WO2006018693A1

WO2006018693A1 - Drive for a yarn guide in a knitting machine

Info

Publication number: WO2006018693A1
Application number: PCT/IB2005/002363
Authority: WO
Inventors: Marcello Baseggio; Michel Prost; Olivier Baseggio; Patrick Dumont
Original assignee: Atelier De Construction Steiger S.A.
Priority date: 2004-08-11
Filing date: 2005-08-08
Publication date: 2006-02-23
Also published as: FR2874221B1; CN101027440A; ES2366792T3; KR101177895B1; KR20070045288A; FR2874221A1; JP4547572B2; HK1112944A1; EP1776495B1; CN101027440B; JP2008510077A; MX2007001654A; EP1776495A1; ATE510054T1

Abstract

A knitting machine comprising at least one needle bed (1) acting as a support for needles and a cam holder (2) which can move along the needle bed in order to drive said needles, at least one yarn guide (6) which is moveably mounted in a striper bar (9), such that the thread tip (12) can distribute thread to the needles, a device for controlling (3) the yarn guide (6), characterized in that the device for controlling (3) the thread guide (6) is joined to the cam holder (2) by a first mechanical link enabling simultaneous displacement with the cam holder, and in that the machine comprises a drive (4) which is distinct from the yarn guide (6) and control device (3), and which is disposed in a driving striper bar (5), cooperating with the control device (3) such that it can be selected and driven by the control device (3), wherein the yarn guide (6) is connected to the drive (4) by means of a second mechanical link such that displacement of the drive (4) results in displacement of the yarn guide (6) inside the striper bar (9) thereof in a synchronous manner in the same direction and of the same amplitude as the displacement of the cam holder (2).

Description

Wire guide drive for knitting machine

The invention relates to a straight knitting machine and a knitting process.

The traditional knitting machines, as described in patent EP0246364, comprise two front and rear needle beds on which are arranged needles and on which a cam carriage moves back and forth to actuate certain needles and thus achieve rows of stitches. The carriages front and rear of each bed are integrally connected by a hoop straddling the needle beds to ensure the synchronization of their displacement, necessary since the two carriages act on the needles handling the same mesh of the same knit, to guarantee the quality. These machines also include several bar-ray parallel to the beds and arranged above the needle beds and under the arch of the cam holders. These bar-scrapers support wire guides that slide along almost the entire length of the machine, which are equipped with a wire-spout to guide the threads to the machine needles. Each wire guide corresponds to one or more spools of specific thread (s) and can guide one or more thread (s) to the needles. Each cam carriage includes an electromagnet-based wire guide selection and drive device which allows a selected wire guide to be directly grasped to slide it into its bar-strip, in a united manner. and synchronized with the displacement of the cam carriage, to bring it to the predefined needles for a knitting operation and thus allow these needles to manipulate their thread to make meshes. With each movement, the carriage can select one or more different wire guide (s). In this type of machine, because of the presence of the arches moving parallel to the beds above the needle beds, it is not possible to route the son to the needles from the top of the machine and these wires are fed from the sides of the machine almost horizontally to the wire guides. This solution finally has the following numerous disadvantages:

the path of a wire from a coil to the wire guide is complex and each wire is subjected to considerable tension, friction and torsion which causes premature wear of the wire, deformations of the meshes, or even breaks in the wire which require stopping the machine. The delicate yarns are very difficult to knit;

this horizontal distribution of the wire towards the wire guide causes a dissymmetry of the operation of the machine. In one direction of movement of the cam carriage and the thread guide, the thread is under tension and pulled from the spool while in the opposite direction of movement, the thread is no longer under tension and must be removed in the opposite direction reverse to the spool so that slack produced on the thread does not cause the thread to fall on the needle beds;

the preceding constraints limit the speed of displacement of the cam carriage and therefore the efficiency of the machine;

the maximum number of possible wire guides is limited since their positioning takes place in a reduced volume between the needle bed and the arches of the cam carriage. On the other hand, the complexity of feeding the wires to the wire guides also limits the number of wire guides. However, to obtain various knitting possibilities, it is necessary to have a large number of son and therefore guide wire available.

