to bring the wheels to any chosen position in the feed range, whether it is the open position, the closed position or any position. what intermediate position between these positions.  Cooperating indication means such as a scale 118 and a mark 119 on the outer cylindrical surfaces of the nut and respectively of the boss may be provided to indicate the position of rotation of the nut, and therefore the chosen feed position of the nuts. wheels.  The pitch of the cooperating nut and the thread of the collar is preferably chosen so that the rotation of the nut slightly less than 360 moves the wheel 71 over the entire feed range. 

  This will prevent incorrect reading of the indicating means, as any particular adjustment of the scale and the mark will always indicate a chosen feed position.  A transverse adjusting screw 120 in the transversely threaded bore in the boss is provided to secure the impeller 71 to the shaft to rotate with it and to be retained against axial movement when the rotation of the nut has. brought the wheels to the selected feed position in the feed range. 



   The front hub 93 of the wheel 71 has a diameter slightly smaller than that of the space 85 of the wheel 70 to allow the front part to be received in the space, which prevents the stop of the front part of the wheel. hub against the inner ends of teeth 86, as the axial spacing is reduced. 



   The wire feed unit is operative to feed the wire at least through a selected or predetermined wire feed range of axial spacing where the teeth of the wheels mesh in a cooperative relationship to positively feed the wire. wire.  In the following description, when referring to a wire feed range, it will be such a chosen or predetermined wire feed range, unless otherwise indicated.  The range begins when the spacing between the wheels is such that the wheels mesh to a degree defining the open wire feed position, preferably as shown in unit 50A in Figs.  4, 6 and 7. 

  The range ends when the spacing is such that the teeth mesh to the degree defining the closed wire feed position, preferably as shown in unit 50B in Figs.  4 and 8.  In each intermediate position, the number of which is infinite, because the axial spacing is continuously variable, the length of the axial spacing is less than that of the start of the range and greater than that of the end of the range, the teeth s 'meshing at an intermediate degree with respect to that of the open and closed positions.  Each tooth of each wheel is disposed between two teeth of the other wheel and close to it, so that each tooth is, according to the wire feed relation, in cooperation with the two teeth of the other wheel contiguous. 



   Since teeth 105 are inclined outward and backward with respect to teeth 86 in each feeding position, each tooth intersects, at an outwardly open angle, each adjacent cooperating tooth with the other. wheel at an intersection 121.  If we put it another way, we can say that the lateral edge 88A of each tooth 86 crosses, at an intersection 121, the lateral edge 108A of the adjacent cooperating tooth 105 on one side thereof, and that the lateral edge 88B of each tooth 86 intersects, at an intersection 121, the lateral edge 108B of the cooperating tooth 105, contiguous, on its other side.  The teeth engage inwardly at intersections and diverge without intermeshing outside intersections. 

  Since teeth 105 and their side edges are oblique with respect to the axis, the radial distance between the intersections and the axis depends on the distance the wheels are axially spaced and, therefore, the greater the axial spacing. is important, the more the intersections are close to the axis and the less the degree of meshing is important. 



   Each pair of cooperating teeth and in particular their two cooperating side edges act to form a jaw 122 for receiving son practically in the form of a V opening outwards, each intersection 121 forming the point of the V and being the innermost part or base of the respective jaw. 

 

  The array of outwardly opening jaws 122 around the axis defines a substantially V-shaped outward opening groove 123 around the rim of the feed unit, the groove being the space between the opposite front faces of the wheels outside the intersections.  The circular network of intersections or base of jaws 121 around the axis defines the internal diameter or base of the groove, the innermost and narrowest part of the groove.  The intersections 121 extend in a circle and determine a circle perpendicular and coaxial to the axis.  It is obvious that this circle is the base of the groove as well as the intersection of the surface defined by the teeth 86 with the surface defined by the teeth 105. 

  The diameter of the base of the groove varies inversely with the axial spacing of the wheels; as the axial spacing decreases or increases, the diameter of the base of the groove increases or decreases respectively.  At its outer end, the groove 123 ends in the annular mouth 124 at the opening towards the outside defined by the front faces diverging from the lips 75 and 95. 



   In the open position of the feed range, the axial spacing is such that the intersections 121 face outward from the inner ends of the teeth 105 as well as the teeth 86 to have at least a low degree of engagement between the teeth. teeth towards the inside of intersections.  Preferably, the intersections are contiguous with the inner ends of the teeth 105 and 86, substantially as shown in FIG.  7 wherein the intersections are approximately 0.159-0.318 cm outside the inner ends of teeth 105 or guard segments 104 of ribs 99. 

  In the closed position, the axial spacing is such that the intersections 121 lie within the outer ends of the teeth 86 as well as the teeth 105 to have at least a small defined portion of both the teeth 86 and 105 diverging and not engaged outside intersections, the teeth engaging inwardly intersections to a greater degree than in the open position.  Preferably, the intersections in the closed position abut the outer ends of the
 teeth 86 and 105, practically as shown in FIG.  8 in
 which they are located approximately 0.159-0.318 cm inside the outer ends of teeth 86 and 105 or marginal portions 78 and 98. 



   In the preferred and illustrated embodiment, wheels in the open position, substantially as shown in FIG.  7, are in the position of maximum axial spacing, and the wheels in the closed position, substantially as shown in fig.  8, are in the position of minimum axial spacing.  Depending on the thickness of the wire as well as other factors, the dimensions of the elements of the feed unit can be chosen so that the intersections in the open position are arranged more inward of the position shown. and / or are disposed more outwardly in the closed position, but this choice can cause problems, as will be pointed out below. 

  The preferred disclosed locations of the open and closed positions provide a suitable maximum feed range utilizing substantially the full length of the teeth.  Obviously, the dimensions of the elements of the unit can be chosen so that the intersections in the open position are more outward than those shown and / or more inward in the closed position, but this choice will reduce the range. feed in relation to the length of the teeth. 



