EP0541591A1 - Textile machine - Google Patents

Abstract

In textile machines, in particular knitting machines comprising controllable working elements and an electromagnetic control system exerting on the working elements (5) a controlled magnetic force, fixed intermediate elements (14-17) made of ferromagnetic material are provided in a stable position between the working elements (5) and the control system (20). This results in a simple structure and a safe and reliable mode of operation of textile machines even at high working speeds, since physical contact between the movable elements relative to each other is avoided.

Description

 Textile machine

The invention relates to a textile machine, in particular a knitting machine with controllable working elements and an electromagnetic control system, which exerts a controlled magnetic force on the working elements.

Textile machines of this type, in particular circular knitting and flat knitting machines are known, for example, from DE15 85 206 A2, DE20 10 973 A2, DE21 50 360 AI, DE25 19 896 AI and DE36 14 220 A2. Arrangements of this type with controllable working elements and an electromagnetic control system are provided in particular for pattern control and as needle selection devices. The needles are selected by acting directly on the individual knitting elements such as needles, sinkers, springs or the like, or by controlling the ferromagnetic parts of the specified knitting elements, the electromagnetic control system being transverse to the knitting elements located in the needle channels Needle expulsion direction moves. So that the working elements reach a starting position required for the selection, permanent magnets are provided which hold the working elements in their starting position for the selection against the spring force of trigger springs, possibly after action by lock parts. The permanent magnet arranged in the movable control system therefore slides on the working elements. In order to reduce the large amount of friction that occurs, a rail made of the best possible sliding and hard material is attached between the poles and the working elements in order to reduce the frictional forces and the wear caused by the friction. The permanent magnet slides along the work elements until the control system with its selection system reaches the knitting element that is to be selected. This selection range is as wide as the working element and separated from the poles of the permanent magnet by a narrow gap, so that the magnetic field

REPLACEMENT LEAF of the permanent magnet can be neutralized in this area by means of a control coil. Under the action of the spring force of a trigger spring, the selected working element is removed from the selection system d & er, while the other working elements continue to be held in position by the magnetic poles of the permanent magnet.

The magnetic flux in the working elements depends on the number of knitting elements still adhering to the selection system, so that the electromagnetic attraction force acting on the working elements also changes. The magnetic flux of the control coil with which the permanent magnet is compensated in the selection area must also be changed accordingly. From DE 36 14 220 A2 it is known to provide a Hall probe for measuring the instantaneous magnetic flux and to change the current applied to the control coil of the electromagnet depending on the output signal of the Hall probe.

As already mentioned, in all of these conventional selection systems, there is considerable friction between the working elements, for example the circuit boards and the control system sliding over them, which affects the reliability of the selection system and the overall functioning of the textile machine, the greater the higher the working speed is. Since the friction depends on the tightening force, i.e. Depending on the magnetic field density in the knitting element and the size of the contact surface, it was important in conventional textile machines of this type to keep the friction low by using as little magnetic flux as possible. However, this had the consequence that the work elements were not always and reliably kept in the selection system, or that work elements detached from the selection system that were not deliberately selected.

EB _SAT ZBLATT Another major disadvantage of conventional selection systems of this type is that due to the small area in which the selection is carried out, there is only a short period of time during which the selection area is magnetically neutral. According to a proposal known from DE-25 56 840 A1, a plurality of selection arrangements are staggered next to one another in order to thereby achieve higher working speeds of the textile machine and safer processes for the selection of the working elements. However, this arrangement has the disadvantage that a lot of space is required and in particular a large number of permanent magnets and control coils have to be used, which also considerably complicate such machines with regard to their manufacture, assembly and maintenance and give rise to a higher degree of susceptibility.

The invention is therefore based on the object of providing a textile machine which does not have the disadvantages of conventional textile machines, has a simple structure, can be operated at high working speeds and nevertheless operates reliably and safely.

The object is achieved according to the invention in that stationary intermediate elements made of ferromagnetic material are provided in a fixed position between the working elements and the control system.

The measure according to the invention of providing intermediate elements made of ferromagnetic material between the working elements and the control system means that there is no longer a direct contact between the working elements and the moving control system. This means that there is no friction with the known disadvantages between the control system and the working elements. This enables contact-free selection of the work elements.

ER _S ATZBLATT According to a preferred embodiment of the invention, the intermediate elements are magnetically isolated from one another. In this way, it is impossible for the individual intermediate elements to influence one another, even at high magnetic flux strengths.

A particularly advantageous embodiment of the invention consists in that the control system can be moved contactlessly over the outer surfaces of the intermediate elements facing away from the working elements. The control system, which can be, for example, a selection system, therefore slides over the intermediate elements without any mechanical contact and without any contact.

According to a further very advantageous embodiment of the invention, the control system has at least one controllable selector magnet which acts on at least one intermediate element with a controllable magnetic force flow. The controllable selection magnet of the control system either generates a magnetic force flow or not or an opposite magnetic force flow in the intermediate element, depending on the control, so that, depending on this, the working elements applied to the intermediate element in the initial state are held, released or repelled becomes.

A particularly advantageous embodiment is that the control system has a permanent magnet which acts on at least one intermediate element with a constant magnetic force flow.

The permanent magnet of the control system has the effect that the intermediate elements in the area of the permanent magnet are subjected to a constant magnetic flux, so that the intermediate elements, possibly against a spring force, adhere magnetically to the intermediate elements and thereby

REPLACEMENT LEAF be kept in the starting position for the selection process.

The permanent magnets have a width in the direction of movement of the control system, which makes it possible for several intermediate elements to come into the area of influence of the permanent magnet.

It is particularly advantageous if the magnetic force flow of the permanent magnet is chosen so large that the working elements adhere magnetically to the intermediate element against a spring force. This ensures that the working elements are in the starting position at the point where they are to be selected by the control system or its selection magnet.