Another knitting machine is described in EP0526406. It includes two needle beds whose associated cam holders are independent and have their own drive means in the form of belts. These drive means are mutually slaved to obtain the synchronization of the displacements of the two cam carriers. This solution therefore eliminates the clutter that was present above the needle beds because of the hoops used and allows to provide a supply of son to the thread guide from above, advantageous solution called "threading In addition, each wire guide has its own small electric motor to move on its bar-rayer.This solution allows to increase the number of bars and tracks and therefore the number of guide wire. these two independent elements, namely the two cam carriers and the wire guides, are controlled and synchronized by a microprocessor programmable logic unit.This solution no longer has the disadvantages of the previous solution, but it is very expensive to use. makes the number of motors needed and the associated electronics to synchronize them.

A general object of the present invention is to provide a knitting machine which has the advantages of the solutions of the prior art without the disadvantages.

More specifically, a first object of the present invention is to provide a knitting machine that allows an advantageous distribution of son.

A second object of the present invention is to provide a knitting machine which allows the use of a large number of thread guides.

A third object of the present invention is to provide a simple and inexpensive knitting machine.

The concept of the invention is to introduce a new separate element, called a "trainer", arranged between a selection and driving device and a wire guide, so that the selection and training device can cause the movement of the trainer, and so that the movement of the trainer causes the remote displacement of a wire guide, without direct contact but via a mechanical connection of cable, belt or chain type, this displacement synchronously, in the same direction and the same amplitude as the cam carrier. This solution makes it possible to resume the arrangement of the wire guides and the feeding of the "direct threading" threads, in a manner similar to that proposed in the solution of the patent EP0526406, by suppressing the numerous motors and the associated electronics, and by replacing by simple and inexpensive mechanical means.

More specifically, the invention relates to a straight knitting machine comprising at least one needle-carrying needle bed and a movable cam carrier device on the needle bed for driving said needles, at least one wire guide mounted in a bar-stripper, of so that its spout can distribute a thread to the needles, a control device of the wire guide connected to the cam carrier by a first mechanical connection allowing its simultaneous movement with the displacement of the cam carrier, the machine having a separate trainer of the guide-wire and the control device, arranged in a driving strip-bar and cooperating with the control device so that it can be selected and driven by the control device, the wire guide being connected to the driver by a second mechanical connection so that the movement of the driver causes the wire guide to move within its bar-rayer synchronously, in the same way feel and the same amplitude as the displacement of the cam holder.

According to a first embodiment, the first mechanical connection consists of a control device integrally attached to the cam carrier.

According to a second embodiment, the cam carrier is mounted on a toothed belt extending over the entire length of the machine parallel to the needle bed, driven by a motor, the control device being mounted on the lower part of the belt. , the first mechanical link consisting of the toothed belt. According to a third embodiment, the cam carrier is mounted on a toothed belt extending over the entire length of the machine parallel to the bed, driven by a motor, the control device being mounted on a belt set in motion by the motor, synchronously and providing a displacement of the same amplitude of the control device with the cam carrier.

According to a first variant, the second mechanical connection between the driver and the wire guide consists of a continuous cable or string guided by several pulleys.

The cable can make two return trips using pulleys placed in the same plane, or two return trips, at least one round trip in the withdrawal of the same guide track, at the same time. using two to four substantially parallel pulleys and using two pulleys substantially perpendicular to the preceding pulleys, or two round trips, the one being in the guide track of a strip bar and the return in a tunnel of a bar-rayer, using two inclined pulleys and two other pulleys.

According to a second variant, the second mechanical connection between the driver and the wire guide comprises at least one toothed belt or chain. This link may also include at least one gear.

The knitting machine according to the invention may comprise a plurality of substantially parallel stripers, at least one wire guide receiving in its spout a wire which is conveyed upwards passing between two bar-scribers.

The knitting machine may also include a plurality of independent control devices. The drive strip-bar has a plurality of guide tracks placed one over the other. It may comprise at least one wire guide directly selected and driven by the control device. Its superimposed guide tracks may have a smaller dimension than those of the bar-rails supporting the wire guides, the latter being offset so that the cables are in parallel planes.