   The teeth and their cooperating side edges of each pair of teeth intersect at an intersection without necessarily touching each other.  The relative width of the teeth and slots may be such that the cooperating side edges actually touch at the intersection, and this structure would be operational.  However, such a structure would require very careful and precise manufacturing and would therefore be relatively expensive.  Therefore, in the illustrated and preferred embodiment, the widths of the teeth and slots
 are such that the side edges which cooperate to form a jaw are spaced at the periphery by a very small distance. 

  In all cases, the cooperating side edges must be close enough to form a jaw in all positions of the feed range, which jaw is capable of gripping the wire with wedging.  Since the teeth, including their side edges, are the only surfaces that coo bead in the wire feed, the depth of the slots is not an important factor.  The slots need only be deep enough to allow them to accommodate the height of the ribs in all positions of the feed range. 



   The way one end of the Y wire is fed
 positively by its corresponding wire feed unit will not be described with particular reference to FIG.  6.  In fig.  6, as in the other figures, the thickness of the wire is shown on an enlarged scale relative to the other elements of the assembly for the sake of clarity.  In reality, the diameter of the wire relative to the elements of the assembly will be much smaller than that shown in the drawings. 

  The yarn Y, in its path downstream from its source of yarns to its knitting station of the knitting machine, passes through a first guide or upstream guide of the guide support 51 like the guide 56A; it then passes through the mouth 124 of its feed unit into the jaw 122 placed at the entry or initial feed station 125 of the yarn path to thereby form an extension of incoming yarn 126, then it passes in the direction along which the power unit turns (clockwise in fig.  6, as indicated by arrow 48) of the entry station 125 around the axis and around at least a peripheral part of the V-shaped groove 123 up to the jaw 122 placed at the discharge or discharge station 127. final feed to the wire path, which forms the wire feed extension 128. 

  Finally, it passes from the discharge station 127 outside the V-shaped groove via the mouth 124 into a second guide or downstream guide, like the guide 56B, to form the outgoing wire extension 129, and it finally passes from the guide 56B to the knitting station. 



   The wire feed extension 128 is that portion of wire which at any particular time during the rotation of the feed unit is disposed in a positive wire feed portion of the wire path.  This is the part where the wire is pulled and positively fed and it is the part of the path from the entrance station 125 to the discharge station 127.  The wire feed extension 128 is grasped by the jaws 122 which, at this particular time, are disposed or extend in the direction of arrow 49 from station 125 to station 127 and, in this way, the rotation of the power unit pulls and routes the wire from post 125 downstream to post 127.  The jaws 122 which at this particular time are disposed in the wire feed part constitute that part of the feed unit which is active in feeding the wire at that time. 



   During the feeding process, the wire Y is under tension and, as can be seen from fig.  6, the tension in the wire will push the wire feed extension 128 towards the axis of the unit, more specifically towards the base of the V-groove.  Note that from the geometry involved, at entry station 125, incoming extension 126 is just about tangential to wire feed extension 128.  As the unit rotates in the direction of arrow 49, as a jaw approaches entry station 125, wire passes through that jaw.  However, the tension in the thread will not generate a force to push the thread towards the base of this jaw enough to cause the thread to be gripped by this jaw. 



  However, as the jaw reaches entry station 125, the force generated by the tension in the wire acts radially on the wire to push it into engaging contact with that jaw.  As described below, the wire is in wedging contact with this jaw.  Normally, the wire remains in wedging contact in this jaw as long as there is no force applied to it which tends to push it radially outside the axis.  If the aforementioned jaw is arbitrarily called the first jaw, one can call the next jaw, which is contiguous to it in a counterclockwise direction, the second jaw, the following jaw then being the third jaw, etc.  

  When the first jaw is at the entry station, however, the second jaw has not arrived at this position and therefore does not jam the wire of the incoming extension 126.  As the unit rotates, the first jaw moves clockwise to discharge station 127 and pulls the wire through entry guide 56A until the second jaw arrives at the entrance post.  At this point, the tension on the wire causes it to be caught with jamming by the second jaw.  As the unit continues to rotate, the second jaw pulls the wire through the entry guide 56A while the first jaw feeds the wire in the arcuate path in which the first jaw moves. 

  This process continues as each successive jaw arrives at the input station to jam the wire, while the previous jaws continue to discharge station 127 and feed the wire through the wire feed path. 



   When the first jaw arrives at the discharge station 127, the tension in the wire, and in particular in the extension of the outgoing wire 129, generates a force thereon in the first jaw which pushes it outwards from the axis, and this causes the first jaw to release or unload the wire.  In actual fact, as the first jaw leaves the discharge station, it pulls the outgoing wire extension 129 away to cause the wire to release.  Since each successive jaw which follows the first jaw arrives at the discharge station, the wire is successively released.  The empty jaws then continue to rotate in the direction of arrow 49 until they again arrive at entry station 125. 

  It should be noted that the discharge station 127 is located substantially where the outgoing wire extension 129 is tangent to the wire feed extension 128. 



   As previously indicated, the yarn goes from guide 56B to its knitting station.  At the knitting station, the yarn is then consumed and this consumption of the yarn at the knitting station has the effect of pulling it through the guide 56B and causing tension in the outgoing extension 129.  In order for a positive feeder to perform its function properly, it must pull the yarn from the yarn source and make it available at the knitting station at the same rate at which the knitting station consumes the yarn.  In order for the positive feeder to feed yarn at the proper speed, it is necessary to avoid relative slippage between the yarn and the yarn feed unit. 

  One of the most important advantages of the present invention is that the wire feed unit can pull it from the wire source and positively feed it without any relative slippage.  The teeth of the wire feed unit are made so that the wire is caught with jamming by the jaws without slipping.  It is obvious that in order to prevent slipping, the wire must always be gripped with a wedging and must therefore always be under the control of at least one jaw and, preferably, several jaws.  In other words, the peripheral spacing of the jaws and the peripheral length of the wire feed portion should be such that there is always at least one jaw and, preferably, more than one jaw in the portion. power supply while this power unit is rotating. 