In this context, it is advantageous if the selection magnet optionally generates a magnetic force flow which is directed in the same or opposite direction to the magnetic force flow generated by the permanent magnet. Thus, if a working element is to be selected, the magnetic flux of the permanent magnet is canceled or even directed in the opposite direction by the selection magnet of the control system, so that the working element can be displaced from the rest position, for example by spring force. Due to the measure according to the invention of providing an intermediate element made of ferromagnetic material between the working elements and the control system, the tightening force with which the working elements rest against the intermediate elements and are brought into the starting position for the selector magnet can be increased without hesitation in order to ensure the safe holding of the working elements in the starting position. Since there is no movement and therefore no friction on the working elements according to the present invention in contrast to the conventional arrangement, one is free to choose the attraction force of the magnetic flux generated by the permanent magnet in the intermediate elements or in the working elements. It is particularly advantageous that an increase in the electromagnetic pulling force by the permanent magnet also enables an increase in the pulling spring force, as a result of which the selection process is safer and more reliable. Due to the now possible high peel force and a more direct control of the Strickwerk¬'s tools, such as knitting needles, instruments without additional Hilfsele¬ as selection ^boards' possible so significantly simpler assembly result.

According to a preferred embodiment of the invention it is provided that when a working element is selected, the selection magnet generates a magnetic force flow in the area of the intermediate element assigned to it, which essentially corresponds in strength to the magnetic force flow generated by the permanent magnet in the intermediate element, however is directed in the opposite direction. The selection of the working elements is thus carried out with the selection magnet in such a way that the flow of force generated by the permanent magnet in the intermediate element is essentially canceled or made zero by the magnetic flow of force generated by the selection magnet. As a result, the working element to be selected can be separated from the intermediate element due to the action of a trigger spring force. If, on the other hand, a certain working element is not to be selected, the selection magnet is not excited, so that the magnetic field generated in the intermediate element by the permanent magnet remains undisturbed and the working element continues to be held in its starting position on the intermediate element.

A further preferred embodiment of the invention consists in the fact that the surfaces of the intermediate elements facing the working elements essentially correspond to the surfaces with which the working elements bear against the intermediate elements in terms of surface shape and size. Due to the mutually adapted surface shapes with which the working elements are in contact with the intermediate elements when the working element is not selected, an optimal dimension is

^- REPLACEMENT LEAF Use of gnet flow possible. This results in a good contact of the working elements on the intermediate elements and sufficiently large contact surfaces and thus tensile forces; this also ensures a good transition of the lines of force of the magnetic fluxes of the magnets of the control system, so that the magnetic stray fluxes are small.

In this context, it is also advantageous if the width of the intermediate elements is substantially equal to the width of the working elements. This further increases the power flow transition and reduces stray flux.

It is advantageous if the selection magnet is an electromagnet with an excitation coil through which a controlled current flows. In this way, the power flow of the selection magnet can be optimally controlled for the selection process.

It is particularly advantageous if the pole faces of the selection magnet in terms of surface shape and size essentially correspond to the outer surfaces of the intermediate elements facing the control system. This embodiment also enables a good magnetic force line transition between the pole faces of the selection magnet and the intermediate elements with little leakage flux. The air gap between the control system, that is to say between the pole faces of the selection magnet and the permanent magnet and the outer surfaces of the intermediate elements facing the control system, should be as small as possible, but sufficiently large, so that the relatively moving parts do not touch.

It is advantageous if the width of the selection magnet seen in the direction of movement of the control system is smaller than the total movement direction of the control system seen between the intermediate elements and the distance provided between two intermediate elements. This ensures that during the selection process, ie Due to the excitation of the selection magnet, only one intermediate element and thus only one working element is selectively influenced magnetically.

An advantageous embodiment of the selector magnet is that an arrangement is provided for changing the position of a magnetic core of the selector magnet. The arrangement for changing the position of the magnetic core can, for example, have screws with which the magnetic resistance of the core is changed.

A particularly advantageous embodiment of the invention consists in that the intermediate elements essentially have two intermediate element branches, which have transverse outer surfaces facing the control system and spaced apart from one another transversely to the direction of movement of the control system. This makes it possible to apply different magnetic fluxes to the same intermediate element and / or to provide different controls of the control system depending on the position of the intermediate element branches.

Preferably, at least one intermediate element branch is acted upon by a constant magnetic force flow generated by the permanent magnet of the control system, and at least one further intermediate element branch is acted upon by controllable magnetic force flow generated by the selection magnet. This embodiment of the invention enables a spatial separation of the selection and permanent magnets perpendicular or transverse to the direction of movement of the control system, so that the permanent and selection magnets cannot have a negative influence on one another.

According to an advantageous embodiment, the selection magnet acts on an intermediate element branch, the so-called main branch, the permanent magnet and on a second intermediate element branch, the so-called controlling or secondary branch.

REPLACEMENT LEAF A particularly advantageous embodiment consists in that n predetermined, fixed distances between the outer surfaces of the intermediate element branches facing the control system are provided transversely to the direction of movement of the control system, and that the control system has n permanent and / or selection magnetic poles at corresponding n predetermined fixed distances perpendicular to the direction of movement of the control system, where n is an integer natural number. It is again advantageous to provide a main branch for the permanent magnet, the controlling or secondary branches being at one or more distances from the main branch, that is to say at one or more additional levels transverse to the direction of movement of the control system. As a result of the increase in the number of secondary or control branch levels, the distance between the branches lying at the same distance or system of the intermediate elements which follow one another in the direction of movement of the control system also increases, so that the action of a selection electromagnet on a secondary or The control branch of the respective intermediate element is lengthened in time and, as a result, even at a high switching frequency or control speed, it is ensured that several intermediate elements are not inadvertently activated simultaneously. The number of selection magnets must be equal to the number of intermediate elements provided transversely to the direction of movement of the control system. The width of the poles in the direction of movement of the control system corresponds to the width of a pole step.

According to a preferred embodiment of the invention, the intermediate elements, the intermediate element branches of which each have a different one of the n predetermined fixed distances, alternate in the direction of movement of the control system. This ensures that a selection magnet acts longer on an intermediate element branch and thus on an intermediate element and therefore at high working speeds. reliable selection of work elements.

According to a particularly advantageous embodiment of the invention, the intermediate elements have a main branch opposite the permanent magnetic pole and a secondary branch opposite the selection magnetic pole.

A particularly advantageous embodiment of the invention consists in the control system having at least two control areas spaced apart in the direction of movement. This makes it possible to further optimize the control, in particular of the selector magnets, namely by spatially and temporally successively solving control processes, seen in the direction of movement, which do not interfere with one another due to the temporal and spatial separation.

The features according to the invention can be used advantageously in particular if the textile machine is a circular or flat knitting machine.

The working elements are advantageously actuating elements which act on the stitch-forming tools, for example the needles. For example, circuit boards can be used as actuating elements.

