EP0607565A2 - Magnet system for a selection block on textile machines - Google Patents

Abstract

For a magnet system for a selection block on textile machines, it is proposed to design the armature of the magnet system directly as a control flap for the needle selection. It is proposed, furthermore, to assemble the selection block from two half-shells, in which the magnet systems are respectively arranged at a double-pitch spacing, the magnet systems of the two half-shells being offset relative to one another, so that the spacing of the control flaps of the selection block corresponds to the single pitch spacing after assembly. <IMAGE>

Description

The invention relates to a magnet system for a selection block in textile machines, in particular a bistable magnet system for the selection of needles, wherein magnetically actuatable control flaps are provided for the selection of the needle associated with the magnet system, and a selection block with such magnet systems.

In modern knitting machines (circular knitting and flat knitting machines), magnet systems are provided for the selection of the needles, which are generally combined in so-called selection blocks. In order to knit a certain knitting pattern, certain knitting needles have to be selected at a time and other needles simply not. The selection means are controlled electronically in modern knitting machines; this is then referred to as electronic needle selection.

The desired pattern is stored in an electronic memory and is read out when the textile part is knitted, and the needles are selected accordingly via the interface of the selection block.

There are energy converters in the selection block, which convert the electrical control signal into a mechanical change in position of the control flaps required for needle selection, which protrude from the selection block. The selection blocks are generally provided with a number of control flaps, each control flap serving a selection level. Each control flap is provided with a control cam that interacts with needle or circuit board feet. The control flap can assume two positions, namely the "basic position" non-selection and the "working position" selection.

In the 'non-select' position, the board feet run past the control flaps and are not touched. If a control flap is moved to the 'Select' position, the associated sinker foot runs on the control cam and is pressed in the direction of the knitting cylinder or needle bed. The change in position of the plate in this way mechanically creates the prerequisite for lifting (selecting) the corresponding needle from the 'non-knitting' position to the 'knitting' or 'catching' position.

Small electric magnets are preferably used in the selection block to drive and position the control flaps in the two positions.

Such a selection block is known from EP-O 219 029-B1.

When using small electrical magnets, which are used as independent magnet systems in the selection block, however, only relatively large distances between the control flaps arranged side by side or one above the other can be realized. Thus, in the known system, no flap distances (pitch distances) significantly smaller than 5 mm can be realized. Finally, the electromagnetic performance of the drive magnets (force, changeover time, power loss, service life) required for the application also depends on the volume of the electromagnet. When minimizing the volume of an optimally dimensioned electromagnet, one quickly reaches a lower limit, which can no longer be undershot, and the volume of the selection block is therefore practically predetermined for a certain number of selection levels and for a certain pitch distance and cannot more can be easily reduced.

In the known selection block there are two bearing points for each drive system, namely a bearing point of the magnet armature and a bearing point of the respective control flap, in each of which friction losses occur. An additional friction point is the connection point between the magnet armature and the respective control flap, in which friction losses occur in each case. The necessary play in the bearing points and the connection point also results in a not inconsiderable bouncing of the control flaps when they reach their end positions. This bouncing has a greater impact the higher the working speed / cycle frequency of the knitting machine.

In addition, the known system is made up of a large number of small magnets, individual parts and assemblies to be specially adjusted, which make assembly of the selection block complex and cost-intensive.

The invention is therefore based on the object of designing a magnet system of the type mentioned in such a way that the required drive power is reduced and the volume can thus be reduced. A simple and inexpensive assembly and a reduction of the pitch distance in the case of magnet systems arranged in the vicinity should also be achieved.

This object is achieved in that the armature of the magnet system is formed in one piece directly as a control flap.

Further advantageous embodiments of the invention are explained in more detail in claims 2 to 5.

The advantages achieved by the invention are, in particular, that the loss of friction of the magnet system is decisively reduced by the elimination of a bearing point and the connection point between the magnet armature and control flap, which means that, for example, a lower drive power is required to actuate the respective control flap. This means that the volume of the magnet system can ultimately be reduced, which in turn means smaller pitch Distances can be realized.

In addition, the magnet system according to the invention also has less wear and thus an increased service life.

In addition, due to the reduction in the number of bearings / connection points, there is also less bouncing of the control flaps, so that the magnet system can be operated at higher clock frequencies.

Finally, a simple construction of the magnet system or a complete selection block also reduces the assembly costs.

• Fig. 1 A,B,C die Ansichten eines Selektions- blockes,
• Fig. 2 die Ansicht des Selektionsblokkes gem. Fig. 1 im Schnitt entlang der Linie 2-2,
• Fig. 3 die Ansicht eines geöffneten Selektions-Blockes,
• Fig. 4 die perspektivische Ansicht eines geöffneten Selektionsblokkes,
• Fig. 5 A,B die Ansichten einer Steuerklappe,
• Fig. 6 A,B die Ansichten einer modifizierten Steuerklappe, und
• Fig. 7 die Ansicht eines Spulenkörpers mit eingefügtem Magnetkern.

An embodiment of the invention is shown in the drawing and will be described in more detail below. Show it

• 1A, B, C are views of a selection block,
• Fig. 2 shows the view of the selection block according. 1 in section along the line 2-2,
• 3 shows the view of an open selection block,
• 4 is a perspective view of an open selection block,
• 5 A, B are views of a control valve,
• Fig. 6 A, B the views of a modified control valve, and
• Fig. 7 is the view of a bobbin with inserted magnetic core.