  Obviously, if the jaws, for example, are angularly spaced 60 apart and post 127 is angularly spaced 45 "from post 125, there are times when there are no jaws in the part of the jaw. feed to grab the wire.  During these times, the wire will be able to slide freely through the feed part at a peripheral speed different from that of the jaws; this is obviously undesirable.  In the illustrated embodiment, there are 24 teeth in each wheel and therefore there will be 48 jaws, since each tooth cooperates to form jaws with 2 teeth of the other wheel. 

  This realization not only ensures that there are always several jaws in the wire feed part, but that there are always enough jaws to jam the wire in the event that some of the jaws in the wire feed part. power supply would fail to jam the wire. 



   As indicated below, the teeth are made in such a way that the jaws which they form are scissor-shaped jaws and it has surprisingly been found that these scissor-shaped jaws wedgedly grip the wire. so sure that there is not normally a relative slip between the wire and the jaw when the tension of the wire is exerted tangentially to the jaw, i.e. when exerted in a perpendicular direction to a wheel spoke to the jaw.  As can be seen from FIG.  6, from the time the wire is grasped at the input station 125 until the time it is discharged at the station 127, the only force on the wire feed portion is tangential to the jaw. 

  It has been found that with the variety of knitting yarns used in a knitting machine, the jaws wedgedly grip the yarn so securely that the yarn will cut before slipping.  It is only when tension or pull on the wire is exerted away from the base of the jaw, as appears at unloading station 127, that the wire will be pulled away from the base of the jaw and away from the jaw base. the grip of the jaw. 



   To ensure that slippage does not occur, it is preferred that the wire is constantly gripped by more than one jaw. 



  In the preferred form of the present invention, the feed unit is made so that there are always several jaws in the feed part and several jaws constantly grip the wire. 



   It should be noted that the location of the entry station 125 as well as the location of the discharge station 127 may vary depending on the setting or axial spacing of the feed unit.  However, even for any particular unit setting and / or for any particular spacing of guides 56A and 56B relative to the feed unit and / or for any particular wire, entry station 125 does not necessarily represent a single precise location but rather identifies with several locations in which successive jaws grip the wire.  The discharge station 127 also represents a range of locations; in fact, it may represent a larger range than that of the entry station, since the location of the discharge station is a function of the uniformity with which the knitting station pulls the yarn. 

  A knitting station, when knitting a jacquard pattern, does not necessarily pull the yarn at a constant speed.  In other words, the rate at which the yarn is consumed at a knitting station can vary from one centimeter to one centimeter, although the consumption per revolution of the machine can be uniform.  However, in all installations, the variation in the speed of consumption of the yarn at the knitting station is essentially compensated for by the use of an elastic arm on the stop device downstream of the positive feed device which absorbs it. .  The effect of this resilient arm is to practically reduce the variation in yarn tension downstream of the feeder. 



   However, when knitting a uniform (non-jacquard) fabric, there are no variations in the feed speed. 



   Reference has been made to the intersecting teeth of the unit's wheels which form scissor-shaped jaws.  Note that since the axial spacing between wheels 70 and 71 is reduced, the edge 88A (or 88B) of a rib of a wheel 70 moves past its cooperating edge 108A (or 108B) of the wheel 71 in a manner analogous to the blade of a pair of scissors with its cooperating blade.  Obviously, after the axial spacing has been set and the feed unit is in operation, the axial spacing does not change when the wire is fed. 

 

  However, the cooperating edges of the teeth of the wheels are, in a relationship analogous to that of a pair of scissors, partially open.  The edges of the teeth are not as sharp as the edges of the blades of a pair of scissors.  In fact, they should be evened enough to remove any rough edges so that the cooperating edges don't tend to cut a wire entering the jaw.  As is well known, a pair of scissors, when partially open, will serve to grasp a thread inserted therein in space.  This is true even if the blades of the scissors are sufficiently blunt so as not to cut the material which is inserted between these blades.  The jaws formed by the teeth of the wheels 70 and 71 similarly grip the thread when the tension on the thread brings it into the jaw at the entry station. 

  Two factors allow the jaw to jam the wire at the entry station and hold that grip on the wire until the jaw arrives at the discharge station. 



  One factor is the size of the angle between the teeth and more specifically their edges which form the jawbone.  In the illustrated embodiment, each tooth 86 (as well as its edges) of wheel 70 forms an outwardly opening angle of about 12 "with each cooperating tooth 105 (and its edges) of wheel 71.  In other words, each tooth can be considered to be inclined outward and backward at an angle of about 12 "with respect to its contiguous cooperating tooth of the other wheel. 



  It should be noted that this inclination is relative and applies even if each tooth of the wheel 70 is perpendicular to the axis and if each tooth of the wheel 71 is oblique to the axis.  Excellent results have been obtained when the angle between the teeth is substantially as shown, but good results can still be obtained.  results when the angle between the teeth is increased or reduced.  However, it should be noted that the greater the increase in the angle, the more possibilities there are for the wire slip, and the greater the decrease in the angle, the greater the possibility of reduced uniformity in wire feed speed. 



   The other factor that concerns the grip of the jaw is the peripheral spacing between the cooperating edges of the teeth. 



  As is well known to every user of a pair of scissors, if the cutting edges of the blades are too far apart laterally, the edges will not cut the material.  If the lateral spacing between the blades is too great and the material to be cut is sufficiently soft or pliable, this material will pass between the opposing surfaces of the blades.  The maximum permissible spacing to a large extent will depend on the material to be processed.  As in a pair of scissors, the spacing between the cooperating edges, according to the present invention, should ideally be as small as possible.  However, as indicated above, it is difficult to fabricate the feed units and make the cooperating edges always contact. 

  It has been found that if the peripheral spacing between the cooperating edges does not exceed, by a large extent, the largest diametrical dimension of the fed wire, the wire will be gripped by the jaws. 