The invention also relates to a knitting process which comprises the following steps:

-select a wire guide using a control device,

moving a cam carrier onto a needle bed to drive the needles of the needle bed,

simultaneously move the control device connected to the cam carrier device by a first mechanical link

characterized by the following steps:

-training a trainer selected by the control device on its driving bar-shredder,

simultaneously moving a wire guide in its strip-bar, connected to the driver by a second mechanical link, in a synchronous manner, in the same direction and with the same amplitude as the displacement of the cam carrier.

These objects, features and advantages of the present invention will be set forth in detail in the following description of a particular embodiment made in a non-limiting manner in relation to the appended figures among which: FIG. 1 schematically represents a view from above of the operating principle according to a first embodiment of the invention

FIG. 2 diagrammatically represents a variant for the mechanical connection in a knitting machine according to the invention; Figure 3 shows schematically another variant for the mechanical connection in a knitting machine according to the invention; FIGS. 4a and 4b schematically represent additional variants for the mechanical connection between trainers and wire guide in a knitting machine according to the invention; Figures 5a and 5b show a sectional view of two variants of guide wire positioning on guide tracks for the implementation modes of a device according to the invention; Figures 6a and 6b show a sectional view of a device according to the first embodiment of the invention for a knitting machine with one and two beds respectively; FIG. 7 represents a front view of the device according to the first embodiment of the invention; FIG. 8 schematically represents a perspective view from above of the operating principle according to a second embodiment of the invention; Figure 9 shows schematically a perspective view from above of the operating principle according to a third embodiment of the invention; Figures 10a and 10b show a sectional view of the details of the invention according to two embodiments.

According to the diagram of FIG. 1, a straight knitting machine according to a first embodiment of the invention comprises a needle bed 1, a cam carrier 2 comprising two independent control devices 3 and 3 'integrally mounted on the holder. 2. These control devices 3 comprise elements with electromagnets or solenoid valves operating in a manner similar to the prior art, having a movable protruding portion engageable in a corresponding opening of a driver 4 to secure the movements of two elements. The control device 3 is inactivated while the control device 3 "is activated and cooperates with a driver 4 slidably mounted in a first bar-raying 5, said drive, parallel to the bed and placed substantially above the and sufficiently close to the cam carrier 2 to be accessible by the control device.The driver 4 is mechanically connected to a wire guide 6 via a smooth and light continuous cable 7 whose course is consists of several parallel trips in the same plane using several pulleys 8.

The controller 3 performs the selection and drive functions of the trainer, similarly to the existing wire guide selection and drive devices in the prior art. When the driver 4 is driven by the control device 3 'in a movement in the direction of the arrow A, the portion 7e of the cable 7 which is firmly fixed to the driver 4 is also driven in the direction of the arrow A By the play of the pulleys 8, the part of the cable 7g which is firmly connected to the wire guide 6 is also driven in a displacement in the direction of the arrow A. This mechanism therefore also causes the displacement of the wire guide 6 placed in a strip-bar 9 parallel to the strip-bar 5 but further away from the cam carrier 2, and therefore not directly drivable by the control device 3 of the cam carrier 2. The driver 4 and the wire guide 6 are arranged in opposite on their respective scribes and as the length of the cable 7 separating them is constant and their parallel movement, their position remains always in opposite. This solution, which is based on a separate trainer 4 and remote from the wire guide 6 and mechanically connected thereto to define its displacement, thus makes it possible to obtain exactly the same effect as with a direct drive mechanism of the guide- wire 6 by the device control 3 or with a motorized wire guide 6 as in the prior art, ie a displacement of the synchronous wire guide 6, in the same direction and of the same amplitude as the displacement of the cam carrier 2.