According to a particularly advantageous embodiment of the invention, the intermediate elements are arranged in an intermediate element bed made of non-magnetic material. The intermediate element bed made of non-magnetic material magnetically isolates the intermediate elements from one another. It is also possible to manufacture the intermediate element bed with the intermediate elements as a component independently of the rest of the textile machine and to note them down thereafter. It is particularly advantageous if the intermediate element bed is attached to a needle bed in the area of the control system.

The intermediate elements are preferably pressed into openings in the intermediate element bed. This ensures a secure, stationary position of the intermediate elements, while at the same time reducing the manufacturing effort.

According to one embodiment of the textile machine according to the invention, in the area of the surfaces of the intermediate elements facing the working elements, a groove is provided along the needle bed which prevents the transfer of the lines of force of the magnetic flow from the intermediate elements to the needle bed. The groove increases the distance and thus the air space in the area of the working elements between these and the needle bed, so that a large magnetic resistance is achieved.

In one embodiment of the invention in connection with a flat knitting machine, at least one longitudinal side of the intermediate element bed is dovetail-shaped, and the intermediate element bed is inserted in a corresponding, complementarily shaped groove of the needle bed. This ensures simple use and the removal of the intermediate element bed on the actual needle bed.

Instead of providing the intermediate elements in an intermediate element bed, it is advantageous according to an alternative embodiment of the invention if the intermediate elements are arranged in webs made of non-magnetizable material. The webs are individually attached to the needle bed in the area of the control system. At least one side of the webs preferably has a dovetail shape which can be used in a correspondingly complementarily shaped groove in the needle bed. In this way, the individual webs are securely guided, locked and held on the needle bed in a defined position. The webs are preferably arranged side by side on the needle bed. The width of the webs preferably corresponds to the mesh size.

It is particularly advantageous if the webs have projections which lie in corresponding grooves in the needle bed. This enables an even more secure, more defined position of the webs in the needle bed.

A particularly advantageous embodiment of the invention is that the needle region which the actuating element engages is elastic. Depending on the selection made by the control system, the needles or needle regions are preferably moved individually into and out of the needle channels by the control system.

The actuating elements are preferably subjected to a magnetic force in both operating positions, that is to say in the rest position and in the working position, so that an electromagnetic pulling force always acts on the actuating element, regardless of which of the two stable positions the actuating element is in. In this way, the actuating element and thus the needle position are in a defined position regardless of the working or rest position.

The needle channel area in which the actuating element engages the needle is preferably deeper than in a front or rear needle channel area. This creates space in the needle channel for the immersion of the needle region to be controlled. At the same time, the front result and / or the rear needle channel region each have a needle support or pivot point.

A part of the rear needle region can preferably be shaped as a leaf spring for elastic formation. The needle channel can have three different needle channel heights.

The actuating element preferably protrudes into the needle channel, and the actuating element has a groove or a hole for receiving the needle and for displacing it in the direction of needle ejection or withdrawal. In this way, it is possible for the actuating element to bring the respective needle into or out of the switching function perpendicular to the needle bed, and at the same time the needle can be moved in the direction of expulsion or withdrawal.

When using an actuating element, the webs are preferably designed as bearing segments for the actuating elements.

The invention is explained in more detail below with reference to the drawings, for example. Show it:

Figure 1: An embodiment of the arrangement according to the invention using the example of a flat knitting machine in a partial, schematic representation as a cross section; Figure 2: The arrangement shown in Figure 1 in schematic supervision;

FIG. 3: the arrangement shown in FIGS. 1 and 2 in a cross section corresponding to cross section line II shown in FIG. 2, FIG. 4: an equivalent circuit diagram for the magnetic circuit arrangements of the embodiment shown in FIGS. 1-3; FIG. 5: an alternative embodiment of the invention in connection with a flat knitting machine as a schematic longitudinal section through the needle bed; FIG. 6: an enlarged, schematic representation of the exemplary embodiment according to the invention in plan view or in the direction of arrow II shown in FIG. 5; 7 shows a schematic cross section through the arrangement according to the invention along the section line III drawn in FIG. 6; 8 shows an enlarged illustration of FIG. 5 with further details and as a cross section along the section line IV-IV shown in FIG

Figure 9a: A schematic plan view of the Zwischenele¬ elements and the selector magnet to explain the operation of the arrangement according to the invention;

FIG. 9b: a schematic circuit diagram of the selection magnet to explain the mode of operation of the arrangement according to the invention;

FIG. 10a: A schematic top view of intermediate elements and the selection magnet to explain an alternative mode of operation of the device according to the invention and

Figure 10b: a schematic circuit diagram for further explanation of the arrangement shown in Figure 10a.

Figures 1, 2 and 3 each show a preferred embodiment of the invention in different forms of representation. A control system 20 is located above a needle bed 1 with needle channels 3 and webs 2 between them. Boards 5 form the working elements.

An intermediate element bed 10 consists of a magnetically non-conductive material, the longitudinal edges of which have a dovetail shape and are inserted or inserted into a correspondingly formed groove in the needle bed of the same length.

The intermediate element bed 10 has grooves 13, in which intermediate elements 14 to 17 are pressed. The intermediate elements 14 to 17 consist of magnetically conductive material and, due to the intermediate element bed 10, which consists of non-magnetic material, are magnetically insulated from one another and from the needle bed.

The intermediate elements 14 to 17 protrude through the intermediate element actuator 10 onto the underside thereof, on which a selection board located in the needle channel 2 rests with its upper edge or surface in the area of the intermediate elements 14 to 17.

In order that good magnetic insulation of the intermediate elements 14 to 17 with respect to the needle bed 1 is also achieved in this area, a groove 4 is provided which extends over the length of the needle bed and the distance between the intermediate elements 14 to 17 or the outer surfaces thereof facing the selection board 5, on the one hand, and the needle bed 1 on the other hand are enlarged.

In each groove 13 of the intermediate element bed 10 there are two intermediate elements symmetrical to the central axis of the intermediate element bed 10, as can best be seen from FIGS. 1 and 2. The respective intermediate elements 14 to 17 have intermediate element secondary branches 14a, 15a, 16a and 17a, which relate in the needle output direction.

REPLACEMENT LEAF lent the main branch are spaced differently. The main part is always transverse to the direction of movement of the control system 20 at the same distance from the intermediate element bed center axis. The intermediate element-side branches 14a, 15a, 16a, 17a are therefore in each case the intermediate elements 14 to 17 in adjacent Zwischen¬ elementenuten 13 in a ^'different distance from its main branches, in this example in two Ab¬ stands transverse to the direction of movement of Control system 20. Thus, in the present exemplary embodiment, there are two levels of intermediate element secondary branches transverse to the direction of movement of the control system 20.