1A, B, C, a selection block 1 for a textile machine is shown in different views. The selection block essentially consists of a cuboid housing in which a plurality of magnet systems are arranged, each of which influences control flaps 2 for controlling the needles of the textile machine.

In the illustration of FIG. 1A, the control flaps protrude on the left side of the selection block. On the opposite side, the selection block is provided with a connector 3, via which the electrical signals for actuating / controlling the individual magnet systems are carried.

The control flaps can each be moved into two different positions, the second possible position being indicated in dashed lines in the illustration of the lower control flap. The front edge of the control flap covers a distance of approx. 2 mm.

The adjacent control flaps 2 are arranged at a pitch distance P of approximately 5 mm, it being mentioned here that even smaller distances are easily possible.

The selection block 1 essentially consists of two half-shells 4, 5, in which magnet systems 6 are inserted. FIG. 2 shows a section through the selection block, and FIG. 3 shows a view of the half shell 4 with the magnet systems used. 4, a half-shell is shown in perspective view in which only one of the magnet systems is used.

The magnet systems 6 essentially consist of a coil former 8 provided with an iron core 7, onto which an excitation winding 9 is wound. The magnet systems are positively inserted into corresponding recesses in the half-shell, the lower end of the core being connected in a magnetically conductive manner to the half-shell, which consists of magnetically conductive material. In the front area of the magnet system, lateral pole pieces 11 are formed in the half shell, which also serve as a stop for the movement of the control flap 2.

The control flap, which is shown enlarged in FIGS. 5 A, B, is rotatably mounted on an axis 12 and its end facing the end face 13 of the iron core 7 of the magnet system is provided with a permanent magnet 14.

The direction of polarization of this permanent magnet extends transversely to the end face of the iron core 7. Due to the action of the permanent magnet, the end of the control flap provided with the permanent magnet, which is arranged between the two pole pieces 11, is first pulled against one of the two pole pieces and remains there due to permanent magnetic adhesion . By energizing the excitation winding of the magnet system with a correspondingly directed current, the permanent magnetic adhesion to this pole piece is eliminated and the end of the control flap provided with the permanent magnet is repelled by the adjacent pole piece and attracted by the other pole piece, where it is again again after the excitation current has been switched off remains permanently magnetically adherent. The front end of the control flap, which is provided with control surfaces 15 for controlling the needles, was moved from a first position to a second position.

The control flap 2 shown in FIGS. 5 A, B is made as a stamped and bent part made of steel. It is provided with a cranked bearing area 16 for receiving the axis 12 and an angled area 17 on which the control surfaces 15 are formed. The opposite area of the control flap is provided with an overmoldable contour with undercut 18 and bore 19, to which a plastic part 20 is molded. The plastic part is provided with a recess into which a permanent magnet is inserted and added is increasing.

6 A, B shows a modified control flap 2 '. Here, a base body 21 made of plastic material by injection molding is provided, which contains the plastic part 20 'with the recess for receiving the permanent magnet, as well as the bearing area 16'. At the front end of the base body a steel part 22 is inserted (molded), which is provided with the control surfaces 15 for controlling the needles of the knitting machine.

7 shows a sectional illustration of the coil body 8 with the iron core 7 of the magnet system. The coil body is injection molded from plastic material and is provided with molded locking tongues 23 and centering means 24 which, when the coil body / magnet system is inserted into the recesses in the half shell, lock behind corresponding locking shoulders and hold the magnet system positioned in the half shell.

The magnet systems are used in the half shells at a mutual distance of 2 P. The magnet systems of one half shell are then offset by the pitch distance P from the magnet systems of the other half shell, so that when the two half shells are joined together, the control flaps have the pitch distance P as a whole. This arrangement makes it possible to provide the magnetic systems of a half-shell viewed at twice the distance as the pitch distance P ultimately achieved, which results in volume advantages for each magnet system.

Claims (5)

1. Magnet system for a selection block in textile machines, in particular bistable magnet system for needle selection, wherein magnetically operable control flaps are provided for the selection of the needle assigned to the magnet system, characterized in that the armature of the magnet system (6) is made in one piece as a control flap (2, 2 ') is trained. 2. Magnet system according to claim 1, characterized in that the magnet system (6) has an elongated magnetic core (7) provided with an excitation winding (9), that in front of the end face (13) of the magnetic core (7) a rotatably mounted, elongated control valve (2, 2 ') or control armature extending essentially in the axial direction of the magnetic core axis is arranged, the end face of which faces the magnetic core with a permanent magnet (14) is provided, the direction of polarization of which extends transversely to the end face (13) or to the magnetic core axis, and that a pole piece (11) is provided on both sides of the magnetic core and the control flap magnet area, which extends in front of the end of the magnetic core and the permanent magnet area of the control flap and is soft-magnetically conductively connected or is integral with the bottom of a half-shell housing, so that for the Return flow of the control flow is a closed soft magnetic inference via the soft magnetic housing shell to the other (rear) core side. 3. Selection block with magnet systems arranged in a housing according to claim 1 or 2, characterized in that
that the housing is designed as a half-shell, and that the magnet systems of the half-shell are functional on their own. 4. Selection block with magnet systems arranged in a housing according to claim 1 or 2, characterized in that
that the housing consists of two half-shells (4, 5), each partial shell containing spaced drive groups which alternately plunge between the drive groups of the other partial shell when the partial shells are joined together. 5. Selection block according to one of the preceding claims, characterized in that
that the housing is made of magnetically conductive material.

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