According to the diagram of FIG. 1, seven pulleys 8 of small size and placed in the same plane are used to obtain the routing of the cable 7. FIG. 2 represents a first variant embodiment in which the driver 4 and the wire guide 6 are connected by a cable 7 making two back and forth 777 "parallel, the portion of the cable representing a go T bearing respectively the coach 4 in its part 7e and the wire guide 6 in its part 7g. located in the plane of each strip-bar, thus making it possible to conceal the cables in the recesses 10 defining the guide tracks of the strip-bars This solution is implemented by four pulleys 8h on the one hand, of which effect is to cause the transverse passage of the cable from one bar-rayer to another, and two 8v pulleys perpendicular to the pulleys 8h on the other hand, whose effect is to allow the return of the cable 7 "in the same bar-scratcher. Optionally, these two pulleys 8v will have a slight inclination, so that the return of the cable 7 "is slightly offset and does not interfere with the movements of the driver 4 and wire guide 6 in their strips 5, 9 respective. cable 7 makes it possible not to clutter the space between the bar-strippers, which will be used for the routing of the son as will be explained later.

FIG. 3 illustrates a second variant in which the cable 7 is guided so as to carry out two return trips 777 ", one go and return in each striper bar 5, 9, as in the previous case, with the aid of two small pulleys 8h and two large pulleys 8i inclined.Each trip T corresponds to the cable portion carrying the trainer and the wire guide, not shown, within the guide tracks 10 of these elements while each return 7 "takes place in a separate tunnel 11 and parallel to the guide tracks 10, provided in each strip-bar. This solution avoids any interference between the different portions of cable 7. Each pulley 8h allows the return of the cable 7 "in the dedicated tunnel 11 of each strip bar, while each pulley 8i connects the cables of a strip bar to the other.

Figures 4a and 4b show two new variants in which toothed belts or chains are used. FIG. 4a shows a variant in which three toothed belts 7 and four toothed pulleys 8 are used to allow the remote mechanical connection of a wire guide 6 with a driver 4. FIG. 4b represents another variant in which the guide wire 6 and the driver 4 are each placed on a toothed belt 7 mounted movably around two pulleys 8, these two systems being connected by two gears 8 'making it possible to interconnect the rotations of the four pulleys 8 in order to obtain a displacement synchronous, of the same direction and of the same amplitude of the wire guide 6 and the driver 4.

All the previous variants illustrated in FIGS. 1 to 4 represent a mechanical connection at a distance between a wire guide 6 and a driver 4, as opposed to a usual mechanical connection according to the prior art in which a wire guide is directly and physically gripped. by a selection and training device. These alternative embodiments fulfill the same function of obtaining the synchronized displacement of a wire guide 6 with a driver 4, or finally a synchronized displacement, in the same direction and of the same amplitude as the cam carrier 2, which is necessary for knitting operations. As an additional remark, FIG. 3 illustrates an embodiment in which each striper bar may have several parallel guide tracks placed one on the other.

FIG. 5a illustrates a strip-bar 9 provided with two guide tracks 10a and 10b respectively carrying two wire guides 6a and 6b, both of which son-nozzles 12a and 12b stop at the same height substantially at the level of the needle so as to supply the needles actuated by the cam holder with thread. This construction allows the crossing of the wire guides.

FIG. 5b illustrates a strip bar 9 comprising only one guide track in which two wire guides 6a and 6b are placed. In this embodiment, the two thread guide can not cross, their use will be subject to a specific order and this solution offers fewer possibilities than the previous one.

Figure 6a illustrates a sectional view in a transverse plane at the cam door of a knitting machine to a needle bed according to the first embodiment of the invention. On the needle bed 1 is the cam carrier 2 provided with a control device 3 rising in a direction perpendicular to the bed 1. This control device comprises three electromagnets or solenoid valves or other drive devices. prior art 3a, 3b, 3c corresponding to three guide tracks 10a, 10b, 10c of the drive strip-bar 5 placed approximately above the end of the needles, and extending parallel to the needle bed. This figure illustrates two electromagnets 3a, 3c in an activated state, which allows to guide both wire guide 6a, 6c whose son-beaks 12a, 12c are positioned at the needles of the needle bed. The two electromagnets 3b and 3c cooperate with two drivers 4b and 4c, respectively moving in the guide tracks 10b and 10c. Each driver 4b, 4c is mechanically connected to a wire guide 6b, 6c, placed in a separate guide track of the same bar-stripper 9, by cables 7b and 7c, according to one of the variants illustrated above. The wire guide 6a, positioned in the guide track 10a of the drive strip-bar 5, is directly actuable by the electromagnet 3a of the control device 3, which comes into direct contact with a solidary drive part. of the wire guide 6a, in a known manner, without resorting to a trainer within the meaning of the invention. This solution thus combines wire guide drive mechanisms according to the invention with conventional wire guide actuation.