The electromagnetic control system 20 moves in the direction indicated by an arrow S or in its opposite direction over the intermediate element bed 10 at a distance? away, so that the control system 20 is not in mechanical contact with the intermediate element bed 10 when it is being moved.

Along the control system 20 there is a permanent magnet 21 with soft iron poles 23, 24 which face the exit surfaces of the main branches of the intermediate elements 14 to 17.

Furthermore, two 2 selection areas A and B (see FIGS. 1 and 2) are provided next to one another in the direction of movement of the control system 20, the selection magnets with associated coils 31 to 34 and 51 to 54 and corresponding ferromagnetic cores 24 to 27 and 55 to 58, the pole faces of which are facing or assigned to the intermediate element bed 10 or the intermediate elements 14 to 17, as will be explained further below.

In each selection area A, B there are two selection magnets in accordance with the two secondary branches 14a and 15a on the one hand and provided at different levels

REPLACEMENT LEAF - 17 -

16a and 17a on the other hand. In the present exemplary embodiment, two levels are provided, so that there are accordingly two selection magnets. Of course, it is also possible to provide more than two levels of the secondary or control branches, which require a corresponding number of selection magnets.

Each selection magnet has two excitation coils 31 to 34, the windings of which are connected in series, so that the magnetic fluxes of the excitation coils 31 to 34 add up. The magnetic resistance of the core can be changed with screws 28, 29.

There is an insulation material 44, 45 between the permanent magnet 21 and the selection magnet, which at the same time also serves as a bearing for the selection magnet. The control system 20 is accommodated in a housing which is formed by the side elements 41 to 44 and the cover 40.

When the control system 20 moves over the intermediate element bed 10, the constant magnetic current generated by the permanent magnet 21 closes via the magnetic pole 22, the respective main branches of the intermediate elements 14 to 17, the selection board 5, which consists of a magnetically conductive material, and the other pole 23. As a result, the selection board 5 is pulled upward against a spring force Fdir (cf. FIG. 1) to the underside of the intermediate element bed 10 and held in this position by the intermediate elements 14 to 17. The selection boards 5 are therefore in the starting position for the selection process. The permanent magnet is selected so that the magnetic force induced by it in the intermediate elements 14 to 17 exceeds or at least compensates for the spring force of the trigger spring.

Reaches a selection area A or B - depending on the direction of movement of the control system - one to be selected

HE ^SAT ZBLATT Intermediate element 14 to 17 assigned to the selection board 5, the magnetic flux of the excitation coils 31 to 34 or 51 to 54 of the selection magnets acts on the secondary branches 14a, 15a, 16a or 17a. If a specific selection board is to be selected, "at the time during which one of the selection areas A or B is located above the selection board 5 to be selected, ^{" are} excited by a current being sent through the corresponding selection magnets. The magnetic flux thus created in the intermediate element 14 to 17 is opposite to that of the permanent 21 and makes it substantially zero or at least so small that the pulling force of the intermediate element 14 to 17 for the selection board 5 drops below the pulling force of the pulling spring, so that the selection board 5 is pulled off.

If a specific selection board 5 is not to be selected, no current is sent through the excitation coils 31 to 34 or 51 to 54 of the selection magnet when the selection system is passed over, so that the magnetic flux of the permanent magnet 21 is located in the intermediate elements 14 to 17 and in the selection board 5 not downsized; the selection board remains in its initial position and adheres to the surfaces of the intermediate elements 14 to 17 facing the selection board 5.

FIG. 4 shows an equivalent circuit diagram of the magnetic fluxes and forces occurring in the arrangement according to the invention. The permanent magnet 21 represents an electromagnetic voltage source Fm and the electromagnet of the selection magnet represents at least one electromotive magnetic source Fe, each of which creates a parallel connection. The two magnetic sources each generate a magnetic flux <m or e. The magnetic resistors Rmh, which corresponds to the magnetic resistance of the selection board 5, are connected at their ends via the magnetic resistors Rlm and Rle. The magnetic flux ψ m of the permanent magnet Fm or 21 runs in the direction indicated by an arrow,

REPLACEMENT LEAF gene the magnetic flux φ e of the selection magnet can change its amount from 0 to its nominal value and also its direction.

If © e is zero, i.e. if the excitation coils 31 to 34 or 51 to 54 are not supplied with current, only the magnetic flux © m of the permanent magnet Fm or 21 occurs. This divides into a magnetic flux that flows through the selection board 5 or Rmh and into a magnetic flux that passes through the core of the selection magnet Fe. Since the magnetic resistance of the selection magnetic core, which is formed by the variable resistance Rmv of the core and by the resistance Rle of the air gap, is significantly greater than the magnetic resistance Rmh of the selection board 5, the magnetic flux © ml in the selection board also becomes 5 can be considerably larger than the magnetic flux γ> me which flows through the selection magnetic core. This means that most of the magnetic flux flows in the selection board 5 and the magnetic flux G-> ml through the selection board 5 depends on the value of the magnet resistance of the air gap and the main branch Rlm.

When the coils of the selection magnet are excited with the control current, a magnetic flux © e is formed in the direction indicated in FIG. 4: arrow direction in series with the current flow direction jό m of the permanent magnet Fm or 21. If the size of this magnetic flux f £ ) e is essentially equal in its absolute value to the magnetic flux © m of the permanent magnet Fm or 21, el becomes essentially equal to O ml, but with an opposite sign, so that the magnetic feet are not passed through the selection board 5, ie the magnetic resistance Rmh, but flow through the magnetic sources Fm and Fe, where they form the magnetic fluxes me and 0 em, respectively, and the poles are oriented in such a way that they support mutual flow.

REPLACEMENT LEAF A further advantageous embodiment is explained below with reference to FIGS. 5 to 10. Details and parts which correspond to those of the exemplary embodiment shown in FIGS. 1 to 5 are provided with the same reference numerals as in FIGS. 1 to 4 and are not explained again.

There is a needle 60 in each of the needle channels 2 of the needle bed 1. The needle channels have three different levels (62, 63, and 63a, 69), as can best be seen from FIG. 5. This leaves the needle

Press 60 into needle channel 2.