   Since it is difficult to establish precise limits for the desirable maximum peripheral spacing between the side edges, it is appropriate to define the scissor-shaped jaw in a somewhat different fashion.  The lateral spacing between the edges which form the jaws should be such that the wire feed extension is not pulled in by the tension of the wire in the direction of the axis beyond the base of the jaw .  In other words, if a yarn under normal tension is moved transversely to its direction of movement radially to the axis, the spacing between the edges defining the jaw must be small enough to prevent the yarn from passing through it. from the base of the jaw. 

  If the spacing between the edges is large enough for the wire to pass through the base of the jaw, it will no longer be caught with jamming by the jaw and we will no longer have a jaw shaped like a pair of scissors. 



   Yarn feed units made according to the present invention have been tested with various types of yarns.  The wheels of the tested units have a diameter of the order of 6.35 cm and are made essentially as shown in the drawings.  Each slot in each wheel is approximately 0.013 cm wider than the rib received therein.  Excellent results are obtained with such units for various types of yarns. 



   The axial spacing between the wheels is adjusted according to the desired feed speed.  Since it is desirable that the spacing between the side edges of the cooperating teeth be substantially the same regardless of the axial spacing, the cooperating side edges should preferably be substantially parallel.  These edges are described above as extending essentially radially.  Obviously, two cooperating edges cannot be parallel nor be arranged in a precise radial relationship.  It should therefore be noted that the lateral sides which define the ribs are not necessarily all in a precise radial relationship. 



   The speed at which the wire is fed is the speed at which the wire moves through the wire feed portion and is proportional to the peripheral speed of the base of the V-groove 123.  If the wire in the wire feed portion were actually lodged against the base of the jaws, the feed speed would be the same as the peripheral speed of the base of the throat.  However, in practice, the wire is actually placed slightly outside the bases of the jaws; the speed of the wire is therefore slightly higher than the speed of the bases. 



   The present invention provides several techniques for varying the wire feed speed.  One technique is to vary the rotational speed or angular speed of the jaws by varying the speed at which the shaft 28 rotates. 



  This can be done in several different ways.  One way is to vary the speed of the endless belt 42, and this will have the effect of proportionally changing the speed of all the feed units driven by the belt.  The speed of the endless belt can be changed by changing the diameter of the control pulley or by setting the regulator 38 to variable speed.  As shown, this variation changes the speed of all belt driven power units.  Another way to change the rotational speed of shaft 28 is to change the diameter of pulley 30 relative to the diameter of other pulleys.  In this way, the speed of all the feed units on a particular shaft 28 can be varied from those on different shafts. 



   The second main technique for varying the feed rate is to vary the axial spacing of the feed unit whose speed is to be changed.  A varying axial spacing changes the diameter of the base of the V-groove 123. 



  The greater the spacing between the wheels of a feed unit, the smaller the diameter of the throat base and hence the slower the feed speed.  Conversely, the smaller the spacing between the wheels of a feed unit, the larger the diameter of the throat base and therefore the greater the feed speed.  From the foregoing description of the present invention, it is evident that each feed unit on each shaft can have its axial spacing which varies independently of other units in its assembly and / or other assemblies.  The present invention therefore provides a simple means for adjusting the feed rate of each feed station independently of the others. 

  It should be noted that since the axial spacing can vary continuously across a range, the feed rate can be fine-tuned as desired.  The two techniques for varying the feed rate noted above can be used together, if desired. 



     It should be noted that the length of the periphery of the wire feed part, that is, the peripheral distance between the entry station 125 and the discharge station 127, does not print the feed speed, but simply adjusts the number of jaws disposed along the wire feed portion. 

 

  In the illustrated embodiment, the wire feed part in FIG.  6 is around 1800.     The angular length of the feed portion may represent a greater or lesser proportion of the feed unit and may even extend to encompass the 360 "range of the unit. 



   Since, in the illustrated embodiment, the teeth of the wheel 70 are substantially perpendicular to the axis, the base of the V-groove 123 will not be displaced axially, regardless of the axial space between the wheels.  In other words, in the illustrated embodiment, whatever the axial spacing, the base of the groove will always be in the plane defined by the teeth 86.  It is desirable that the guides 56A and 56B be placed such that they direct the wire in a substantially straight line into the entry station 125 and in a substantially straight line outside of the discharge station 127.  Therefore, the guide support 51 in the operational position, as shown in solid lines in FIG.  4, should lead the wire as close as possible to the front face of the wheel 70. 

  When set in this way, it is not necessary to move the guide bracket even when the axial space of the unit varies to vary the wire feed speed. 



   When it is desired for a particular feed unit to be inactive and not feeding yarn, the yarn holder can be swung to the inactive position shown in dotted lines by 51 'in FIG.  4. 



  This automatically lifts the wire up and moves it to the rear of the front face of the wheel 70, the wire then sliding around the uprights 80.  Even if the power unit is still spinning, there will be no wire feed due to the uniformity of the posts. 



  The ring 80 'at the rear end of the posts 80 prevents the wire from being moved behind the posts and becoming tangled.  The polygonal shape of the wheel 70 aids movement of the wire when the guide support is moved from the operational position to the neutral or inactive position and vice versa.  Although the feed unit could operate just as well even if the periphery of the wheel 70 were circular, such a circular periphery could cause a slowing down in the movement of the wire either backward or forward when the carrier. guide is suitably moved. 

  When the guide support is in the feeding or operational position, it should preferably direct the wire as close as possible to the front face of the wheel 70 as indicated above, but it should not direct it. so that either the incoming extension or the outgoing extension of the wire comes into contact with the teeth outside the jaw.  The guide support 51 should preferably be made so that the upstream guide 56A is as close as possible to the mouth 124 while allowing the guides to pass through the periphery of the wheel 70 as the guide support is moved. between neutral and operational positions. 