As illustrated in this FIG. 6a, each spout 12a, 12b, 12c of each thread guide 6a, 6b, 6c makes it possible to convey a thread, respectively 13a, 13b, 13c, at the needles of the needle bed 1. The curvature and length of the spouts differ according to the positioning of the thread guides in different guide tracks and / or in different bar-rays. The routing of each wire is optimized since each wire is brought from the top, according to the routing "direct threading", which allows a path of the shortest wire possible, minimizing tensions, twists, dissymmetries and friction. A first series of cylindrical bars 15, then a second series of cylindrical bars 14a, 14b guide the son 13a and 13b with the minimum of friction, torsion and effort. The son 13a and 13b are routed in the space between the bar-strippers 5 and 9. This routing son also provides a solution in which each wire is not likely to interfere with the other son.

FIG. 6b shows a straight needle double knitting machine whose elements described with reference to FIG. 6a are split symmetrically above the second needle bed. This machine therefore has a total of six thread guides. As a reminder, this same configuration could work with more wire guide disposed in the same guide tracks according to a solution as shown in Figure 5b.

Figure 7 illustrates a front view of a straight knitting machine as shown in Figures 6a and 6b. It comprises a bed 1 on which moves a cam holder 2 comprising two control devices 3. Above the bed is the drive bar-stripper 5 which comprises three guide tracks 10a, 10b, 10c. The lower guide track 10a supports a wire guide 6a that can be driven directly by the control device 3. The upper guide track 10c supports two trainers 4c and 4c ¹ , corresponding to two wire guide 6c and 6c ¹ placed on a striper bar further away and not visible in this view. These elements are mounted according to the diagram of Figure 5b. The driver 4b on the intermediate guide track 10b of the drive-eraser bar 5, actuated by the control device 3 ', drives the wire guide 6b, placed on a remote bar-ray and not visible on this view in a manner synchronized with the displacement of the cam carrier 2. The wire guides 6b, 6c and 6c 'are mechanically connected to the drivers 4b, 4c and 4c', by a means not shown, in order to allow their remote training, such as this has been explained above. The routing of the son is done by direct threading, the son 13a, 13b, 13c and 13c 'being routed to son nozzles 12a, 12b, 12c and 12c' from their highest points 16a, 16b, 16c and 16c '.

Figure 8 schematically illustrates a second embodiment of the invention, for a straight knitting machine with two needle beds. For reasons of simplification of the representation, the device of the invention is shown in connection with the front only. The front cam carrier 2 is mounted on a toothed belt 20, extending over the entire length of the machine, driven by a toothed wheel 21 itself driven by a motor 22. The belt forms a loop around two notched wheels 21 and 24. This mechanism allows the cam carrier 2 to move on the needle bed. The lower part 23 of the belt moves in the opposite direction to that of part 20. According to this embodiment of the invention, the control device 3 is no longer secured to the cam carrier 2 but is mounted on this second portion 23 of the toothed belt. It also makes it possible to select and set in motion a not shown driver 4, connected to a wire guide 6 by a cable 7. A first advantage of such an implementation comes from the fact that as the control device 3 has a displacement opposite to that of the cam holder 2, the path of the cable 7 can be the most simple possible, with only a round trip, to allow the wire guide 6 to have a simultaneous movement and in the same direction as the cam holder 2. On the other hand, this solution reduces the overall size, above the needle beds, since several elements are placed in a lower space of the machine, which offers greater possibilities to route the threads from the top of the machine and to have wire guide bar-stripers.

Figure 9 schematically illustrates a third embodiment of the invention, for a straight knitting machine with two needle beds. The cam carrier 2 is mounted on a belt 20 driven by a motor 22 as in the previous solution. The control device 3 is mounted on a belt 25 set in motion around four pulleys 8v at least one of which is connected to the motor shaft 22. The dimensions of these pulleys are chosen so that the two belts 20 and 25 are set in motion simultaneously, synchronously and at the same speed by the motor 22. The control device 3 is thus able to select and drive a driver 4 mounted on a not shown bar-ray. The trainer 4 is connected to a wire guide 6 by one of the solutions described above. According to a variant not shown of this embodiment, the mechanical connection between the control device 3 and the cam carrier 2 could allow a displacement of the control device 3 in the opposite direction of the cam carrier 2, to obtain the same advantage than that mentioned in the second implementation mode described with reference to FIG. 8.