The needle 60 is designed in the front part up to the needle foot 60a in the usual manner and with a bar

61 held in the needle channel 2. From the needle foot 60a, the needle merges into a rear part 60d, a region 60e of the needle 1 being designed as a leaf spring.

When the needle 60 is in its normal position, in which no force is exerted on it, it rests with its front part on the needle bed part 62 and with the elastic rear part 60e on the needle bed part 63a.

If a force is now exerted on the needle 60 perpendicular to the plane of the needle bed, for example by an actuating element 64, the needle 60 together with the needle foot 60a is pressed into the needle channel 2, the points of contact of the needle 60 on the aforementioned Needle bed areas 62 and 63a are located. When the needle 60 is pressed down into the needle channel 2, the elastic part of the needle 60e is elastically deformed. When the force acting on the needle is released, the needle 60 returns to its original position under the action of the elastic member 60e, i.e. in their working position, in which their needle foot 60a can be gripped by a lock part. If the needle 60 is extended with a lock part which acts on the needle foot 60a,

REPLACEMENT LEAF is driven, the knee 60c of the needle 60 slides to the level or the area 63 in the needle channel 2, so that the needle can no longer be pressed further down into the needle channel 2, but remains in its working position.

In the needle bed 1 there are 20 webs in the form of bearing segments 65 in the area of the control system, which are made of magnetizable material. The bearing segments 65 have dovetail-shaped side edges which lie in correspondingly complementarily shaped grooves in the needle bed 1. The thickness of a segment is 1 / E where E is the machine or mesh size in inches. The segments are pushed one next to the other into the corresponding groove in the needle bed 1. An edge 65a of the bearing segment 65 engages in the needle channel 2 (cf. FIG. 7) and centers each individual segment. Then the individual bearing segments 65 are fixed in their position in the needle bed 1 with a strip 66 and the screws 67 and 68 (cf. FIG. 6).

Grooves are provided on one side of the bearing segments 65, in which a pair of intermediate elements 70, 71 made of magnetically conductive material and an actuating element 64 are inserted. The width of the grooves seen in the direction of movement of the control system 20 is substantially equal to the width d of the intermediate elements 70 or 71, while the remaining part of the width of the bearing segment 65 is the distance e from the adjacent intermediate elements 70, 71 or Bearing segment 65 represents (see FIG. 9). The sum of the distances d and e is the total width of the intermediate elements and is 1 / E. The ratio between the sizes d and e should be chosen so that the thickness or thickness of the intermediate elements 70, 71 can be chosen to be as large as possible because of the largest possible surface area of an anchor part 64a of the actuating element 64. The distance e between neighboring

REPLACEMENT LEAF bartender intermediate elements 70, 71 should be so large that no leakage occurs between the adjacent intermediate elements 70, 71. The thickness or width of the actuating element 64 is preferably somewhat smaller than the width of the intermediate elements 70, 71 so that the actuating element 64 can slide easily in the bearing segment 65.

When the armature part 64a of the actuating element 64 bears against pole faces 70c and 71c of the intermediate elements 70 and 71, the actuating element 64 is in the working position. If, on the other hand, the armature part 64a lies against the pole faces 70b and 71b of the intermediate elements 70 and 71, the actuating element 64 is in the rest position.

In the part of the actuating element 64 protruding into the needle channel 2 of the needle bed there is a groove 64b, through which the region 60d of the needle 60 passes. Due to the groove 64b, the thickness or width of the actuating element 64 is increased to the value 1 / E and the needle channel 2 is widened in the area of the actuating element 64 by the groove 72, which extends over the entire length of the needle bed 1. This creates space for the actuation elements 64 so that they have space for pressing down (cf. FIG. 7).

The magnet control system 20 has a permanent magnet 74, the permanent magnet poles 75 of which first extend in the longitudinal direction, ie in the direction of movement of the magnet control system 20. Furthermore, each selection range A and B has a selection magnet 77 and 78, each with two excitation coils 79, 80 and 81, 82. All together is housed in a housing, which consists of the two elements 83, 84, the upper cover 85 and lower separating elements 86,87,88, the latter also serving as a bearing for the selection magnet. The parts of the housing mentioned are made of non-magnetizable material. The magnetic force lines of flux of the permanent magnet 74 ver. run from the permanent magnet pole 75 through an air slot f into the side surface 70a of the intermediate element 70 and further through the armature part 64a irrespective of the stable positions of the actuating element 64 and back over the side surface 71a through the in the opposite permanent magnet pole 76 of the permanent magnet 74.

The pulling forces in the between the intermediate elements 70 and the permanent magnet poles 75 and 76 of the permanent magnet 74 occur in the bearing segments t. and compensated on the housing of the magnetic control system 20 and do not transfer further to the other machine parts. Before a selection range A or B reaches the respective actuating element 64, they are moved into the rest position against a spring force with a conically illustrated cam, which is part of the separating element 76 when the control system 20 is in the position indicated by an arrow S indicated direction of movement moves.

In selection ranges A and B, the permanent magnets 74, slots 90, 91 and 92, 93 are left free on the permanent magnet poles 75, 76, so that the magnetic flux formed by the permanent magnet 74 in the intermediate elements 70 and 71 and the armature part is located at this point 74a is interrupted. Poles of the selection magnet 94 and 95 are provided in this area, the magnetic fluxes of which are provided by air protection. - act on the pole faces 70d or 71d of the intermediate elements 70 or.

The effect of the selection magnets 94 and 95 on the intermediate elements 70 and 71 can be seen from FIG. 9. The width of the slot x at the permanent magnet poles 75 and 76 of the permanent magnet 74 is 1 / E, where E is the mesh size, or this width of the slot x is equal to the sum of the distances d and e. The width of the poles

ER ^S ATZBLATT the selection magnet 94 or 95 corresponds essentially to this width of the slot x.