   In the embodiment thus described, the teeth of the wheel 70 are in a plane substantially perpendicular to the axis, while the teeth of the wheel 71 are located at an oblique angle with respect to the axis.     According to the present invention, it is only necessary that the teeth of the wheels lie at an angle to each other so that, as the axial spacing between the wheels varies, the diameter of the curve defined by the intersections also changes.  Therefore, the teeth of the two wheels can be substantially oblique to the axis and such an embodiment is illustrated in connection with the power unit 50C which is shown in FIG.  11, unit using the 70 'and 71' wheels. 



  In this embodiment, the elements of the power supply unit may be identical to the units 50A and 50B described above, except for the differences which will be pointed out below. 



   The fixed wheel 70 'differs from the wheel 70 in that the inner side 84' of the wheel 70 'extends forward a greater distance than the corresponding inner side 84 of the wheel 70.  As a result, the front face 86 'or tooth of the rib 83' slopes backward and outward instead of being substantially perpendicular to the axis of the shaft 28.  The annular body 90 'of the movable wheel 71' is inclined forward and outward relative to the axis of the shaft 28 instead of being substantially perpendicular to this axis, like the annular body 90 of the wheel 71.  This modification increases the depth of the slots between the ribs 99 'of the wheel 71' to accommodate a greater height of the ribs 83 'of the wheel 70'. 

  The front teeth 105 'faces are inclined rearwardly and outwardly with respect to the axis of the shaft 28.  The impeller 70 'can be fixed to the shaft 28 by means of a set of screws 110', while the impeller 71 'can be adjusted axially by means of the nut 116', the structure of which can be similar to that of nut 116. 



   It was stated above that the angle between teeth 86 and cooperating teeth 105 is approximately 12 ".     Since teeth 86 are substantially perpendicular to the axis, teeth 105 will be inclined approximately 12 "from the axis.  If the same angular spacing is desired in the variant of FIG.  11, the teeth 86 'will be inclined about 6 "from the axis and the teeth 105' will also be inclined about 69 from the axis but in the opposite direction, giving a global angle.
 ball of about 12 "between the cooperating teeth. 



   In the variant embodiment of FIG.    II, the frontal shape of the ribs and slots of the two wheels may be the same as that of the wheels 70 and 71. 



   It is evident that since the axial spacing between the
 wheels 70 'and 71' vary, the plane defined by the intersections of the teeth
 will extend in different axial locations.  Given
 that it is preferred that the wire, which is guided to the feed unit and from this unit by the guide support (51A in fig.  11), extends practically in the plane of the intersections of the teeth, it is necessary to adjust the guide support 51A when the es
 Axial spacing between the wheels changes.  Guide support 51A
 may have the same embodiment as that of the support 51, but it must be provided with a device to fix it in the ali position.
 adequate mentation or non-feeding. 

  A simplified way
 to achieve this construction is to mount the support of
 guide 5 lA on a bolt 54 'passing through the central branch 18 of the mounting console.  Bolt 54 'can be loosened to allow movement of bracket 51A to desired position
 and can then be tightened to be held in this position. 



   Although, in the embodiment illustrated in FIG.    He, the
 impeller 70 'is fixed to the shaft and impeller 71' is axially adjustable
 along the shaft it is evident that the 70 'wheel can also be
 axially adjustable (not shown).  In such a modification,
 The operator can vary the axial spacing between the wheels by moving one or the other or both.  If the operator prefers that the plane defined by the intersections remain in the same place
 axially, whatever the axial space, the adjustment of the feed
 tion of the guide bracket 51A can be fixed and the operator can
 adjust the axial spacing of the two wheels to maintain the
 sections aligned in plane with the guide support. 



   According to the preferred embodiment of the present
 In accordance with the invention, each tooth and each slot of each toothed member of the feed unit are shaped such that at least in the feed range, each tooth is received in
 the opposing slot between two contiguous teeth of the other element
 toothed and cooperates with these two contiguous teeth to form two
 jaws spaced at the periphery.  This cooperation is obtained when the frontal shape of each tooth, at least in the area of the unit where these teeth cooperate during feeding, is practically the same as that of the opposite slot of the other element receiving this tooth.  In other words, the configuration of the front face of each toothed element is practically the complement of that of the other toothed element in at least this zone. 

 

   For each location in an element which is occupied by one tooth, there is an opposite and corresponding location in the other element which is occupied by a slot of substantially the same frontal shape as that of the opposite tooth and vice versa. 



  Of course, for a tooth to be received in its opposite slot, the tooth must be slightly narrower than the slot to provide the necessary clearance, and it should be noted that this condition prevails in the various configurations of the teeth and slots in question. .  It has also been mentioned above that the cooperating side edges of the opposing teeth can be spaced slightly apart as long as they are close enough to provide a scissor-shaped jaw and, therefore, it is apparent from this description that this spacing also applies. well at the spacing necessary for the game.   



   With respect to the foregoing concept, it is evident that there are many possible configurations of the teeth which satisfy the preferred requirements.  Some of these changes will be briefly noted but are not illustrated.  In one type of modification, all teeth and slots of the two elements flare outward with the side edges of the teeth extending essentially radially, with variations in the frontal shape resulting from variations in the angular width of the teeth and slits.  The angular width of each tooth of an element may be the same, greater or less than that of the other teeth of this element. 

  By way of example, all the teeth can have the same angular width, or the angular width of each tooth can be different from that of each of the other teeth, or each tooth can have the same width as one tooth or more teeth.  Naturally, the other wheel will have to be of complementary shape.  Similarly, the angular width of each slot of a wheel may be the same, or may be greater or less than the other slots of this wheel. 



   In other types of modifications, not all teeth on a wheel need to be flared outward.  For example, in a wheel, the teeth may be defined by the substantially parallel edges while the slots would be flared outwards.  The cooperating wheel would then obviously be of complementary shape.  In the illustrated embodiments, the edges of the teeth extend substantially radially and are substantially straight.  Obviously, they do not need to be straight or to extend essentially radially (not shown).  It is only necessary that the edges of the cooperating teeth be shaped so that, as the axial spacing between the teeth decreases, the intersection of the cooperating edges moves outward with respect to the axis and vice versa. 