Figs. 10a and 10b show cross-sectional views of a drive bar-striper 5 and two bar-strips 9 and 26, according to one of the previous four wire guide embodiments. According to this solution, four elements 3a to 3d make it possible respectively to drive four drivers 4a to 4d placed in superimposed guide tracks of a drive bar-razor 5 and respectively connected by four cables. 7a to 7d to four wire guide 6a to 6d, distributing four son 13a to 13d. The two wire guides 6c and 6d are positioned in two superimposed guide tracks of the strip bar 9 while the two wire guides 6a and 6b are positioned in two superimposed guide tracks of the parallel strip bar 26.

According to the embodiment shown in FIG. 10a, the dimensions of the guide tracks of the driving strip-bar 5 are the same as those of the strip-bars 9 and 26 and the strip-bar 26 is entirely under the strip-bar 9, so that the cables 7a to 7d remain in parallel planes.

According to the embodiment shown in FIG. 10b, the guide tracks of the driving strip-bar 5 are smaller than those of the strip-bars 9 and 26. They have a height that is twice as small in this variant. Thus, the second strip bar 26 is positioned at a height offset by half the height of a guide track of the first strip bar 9 in order to obtain a positioning of the cables 7a to 7d in parallel planes. This variant makes it possible to reduce the dimensions of the drive strip-bar and thus its bulk, while reducing the volume necessary to have several parallel stripers.

According to another variant not shown, it is conceivable to superimpose at least three wire guide guide tracks on the same wire guide bar-bar. In such a variant, the distribution of the son will have to be arranged to avoid their crossing: two son will be distributed from above, distributed on both sides of the bar-stripper, according to the example of the son 13c and 13d of the bar for example, the other wires for the other wire guides superimposed on the same strip bar will be distributed horizontally by the sides according to a method of the prior art. As a remark, this solution answers the technical problem limiting the space above the bedbug and / or increasing the number of wire guides. In summary, the solution is a wire guide bar, comprising at least three wire guide guide tracks superimposed and combining a vertical and horizontal distribution of wires. As a further remark, this technical problem and this solution also apply to a knitting machine comprising a bar-striper combining motorized wire guides according to the prior art with wire guides driven according to a device of the present invention, or a bar-striper with all motorized or driven wire guides according to any other principle.

Previous modes of implementation use a cable or belts. It may be a single, smooth, toothless, twine-type continuous strand used with small bending radii to minimize straining efforts since the device is very light. Alternatively, any cable, chain, belt, tape, could be suitable.

The concept of the invention has been implemented on a straight and automatic knitting machine but it could be operated on a manual knitting machine.

For the sake of simplification of the representation, the described embodiments comprise few wire guides, but it will be obvious that the principle of the invention easily allows the arrangement of twenty-four wire guides or more, by multiplying the bars. rays and guide tracks.

Finally, the knitting machines according to the invention have the following advantages: they allow routing of the yarn from the top optimally; they allow the use of a large number of guide wire, since they can be on several parallel bar-ray possibly distant from the cam carrier. In addition, each bar-rayer can have several guide tracks and each guide track can support several guide-wire. In addition, the solution of the invention can be combined with the actuation of wire guide according to the known methods

the implementation of the invention is simple and economical, since the setting in motion of a wire guide is done by means of a simple mechanical connection of cable type, directly connecting the wire guide to a trainer itself set in motion by a control device;

This control device is advantageously set in motion by the same motor as that used to move the cam carrier, which makes it possible to limit the number of necessary motors to a minimum;

the synchronization of the displacements of the different elements is simply carried out.