As can be seen from FIG. 9b, when the control system 20 moves in the direction of movement indicated by the arrow S, the selection range A or B is in the position I above the intermediate element 70 or 71, corresponding to a knitting pattern or the present program should be selected and for which the magnetic flux should therefore be interrupted since the preceding intermediate element 70 or 71 is in state 1. Magnetic flux is not interrupted by the preceding intermediate element 70 or 71, because the current through the excitation coils 79-82 of the selector magnet 94, 95 is interrupted when the selector magnet is in position 1, i.e. when the poles 75, 76 of the permanent magnet 74 cover the actuating elements 70 and 71 in state 1. If the magnetic flux of the selection magnet 94, 95 is interrupted, the magnetic flux is interrupted by the intermediate elements 70 and 71, which are then in state 0. This state continues up to the movement position II, when the control system 20 thus moves one step, i.e. by the distance x / 3, i.e. moved further by the distance e. Since the next intermediate element 70 or 71 is to be in state 1, the magnetic flux of the selection magnet 94, 95 must be generated again, which will replace the magnetic flux of the permanent magnet 74 in the slots 90 and 91. The selector magnet 94, 95 is then in the state 1 up to the movement position VII, in which it then changes to the state 0, since the next intermediate element 70 or 71 is to be in the state 0. The same takes place when a selection magnet comes to a selection point at which a needle to be knitted is to be selected, in the worst case when a needle is in the working position and the other needle is in the switched-off state between positions I and II Is in the rest position, the magnetic flux between positions I and II being

ER ^S ATZBLATT Kera 64a is interrupted and the spring brings the actuating element 64 back into the working position.

In the event that the interruption of the magnetic flux through the armature part 64a is too short, so that there is not enough time for the spring to move the actuating element 64 into the working position, since the magnetic flux of the permanent magnet 74 becomes active again too early, can occur on one Selection point can be provided several selector magnets. This exemplary embodiment is explained below with reference to FIG. 10a.

A selector has two selector magnets 94a and 94b with slots 90 and 91 on the permanent magnet poles 75 and 76 of the permanent magnet 74. The width of the slots 90 and 91 is y = d + 2e, whereas the width of the poles of the electromagnet is y / 2.

FIG. 10b shows the effect of the selection magnets 94a and 94b when the control system 20 moves in the direction of movement indicated by the movement arrow S, in the worst case when a needle is selected, namely when one needle is in the working position and the other needle is not in the working position located. It can be seen directly from FIG. 10b that the selection magnets 94a and 94b act successively on the individual intermediate elements 70 and 71 and in this way maintain the magnetic flux through the armature part 64a and the intermediate elements 70 and 71 or is interrupted. In this embodiment, there is no good overlap between the intermediate elements 70 or 71, because the width of the selection magnet poles is greater than the width e; however, a larger width of the selection area is achieved. As a further possibility, a plurality of selection magnets on two levels 94a and 94b, i.e. be arranged on two areas at different distances from the actuating element 64, so that

REPLACEMENT LEAF the width of the selection area can be selected depending on the existing requirements and conditions.

In the case of the exemplary embodiments described with reference to FIGS. 5 to 10, the essence of the invention therefore lies in the fact that each knitting needle is assigned an actuating element 64. This actuating element 64 can be displaced perpendicularly to the needle bed plane and can be in one of the two stable positions, namely the so-called working position and the rest position, which is dependent on the magnetic state of the intermediate elements 70 and 71, respectively. Due to its armature part 64a, the actuating element 64 is designed in such a way that the magnetic source is evenly loaded and an electromagnetic pulling force acts on it irrespective of which of the two stable positions the actuating element 64 is in. In the rear area 60d, the needle 60 is connected directly to the actuating element 64, so that when the actuating element 64 is displaced vertically, the entire needle rotates about your support point, which is located in the comb area of the needle bed. When the actuating element 64 is in the rest position, the needle foot 60a is pressed into the needle channel 2 and can therefore not be caught by lock parts. The needle 60 is therefore "switched off". In contrast, when the actuating element 64 is in the working position, the needle foot 60a projects beyond the needle bed surface; The needle 60 is therefore in the working position and can be gripped by lock parts.

In the area in which the needle is selected, there is a slot on the permanent magnet poles 76 and 76 of the permanent magnet 74, so that the magnetic flux of the permanent magnet 74 to the intermediate elements 70 and 71 is interrupted at this point. In this area, the selector magnet is arranged on the control system 20, which also acts on the intermediate elements 70 and 71 and whose magnetic poles have the same width as the width of the slots on the permanent magnet poles 75 and 76 of the permanent magnet 74. However, there is no direct magnetic connection between the permanent magnet 74 and the selection magnets 94 and 95, respectively, between the permanent magnet 74 and the selection magnet independently of one another on the intermediate elements 70 and 71. Since only the magnetic flux of the selection magnet 94 and 95 act on the intermediate elements 70 and 71 in the selection range, the magnetic state of the intermediate elements 70 and 71 depends only on the magnetic flux generated by the selection magnet 94 and 95. Become the excitation coils

79, 80, 81, 82 excited by a control current, the magnetic flux generated thereby, which flows through the intermediate elements 70 and 71 and the armature part 64a, compensates the actuating element 64, the magnetic flux of the permanent magnet 74 interrupted in this area. In this case the magnetic flux that penetrates the armature part 64a is not interrupted. On the other hand, if the excitation coils 79,

80, 81, 82 not supplied with current, the magnetic flux flowing through the armature part 64a is interrupted and that

Armature part 64a and thus the actuating element 64 released by the then non-existing electromagnetic pulling force.

According to a particularly advantageous embodiment of the invention, in particular when higher mesh fineness and working speeds of the textile machine are required, instead of just one selection magnet, a plurality of selection magnets can be provided at a selection point, which successively act on an intermediate element 70 or 71 ken. In this way, the selection range is widened, so that the selection system in the selection range can maintain the desired magnetic state of an intermediate element or of an intermediate element pair for a sufficiently long time even at high speeds.

REPLACEMENT LEAF If several selection magnets are provided, their poles are alternately at two distances from the actuating element 64 transversely to the direction of movement of the control system 20, ie at two levels. This means that every second pole is at the same level. Therefore, the width of the intermediate elements 70 and 71 at the point at which the poles of the selection magnets 94a and 94b act must be equal to or greater than twice the width of the selection magnet poles, whereas the width of the slots on the permanent magnet poles 75 and 76 of the The number and the width of the poles of the selection magnets can be selected in different ways depending on which steps of the covering of the intermediate elements 70 or 71 by the selection magnet poles is desired.

The intermediate elements 70 and 71 have two parallel branches which are connected with a transverse branch. They serve to direct the magnetic flux from the control system 20 to the actuating elements 64 and therefore consist of soft iron with low magnetic resistance. The actuating elements 64 are preferably made of steel and have the shape of a cross, the horizontal part forming the anchor part 64a. The armature part 64a limits the movements of the actuating element 64 between the two stable positions, wherein it touches one or the other parallel branch of the intermediate elements 70 and 71, respectively. The vertical part of the actuator 64 guides it as it moves.