   In the preceding description, each tooth cooperates with the two contiguous teeth of the other wheel to have two jaws in the form of a pair of scissors, and this result is obtained when the front faces of the two cooperating wheels are complementary. 



   However, the present invention encompasses structures in which one tooth can cooperate to feed the wire only with contiguous teeth of the other wheel.  In other words, a tooth 86 may have its edge 88A sufficiently close to the edge 108A of the
 tooth 105 on one side of it to form a scissor-shaped jaw.  However, the same tooth 86 may have its
 edge 88B sufficiently spaced from edge 108B of tooth 105 on
 its other side so as not to create a scissor-shaped jaw.  The edges defining the last jaw would not be
 considered to be in a cooperative relationship for
 positively feed the wire and the teeth would not be considered
 rees as being in a cooperative relationship. 



   It should also be noted, from the pre description
 cedent, that the effective parts of the power supply unit, for
 as far as feeding a wire is concerned, are the teeth
 cooperating, including their lateral edges.  The particular shape
 teeth, the structure to mount the teeth on their supports,
 etc. , are not critical.  In the illustrated embodiment, the
 network of intersections in each position of the range of ali
 mentation defines a circle and this is the preferred curve, but,
 obviously, the invention is not limited to such a curve. 



   It is evident that the axial spacing is set to produce
 a desired feed rate.  When the spacing is set
 thus, the machine is then put into operation to achieve
 its knitting function.  Since the power supply unit
 is driven in synchronism with the knitting machine, as
 previously described, when the speed of the knitting machine is
 changed, the feed rate is changed proportionally.
 tional. 



   As the wheels are adjusted from the open position shown
 ty in fig.  7 to the closed position shown in FIG.  8, the inter
 sections of the teeth move outward into an annu area
 area surrounding the axis of the unit.  The internal limit of the zone is defined by the intersections when the wheels are in the position of fig.  7 and the outer limit of this zone is defined by the intersections when the wheels are in the position shown in FIG.  8.  Intersections fall in various locations in this area because the axial spacing is set in the feed range.  Therefore, the parts of the teeth which fall into this annular zone are the parts which cooperate in feeding the wire.  It is the frontal shape of the teeth in at least this zone which determines the cooperation between the teeth of the wheels. 

  If we express it differently, we can say that the teeth cooperating in at least this zone are inclined outwards and backwards with respect to each contiguous tooth cooperating with them; therefore, each of these teeth intersects each cooperating tooth at an outwardly opening angle at least in the range of axial spacing, which defines a groove with a V-shaped periphery opening outwardly around the assembled unit.  The diameter of the groove increases as the axial spacing decreases and vice versa.  It should be noted that the cooperating teeth mesh in at least this annular zone at least in the feed range or in the axial spacing range.  This does not mean that in every position of the feed range the teeth mesh across the area. 

  Of course, it is obvious that in the closed position shown in FIG.  8, the teeth mesh across the width of the area.  However, in the positions intermediate to those shown in FIGS.  7 and 8, the teeth mesh only at the intersections and on the part of the area inside the intersections.  It should be noted that the teeth are considered to mesh at the intersection so that in the open position of fig.  7, the teeth mesh only on the innermost edge of the annular zone. 



   It has been mentioned previously that the intersections in the open position may be disposed more inward than the position illustrated in FIG.  7 or that they may be disposed more outward from the position illustrated in the closed position of FIG.  8, but this can cause problems.  In the event that the axial spacing is increased beyond that shown in fig.  7, it may be possible for the wire to slip inward past the intersection and get tangled on the shaft.  This is obviously undesirable.  In fact, to prevent this possibility from occurring, the guard segment 104 has been provided on the ribs 99 of the wheel 71.  These guard segments prevent any wire that might move inward at the intersections from being tangled with the spring 111. 



  Even when the open position is fixed, as shown in fig.  7, the wire may occasionally move inward beyond the intersection due to defective teeth or other defects. 



   If the intersections are arranged more outward in the closed position rather than in the position shown in fig.  8, the wire could be contacted by the uniform yeast surface of the wheels rather than by the jaws defined by the teeth.  It is therefore desirable that the portions of the teeth extend outward from the intersections to have a jaw which can grip the wire. 

 

   It is apparent from the description of the apparatus of the present invention that this invention also encompasses a method of feeding yarn.  The method of the present invention consists in extending the yarn in the yarn path from the source of yarns to the knitting machine, in repeatedly performing the operations:

   a) jamming of the wire in a first location or upstream location (the entry station) in the wire path in several scissor-shaped jaws for gripping the wire, b) moving the jaws with the wire thus grasped downstream along the path to pull the wire from the wire source and route it downstream through part of the wire path, and c) releasing the wire from the jaws at a location (discharge station) in the wire path downstream of the first location, these repeated operations overlap so that the wire is continuously grasped and fed by at least one jaw to continuously maintain the movement of the wire under the control of the jaws.  In this way, the wire is positively fed by the moving jaws, the jaws being moved synchronously with the operation of the machine. 

  It should be noted from the description of the apparatus of the present invention that, during the feeding operation, the yarn is continuously gripped by at least one jaw in the yarn feeding portion of the path, but it is not always the same jaw that grasps the thread.  Of course, the wire is preferably grasped and fed continuously by several jaws to prevent slippage. 



   In the illustrated embodiment of the present invention, the repeated operations of the method are performed by cyclically moving a plurality of jaws to grip, feed and release the yarn, and these jaws are moved in a generally circular path.  The feed speed is changed by changing the speed of the jaws along the path that the jaws move as they grip and feed the wire.  This can be called linear velocity.  Since the jaws move in a generally circular path, the linear speed and hence the feed rate can be changed by varying the angular speed of the jaws and / or by changing the diameter of the circular path. 

  When considering the diameter of the jaw path, we are actually considering the diameter of the jaw base path. 