Claims

claims

1. A straight knitting machine comprising at least one bedbug (1) carrying needles and a cam carrier device (2) movable on the needle bed for driving these needles, at least one wire guide (6) movably mounted in a bar stripper (9), so that its spout (12) can distribute a thread to the needles, a control device (3) of the guide wire (6), characterized in that the control device (3) of the guide -fil (6) is connected to the cam carrier (2) by a first mechanical connection allowing its simultaneous displacement with the displacement of the cam carrier, and in that the machine comprises a driver (4), distinct from the guide wire ( 6) and the control device (3), arranged in a drive strip-bar (5) and cooperating with the control device (3) so that it can be selected and driven by the control device (3), the wire guide (6) being connected to the driver (4) by a second mechanical connection so that the movement of the e The trainer (4) causes the wire guide (6) to move within its strip-bar (9) synchronously in the same direction and with the same amplitude as the displacement of the cam carrier (2).

2. Knitting machine according to claim 1, characterized in that the first mechanical connection consists of a control device (3) integral with the cam carrier (2).

3. Knitting machine according to claim 1, characterized in that the cam carrier (2) is mounted on a toothed belt (20) extending over the entire length of the machine parallel to the needle bed, driven by a motor (22), and in that the control device (3) is mounted on the lower part (23) of the belt, the first mechanical connection consisting of the toothed belt (20).

4. Knitting machine according to claim 1, characterized in that the cam carrier (2) is mounted on a toothed belt (20) extending over the entire length of the machine parallel to the needle bed, driven by a motor (22), and in that the control device (3) is mounted on a belt (25) which is moved by the motor (22) synchronously and provides a displacement of the same amplitude of the control device (3). with the cam holder (2).

5. Knitting machine according to one of claims 1 to 4, characterized in that the second mechanical connection between the driver (4) and the wire guide (6) consists of a cable (7) or a continuous string ( e) guided by several pulleys (8).

6. Knitting machine according to claim 5, characterized in that the cable (7) makes two trips and returns using pulleys placed in the same plane.

7. Knitting machine according to claim 5, characterized in that the cable (7) makes two back and forth, at least one round trip in the withdrawal of the same guide track (10), at using two to four pulleys (8h) substantially parallel and with two pulleys (8v) substantially perpendicular to the pulleys (8h).

8. Knitting machine according to claim 5, characterized in that the cable (7) makes two back and forth, the one being in the guide track (10) of a strip bar and the return in a tunnel ( 11) of a bar-rayer, using two inclined pulleys (8i) and two pulleys (8h).

9. Knitting machine according to one of claims 1 to 4, characterized in that the second mechanical connection between the driver (4) and the wire guide (6) comprises at least one toothed belt or chain.

10. Knitting machine according to claim 9, characterized in that the second mechanical connection between the driver (4) and the wire guide (6) comprises at least one gear (8 ¹ )

11. Knitting machine according to one of the preceding claims, characterized in that it comprises a plurality of substantially parallel bar-strips (5, 9, 26) and that at least one wire guide (6) receives in its spout. wire (12) a wire (13) which is conveyed upwards passing between two bar-strips (5, 9; 9, 26).

12. Knitting machine according to one of the preceding claims, characterized in that it comprises a plurality of independent control devices (3).

13. Knitting machine according to one of the preceding claims, characterized in that the drive strip-bar (5) has a plurality of guide tracks placed on one another.

14. Knitting machine according to one of the preceding claims, characterized in that the driving strip-bar (5) comprises at least one wire guide (6a) directly selected and driven by the control device (3).

15. Knitting machine according to one of the preceding claims, characterized in that the superimposed guide tracks of the drive strip-bar (5) have a smaller dimension than those of the strip-bars (9, 26) supporting the wire guides (6), the latter being offset so that the cables (7) are in parallel planes.

16. Knitting process comprising the following steps:

-selecting a wire guide (6) using a control device (3), displacing a cam carrier (2) on a needle bed (1) to drive the needles of the needle bed (1),

simultaneously moving the control device connected to the cam carrier device (2) by a first mechanical link,

characterized by the following steps:

driving a trainer (4) selected by the control device (3) on its driving bar (5),

simultaneously moving a wire guide (6) in its strip-bar (9), connected to the driver (4) by a second mechanical connection, in a synchronous manner, in the same direction and with the same amplitude as the displacement of the cam holders (2).