As already stated, the rear region of the needle 60 is elastic and is designed as a leaf spring, so that the needle 60 together with the actuating element 64 is in its normal state in the working position, i.e. the needle foot 60a can be gripped by lock parts. Under the needle foot is a knee 60c which rests on an edge 63 in the needle channel 2 when the needle 60 is

^ERS ATZBLATT is driven. The needle channel 2 thus has three different channel depths or levels, namely the levels 62, 63 and 63a and 69. The knee 60c lies on the level 63 when the needle 60 is driven out, so that it is avoided that the needle flow 60a can be pressed into the needle channel 2.

Due to the very advantageous configuration of the actuating element 64 and the intermediate elements 70 and 71 in the exemplary embodiment shown in FIGS. 5 to 10, it is ensured that the actuating element 64 is held in a stable position in both switching positions. This is achieved in that the intermediate elements 70 and 71, on the one hand, and the actuating element with the anchor part 64a, on the other hand, are shaped in the manner already described in such a way that an electromagnetic attraction force acts on the anchor part 64a and thus on the actuating element 64 in both positions. If the actuating element 64 has been brought into the rest position mechanically, the selector element is held in this position until the magnetic flux is interrupted by the armature part 64a, so that the spring force can bring the actuating element 64 back into the working position. If, on the other hand, the actuating element 64 is in the working position, the spring force is supported by the electromagnetic force and hold the armature part 64a in the working position. This total force resulting from the spring force and the electromagnetic force must be greater than the forces which occur when the needle feet of the lock parts are gripped so that individual needles are not accidentally and unintentionally pressed into the needle channel 2 and an unwanted "jumping" of needles occurs. Furthermore, the load on the magnetic source is constant and does not depend on how many of the actuating elements 64 are in the working position or in the rest position, since approximately the same flow flows through the armature part 64a in both positions. As has already been stated, all the actuating elements 64 must be brought into the rest position with the aid of a mechanical element, which can be attached between the permanent magnet poles 75 and 76 of the permanent magnet 74, before the selection process takes place. Since the 'electromagnetic pull-off force acts on the armature part 64a in the same direction as the spring force, in multi-system flat knitting machines which operate in both directions of movement of the slide, the action of the electromagnetic force must be canceled immediately before the actuating element 64 is switched, so that the Actuating required force is reduced and thus frictional forces are kept as low as possible. The selection area must therefore be provided at the beginning of the lock or - in the case of multi-system locks - on both sides. When the direction of movement is opposite, the magnetic flux is compensated by the armature part 64a so that an easier switching is possible. With the carriage moving in the opposite direction, the needles 60 provided for the knitting process are then selected.

All actuating elements 64, which were brought into the starting position with the aid of lock parts, remain in this position due to the action of the pulling force of the magnetic flux of the permanent magnet 74 up to the selection range, at which the magnetic flux through the armature part 64a - if desired - for a short time. interrupted and thus the electromagnetic pull force is canceled. As a result, the actuating element 64 and thus the needle 60 come into the working position due to the action of spring force. The interruption of the magnetic flux must, however, last for a sufficiently long time so that the armature part 64a can be pulled away from the poles of the intermediate elements 70 and 71 by the spring action and not because of the magnetic flux of the permanent magnet 74 which occurs again in the Rest position remains. If the magnetic flux is not interrupted the actuating element 64 and thus the needle 60 remains in the rest position. After the selection range has moved over the respective intermediate element 70 or 71, the magnetic flux is restored by the permanent magnet 74, which fixes the armature part 64a of the actuating element 64 in the switch position as long as the magnetic flux flows through the armature part 64a.

The invention has been described using preferred examples. However, modifications and configurations are possible for the person skilled in the art, or that the inventive concept is thereby abandoned.

Claims

Claims

1. Textile machine, in particular knitting machine with controllable working elements and an electromagnetic control system, which exerts a controlled magnetic force on the working elements, characterized in that stationary intermediate elements (14 to 17; 70, 71) made of ferromagnetic material in solid Position between the working elements (5; 64) and the Steuer¬ system (20) are provided.

2. Textile machine according to claim 1, characterized in that the intermediate elements (14 to 17; 70, 71) are magnetically insulated from one another.

3. Textile machine according to claim 1 or 2, characterized gekenn¬ characterized in that the control system (20) on the Ar¬ beitselemente (5; 64) facing away from the outer surfaces of the intermediate elements (14 to 17; 70,71) is contactlessly movable.

4. Textile machine according to one of the preceding claims, characterized in that the control system (20) has at least one controllable selection magnet (31-34, 51-54, 55-58; 94, 95) which has at least one intermediate element ( 14 to 17, 70, 71) with a controllable magnetic force flow.

5. Textile machine according to one of the preceding Ansprü¬ surface, characterized in that the control system (20) has a permanent magnet (21, 74) which acts on at least one intermediate element (14 to 17; 70, 71) with a constant magnetic force flow .

6. Textile machine according to one of the preceding Ansprü¬ surface, characterized in that the magnetic Force flow of the permanent magnet (21; 74) is selected so large that the working elements (5; 64) magnetically adhere to the intermediate elements (14 to 17; 70, 71) against a spring force.

7. Textile machine according to one of the preceding Ansprü¬ che, characterized in that derm selector magnet (31- 34, 51-54, 55-58; 94, 95) optionally generates a magnetic force flow that generated by the permanent magnet (21; 74) magnetic force flow is the same or opposite.

8. Textile machine according to one of the preceding Ansprü¬ surface, characterized in that the selection magnet (31- 34, 51-54, 55-58; 94, 95) when selecting a working element (5; 64) in the area of the associated Intermediate element generates a magnetic force flow which essentially corresponds in its strength to the magnetic force flow generated by the permanent magnet (21; 74) in the intermediate element (14 to 17; 70, 71), but is directed in the opposite direction.

9. Textile machine according to one of the preceding claims, characterized in that the surfaces of the intermediate elements (14 to 17, 70, 71) facing the working elements (5; 64) correspond in terms of surface shape and size substantially to the surfaces , with which the working elements (5; 64) rest on the intermediate elements (14 to 17; 70, 71).

10. Textile machine according to one of the preceding Ansprü¬ che, characterized in that the width of the intermediate elements (14 to 17, 70, 71) are substantially equal to the width of the working elements (5; 64).