   CLAIM I
 I.  Method for feeding a wire of independent length without slipping
 finished from a source of yarns to a machine, in particular a knitting machine, characterized in that it consists:
 a) stretching this yarn in its path from a source of yarns to the machine;
 b) feeding the wire into this path via a planar arcuate track;
 c) while bringing this wire in this path by means of said planar arcuate path, in repeatedly performing the operations consisting of:

  :
 1) in wedging the wire in a first location of said path
 flat arch in at least one scissor-shaped jaw
 delimited by an angular rib of a set of jaws with
 ribs in said planar arcuate track, so as to grip and non-slip said yarn preventing it from slipping with respect to both said ribbed jaw and said yarn path;

  ;
 2) while tightening and holding the wire preventing it from slipping relative to said jaw, at the same time as the wire is tightened, downstream along the flat arcuate track, so as to draw this wire from this source and carry that wire downstream through part of that path, and
 3) disengaging the wire from said ribbed jaws in a location in said planar arcuate track located downstream of the first location, while wedging the wire in said planar arcuate path upstream of the release location and at said first location in at least one other jaw of the set of scissor-shaped jaws delimited by angular ribs;

  ;
 d) overlapping said repeated operations so that the yarn is continuously grasped, held and transported by at least one ribbed jaw so as to continuously maintain the movement of the yarn under the control of these jaws, so that the yarn is fed without slipping by moving jaws;
 e) moving said jaws, during this movement, in synchronism with the operation of the machine. 



   CLAIM II
   II.     Apparatus for carrying out the method according to claim
 cation I, characterized in that:
 a) at least one wire feed unit (16, 50) comprises a first toothed element (70) and a second toothed element (71), each element having an axis and a front face;
 b) each front face comprises several teeth for bringing into contact with the wire, spaced at the periphery, facing forward and arranged around the axis;

  ;
 c) the teeth (86) of the first member (70) can mesh with the teeth (105) of the second member (71) to place each tooth of each member in a cooperative relationship with at least one contiguous tooth of the another element so as to delimit between them angular ribs (83, 99) cooperating and forming jaw jaws in the form of scissors for gripping, holding and feeding the wire between these elements without slipping through the intermediary of a track flat at the jaw jaws in the form of scissors;

  ;
 d) a device (85, 93) is provided for coaxially mounting these elements, the faces of the elements being opposite and the teeth interlocking to form an assembled wire feed unit planar, arcuate, and rotatable about the same. 'common axis of these elements and to vary, in a selective manner, the axial spacing between the elements of the assembled unit at least within a selected range (50A, 50B) of axial spacing,
 e) a device (30) is provided for rotating this assembled unit around the axis;

  ;
 f) the teeth (86, 105) of the assembled unit mesh at least in one annular region of the assembly and form scissor-shaped jaw jaws, at least in the range of axial spacing,
 g) each of these teeth, at least in the annular zone, is inclined outwards and backwards with respect to each contiguous tooth cooperating with it, so that each of the teeth crosses each tooth cooperating with it, at least in said range of axial spacing, at an outwardly open angle to form a wire receiving path around the assembled unit, said path being arcuate, planar, peripheral, substantially V-shaped and open towards the outside. exterior, the base of this angular path delimiting the scissor-shaped jaw,

   the diameter of the base of the arcuate and planar wire receiving path increasing as the axial spacing between these elements decreases, and vice versa;
 h) a device (55b) directs the yarn from the yarn source into said scissor-shaped jaw of the arcuate and planar yarn receiving path, and around at least a part thereof, and then to the 'outside this jaw and in the direction of the machine;
 i) when the assembled unit is rotated, said scissor-shaped jaw delimited by the teeth which cooperate with each other comes into contact with the wire, clamps it and holds it in the flat arcuate path, to pull the wire from the wire source and bring it to the machine without slipping at the jaw between this wire and the assembled unit. 

 

   SUB-CLAIMS
 1.  A method as claimed in Claim I, characterized in that the repeated operations overlap sufficiently for the wire to be gripped and continuously fed by several jaws. 



   2.  A method as claimed in claim I and sub-claim 1, characterized in that the repeated operations are carried out by moving, in a cyclical manner, several of these jaws so that they wedgedly grip, feed and release the wire.  

** ATTENTION ** end of DESC field can contain start of CLMS **. 



   

 

Claims (1)