11. Textile machine according to one of the preceding Ansprü¬ surface, characterized in that the selection magnet (31-

REPLACEMENT LEAF 34, 51-54, 55-58; 94, 95) is an electromagnet with at least one excitation coil through which a controlled current flows.

12. Textile machine according to one of the preceding claims, characterized in that the pole faces of the selection magnet (31-34, 51-54, 55-58; 94, 95) with respect to the shape and size of the surface essentially match the control system (20th ) correspond to facing outer surfaces of the intermediate elements (14 to 17, 70, 71).

13. Textile machine according to one of the preceding claims, characterized in that the width of the selection magnet (31-34, 51-54, 55-58; 94, 95) seen in the direction of movement of the control system (20) is smaller than the sum of the width of the intermediate elements (14 to 17, 70, 71) seen in the direction of movement (S) of the control system (20) and the distance provided between two intermediate elements (14 to 17, 70, 71).

14. Textile machine according to one of the preceding claims, characterized in that an arrangement (28; 29) for changing the position of a magnetic core (24 to 27, 55 to 58; 94.95) of the selection magnet (31-34, 51-54, 55-58; 94, 95) is provided.

15. Textile machine according to one of the preceding claims, characterized in that the intermediate elements (14 to 17, 70, 71) have at least two intermediate element branches (14a, 15a, 16a, 17a) which are transverse to the direction of movement (S) of the Control system (20) have spaced outer surfaces facing the control system (20).

16. Textile machine according to one of the preceding claims, characterized in that at least one intermediate element branch (14a, 15a, 16a, 17a) with one of Permanent magnets (21) of the control system (20) generated constant magnetic force flow, and at least one further intermediate element branch (14a, 15a, 16a, 17a) with the selection magnet (31-34, 51-54, 55-58; 94, 95) generated controllable magnetic flux is applied.

17. Textile machine according to one of the preceding Ansprü¬ che, characterized in that n predetermined, fixed distances between the control system (20) facing outer surfaces of the intermediate element branches (14a, Iδa, 16a, 17a) perpendicular to the direction of movement (S) of the control system (20) are provided, and that the control system has n permanent and / or selection magnetic poles at corresponding n predetermined, fixed distances perpendicular to the direction of movement of the control system (20), n being a natural number.

18. Textile machine according to one of the preceding claims, characterized in that the intermediate elements (14 to 17, 70, 71), whose intermediate element branches (14a, 15a, 16a, 17a) each have a different one of the "predetermined, have fixed distances, alternate in the direction of movement (S) of the control system (20).

19. Textile machine according to one of the preceding claims, characterized in that the intermediate elements (14 to 17, 70, 71) have a main branch opposite the permanent magnet pole and a secondary branch (14a, 15a, 16a, 17a) opposite the selector magnet pole. exhibit.

20. Textile machine according to one of the preceding claims, characterized in that the control system (20) has at least two control areas (A, B) spaced apart in the direction of movement (S). 21. Textile machine according to one of the preceding Ansprü¬ surface, characterized in that the textile machine is a circular or flat knitting machine.

22. Textile machine according to one of the preceding claims, characterized in that the working elements (5; 64) are blanks (5) (FIGS. 1 to 4).

22. Textile machine according to one of the preceding claims, characterized in that the working elements (5; 64) are actuating elements (64) which act on needles (60) (FIGS. 5 to 10).

24. Textile machine according to one of the preceding claims, characterized in that the intermediate elements (14 to 17; 70, 71) are arranged in an intermediate element bed made of non-magnetic material.

25. Textile machine according to one of the preceding claims, characterized in that the intermediate element bed (10) is attached to a needle bed (1) in the region of the control system (20).

26. Textile machine according to one of the preceding claims, characterized in that the intermediate elements (14 to 17, 70, 71) are pressed into the opening in the intermediate element bed (10).

27. Textile machine according to one of the preceding claims, characterized in that a groove is provided along the needle bed (1) in the area of the surfaces of the intermediate elements (14 to 17; 70, 71) assigned to the working elements (5; 64) , which prevents the transfer of the lines of force of the magnetic flux from the intermediate elements (14 to 17, 70, 71) to the needle bed (1). 28. Textile machine according to one of the preceding claims, characterized in that, in the case of a flat knitting machine, at least one longitudinal side of the intermediate element bed is dovetail-shaped and the intermediate element bed (10) is inserted in a correspondingly shaped groove of the needle bed (1) .

29. Textile machine according to one of claims 1 to 23, characterized in that the intermediate elements (14 to 17, 70, 71) are arranged in webs made of non-magnetizable material.

30. Textile machine according to one of claims 1 to 23 and 29, characterized in that the webs in the area of the control system (20) are attached to the needle bed (1).

31. Textile machine according to one of claims 1 to 23, 29 and 30, characterized in that at least one side of the webs has a dovetail shape that is insertable into a complementarily shaped groove er ^* speaking of the needle bed (1).

32. Textile machine according to one of claims 1 to 23, 29 to 31, characterized in that the webs are arranged side by side on the needle bed (1).

33. Textile machine according to one of claims 1 to 23, 29 to 32, characterized in that the width of the webs corresponds to the mesh size E.

34. Textile machine according to one of claims 1 to 23, 29 to 33, characterized in that the webs have projections which lie in corresponding grooves in the needle bed (1).

ER ^S ATZBLATT 35. Textile machine according to one of claims 1 to 23, 29 to 34, characterized in that the needle region on which the actuating element engages is elastic.

36. Textile machine according to one of claims 1 to 23, 29 to 35, characterized in that the needles (60) or needle areas (60d) by the actuating elements (64) are moved individually into and out of the needle channel (2).

37. Textile machine according to one of claims 1 to 23, 29 to 36, characterized in that the Nadelkanalbe¬ area (69) in which the actuating element (64) acts on the needle, deeper than the front and / or rear needle channel area ( 62, 63, 63a).

38. Textile machine according to one of claims 1 to 23, 29 to 37, characterized in that the actuating devices (64) protrude into the needle channel (2) and a groove (64b) for the displacement of the needle (60) in the needle output or deduction direction.

39. Textile machine according to one of claims 1 to 23, 29 to 38, characterized in that the webs are designed as bearing segments (65) for the actuating elements (64).

40. Textile machine according to one of claims 1 to 23, 29 to 39, characterized in that the actuating elements (64) in the rest and in the working position are acted upon by a magnetic force.