** ATTENTION ** start of field CLMS can contain end of DESC **. although the wire is continuously grasped and fed by at least one jaw to continually maintain the movement of the wire under the control of the jaws. In this way, the wire is positively fed by the moving jaws, the jaws being moved synchronously with the operation of the machine. It should be noted from the description of the apparatus of the present invention that, during the feeding operation, the yarn is continuously gripped by at least one jaw in the yarn feeding portion of the path, but it is not always the same jaw that grasps the thread. Of course, the wire is preferably grasped and fed continuously by several jaws to prevent slippage. In the illustrated embodiment of the present invention, the repeated operations of the method are performed by cyclically moving a plurality of jaws to grip, feed and release the yarn, and these jaws are moved in a generally circular path. The feed speed is changed by changing the speed of the jaws along the path that the jaws move as they grip and feed the wire. This can be called linear velocity. Since the jaws move in a generally circular path, the linear speed and hence the feed rate can be changed by varying the angular speed of the jaws and / or by changing the diameter of the circular path. When considering the diameter of the jaw path, we are actually considering the diameter of the jaw base path. CLAIM I I. Method for feeding a wire of independent length without slipping finished from a source of yarns to a machine, in particular a knitting machine, characterized in that it consists: a) stretching this yarn in its path from a source of yarns to the machine; b) feeding the wire into this path via a planar arcuate track; c) while bringing this wire in this path by means of said planar arcuate path, in repeatedly performing the operations consisting of: : 1) in wedging the wire in a first location of said path flat arch in at least one scissor-shaped jaw delimited by an angular rib of a set of jaws with ribs in said planar arcuate track, so as to grip and non-slip said yarn preventing it from slipping with respect to both said ribbed jaw and said yarn path; ; 2) while tightening and holding the wire preventing it from slipping relative to said jaw, at the same time as the wire is tightened, downstream along the flat arcuate track, so as to draw this wire from this source and carry that wire downstream through part of that path, and 3) disengaging the wire from said ribbed jaws in a location in said planar arcuate track located downstream of the first location, while wedging the wire in said planar arcuate path upstream of the release location and at said first location in at least one other jaw of the set of scissor-shaped jaws delimited by angular ribs; ; d) overlapping said repeated operations so that the yarn is continuously grasped, held and transported by at least one ribbed jaw so as to continuously maintain the movement of the yarn under the control of these jaws, so that the yarn is fed without slipping by moving jaws; e) moving said jaws, during this movement, in synchronism with the operation of the machine. CLAIM II II. Apparatus for carrying out the method according to claim cation I, characterized in that: a) at least one wire feed unit (16, 50) comprises a first toothed element (70) and a second toothed element (71), each element having an axis and a front face; b) each front face comprises several teeth for bringing into contact with the wire, spaced at the periphery, facing forward and arranged around the axis; ; c) the teeth (86) of the first member (70) can mesh with the teeth (105) of the second member (71) to place each tooth of each member in a cooperative relationship with at least one contiguous tooth of the another element so as to delimit between them angular ribs (83, 99) cooperating and forming jaw jaws in the form of scissors for gripping, holding and feeding the wire between these elements without slipping through the intermediary of a track flat at the jaw jaws in the form of scissors; ; d) a device (85, 93) is provided for coaxially mounting these elements, the faces of the elements being opposite and the teeth interlocking to form an assembled wire feed unit planar, arcuate, and rotatable about the same. 'common axis of these elements and to vary, in a selective manner, the axial spacing between the elements of the assembled unit at least within a selected range (50A, 50B) of axial spacing, e) a device (30) is provided for rotating this assembled unit around the axis; ; f) the teeth (86, 105) of the assembled unit mesh at least in one annular region of the assembly and form scissor-shaped jaw jaws, at least in the range of axial spacing, g) each of these teeth, at least in the annular zone, is inclined outwards and backwards with respect to each contiguous tooth cooperating with it, so that each of the teeth crosses each tooth cooperating with it, at least in said range of axial spacing, at an outwardly open angle to form a wire receiving path around the assembled unit, said path being arcuate, planar, peripheral, substantially V-shaped and open towards the outside. exterior, the base of this angular path delimiting the scissor-shaped jaw, the diameter of the base of the arcuate and planar wire receiving path increasing as the axial spacing between these elements decreases, and vice versa; h) a device (55b) directs the yarn from the yarn source into said scissor-shaped jaw of the arcuate and planar yarn receiving path, and around at least a part thereof, and then to the 'outside this jaw and in the direction of the machine; i) when the assembled unit is rotated, said scissor-shaped jaw delimited by the teeth which cooperate with each other comes into contact with the wire, clamps it and holds it in the flat arcuate path, to pull the wire from the wire source and bring it to the machine without slipping at the jaw between this wire and the assembled unit. SUB-CLAIMS 1. Method according to claim I, characterized in that the repeated operations overlap sufficiently for the wire to be grasped and continuously conveyed by several jaws. 2. Method according to claim I and sub-claim 1, characterized in that the repeated operations are carried out by moving, in a cyclical manner, several of these jaws so that they grip with wedging, convey and release the wire. 3. A method according to claim I and the subclaims tions 1 and 2, characterized in that several of the jaws are moved cyclically in a generally circular path. 4. A method according to claim I and sub-claims 1 to 3, characterized in that the feed rate is changed by changing the diameter of said circular path. 5. A method according to claim I and sub-claims 1 to 4, characterized in that, in order to supply several yarns simultaneously to a knitting machine or the like, at least some of the yarns are fed individually, each from its respective source. by its respective group of several jaws. 6. A method according to claim I and sub-claim 5, characterized in that the son fed have their feed speeds adjusted independently. 7. A method according to claim I and sub-claims 5 and 6, characterized in that some of the groups of jaws are moved through a path of a diameter greater than that of the path of other groups of jaws. 8. A method according to claim I and sub-claims 5 to 7, characterized in that some of the groups of jaws are moved at an angular speed different from that of the other groups of jaws. 9. A method according to claim I and sub-claims 5 to 8, characterized in that at least some of the groups of jaws are moved at the same angular speed and, among those groups which move at the same angular speed, some are moved on a track whose diameter is different from that of the others. 10. The method of claim I and sub-claims 5 and 6, characterized in that the diameter of the path of movement of each of the groups of jaws is adjusted independently. 11. Apparatus according to claim II, characterized in that the teeth are shaped and spaced such that each at least some of the intersections between the cooperating teeth defines a scissor-shaped jaw for receiving and gripping the wire. 12. Apparatus according to claim II and sub-claim II, characterized in that the device for rotating the assembled unit rotates this unit synchronously with the operation of the machine. 13. Apparatus according to claim II and sub-claims 1 1 and 12, characterized in that it comprises several wire feed units. 14. Apparatus according to claim II and sub-claims 1 1 to 13, characterized in that the feed rate of each of these units is independently adjustable. 15. Apparatus according to claim II and sub-claims 1 1 to 13, characterized in that the axial spacing between the elements of each of these units is independently adjustable. 16. Apparatus according to claim II and sub-claims 1 1 to 12, characterized in that, in at least the annular zone, the teeth of the first element are oblique with respect to the axis and the teeth of the second element are substantially perpendicular to this axis. 17. Apparatus according to claim II and sub-claims 1 1 to 16, characterized in that the elements are mounted coaxially on a common shaft to rotate with it, the first element being fixed axially to the shaft and the second element being capable of sliding axially, in an adjustable manner, along this shaft to vary the axial spacing between these elements. 18. Apparatus according to claim II and sub-claims 11 and 12, characterized in that the front shape of the two elements is practically the same in at least the annular zone. 19. Apparatus according to claim II and sub-claims 1 1 and 12, characterized in that, in at least the annular zone, the front configurations of the elements are practically complementary.